Your search keyword '"Kaushal, GP"' showing total 99 results

1. Perinatal Outcome in Overweight Women: An Audit

Author

Malik, Neeru, primary, Sharma, Neeraj, additional, Kaushal, GP, additional, Lochan, Dakshika, additional, Jain, Sandhya, additional, Ghotiya, Manju, additional, and Madaan, Nikita, additional

Published

2023

2. Guidelines for the use and interpretation of assays for monitoring autophagy (4th edition)

Author

Klionsky, DJ, Abdel-Aziz, AK, Abdelfatah, S, Abdellatif, M, Abdoli, A, Abel, S, Abeliovich, H, Abildgaard, MH, Abudu, YP, Acevedo-Arozena, A, Adamopoulos, IE, Adeli, K, Adolph, TE, Adornetto, A, Aflaki, E, Agam, G, Agarwal, A, Aggarwal, BB, Agnello, M, Agostinis, P, Agrewala, JN, Agrotis, A, Aguilar, PV, Ahmad, ST, Ahmed, ZM, Ahumada-Castro, U, Aits, S, Aizawa, S, Akkoc, Y, Akoumianaki, T, Akpinar, HA, Al-Abd, AM, Al-Akra, L, Al-Gharaibeh, A, Alaoui-Jamali, MA, Alberti, S, Alcocer-Gómez, E, Alessandri, C, Ali, M, Alim Al-Bari, MA, Aliwaini, S, Alizadeh, J, Almacellas, E, Almasan, A, Alonso, A, Alonso, GD, Altan-Bonnet, N, Altieri, DC, Álvarez, ÉMC, Alves, S, Alves da Costa, C, Alzaharna, MM, Amadio, M, Amantini, C, Amaral, C, Ambrosio, S, Amer, AO, Ammanathan, V, An, Z, Andersen, SU, Andrabi, SA, Andrade-Silva, M, Andres, AM, Angelini, S, Ann, D, Anozie, UC, Ansari, MY, Antas, P, Antebi, A, Antón, Z, Anwar, T, Apetoh, L, Apostolova, N, Araki, T, Araki, Y, Arasaki, K, Araújo, WL, Araya, J, Arden, C, Arévalo, M-A, Arguelles, S, Arias, E, Arikkath, J, Arimoto, H, Ariosa, AR, Armstrong-James, D, Arnauné-Pelloquin, L, Aroca, A, Arroyo, DS, Arsov, I, Artero, R, Asaro, DML, Aschner, M, Ashrafizadeh, M, Ashur-Fabian, O, Atanasov, AG, Au, AK, Auberger, P, Auner, HW, Aurelian, L, Autelli, R, Avagliano, L, Ávalos, Y, Aveic, S, Aveleira, CA, Avin-Wittenberg, T, Aydin, Y, Ayton, S, Ayyadevara, S, Azzopardi, M, Baba, M, Backer, JM, Backues, SK, Bae, D-H, Bae, O-N, Bae, SH, Baehrecke, EH, Baek, A, Baek, S-H, Baek, SH, Bagetta, G, Bagniewska-Zadworna, A, Bai, H, Bai, J, Bai, X, Bai, Y, Bairagi, N, Baksi, S, Balbi, T, Baldari, CT, Balduini, W, Ballabio, A, Ballester, M, Balazadeh, S, Balzan, R, Bandopadhyay, R, Banerjee, S, Bánréti, Á, Bao, Y, Baptista, MS, Baracca, A, Barbati, C, Bargiela, A, Barilà, D, Barlow, PG, Barmada, SJ, Barreiro, E, Barreto, GE, Bartek, J, Bartel, B, Bartolome, A, Barve, GR, Basagoudanavar, SH, Bassham, DC, Bast, RC, Basu, A, Batoko, H, Batten, I, Baulieu, EE, Baumgarner, BL, Bayry, J, Beale, R, Beau, I, Beaumatin, F, Bechara, LRG, Beck, GR, Beers, MF, Begun, J, Behrends, C, Behrens, GMN, Bei, R, Bejarano, E, Bel, S, Behl, C, Belaid, A, Belgareh-Touzé, N, Bellarosa, C, Belleudi, F, Belló Pérez, M, Bello-Morales, R, Beltran, JSDO, Beltran, S, Benbrook, DM, Bendorius, M, Benitez, BA, Benito-Cuesta, I, Bensalem, J, Berchtold, MW, Berezowska, S, Bergamaschi, D, Bergami, M, Bergmann, A, Berliocchi, L, Berlioz-Torrent, C, Bernard, A, Berthoux, L, Besirli, CG, Besteiro, S, Betin, VM, Beyaert, R, Bezbradica, JS, Bhaskar, K, Bhatia-Kissova, I, Bhattacharya, R, Bhattacharya, S, Bhattacharyya, S, Bhuiyan, MS, Bhutia, SK, Bi, L, Bi, X, Biden, TJ, Bijian, K, Billes, VA, Binart, N, Bincoletto, C, Birgisdottir, AB, Bjorkoy, G, Blanco, G, Blas-Garcia, A, Blasiak, J, Blomgran, R, Blomgren, K, Blum, JS, Boada-Romero, E, Boban, M, Boesze-Battaglia, K, Boeuf, P, Boland, B, Bomont, P, Bonaldo, P, Bonam, SR, Bonfili, L, Bonifacino, JS, Boone, BA, Bootman, MD, Bordi, M, Borner, C, Bornhauser, BC, Borthakur, G, Bosch, J, Bose, S, Botana, LM, Botas, J, Boulanger, CM, Boulton, ME, Bourdenx, M, Bourgeois, B, Bourke, NM, Bousquet, G, Boya, P, Bozhkov, PV, Bozi, LHM, Bozkurt, TO, Brackney, DE, Brandts, CH, Braun, RJ, Braus, GH, Bravo-Sagua, R, Bravo-San Pedro, JM, Brest, P, Bringer, M-A, Briones-Herrera, A, Broaddus, VC, Brodersen, P, Brodsky, JL, Brody, SL, Bronson, PG, Bronstein, JM, Brown, CN, Brown, RE, Brum, PC, Brumell, JH, Brunetti-Pierri, N, Bruno, D, Bryson-Richardson, RJ, Bucci, C, Buchrieser, C, Bueno, M, Buitrago-Molina, LE, Buraschi, S, Buch, S, Buchan, JR, Buckingham, EM, Budak, H, Budini, M, Bultynck, G, Burada, F, Burgoyne, JR, Burón, MI, Bustos, V, Büttner, S, Butturini, E, Byrd, A, Cabas, I, Cabrera-Benitez, S, Cadwell, K, Cai, J, Cai, L, Cai, Q, Cairó, M, Calbet, JA, Caldwell, GA, Caldwell, KA, Call, JA, Calvani, R, Calvo, AC, Calvo-Rubio Barrera, M, Camara, NO, Camonis, JH, Camougrand, N, Campanella, M, Campbell, EM, Campbell-Valois, F-X, Campello, S, Campesi, I, Campos, JC, Camuzard, O, Cancino, J, Candido de Almeida, D, Canesi, L, Caniggia, I, Canonico, B, Cantí, C, Cao, B, Caraglia, M, Caramés, B, Carchman, EH, Cardenal-Muñoz, E, Cardenas, C, Cardenas, L, Cardoso, SM, Carew, JS, Carle, GF, Carleton, G, Carloni, S, Carmona-Gutierrez, D, Carneiro, LA, Carnevali, O, Carosi, JM, Carra, S, Carrier, A, Carrier, L, Carroll, B, Carter, AB, Carvalho, AN, Casanova, M, Casas, C, Casas, J, Cassioli, C, Castillo, EF, Castillo, K, Castillo-Lluva, S, Castoldi, F, Castori, M, Castro, AF, Castro-Caldas, M, Castro-Hernandez, J, Castro-Obregon, S, Catz, SD, Cavadas, C, Cavaliere, F, Cavallini, G, Cavinato, M, Cayuela, ML, Cebollada Rica, P, Cecarini, V, Cecconi, F, Cechowska-Pasko, M, Cenci, S, Ceperuelo-Mallafré, V, Cerqueira, JJ, Cerutti, JM, Cervia, D, Cetintas, VB, Cetrullo, S, Chae, H-J, Chagin, AS, Chai, C-Y, Chakrabarti, G, Chakrabarti, O, Chakraborty, T, Chami, M, Chamilos, G, Chan, DW, Chan, EYW, Chan, ED, Chan, HYE, Chan, HH, Chan, H, Chan, MTV, Chan, YS, Chandra, PK, Chang, C-P, Chang, C, Chang, H-C, Chang, K, Chao, J, Chapman, T, Charlet-Berguerand, N, Chatterjee, S, Chaube, SK, Chaudhary, A, Chauhan, S, Chaum, E, Checler, F, Cheetham, ME, Chen, C-S, Chen, G-C, Chen, J-F, Chen, LL, Chen, L, Chen, M, Chen, M-K, Chen, N, Chen, Q, Chen, R-H, Chen, S, Chen, W, Chen, X-M, Chen, X-W, Chen, X, Chen, Y, Chen, Y-G, Chen, Y-J, Chen, Y-Q, Chen, ZS, Chen, Z, Chen, Z-H, Chen, ZJ, Cheng, H, Cheng, J, Cheng, S-Y, Cheng, W, Cheng, X, Cheng, X-T, Cheng, Y, Cheng, Z, Cheong, H, Cheong, JK, Chernyak, BV, Cherry, S, Cheung, CFR, Cheung, CHA, Cheung, K-H, Chevet, E, Chi, RJ, Chiang, AKS, Chiaradonna, F, Chiarelli, R, Chiariello, M, Chica, N, Chiocca, S, Chiong, M, Chiou, S-H, Chiramel, AI, Chiurchiù, V, Cho, D-H, Choe, S-K, Choi, AMK, Choi, ME, Choudhury, KR, Chow, NS, Chu, CT, Chua, JP, Chua, JJE, Chung, H, Chung, KP, Chung, S, Chung, S-H, Chung, Y-L, Cianfanelli, V, Ciechomska, IA, Cifuentes, M, Cinque, L, Cirak, S, Cirone, M, Clague, MJ, Clarke, R, Clementi, E, Coccia, EM, Codogno, P, Cohen, E, Cohen, MM, Colasanti, T, Colasuonno, F, Colbert, RA, Colell, A, Čolić, M, Coll, NS, Collins, MO, Colombo, MI, Colón-Ramos, DA, Combaret, L, Comincini, S, Cominetti, MR, Consiglio, A, Conte, A, Conti, F, Contu, VR, Cookson, MR, Coombs, KM, Coppens, I, Corasaniti, MT, Corkery, DP, Cordes, N, Cortese, K, Costa, MDC, Costantino, S, Costelli, P, Coto-Montes, A, Crack, PJ, Crespo, JL, Criollo, A, Crippa, V, Cristofani, R, Csizmadia, T, Cuadrado, A, Cui, B, Cui, J, Cui, Y, Culetto, E, Cumino, AC, Cybulsky, AV, Czaja, MJ, Czuczwar, SJ, D'Adamo, S, D'Amelio, M, D'Arcangelo, D, D'Lugos, AC, D'Orazi, G, da Silva, JA, Dafsari, HS, Dagda, RK, Dagdas, Y, Daglia, M, Dai, X, Dai, Y, Dal Col, J, Dalhaimer, P, Dalla Valle, L, Dallenga, T, Dalmasso, G, Damme, M, Dando, I, Dantuma, NP, Darling, AL, Das, H, Dasarathy, S, Dasari, SK, Dash, S, Daumke, O, Dauphinee, AN, Davies, JS, Dávila, VA, Davis, RJ, Davis, T, Dayalan Naidu, S, De Amicis, F, De Bosscher, K, De Felice, F, De Franceschi, L, De Leonibus, C, de Mattos Barbosa, MG, De Meyer, GRY, De Milito, A, De Nunzio, C, De Palma, C, De Santi, M, De Virgilio, C, De Zio, D, Debnath, J, DeBosch, BJ, Decuypere, J-P, Deehan, MA, Deflorian, G, DeGregori, J, Dehay, B, Del Rio, G, Delaney, JR, Delbridge, LMD, Delorme-Axford, E, Delpino, MV, Demarchi, F, Dembitz, V, Demers, ND, Deng, H, Deng, Z, Dengjel, J, Dent, P, Denton, D, DePamphilis, ML, Der, CJ, Deretic, V, Descoteaux, A, Devis, L, Devkota, S, Devuyst, O, Dewson, G, Dharmasivam, M, Dhiman, R, di Bernardo, D, Di Cristina, M, Di Domenico, F, Di Fazio, P, Di Fonzo, A, Di Guardo, G, Di Guglielmo, GM, Di Leo, L, Di Malta, C, Di Nardo, A, Di Rienzo, M, Di Sano, F, Diallinas, G, Diao, J, Diaz-Araya, G, Díaz-Laviada, I, Dickinson, JM, Diederich, M, Dieudé, M, Dikic, I, Ding, S, Ding, W-X, Dini, L, Dinić, J, Dinic, M, Dinkova-Kostova, AT, Dionne, MS, Distler, JHW, Diwan, A, Dixon, IMC, Djavaheri-Mergny, M, Dobrinski, I, Dobrovinskaya, O, Dobrowolski, R, Dobson, RCJ, Đokić, J, Dokmeci Emre, S, Donadelli, M, Dong, B, Dong, X, Dong, Z, Dorn Ii, GW, Dotsch, V, Dou, H, Dou, J, Dowaidar, M, Dridi, S, Drucker, L, Du, A, Du, C, Du, G, Du, H-N, Du, L-L, du Toit, A, Duan, S-B, Duan, X, Duarte, SP, Dubrovska, A, Dunlop, EA, Dupont, N, Durán, RV, Dwarakanath, BS, Dyshlovoy, SA, Ebrahimi-Fakhari, D, Eckhart, L, Edelstein, CL, Efferth, T, Eftekharpour, E, Eichinger, L, Eid, N, Eisenberg, T, Eissa, NT, Eissa, S, Ejarque, M, El Andaloussi, A, El-Hage, N, El-Naggar, S, Eleuteri, AM, El-Shafey, ES, Elgendy, M, Eliopoulos, AG, Elizalde, MM, Elks, PM, Elsasser, H-P, Elsherbiny, ES, Emerling, BM, Emre, NCT, Eng, CH, Engedal, N, Engelbrecht, A-M, Engelsen, AST, Enserink, JM, Escalante, R, Esclatine, A, Escobar-Henriques, M, Eskelinen, E-L, Espert, L, Eusebio, M-O, Fabrias, G, Fabrizi, C, Facchiano, A, Facchiano, F, Fadeel, B, Fader, C, Faesen, AC, Fairlie, WD, Falcó, A, Falkenburger, BH, Fan, D, Fan, J, Fan, Y, Fang, EF, Fang, Y, Fanto, M, Farfel-Becker, T, Faure, M, Fazeli, G, Fedele, AO, Feldman, AM, Feng, D, Feng, J, Feng, L, Feng, Y, Feng, W, Fenz Araujo, T, Ferguson, TA, Fernández, ÁF, Fernandez-Checa, JC, Fernández-Veledo, S, Fernie, AR, Ferrante, AW, Ferraresi, A, Ferrari, MF, Ferreira, JCB, Ferro-Novick, S, Figueras, A, Filadi, R, Filigheddu, N, Filippi-Chiela, E, Filomeni, G, Fimia, GM, Fineschi, V, Finetti, F, Finkbeiner, S, Fisher, EA, Fisher, PB, Flamigni, F, Fliesler, SJ, Flo, TH, Florance, I, Florey, O, Florio, T, Fodor, E, Follo, C, Fon, EA, Forlino, A, Fornai, F, Fortini, P, Fracassi, A, Fraldi, A, Franco, B, Franco, R, Franconi, F, Frankel, LB, Friedman, SL, Fröhlich, LF, Frühbeck, G, Fuentes, JM, Fujiki, Y, Fujita, N, Fujiwara, Y, Fukuda, M, Fulda, S, Furic, L, Furuya, N, Fusco, C, Gack, MU, Gaffke, L, Galadari, S, Galasso, A, Galindo, MF, Gallolu Kankanamalage, S, Galluzzi, L, Galy, V, Gammoh, N, Gan, B, Ganley, IG, Gao, F, Gao, H, Gao, M, Gao, P, Gao, S-J, Gao, W, Gao, X, Garcera, A, Garcia, MN, Garcia, VE, García-Del Portillo, F, Garcia-Escudero, V, Garcia-Garcia, A, Garcia-Macia, M, García-Moreno, D, Garcia-Ruiz, C, García-Sanz, P, Garg, AD, Gargini, R, Garofalo, T, Garry, RF, Gassen, NC, Gatica, D, Ge, L, Ge, W, Geiss-Friedlander, R, Gelfi, C, Genschik, P, Gentle, IE, Gerbino, V, Gerhardt, C, Germain, K, Germain, M, Gewirtz, DA, Ghasemipour Afshar, E, Ghavami, S, Ghigo, A, Ghosh, M, Giamas, G, Giampietri, C, Giatromanolaki, A, Gibson, GE, Gibson, SB, Ginet, V, Giniger, E, Giorgi, C, Girao, H, Girardin, SE, Giridharan, M, Giuliano, S, Giulivi, C, Giuriato, S, Giustiniani, J, Gluschko, A, Goder, V, Goginashvili, A, Golab, J, Goldstone, DC, Golebiewska, A, Gomes, LR, Gomez, R, Gómez-Sánchez, R, Gomez-Puerto, MC, Gomez-Sintes, R, Gong, Q, Goni, FM, González-Gallego, J, Gonzalez-Hernandez, T, Gonzalez-Polo, RA, Gonzalez-Reyes, JA, González-Rodríguez, P, Goping, IS, Gorbatyuk, MS, Gorbunov, NV, Görgülü, K, Gorojod, RM, Gorski, SM, Goruppi, S, Gotor, C, Gottlieb, RA, Gozes, I, Gozuacik, D, Graef, M, Gräler, MH, Granatiero, V, Grasso, D, Gray, JP, Green, DR, Greenhough, A, Gregory, SL, Griffin, EF, Grinstaff, MW, Gros, F, Grose, C, Gross, AS, Gruber, F, Grumati, P, Grune, T, Gu, X, Guan, J-L, Guardia, CM, Guda, K, Guerra, F, Guerri, C, Guha, P, Guillén, C, Gujar, S, Gukovskaya, A, Gukovsky, I, Gunst, J, Günther, A, Guntur, AR, Guo, C, Guo, H, Guo, L-W, Guo, M, Gupta, P, Gupta, SK, Gupta, S, Gupta, VB, Gupta, V, Gustafsson, AB, Gutterman, DD, H B, R, Haapasalo, A, Haber, JE, Hać, A, Hadano, S, Hafrén, AJ, Haidar, M, Hall, BS, Halldén, G, Hamacher-Brady, A, Hamann, A, Hamasaki, M, Han, W, Hansen, M, Hanson, PI, Hao, Z, Harada, M, Harhaji-Trajkovic, L, Hariharan, N, Haroon, N, Harris, J, Hasegawa, T, Hasima Nagoor, N, Haspel, JA, Haucke, V, Hawkins, WD, Hay, BA, Haynes, CM, Hayrabedyan, SB, Hays, TS, He, C, He, Q, He, R-R, He, Y-W, He, Y-Y, Heakal, Y, Heberle, AM, Hejtmancik, JF, Helgason, GV, Henkel, V, Herb, M, Hergovich, A, Herman-Antosiewicz, A, Hernández, A, Hernandez, C, Hernandez-Diaz, S, Hernandez-Gea, V, Herpin, A, Herreros, J, Hervás, JH, Hesselson, D, Hetz, C, Heussler, VT, Higuchi, Y, Hilfiker, S, Hill, JA, Hlavacek, WS, Ho, EA, Ho, IHT, Ho, PW-L, Ho, S-L, Ho, WY, Hobbs, GA, Hochstrasser, M, Hoet, PHM, Hofius, D, Hofman, P, Höhn, A, Holmberg, CI, Hombrebueno, JR, Yi-Ren Hong, C-WH, Hooper, LV, Hoppe, T, Horos, R, Hoshida, Y, Hsin, I-L, Hsu, H-Y, Hu, B, Hu, D, Hu, L-F, Hu, MC, Hu, R, Hu, W, Hu, Y-C, Hu, Z-W, Hua, F, Hua, J, Hua, Y, Huan, C, Huang, C, Huang, H, Huang, K, Huang, MLH, Huang, R, Huang, S, Huang, T, Huang, X, Huang, YJ, Huber, TB, Hubert, V, Hubner, CA, Hughes, SM, Hughes, WE, Humbert, M, Hummer, G, Hurley, JH, Hussain, S, Hussey, PJ, Hutabarat, M, Hwang, H-Y, Hwang, S, Ieni, A, Ikeda, F, Imagawa, Y, Imai, Y, Imbriano, C, Imoto, M, Inman, DM, Inoki, K, Iovanna, J, Iozzo, RV, Ippolito, G, Irazoqui, JE, Iribarren, P, Ishaq, M, Ishikawa, M, Ishimwe, N, Isidoro, C, Ismail, N, Issazadeh-Navikas, S, Itakura, E, Ito, D, Ivankovic, D, Ivanova, S, Iyer, AKV, Izquierdo, JM, Izumi, M, Jäättelä, M, Jabir, MS, Jackson, WT, Jacobo-Herrera, N, Jacomin, A-C, Jacquin, E, Jadiya, P, Jaeschke, H, Jagannath, C, Jakobi, AJ, Jakobsson, J, Janji, B, Jansen-Dürr, P, Jansson, PJ, Jantsch, J, Januszewski, S, Jassey, A, Jean, S, Jeltsch-David, H, Jendelova, P, Jenny, A, Jensen, TE, Jessen, N, Jewell, JL, Ji, J, Jia, L, Jia, R, Jiang, L, Jiang, Q, Jiang, R, Jiang, T, Jiang, X, Jiang, Y, Jimenez-Sanchez, M, Jin, E-J, Jin, F, Jin, H, Jin, L, Jin, M, Jin, S, Jo, E-K, Joffre, C, Johansen, T, Johnson, GVW, Johnston, SA, Jokitalo, E, Jolly, MK, Joosten, LAB, Jordan, J, Joseph, B, Ju, D, Ju, J-S, Ju, J, Juárez, E, Judith, D, Juhász, G, Jun, Y, Jung, CH, Jung, S-C, Jung, YK, Jungbluth, H, Jungverdorben, J, Just, S, Kaarniranta, K, Kaasik, A, Kabuta, T, Kaganovich, D, Kahana, A, Kain, R, Kajimura, S, Kalamvoki, M, Kalia, M, Kalinowski, DS, Kaludercic, N, Kalvari, I, Kaminska, J, Kaminskyy, VO, Kanamori, H, Kanasaki, K, Kang, C, Kang, R, Kang, SS, Kaniyappan, S, Kanki, T, Kanneganti, T-D, Kanthasamy, AG, Kanthasamy, A, Kantorow, M, Kapuy, O, Karamouzis, MV, Karim, MR, Karmakar, P, Katare, RG, Kato, M, Kaufmann, SHE, Kauppinen, A, Kaushal, GP, Kaushik, S, Kawasaki, K, Kazan, K, Ke, P-Y, Keating, DJ, Keber, U, Kehrl, JH, Keller, KE, Keller, CW, Kemper, JK, Kenific, CM, Kepp, O, Kermorgant, S, Kern, A, Ketteler, R, Keulers, TG, Khalfin, B, Khalil, H, Khambu, B, Khan, SY, Khandelwal, VKM, Khandia, R, Kho, W, Khobrekar, NV, Khuansuwan, S, Khundadze, M, Killackey, SA, Kim, D, Kim, DR, Kim, D-H, Kim, D-E, Kim, EY, Kim, E-K, Kim, H-R, Kim, H-S, Hyung-Ryong Kim, Kim, JH, Kim, JK, Kim, J-H, Kim, J, Kim, KI, Kim, PK, Kim, S-J, Kimball, SR, Kimchi, A, Kimmelman, AC, Kimura, T, King, MA, Kinghorn, KJ, Kinsey, CG, Kirkin, V, Kirshenbaum, LA, Kiselev, SL, Kishi, S, Kitamoto, K, Kitaoka, Y, Kitazato, K, Kitsis, RN, Kittler, JT, Kjaerulff, O, Klein, PS, Klopstock, T, Klucken, J, Knævelsrud, H, Knorr, RL, Ko, BCB, Ko, F, Ko, J-L, Kobayashi, H, Kobayashi, S, Koch, I, Koch, JC, Koenig, U, Kögel, D, Koh, YH, Koike, M, Kohlwein, SD, Kocaturk, NM, Komatsu, M, König, J, Kono, T, Kopp, BT, Korcsmaros, T, Korkmaz, G, Korolchuk, VI, Korsnes, MS, Koskela, A, Kota, J, Kotake, Y, Kotler, ML, Kou, Y, Koukourakis, MI, Koustas, E, Kovacs, AL, Kovács, T, Koya, D, Kozako, T, Kraft, C, Krainc, D, Krämer, H, Krasnodembskaya, AD, Kretz-Remy, C, Kroemer, G, Ktistakis, NT, Kuchitsu, K, Kuenen, S, Kuerschner, L, Kukar, T, Kumar, A, Kumar, D, Kumar, S, Kume, S, Kumsta, C, Kundu, CN, Kundu, M, Kunnumakkara, AB, Kurgan, L, Kutateladze, TG, Kutlu, O, Kwak, S, Kwon, HJ, Kwon, TK, Kwon, YT, Kyrmizi, I, La Spada, A, Labonté, P, Ladoire, S, Laface, I, Lafont, F, Lagace, DC, Lahiri, V, Lai, Z, Laird, AS, Lakkaraju, A, Lamark, T, Lan, S-H, Landajuela, A, Lane, DJR, Lane, JD, Lang, CH, Lange, C, Langel, Ü, Langer, R, Lapaquette, P, Laporte, J, LaRusso, NF, Lastres-Becker, I, Lau, WCY, Laurie, 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Y, Oshima, S, Rong, Y, Sluimer, JC, Stallings, CL, and Tong, C-K

Abstract

In 2008, we published the first set of guidelines for standardizing research in autophagy. Since then, this topic has received increasing attention, and many scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Thus, it is important to formulate on a regular basis updated guidelines for monitoring autophagy in different organisms. Despite numerous reviews, there continues to be confusion regarding acceptable methods to evaluate autophagy, especially in multicellular eukaryotes. Here, we present a set of guidelines for investigators to select and interpret methods to examine autophagy and related processes, and for reviewers to provide realistic and reasonable critiques of reports that are focused on these processes. These guidelines are not meant to be a dogmatic set of rules, because the appropriateness of any assay largely depends on the question being asked and the system being used. Moreover, no individual assay is perfect for every situation, calling for the use of multiple techniques to properly monitor autophagy in each experimental setting. Finally, several core components of the autophagy machinery have been implicated in distinct autophagic processes (canonical and noncanonical autophagy), implying that genetic approaches to block autophagy should rely on targeting two or more autophagy-related genes that ideally participate in distinct steps of the pathway. Along similar lines, because multiple proteins involved in autophagy also regulate other cellular pathways including apoptosis, not all of them can be used as a specific marker for bona fide autophagic responses. Here, we critically discuss current methods of assessing autophagy and the information they can, or cannot, provide. Our ultimate goal is to encourage intellectual and technical innovation in the field.

Published

2021

3. Prevalence and Clinical Correlates of COVID-19 Outbreak Among Health Care Workers in a Tertiary Level Hospital in Delhi

Author

Khurana, Ankit, primary, Kaushal, GP, additional, Gupta, Rishi, additional, Verma, Vansh, additional, Sharma, Kabir, additional, and Kohli, PM, additional

Published

2021

4. Prevalence and clinical correlates of COVID-19 outbreak among health care workers in a tertiary level hospital in Delhi

Author

Khurana, Ankit, primary, Kaushal, GP, additional, Gupta, Rishi, additional, Verma, Vansh, additional, Sharma, Kabir, additional, and Kohli, Manmohan, additional

Published

2020

5. Guidelines for the use and interpretation of assays for monitoring autophagy.

Author

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Paris, I, Park, J, Park, Ok, Parys, Jb, Parzych, Kr, Patschan, S, Patterson, C, Pattingre, S, Pawelek, Jm, Peng, J, Perlmutter, Dh, Perrotta, I, Perry, G, Pervaiz, S, Peter, M, Peters, Gj, Petersen, M, Petrovski, G, Phang, Jm, Piacentini, M, Pierre, P, Pierrefite-Carle, V, Pierron, G, Pinkas-Kramarski, R, Piras, A, Piri, N, Platanias, Lc, Pöggeler, S, Poirot, M, Poletti, A, Poüs, C, Pozuelo-Rubio, M, Prætorius-Ibba, M, Prasad, A, Prescott, M, Priault, M, Produit-Zengaffinen, N, Progulske-Fox, A, Proikas-Cezanne, T, Przedborski, S, Przyklenk, K, Puertollano, R, Puyal, J, Qian, Sb, Qin, L, Qin, Zh, Quaggin, Se, Raben, N, Rabinowich, H, Rabkin, Sw, Rahman, I, Rami, A, Ramm, G, Randall, G, Randow, F, Rao, Va, Rathmell, Jc, Ravikumar, B, Ray, Sk, Reed, Bh, Reed, Jc, Reggiori, F, Régnier-Vigouroux, A, Reichert, A, Reiners JJ, Jr, Reiter, Rj, Ren, J, Revuelta, Jl, Rhodes, Cj, Ritis, K, Rizzo, E, Robbins, J, Roberge, M, Roca, H, Roccheri, Mc, Rocchi, S, Rodemann, Hp, Rodríguez de Córdoba, S, Rohrer, B, Roninson, Ib, Rosen, K, Rost-Roszkowska, Mm, Rouis, M, Rouschop, Km, Rovetta, F, Rubin, Bp, Rubinsztein, Dc, Ruckdeschel, K, Rucker EB, 3rd, Rudich, A, Rudolf, E, Ruiz-Opazo, N, Russo, R, Rusten, Te, Ryan, Km, Ryter, Sw, Sabatini, Dm, Sadoshima, J, Saha, T, Saitoh, T, Sakagami, H, Sakai, Y, Salekdeh, Gh, Salomoni, P, Salvaterra, Pm, Salvesen, G, Salvioli, R, Sanchez, Am, Sánchez-Alcázar, Ja, Sánchez-Prieto, R, Sandri, M, Sankar, U, Sansanwal, P, Santambrogio, L, Saran, S, Sarkar, S, Sarwal, M, Sasakawa, C, Sasnauskiene, A, Sass, M, Sato, K, Sato, M, Schapira, Ah, Scharl, M, Schätzl, Hm, Scheper, W, Schiaffino, S, Schneider, C, Schneider, Me, Schneider-Stock, R, Schoenlein, Pv, Schorderet, Df, Schüller, C, Schwartz, Gk, Scorrano, L, Sealy, L, Seglen, Po, Segura-Aguilar, J, Seiliez, I, Seleverstov, O, Sell, C, Seo, Jb, Separovic, D, Setaluri, V, Setoguchi, T, Settembre, C, Shacka, Jj, Shanmugam, M, Shapiro, Im, Shaulian, E, Shaw, Rj, Shelhamer, Jh, Shen, Hm, Shen, Wc, Sheng, Zh, Shi, Y, Shibuya, K, Shidoji, Y, Shieh, Jj, Shih, Cm, Shimada, Y, Shimizu, S, Shintani, T, Shirihai, O, Shore, Gc, Sibirny, Aa, Sidhu, Sb, Sikorska, B, Silva-Zacarin, Ec, Simmons, A, Simon, Ak, Simon, Hu, Simone, C, Simonsen, A, Sinclair, Da, Singh, R, Sinha, D, Sinicrope, Fa, Sirko, A, Siu, Pm, Sivridis, E, Skop, V, Skulachev, Vp, Slack, R, Smaili, S, Smith, Dr, Soengas, M, Soldati, T, Song, X, Sood, Ak, Soong, Tw, Sotgia, F, Spector, Sa, Spies, Cd, Springer, W, Srinivasula, Sm, Stefanis, L, Steffan, J, Stendel, R, Stenmark, H, Stephanou, A, Stern, St, Sternberg, C, Stork, B, Strålfors, P, Subauste, C, Sui, X, Sulzer, D, Sun, J, Sun, Sy, Sun, Zj, Sung, Jj, Suzuki, K, Suzuki, T, Swanson, M, Swanton, C, Sweeney, St, Sy, Lk, Szabadkai, G, Tabas, I, Taegtmeyer, H, Tafani, M, Takács-Vellai, K, Takano, Y, Takegawa, K, Takemura, G, Takeshita, F, Talbot, Nj, Tan, K, Tanaka, K, Tang, D, Tanida, I, Tannous, Ba, Tavernarakis, N, Taylor, G, Taylor, Ga, Taylor, Jp, Terada, L, Terman, A, Tettamanti, G, Thevissen, K, Thompson, Cb, Thorburn, A, Thumm, M, Tian, F, Tian, Y, Tocchini-Valentini, G, Tolkovsky, Am, Tomino, Y, Tönges, L, Tooze, Sa, Tournier, C, Tower, J, Towns, R, Trajkovic, V, Travassos, Lh, Tsai, Tf, Tschan, Mp, Tsubata, T, Tsung, A, Turk, B, Turner, L, Tyagi, Sc, Uchiyama, Y, Ueno, T, Umekawa, M, Umemiya-Shirafuji, R, Unni, Vk, Vaccaro, Mi, Valente, Em, Van den Berghe, G, van der Klei, Ij, van Doorn, W, van Dyk, Lf, van Egmond, M, van Grunsven, La, Vandenabeele, P, Vandenberghe, Wp, Vanhorebeek, I, Vaquero, Ec, Velasco, G, Vellai, T, Vicencio, Jm, Vierstra, Rd, Vila, M, Vindis, C, Viola, G, Viscomi, Maria Teresa, Voitsekhovskaja, Ov, von Haefen, C, Votruba, M, Wada, K, Wade-Martins, R, Walker, Cl, Walsh, Cm, Walter, J, Wan, Xb, Wang, A, Wang, C, Wang, D, Wang, F, Wang, G, Wang, H, Wang, Hg, Wang, Hd, Wang, J, Wang, K, Wang, M, Wang, Rc, Wang, X, Wang, Yj, Wang, Y, Wang, Z, Wang, Zc, Wansink, Dg, Ward, Dm, Watada, H, Waters, Sl, Webster, P, Wei, L, Weihl, Cc, Weiss, Wa, Welford, Sm, Wen, Lp, Whitehouse, Ca, Whitton, Jl, Whitworth, Aj, Wileman, T, Wiley, Jw, Wilkinson, S, Willbold, D, Williams, Rl, Williamson, Pr, Wouters, Bg, Wu, C, Wu, Dc, Wu, Wk, Wyttenbach, A, Xavier, Rj, Xi, Z, Xia, P, Xiao, G, Xie, Z, Xu, Dz, Xu, J, Xu, L, Xu, X, Yamamoto, A, Yamashina, S, Yamashita, M, Yan, X, Yanagida, M, Yang, D, Yang, E, Yang, Jm, Yang, Sy, Yang, W, Yang, Wy, Yang, Z, Yao, Mc, Yao, Tp, Yeganeh, B, Yen, Wl, Yin, Jj, Yin, Xm, Yoo, Oj, Yoon, G, Yoon, Sy, Yorimitsu, T, Yoshikawa, Y, Yoshimori, T, Yoshimoto, K, You, Hj, Youle, Rj, Younes, A, Yu, L, Yu, Sw, Yu, Wh, Yuan, Zm, Yue, Z, Yun, Ch, Yuzaki, M, Zabirnyk, O, Silva-Zacarin, E, Zacks, D, Zacksenhaus, E, Zaffaroni, N, Zakeri, Z, Zeh HJ, 3rd, Zeitlin, So, Zhang, H, Zhang, Hl, Zhang, J, Zhang, Jp, Zhang, L, Zhang, My, Zhang, Xd, Zhao, M, Zhao, Yf, Zhao, Y, Zhao, Zj, Zheng, X, Zhivotovsky, B, Zhong, Q, Zhou, Cz, Zhu, C, Zhu, Wg, Zhu, Xf, Zhu, X, Zhu, Y, Zoladek, T, Zong, Wx, Zorzano, A, Zschocke, J, Zuckerbraun, B., and Viscomi M. T. (ORCID:0000-0002-9096-4967)

Abstract

In 2008 we published the first set of guidelines for standardizing research in autophagy. Since then, research on this topic has continued to accelerate, and many new scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Accordingly, it is important to update these guidelines for monitoring autophagy in different organisms. Various reviews have described the range of assays that have been used for this purpose. Nevertheless, there continues to be confusion regarding acceptable methods to measure autophagy, especially in multicellular eukaryotes. A key point that needs to be emphasized is that there is a difference between measurements that monitor the numbers or volume of autophagic elements (e.g., autophagosomes or autolysosomes) at any stage of the autophagic process vs. those that measure flux through the autophagy pathway (i.e., the complete process); thus, a block in macroautophagy that results in autophagosome accumulation needs to be differentiated from stimuli that result in increased autophagic activity, defined as increased autophagy induction coupled with increased delivery to, and degradation within, lysosomes (in most higher eukaryotes and some protists such as Dictyostelium) or the vacuole (in plants and fungi). In other words, it is especially important that investigators new to the field understand that the appearance of more autophagosomes does not necessarily equate with more autophagy. In fact, in many cases, autophagosomes accumulate because of a block in trafficking to lysosomes without a concomitant change in autophagosome biogenesis, whereas an increase in autolysosomes may reflect a reduction in degradative activity. Here, we present a set of guidelines for the selection and interpretation of methods for use by investigators who aim to examine macroautophagy and related processes, as well as for reviewers who need to provide realistic and reasonable critiques of papers that are focused o

Published

2012

6. A systemic evaluation of COVID-19 vaccination drives in LICs, LMICs, UMICs, and HICs: Preparedness for future pandemics.

Author

Kumar P, Sarkar M, Unnithan VB, Martínez DJG, Arlettaz ME, Gnanaraj R, Júarez MMF, Panchawagh S, Abhishek K, Agrawal P, Kaushal GP, Mbwogge M, Morales YF, Alnaasan M, Kozum R, Pisfil-Farroñay Y, Reddy AP, and Shukla R

Abstract

Introduction: The COVID-19 pandemic has significantly impacted global healthcare systems. Vaccination is an effective strategy to battle the disease. Policies and distribution frameworks have varied widely across countries. The paper aims to highlight the global vaccination trends in these nations, based on their economic classification, which will illuminate key takeaways that will allow for better pandemic management policies., Methods: A list of the most populated countries across each income slab was drawn up, and information on their vaccination campaigns was collected from national government portals and official health department websites of these countries in a structured manner. Data collected for the attributes was qualitatively described and converted into binary responses for quantitative analysis. ANOVA test, Chi-square test, and regression models were employed., Results: A consistent decreasing trend was noted in the percentage of the population vaccinated as the spectrum from higher-income countries to lower-income countries was traversed for all dose statuses. Fewer types of vaccines were available in the lower-income countries. Though compliance with the CDC vaccination strategies guide was largely noted, a linear regression univariate analysis of vaccination drive parameters carried out for single-dose vaccination yielded statistically significant results for medical provider vaccine standardization ( P -value = 0.002), vaccination requirements ( P -values <0.001), and provider recommendation. ( P -values <0.001) Vaccine hesitancy was not dependent on economic status., Conclusion: Concerted global initiatives like vaccine donation would assist efforts in mitigating disease spread. Prompt busting of baseless anti-vaccine narratives and strengthening healthcare infrastructure to meet national requirements should be given due importance., Competing Interests: There are no conflicts of interest., (Copyright: © 2024 Journal of Family Medicine and Primary Care.)

Published

2024

7. Prevalence and Assessment of Factors Associated With Malnutrition in Children Residing in Slums of Mumbai: A Cross-Sectional Study.

Author

Kumar P, Abhishek K, Shukla R, Sarkar M, Kaushal GP, Gharde P, Shah U, Panchawagh S, and Srikumar S

Abstract

Background Malnutrition in children continues to be a serious public health problem in India. Therefore, this study aims to evaluate the prevalence of malnutrition and assess factors contributing to it in children of the marginalized slum population of India, masked in the metropolitan cities.  Methods A retrospective data analysis with a cross-sectional model was conducted by medical volunteers affiliated with the Rotaract Club of Medicrew who had organized a free pediatric health check-up camp in the Dharavi village of Mumbai, India for children under five. Children under five years of age group of either sex residing in the slums of Dharavi and whose parents consented are included in the study. Neonates, children older than five years of age, and children whose parents did not consent for them to be included in the study were excluded. A pretested, pre-validated questionnaire was administered, and statistical analysis was done with p-values <0.05 considered to be statistically significant. Results  A total of 126 children were included. Out of these children, 109 of them (86.50%) had a mid-arm circumference of more than 12.5 cm (normal), 11 (8.73%) were between 11.5 cm and 12.5 cm (moderate acute malnutrition), and five (4.77%) were less than 11.5 cm (severe acute malnutrition). Among the 126 kids, 86 kids were above the age of two and their BMI was assessed, 36 (44.19%) were found to be underweight (<5th percentile) while 14 (16.3%) were obese (>95th percentile), and four (4.65%) were overweight (85th-95th percentile). For 106 (84.13%) of these children, the caregivers were mothers while others were fathers (n=4; 3.18%), grandmothers (n=5; 3.97%), sisters (n=5; 3.97%), and aunts (n=6; 4.76%). Out of those who had commenced receiving formal education, only 39 (55.71%) were in an appropriate grade for their age. The mean expenditure on food as a proportion of the total household income was 36.40% (standard deviation (SD) 15.0%). On the single-item sleep quality scale, the sleep of only 36 kids (28.58%) was reported by their caregivers as excellent. A high proportion of other medical problems were reported in the children. Conclusion Our study reports a substantial burden of malnutrition among children residing in the slums of Dharavi. Rigorous strengthening and conceptualization of on-ground nutritional programs targeted toward slum children should be done by Indian healthcare policymakers., Competing Interests: The authors have declared that no competing interests exist., (Copyright © 2024, Kumar et al.)

Published

2024

8. Autophagy Function and Regulation in Kidney Disease.

Author

Kaushal GP, Chandrashekar K, Juncos LA, and Shah SV

Subjects

Acute Kidney Injury metabolism, Acute Kidney Injury therapy, Animals, Apoptosis, Fibrosis, Homeostasis, Humans, Kidney pathology, Signal Transduction, Acute Kidney Injury pathology, Autophagy physiology, Kidney Diseases physiopathology

Abstract

Autophagy is a dynamic process by which intracellular damaged macromolecules and organelles are degraded and recycled for the synthesis of new cellular components. Basal autophagy in the kidney acts as a quality control system and is vital for cellular metabolic and organelle homeostasis. Under pathological conditions, autophagy facilitates cellular adaptation; however, activation of autophagy in response to renal injury may be insufficient to provide protection, especially under dysregulated conditions. Kidney-specific deletion of Atg genes in mice has consistently demonstrated worsened acute kidney injury (AKI) outcomes supporting the notion of a pro-survival role of autophagy. Recent studies have also begun to unfold the role of autophagy in progressive renal disease and subsequent fibrosis. Autophagy also influences tubular cell death in renal injury. In this review, we reported the current understanding of autophagy regulation and its role in the pathogenesis of renal injury. In particular, the classic mammalian target of rapamycin (mTOR)-dependent signaling pathway and other mTOR-independent alternative signaling pathways of autophagy regulation were described. Finally, we summarized the impact of autophagy activation on different forms of cell death, including apoptosis and regulated necrosis, associated with the pathophysiology of renal injury. Understanding the regulatory mechanisms of autophagy would identify important targets for therapeutic approaches.

Published

2020

9. Molecular Interactions Between Reactive Oxygen Species and Autophagy in Kidney Disease.

Author

Kaushal GP, Chandrashekar K, and Juncos LA

Subjects

AMP-Activated Protein Kinase Kinases, Acute Kidney Injury pathology, Autophagy-Related Protein-1 Homolog genetics, Humans, Intracellular Signaling Peptides and Proteins genetics, Kelch-Like ECH-Associated Protein 1 genetics, Mechanistic Target of Rapamycin Complex 1 genetics, NF-E2-Related Factor 2 genetics, Protein Kinases genetics, RNA-Binding Proteins genetics, Reactive Oxygen Species metabolism, Renal Insufficiency, Chronic pathology, Acute Kidney Injury genetics, Autophagy genetics, Oxidative Stress genetics, Renal Insufficiency, Chronic genetics

Abstract

Reactive oxygen species (ROS) are highly reactive signaling molecules that maintain redox homeostasis in mammalian cells. Dysregulation of redox homeostasis under pathological conditions results in excessive generation of ROS, culminating in oxidative stress and the associated oxidative damage of cellular components. ROS and oxidative stress play a vital role in the pathogenesis of acute kidney injury and chronic kidney disease, and it is well documented that increased oxidative stress in patients enhances the progression of renal diseases. Oxidative stress activates autophagy, which facilitates cellular adaptation and diminishes oxidative damage by degrading and recycling intracellular oxidized and damaged macromolecules and dysfunctional organelles. In this review, we report the current understanding of the molecular regulation of autophagy in response to oxidative stress in general and in the pathogenesis of kidney diseases. We summarize how the molecular interactions between ROS and autophagy involve ROS-mediated activation of autophagy and autophagy-mediated reduction of oxidative stress. In particular, we describe how ROS impact various signaling pathways of autophagy, including mTORC1-ULK1, AMPK-mTORC1-ULK1, and Keap1-Nrf2-p62, as well as selective autophagy including mitophagy and pexophagy. Precise elucidation of the molecular mechanisms of interactions between ROS and autophagy in the pathogenesis of renal diseases may identify novel targets for development of drugs for preventing renal injury.

Published

2019

10. Role of meprin metalloproteinases in cytokine processing and inflammation.

Author

Herzog C, Haun RS, and Kaushal GP

Subjects

Amino Acid Sequence, Animals, Cytokines metabolism, Extracellular Matrix Proteins metabolism, Humans, Metalloproteases chemistry, Proteolysis, Inflammation metabolism, Inflammation pathology, Metalloproteases metabolism

Abstract

Meprin metalloendopeptidases, comprising α and β isoforms, are widely expressed in mammalian cells and organs including kidney, intestines, lungs, skin, and bladder, and in a variety of immune cells and cancer cells. Meprins proteolytically process many inflammatory mediators, including cytokines, chemokines, and other bioactive proteins and peptides that control the function of immune cells. The knowledge of meprin-mediated processing of inflammatory mediators and other target substrates provides a pathophysiologic link for the involvement of meprins in the pathogenesis of many inflammatory disorders. Meprins are now known to play important roles in inflammatory diseases including acute kidney injury, sepsis, urinary tract infections, bladder inflammation, and inflammatory bowel disease. The proteolysis of epithelial and endothelial barriers including cell junctional proteins by meprins promotes leukocyte influx into areas of tissue damage to result in inflammation. Meprins degrade extracellular matrix proteins; this ability of meprins is implicated in the cell migration of leukocytes and the invasion of tumor cells that express meprins. Proteolytic processing and maturation of procollagens provides evidence that meprins are involved in collagen maturation and deposition in the fibrotic processes involved in the formation of keloids and hypertrophic scars and lung fibrosis. This review highlights recent progress in understanding the role of meprins in inflammatory disorders in both human and mouse models., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2019

11. Carbamylated Low-Density Lipoprotein (cLDL)-Mediated Induction of Autophagy and Its Role in Endothelial Cell Injury.

Author

Bose C, Shah SV, Karaduta OK, and Kaushal GP

Subjects

Adenine analogs & derivatives, Adenine pharmacology, Atherosclerosis, Autophagosomes, Autophagy-Related Protein 5 metabolism, Beclin-1 metabolism, Cell Death, Cells, Cultured, Coronary Vessels cytology, Cytosol metabolism, DNA Fragmentation, Endothelial Cells cytology, Humans, L-Lactate Dehydrogenase metabolism, Lipids chemistry, Microcirculation, Microscopy, Fluorescence, Microtubule-Associated Proteins metabolism, RNA, Small Interfering metabolism, Autophagy drug effects, Endothelial Cells drug effects, Lipoproteins, LDL pharmacology, Renal Insufficiency, Chronic physiopathology

Abstract

Patients with chronic kidney disease (CKD) have high risk of cardiovascular complications. Plasma levels of carbamylated proteins produced by urea-derived isocyanate or thiocyanate are elevated in CKD patients and that they are significant predictors of cardiovascular events and all-cause mortality. Carbamylated LDL (cLDL) has pro-atherogenic properties and is known to affect major biological processes relevant to atherosclerosis including endothelial cell injury. The underlying mechanisms of cLDL-induced endothelial cell injury are not well understood. Although autophagy has been implicated in atherosclerosis, cLDL-mediated induction of autophagy and its role in endothelial cell injury is unknown. Our studies demonstrate that human coronary artery endothelial cells (HCAECs) respond to cLDL by specific induction of key autophagy proteins including LC3-I, beclin-1, Atg5, formation of lipid-conjugated LC3-II protein, and formation of punctate dots of autophagosome-associated LC3-II. We demonstrated that autophagy induction is an immediate response to cLDL and occurred in a dose and time-dependent manner. Inhibition of cLDL-induced autophagy by a specific siRNA to LC3 as well as by an autophagy inhibitor provided protection from cLDL-induced cell death and DNA fragmentation. Our studies demonstrate that autophagy plays an important role in cLDL-mediated endothelial cell injury and may provide one of the underlying mechanisms for the pathogenesis of cLDL-induced atherosclerosis in CKD patients., Competing Interests: The authors have declared that no competing interests exist. There are no conflict of financial interests.

Published

2016

12. Epigenetic regulation of KLK7 gene expression in pancreatic and cervical cancer cells.

Author

Raju I, Kaushal GP, and Haun RS

Subjects

Cell Line, Tumor, Female, Gene Expression Regulation, Neoplastic drug effects, Histones metabolism, Humans, Hydroxamic Acids pharmacology, Pancreatic Neoplasms genetics, Promoter Regions, Genetic genetics, RNA, Messenger genetics, RNA, Messenger metabolism, Sp1 Transcription Factor genetics, Transcription, Genetic, Uterine Cervical Neoplasms genetics, Epigenesis, Genetic drug effects, Gene Expression Regulation, Neoplastic genetics, Kallikreins genetics, Pancreatic Neoplasms pathology, Uterine Cervical Neoplasms pathology

Abstract

Kallikrein-related peptidase 7 (KLK7) is a serine protease encoded within the kallikrein gene cluster located on human chromosome region 19q13.3-13.4. KLK7 is overexpressed in human pancreatic ductal adenocarcinomas (PDACs), but not in normal pancreas. Examination of KLK7 mRNA levels in pancreatic cancer cell lines revealed that it is readily detected in MIA PaCa-2 and PK-1 cells, but not in Panc-1 cells. Treatment of Panc-1 cells with the histone deacetylase (HDAC) inhibitor trichostatin A (TSA) significantly induced KLK7 mRNA expression. Similarly, KLK7 is highly expressed in cervical cancer cells, but its expression in the human cervical cancer cell line HeLa is only detected following TSA treatment. Promoter deletion analysis revealed that the proximal -238 promoter region, containing a putative Sp1-binding site, was sufficient for TSA activation of luciferase reporter activity, which was abrogated by the disruption of the Sp1-binding sequence. Consistent with the notion that TSA induced KLK7 expression via Sp1, co-expression of Sp1 with the KLK7-promoter/luciferase construct produced a significant increase in reporter activity. Chromatin immunoprecipitation (ChIP) analysis revealed enriched Sp1 occupancy on the KLK7 promoter following TSA treatment. Similarly, ChIP analysis showed the histone active mark, H3K4Me3, in the KLK7 promoter region was significantly increased after exposure to TSA.

Published

2016

13. Proteolytic processing and inactivation of CCL2/MCP-1 by meprins.

Author

Herzog C, Haun RS, Shah SV, and Kaushal GP

Abstract

Monocyte chemotactic protein 1 (CCL2/MCP-1) is a small chemokine involved in the recruitment and trafficking of mononuclear immune cells to inflammation sites. Our studies demonstrate that the metalloendopeptidases meprin A (purified from kidney cortex), recombinant meprin α, and recombinant meprin β can all process CCL2/MCP-1. The cleavage sites were determined by amino acid sequencing and mass spectrometry analysis of the generated products, and the biological activity of the products was evaluated by chemotactic migration assay using THP-1 cells. The cleavage sites generated by the meprin isoforms revealed that meprin A and meprin α cleaved the N-terminal domain of mouse CCL2/MCP-1 at the Asn 6 and Ala 7 bond, resulting in significant reduction in the chemotactic activity of the cleaved CCL2/MCP-1. Meprin β was unable to cleave the N-terminus of mouse CCL2/MCP-1 but cleaved the C-terminal region between Ser 74 and Glu 75 . Human CCL2/MCP-1 that lacks the murine C-terminal region was also cleaved by meprin α at the N-terminus resulting in significant loss of CCL2/MCP-1 biological activity, whereas meprin β did not affect the biological activity. These studies suggest that meprin α and meprin β may play important roles in regulating the CCL2/MCP-1 chemokine activity during inflammation.

Published

2016

14. Autophagy in acute kidney injury.

Author

Kaushal GP and Shah SV

Subjects

Animals, Antineoplastic Agents adverse effects, Apoptosis, Caspases metabolism, Cisplatin adverse effects, Humans, Lysosomes metabolism, Mechanistic Target of Rapamycin Complex 1, Multiprotein Complexes antagonists & inhibitors, Sepsis complications, TOR Serine-Threonine Kinases antagonists & inhibitors, Acute Kidney Injury etiology, Autophagy

Abstract

Autophagy is a conserved multistep pathway that degrades and recycles damaged organelles and macromolecules to maintain intracellular homeostasis. The autophagy pathway is upregulated under stress conditions including cell starvation, hypoxia, nutrient and growth-factor deprivation, endoplasmic reticulum stress, and oxidant injury, most of which are involved in the pathogenesis of acute kidney injury (AKI). Recent studies demonstrate that basal autophagy in the kidney is vital for the normal homeostasis of the proximal tubules. Deletion of key autophagy proteins impaired renal function and increased p62 levels and oxidative stress. In models of AKI, autophagy deletion in proximal tubules worsened tubular injury and renal function, highlighting that autophagy is renoprotective in models of AKI. In addition to nonselective sequestration of autophagic cargo, autophagy can facilitate selective degradation of damaged organelles, particularly mitochondrial degradation through the process of mitophagy. Damaged mitochondria accumulate in autophagy-deficient kidneys of mice subjected to ischemia-reperfusion injury, but the precise mechanisms of regulation of mitophagy in AKI are not yet elucidated. Recent progress in identifying the interplay of autophagy, apoptosis, and regulated necrosis has revived interest in examining shared pathways/molecules in this crosstalk during the pathogenesis of AKI. Autophagy and its associated pathways pose potentially unique targets for therapeutic interventions in AKI., (Published by Elsevier Inc.)

Published

2016

15. Endoplasmic Reticulum Stress-Induced Autophagy Provides Cytoprotection from Chemical Hypoxia and Oxidant Injury and Ameliorates Renal Ischemia-Reperfusion Injury.

Author

Chandrika BB, Yang C, Ou Y, Feng X, Muhoza D, Holmes AF, Theus S, Deshmukh S, Haun RS, and Kaushal GP

Subjects

Adenosine Triphosphate metabolism, Animals, Caspases metabolism, Cell Line, Cytoprotection drug effects, Endoplasmic Reticulum Chaperone BiP, Endoplasmic Reticulum Stress drug effects, Heat-Shock Proteins metabolism, Hypoxia complications, Hypoxia metabolism, Hypoxia pathology, Kidney metabolism, Kidney pathology, Male, Mice, Mice, Inbred C57BL, Oxidants adverse effects, Oxidative Stress drug effects, Renal Insufficiency complications, Renal Insufficiency metabolism, Renal Insufficiency pathology, Reperfusion Injury complications, Reperfusion Injury metabolism, Reperfusion Injury pathology, Unfolded Protein Response drug effects, Autophagy drug effects, Hypoxia drug therapy, Kidney drug effects, Protective Agents therapeutic use, Renal Insufficiency drug therapy, Reperfusion Injury drug therapy, Tunicamycin therapeutic use

Abstract

We examined whether endoplasmic reticulum (ER) stress-induced autophagy provides cytoprotection from renal tubular epithelial cell injury due to oxidants and chemical hypoxia in vitro, as well as from ischemia-reperfusion (IR) injury in vivo. We demonstrate that the ER stress inducer tunicamycin triggers an unfolded protein response, upregulates ER chaperone Grp78, and activates the autophagy pathway in renal tubular epithelial cells in culture. Inhibition of ER stress-induced autophagy accelerated caspase-3 activation and cell death suggesting a pro-survival role of ER stress-induced autophagy. Compared to wild-type cells, autophagy-deficient MEFs subjected to ER stress had enhanced caspase-3 activation and cell death, a finding that further supports the cytoprotective role of ER stress-induced autophagy. Induction of autophagy by ER stress markedly afforded cytoprotection from oxidants H2O2 and tert-Butyl hydroperoxide and from chemical hypoxia induced by antimycin A. In contrast, inhibition of ER stress-induced autophagy or autophagy-deficient cells markedly enhanced cell death in response to oxidant injury and chemical hypoxia. In mouse kidney, similarly to renal epithelial cells in culture, tunicamycin triggered ER stress, markedly upregulated Grp78, and activated autophagy without impairing the autophagic flux. In addition, ER stress-induced autophagy markedly ameliorated renal IR injury as evident from significant improvement in renal function and histology. Inhibition of autophagy by chloroquine markedly increased renal IR injury. These studies highlight beneficial impact of ER stress-induced autophagy in renal ischemia-reperfusion injury both in vitro and in vivo.

Published

2015

16. Impact of Hydroxychloroquine on Atherosclerosis and Vascular Stiffness in the Presence of Chronic Kidney Disease.

Author

Shukla AM, Bose C, Karaduta OK, Apostolov EO, Kaushal GP, Fahmi T, Segal MS, and Shah SV

Subjects

Animals, Aorta pathology, Aorta physiopathology, Atherosclerosis blood, Atherosclerosis complications, Bilirubin blood, Blood Glucose metabolism, Elasticity, Hydroxychloroquine pharmacology, Inflammation pathology, Male, Mice, Inbred C57BL, Postmortem Changes, Renal Insufficiency, Chronic blood, Renal Insufficiency, Chronic physiopathology, Urea blood, Atherosclerosis drug therapy, Atherosclerosis physiopathology, Hydroxychloroquine therapeutic use, Renal Insufficiency, Chronic complications, Renal Insufficiency, Chronic drug therapy, Vascular Stiffness drug effects

Abstract

Cardiovascular disease is the largest cause of morbidity and mortality among patients with chronic kidney disease (CKD) and end-stage kidney disease, with nearly half of all deaths attributed to cardiovascular disease. Hydroxychloroquine (HCQ), an anti-inflammatory drug, has been shown to have multiple pleiotropic actions relevant to atherosclerosis. We conducted a proof-of-efficacy study to evaluate the effects of hydroxychloroquine in an animal model of atherosclerosis in ApoE knockout mice with and without chronic kidney disease. Forty male, 6-week-old mice were divided into four groups in a 2 x 2 design: sham placebo group; sham treatment group; CKD placebo group; and CKD treatment group. CKD was induced by a two-step surgical procedure. All mice received a high-fat diet through the study duration and were sacrificed after 16 weeks of therapy. Mice were monitored with ante-mortem ultrasonic echography (AUE) for atherosclerosis and vascular stiffness and with post-mortem histology studies for atherosclerosis. Therapy with HCQ significantly reduced the severity of atherosclerosis in CKD mice and sham treated mice. HCQ reduced the area of aortic atherosclerosis on en face examination by approximately 60% in HCQ treated groups compared to the non-treated groups. Additionally, therapy with HCQ resulted in significant reduction in vascular endothelial dysfunction with improvement in vascular elasticity and flow patterns and better-preserved vascular wall thickness across multiple vascular beds. More importantly, we found that presence of CKD had no mitigating effect on HCQ's anti-atherosclerotic and vasculoprotective effects. These beneficial effects were not due to any significant effect of HCQ on inflammation, renal function, or lipid profile at the end of 16 weeks of therapy. This study, which demonstrates structural and functional protection against atherosclerosis by HCQ, provides a rationale to evaluate its use in CKD patients. Further studies are needed to define the exact mechanisms through which HCQ confers these benefits.

Published

2015

17. Basement membrane protein nidogen-1 is a target of meprin β in cisplatin nephrotoxicity.

Author

Herzog C, Marisiddaiah R, Haun RS, and Kaushal GP

Subjects

Acute Kidney Injury metabolism, Animals, Antineoplastic Agents toxicity, Gene Expression Regulation drug effects, Genotype, Hydroxamic Acids, Male, Metalloendopeptidases genetics, Mice, Mice, Inbred C57BL, Mice, Knockout, Protein Transport, Acute Kidney Injury chemically induced, Basement Membrane metabolism, Cisplatin toxicity, Membrane Glycoproteins metabolism, Metalloendopeptidases metabolism

Abstract

Meprins are oligomeric metalloproteinases that are abundantly expressed in the brush-border membranes of renal proximal tubules. During acute kidney injury (AKI) induced by cisplatin or ischemia-reperfusion, membrane-bound meprins are shed and their localization is altered from the apical membranes toward the basolateral surface of the proximal tubules. Meprins are capable of cleaving basement membrane proteins in vitro, however, it is not known whether meprins are able to degrade extracellular matrix proteins under pathophysiological conditions in vivo. The present study demonstrates that a basement membrane protein, nidogen-1, is cleaved and excreted in the urine of mice subjected to cisplatin-induced nephrotoxicity, a model of AKI. Cleaved nidogen-1 was not detected in the urine of untreated mice, but during the progression of cisplatin nephrotoxicity, the excretion of cleaved nidogen-1 increased in a time-dependent manner. The meprin inhibitor actinonin markedly prevented urinary excretion of the cleaved nidogen-1. In addition, meprin β-deficient mice, but not meprin α-deficient mice, subjected to cisplatin nephrotoxicity significantly suppressed excretion of cleaved nidogen-1, further suggesting that meprin β is involved in the cleavage of nidogen-1. These studies provide strong evidence for a pathophysiological link between meprin β and urinary excretion of cleaved nidogen-1 during cisplatin-induced AKI., (Published by Elsevier Ireland Ltd.)

Published

2015

18. ADAM10 is the major sheddase responsible for the release of membrane-associated meprin A.

Author

Herzog C, Haun RS, Ludwig A, Shah SV, and Kaushal GP

Subjects

ADAM Proteins genetics, ADAM10 Protein, ADAM17 Protein, Acute Kidney Injury genetics, Acute Kidney Injury pathology, Amyloid Precursor Protein Secretases genetics, Animals, Calcium Ionophores pharmacology, Carcinogens pharmacology, Cell Membrane genetics, Cell Membrane pathology, HEK293 Cells, Humans, Ionomycin pharmacology, Male, Membrane Proteins genetics, Metalloendopeptidases genetics, Mice, Tetradecanoylphorbol Acetate pharmacology, ADAM Proteins metabolism, Acute Kidney Injury enzymology, Amyloid Precursor Protein Secretases metabolism, Cell Membrane enzymology, Membrane Proteins metabolism, Metalloendopeptidases metabolism

Abstract

Meprin A, composed of α and β subunits, is a membrane-bound metalloproteinase in renal proximal tubules. Meprin A plays an important role in tubular epithelial cell injury during acute kidney injury (AKI). The present study demonstrated that during ischemia-reperfusion-induced AKI, meprin A was shed from proximal tubule membranes, as evident from its redistribution toward the basolateral side, proteolytic processing in the membranes, and excretion in the urine. To identify the proteolytic enzyme responsible for shedding of meprin A, we generated stable HEK cell lines expressing meprin β alone and both meprin α and meprin β for the expression of meprin A. Phorbol 12-myristate 13-acetate and ionomycin stimulated ectodomain shedding of meprin β and meprin A. Among the inhibitors of various proteases, the broad spectrum inhibitor of the ADAM family of proteases, tumor necrosis factor-α protease inhibitor (TAPI-1), was most effective in preventing constitutive, phorbol 12-myristate 13-acetate-, and ionomycin-stimulated shedding of meprin β and meprin A in the medium of both transfectants. The use of differential inhibitors for ADAM10 and ADAM17 indicated that ADAM10 inhibition is sufficient to block shedding. In agreement with these results, small interfering RNA to ADAM10 but not to ADAM9 or ADAM17 inhibited meprin β and meprin A shedding. Furthermore, overexpression of ADAM10 resulted in enhanced shedding of meprin β from both transfectants. Our studies demonstrate that ADAM10 is the major ADAM metalloproteinase responsible for the constitutive and stimulated shedding of meprin β and meprin A. These studies further suggest that inhibiting ADAM 10 activity could be of therapeutic benefit in AKI.

Published

2014

19. Challenges and advances in the treatment of AKI.

Author

Kaushal GP and Shah SV

Subjects

Humans, Acute Kidney Injury therapy, Nephrology trends

Abstract

Treating or preventing AKI requires treating or preventing a rise in serum creatinine as well as the immediate and remote clinical consequences associated with AKI. Because a substantial number of patients with AKI progress to ESRD, identifying patients likely to progress and halting progression are important goals for treating AKI. Many therapies for AKI are being developed, including RenalGuard Therapy, which aims to maintain high urine output; α-melanocyte-stimulating hormone, with anti-inflammatory and antiapoptotic activities; alkaline phosphatase, which detoxifies proinflammatory substances; novel, small interfering RNA, directed at p53 activation; THR-184, a peptide agonist of bone morphogenetic proteins; removal of catalytic iron, important in free-radical formation; and cell-based therapies, including mesenchymal stem cells in vivo and renal cell therapy in situ. In this review, we explore what treatment of AKI really means, discuss the emerging therapies, and examine the windows of opportunity for treating AKI. Finally, we provide suggestions for accelerating the pathways toward preventing and treating AKI, such as establishing an AKI network, implementing models of catalytic philanthropy, and directing a small percentage of the Medicare ESRD budget for developing therapies to prevent and treat AKI and halt progression of CKD., (Copyright © 2014 by the American Society of Nephrology.)

Published

2014

20. Caspase protocols in mice.

Author

Kaushal V, Herzog C, Haun RS, and Kaushal GP

Subjects

Animals, Caspases genetics, Mice, Apoptosis genetics, Caspases isolation & purification, Molecular Biology methods

Abstract

Members of the caspase family of proteases are evolutionarily conserved cysteine proteases that play a crucial role as the central executioners of the apoptotic pathway. Since the discovery of caspases, many methods have been developed to detect their activation and are widely used in basic and clinical studies. In a mouse tissue, caspase activation can be monitored by cleavage of caspase-specific synthetic substrates and by detecting cleaved caspase by western blot analysis of the tissue extract. In tissue sections, active caspase can be detected by immunostaining using specific antibodies to the active caspase. In addition, among the myriads of caspase-specific substrates known so far, cleaved fragments produced by caspases from the substrates such as PARP, lamin A, and cytokeratin-18 can be monitored in tissue sections by immunostaining as well as western blots of tissue extracts. In general, more than one method should be used to ascertain detection of activation of caspases in a mouse tissue.

Published

2014

21. Meprin A metalloproteinase and its role in acute kidney injury.

Author

Kaushal GP, Haun RS, Herzog C, and Shah SV

Subjects

Animals, Cell Membrane pathology, Cell Membrane physiology, Disease Models, Animal, Epithelial Cells pathology, Epithelial Cells physiology, Humans, Leukocytes pathology, Leukocytes physiology, Metalloendopeptidases genetics, Mice, Mice, Knockout, Rats, Acute Kidney Injury pathology, Acute Kidney Injury physiopathology, Metalloendopeptidases physiology

Abstract

Meprin A, composed of α- and β-subunits, is a membrane-associated neutral metalloendoprotease that belongs to the astacin family of zinc endopeptidases. It was first discovered as an azocasein and benzoyl-l-tyrosyl-p-aminobenzoic acid hydrolase in the brush-border membranes of proximal tubules and intestines. Meprin isoforms are now found to be widely distributed in various organs (kidney, intestines, leukocytes, skin, bladder, and a variety of cancer cells) and are capable of hydrolyzing and processing a large number of substrates, including extracellular matrix proteins, cytokines, adherens junction proteins, hormones, bioactive peptides, and cell surface proteins. The ability of meprin A to cleave various substrates sheds new light on the functional properties of this enzyme, including matrix remodeling, inflammation, and cell-cell and cell-matrix processes. Following ischemia-reperfusion (IR)- and cisplatin-induced acute kidney injury (AKI), meprin A is redistributed toward the basolateral plasma membrane, and the cleaved form of meprin A is excreted in the urine. These studies suggest that altered localization and shedding of meprin A in places other than the apical membranes may be deleterious in vivo in acute tubular injury. These studies also provide new insight into the importance of a sheddase involved in the release of membrane-associated meprin A under pathological conditions. Meprin A is injurious to the kidney during AKI, as meprin A-knockout mice and meprin inhibition provide protective roles and improve renal function. Meprin A, therefore, plays an important role in AKI and potentially is a unique target for therapeutic intervention during AKI.

Published

2013

22. Non-apoptotic effects of antiapoptotic agent zVAD-fmk in renal injury.

Author

Kaushal GP and Shah SV

Subjects

Animals, Humans, Male, Kidney injuries, Receptor-Interacting Protein Serine-Threonine Kinases physiology, Reperfusion Injury enzymology, Reperfusion Injury pathology

Published

2013

23. Autophagy protects proximal tubular cells from injury and apoptosis.

Author

Kaushal GP

Subjects

Animals, Acute Kidney Injury prevention & control, Autophagy, Kidney Tubules, Proximal pathology, Reperfusion Injury prevention & control

Abstract

Autophagy is upregulated during ischemia-reperfusion (IR)-induced and cisplatin-induced acute kidney injury (AKI). Proximal tubule-specific Atg7 knockout mice exhibited increased renal injury compared with wild-type mice following cisplatin- and IR-induced AKI. Inhibition of autophagy by chloroquine aggravated AKI, whereas upregulation of autophagy by rapamycin recovered lost renal function and histology, further indicating a protective role of autophagy in AKI. These findings reported by Jiang et al. will provide stimulus to further examine the role and mechanism of the enhancement of autophagy in AKI.

Published

2012

24. Kidney-liver dialogue in acute kidney injury.

Author

Kaushal GP and Shah SV

Subjects

Animals, Humans, Male, Acute Kidney Injury metabolism, Hemopexin metabolism, Kidney Cortex metabolism

Published

2012

25. zVAD-fmk prevents cisplatin-induced cleavage of autophagy proteins but impairs autophagic flux and worsens renal function.

Author

Herzog C, Yang C, Holmes A, and Kaushal GP

Subjects

Animals, Apoptosis Regulatory Proteins metabolism, Autophagy-Related Protein 12, Autophagy-Related Protein 5, Beclin-1, Calpain metabolism, Cathepsin B metabolism, Cells, Cultured, Kidney metabolism, Lysosomes drug effects, Microtubule-Associated Proteins metabolism, Proteins metabolism, Amino Acid Chloromethyl Ketones pharmacology, Antineoplastic Agents pharmacology, Autophagy drug effects, Caspase Inhibitors pharmacology, Cisplatin pharmacology, Kidney drug effects

Abstract

Cisplatin injury to renal tubular epithelial cells (RTEC) is accompanied by autophagy and caspase activation. However, autophagy gradually decreases during the course of cisplatin injury. The role of autophagy and the mechanism of its decrease during cisplatin injury are not well understood. This study demonstrated that autophagy proteins beclin-1, Atg5, and Atg12 were cleaved and degraded during the course of cisplatin injury in RTEC and the kidney. zVAD-fmk, a widely used pancaspase inhibitor, blocked cleavage of autophagy proteins suggesting that zVAD-fmk would promote the autophagy pathway. Unexpectedly, zVAD-fmk blocked clearance of the autophagosomal cargo, indicating lysosomal dysfunction. zVAD-fmk markedly inhibited cisplatin-induced lysosomal cathepsin B and calpain activities and therefore impaired autophagic flux. In a mouse model of cisplatin nephrotoxicity, zVAD-fmk impaired autophagic flux by blocking autophagosomal clearance as revealed by accumulation of key autophagic substrates p62 and LC3-II. Furthermore, zVAD-fmk worsened cisplatin-induced renal dysfunction. Chloroquine, a lysomotropic agent that is known to impair autophagic flux, also exacerbated cisplatin-induced decline in renal function. These findings demonstrate that impaired autophagic flux induced by zVAD-fmk or a lysomotropic agent worsened renal function in cisplatin acute kidney injury (AKI) and support a protective role of autophagy in AKI. These studies also highlight that the widely used antiapoptotic agent zVAD-fmk may be contraindicated as a therapeutic agent for preserving renal function in AKI.

Published

2012

26. Guidelines for the use and interpretation of assays for monitoring autophagy.

Author

Klionsky DJ, Abdalla FC, Abeliovich H, Abraham RT, Acevedo-Arozena A, Adeli K, Agholme L, Agnello M, Agostinis P, Aguirre-Ghiso JA, Ahn HJ, Ait-Mohamed O, Ait-Si-Ali S, Akematsu T, Akira S, Al-Younes HM, Al-Zeer MA, Albert ML, Albin RL, Alegre-Abarrategui J, Aleo MF, Alirezaei M, Almasan A, Almonte-Becerril M, Amano A, Amaravadi R, Amarnath S, Amer AO, Andrieu-Abadie N, Anantharam V, Ann DK, Anoopkumar-Dukie S, Aoki H, Apostolova N, Arancia G, Aris JP, Asanuma K, Asare NY, Ashida H, Askanas V, Askew DS, Auberger P, Baba M, Backues SK, Baehrecke EH, Bahr BA, Bai XY, Bailly Y, Baiocchi R, Baldini G, Balduini W, Ballabio A, Bamber BA, Bampton ET, Bánhegyi G, Bartholomew CR, Bassham DC, Bast RC Jr, Batoko H, Bay BH, Beau I, Béchet DM, Begley TJ, Behl C, Behrends C, Bekri S, Bellaire B, Bendall LJ, Benetti L, Berliocchi L, Bernardi H, Bernassola F, Besteiro S, Bhatia-Kissova I, Bi X, Biard-Piechaczyk M, Blum JS, Boise LH, Bonaldo P, Boone DL, Bornhauser BC, Bortoluci KR, Bossis I, Bost F, Bourquin JP, Boya P, Boyer-Guittaut M, Bozhkov PV, Brady NR, Brancolini C, Brech A, Brenman JE, Brennand A, Bresnick EH, Brest P, Bridges D, Bristol ML, Brookes PS, Brown EJ, Brumell JH, Brunetti-Pierri N, Brunk UT, Bulman DE, Bultman SJ, Bultynck G, Burbulla LF, Bursch W, Butchar JP, Buzgariu W, Bydlowski SP, Cadwell K, Cahová M, Cai D, Cai J, Cai Q, Calabretta B, Calvo-Garrido J, Camougrand N, Campanella M, Campos-Salinas J, Candi E, Cao L, Caplan AB, Carding SR, Cardoso SM, Carew JS, Carlin CR, Carmignac V, Carneiro LA, Carra S, Caruso RA, Casari G, Casas C, Castino R, Cebollero E, Cecconi F, Celli J, Chaachouay H, Chae HJ, Chai CY, Chan DC, Chan EY, Chang RC, Che CM, Chen CC, Chen GC, Chen GQ, Chen M, Chen Q, Chen SS, Chen W, Chen X, Chen X, Chen X, Chen YG, Chen Y, Chen Y, Chen YJ, Chen Z, Cheng A, Cheng CH, Cheng Y, Cheong H, Cheong JH, Cherry S, Chess-Williams R, Cheung ZH, Chevet E, Chiang HL, Chiarelli R, Chiba T, Chin LS, Chiou SH, Chisari FV, Cho CH, Cho DH, Choi AM, Choi D, Choi KS, Choi ME, Chouaib S, Choubey D, Choubey V, Chu CT, Chuang TH, Chueh SH, Chun T, Chwae YJ, Chye ML, Ciarcia R, Ciriolo MR, Clague MJ, Clark RS, Clarke PG, Clarke R, Codogno P, Coller HA, Colombo MI, Comincini S, Condello M, Condorelli F, Cookson MR, Coombs GH, Coppens I, Corbalan R, Cossart P, Costelli P, Costes S, Coto-Montes A, Couve E, Coxon FP, Cregg JM, Crespo JL, Cronjé MJ, Cuervo AM, Cullen JJ, Czaja MJ, D'Amelio M, Darfeuille-Michaud A, Davids LM, Davies FE, De Felici M, de Groot JF, de Haan CA, De Martino L, De Milito A, De Tata V, Debnath J, Degterev A, Dehay B, Delbridge LM, Demarchi F, Deng YZ, Dengjel J, Dent P, Denton D, Deretic V, Desai SD, Devenish RJ, Di Gioacchino M, Di Paolo G, Di Pietro C, Díaz-Araya G, Díaz-Laviada I, Diaz-Meco MT, Diaz-Nido J, Dikic I, Dinesh-Kumar SP, Ding WX, Distelhorst CW, Diwan A, Djavaheri-Mergny M, Dokudovskaya S, Dong Z, Dorsey FC, Dosenko V, Dowling JJ, Doxsey S, Dreux M, Drew ME, Duan Q, Duchosal MA, Duff K, Dugail I, Durbeej M, Duszenko M, Edelstein CL, Edinger AL, Egea G, Eichinger L, Eissa NT, Ekmekcioglu S, El-Deiry WS, Elazar Z, Elgendy M, Ellerby LM, Eng KE, Engelbrecht AM, Engelender S, Erenpreisa J, Escalante R, Esclatine A, Eskelinen EL, Espert L, Espina V, Fan H, Fan J, Fan QW, Fan Z, Fang S, Fang Y, Fanto M, Fanzani A, Farkas T, Farré JC, Faure M, Fechheimer M, Feng CG, Feng J, Feng Q, Feng Y, Fésüs L, Feuer R, Figueiredo-Pereira ME, Fimia GM, Fingar DC, Finkbeiner S, Finkel T, Finley KD, Fiorito F, Fisher EA, Fisher PB, Flajolet M, Florez-McClure ML, Florio S, Fon EA, Fornai F, Fortunato F, Fotedar R, Fowler DH, Fox HS, Franco R, Frankel LB, Fransen M, Fuentes JM, Fueyo J, Fujii J, Fujisaki K, Fujita E, Fukuda M, Furukawa RH, Gaestel M, Gailly P, Gajewska M, Galliot B, Galy V, Ganesh S, Ganetzky B, Ganley IG, Gao FB, Gao GF, Gao J, Garcia L, Garcia-Manero G, Garcia-Marcos M, Garmyn M, Gartel AL, Gatti E, Gautel M, Gawriluk TR, Gegg ME, Geng J, Germain M, Gestwicki JE, Gewirtz DA, Ghavami S, Ghosh P, Giammarioli AM, Giatromanolaki AN, Gibson SB, Gilkerson RW, Ginger ML, Ginsberg HN, Golab J, Goligorsky MS, Golstein P, Gomez-Manzano C, Goncu E, Gongora C, Gonzalez CD, Gonzalez R, González-Estévez C, González-Polo RA, Gonzalez-Rey E, Gorbunov NV, Gorski S, Goruppi S, Gottlieb RA, Gozuacik D, Granato GE, Grant GD, Green KN, Gregorc A, Gros F, Grose C, Grunt TW, Gual P, Guan JL, Guan KL, Guichard SM, Gukovskaya AS, Gukovsky I, Gunst J, Gustafsson AB, Halayko AJ, Hale AN, Halonen SK, Hamasaki M, Han F, Han T, Hancock MK, Hansen M, Harada H, Harada M, Hardt SE, Harper JW, Harris AL, Harris J, Harris SD, Hashimoto M, Haspel JA, Hayashi S, Hazelhurst LA, He C, He YW, Hébert MJ, Heidenreich KA, Helfrich MH, Helgason GV, Henske EP, Herman B, Herman PK, Hetz C, Hilfiker S, Hill JA, Hocking LJ, Hofman P, Hofmann TG, Höhfeld J, Holyoake TL, Hong MH, Hood DA, Hotamisligil GS, Houwerzijl EJ, Høyer-Hansen M, Hu B, Hu CA, Hu HM, Hua Y, Huang C, Huang J, Huang S, Huang WP, Huber TB, Huh WK, Hung TH, Hupp TR, Hur GM, Hurley JB, Hussain SN, Hussey PJ, Hwang JJ, Hwang S, Ichihara A, Ilkhanizadeh S, Inoki K, Into T, Iovane V, Iovanna JL, Ip NY, Isaka Y, Ishida H, Isidoro C, Isobe K, Iwasaki A, Izquierdo M, Izumi Y, Jaakkola PM, Jäättelä M, Jackson GR, Jackson WT, Janji B, Jendrach M, Jeon JH, Jeung EB, Jiang H, Jiang H, Jiang JX, Jiang M, Jiang Q, Jiang X, Jiang X, Jiménez A, Jin M, Jin S, Joe CO, Johansen T, Johnson DE, Johnson GV, Jones NL, Joseph B, Joseph SK, Joubert AM, Juhász G, Juillerat-Jeanneret L, Jung CH, Jung YK, Kaarniranta K, Kaasik A, Kabuta T, Kadowaki M, Kagedal K, Kamada Y, Kaminskyy VO, Kampinga HH, Kanamori H, Kang C, Kang KB, Kang KI, Kang R, Kang YA, Kanki T, Kanneganti TD, Kanno H, Kanthasamy AG, Kanthasamy A, Karantza V, Kaushal GP, Kaushik S, Kawazoe Y, Ke PY, Kehrl JH, Kelekar A, Kerkhoff C, Kessel DH, Khalil H, Kiel JA, Kiger AA, Kihara A, Kim DR, Kim DH, Kim DH, Kim EK, Kim HR, Kim JS, Kim JH, Kim JC, Kim JK, Kim PK, Kim SW, Kim YS, Kim Y, Kimchi A, Kimmelman AC, King JS, Kinsella TJ, Kirkin V, Kirshenbaum LA, Kitamoto K, Kitazato K, Klein L, Klimecki WT, Klucken J, Knecht E, Ko BC, Koch JC, Koga H, Koh JY, Koh YH, Koike M, Komatsu M, Kominami E, Kong HJ, Kong WJ, Korolchuk VI, Kotake Y, Koukourakis MI, Kouri Flores JB, Kovács AL, Kraft C, Krainc D, Krämer H, Kretz-Remy C, Krichevsky AM, Kroemer G, Krüger R, Krut O, Ktistakis NT, Kuan CY, Kucharczyk R, Kumar A, Kumar R, Kumar S, Kundu M, Kung HJ, Kurz T, Kwon HJ, La Spada AR, Lafont F, Lamark T, Landry J, Lane JD, Lapaquette P, Laporte JF, László L, Lavandero S, Lavoie JN, Layfield R, Lazo PA, Le W, Le Cam L, Ledbetter DJ, Lee AJ, Lee BW, Lee GM, Lee J, Lee JH, Lee M, Lee MS, Lee SH, Leeuwenburgh C, Legembre P, Legouis R, Lehmann M, Lei HY, Lei QY, Leib DA, Leiro J, Lemasters JJ, Lemoine A, Lesniak MS, Lev D, Levenson VV, Levine B, Levy E, Li F, Li JL, Li L, Li S, Li W, Li XJ, Li YB, Li YP, Liang C, Liang Q, Liao YF, Liberski PP, Lieberman A, Lim HJ, Lim KL, Lim K, Lin CF, Lin FC, Lin J, Lin JD, Lin K, Lin WW, Lin WC, Lin YL, Linden R, Lingor P, Lippincott-Schwartz J, Lisanti MP, Liton PB, Liu B, Liu CF, Liu K, Liu L, Liu QA, Liu W, Liu YC, Liu Y, Lockshin RA, Lok CN, Lonial S, Loos B, Lopez-Berestein G, López-Otín C, Lossi L, Lotze MT, Lőw P, Lu B, Lu B, Lu B, Lu Z, Luciano F, Lukacs NW, Lund AH, Lynch-Day MA, Ma Y, Macian F, MacKeigan JP, Macleod KF, Madeo F, Maiuri L, Maiuri MC, Malagoli D, Malicdan MC, Malorni W, Man N, Mandelkow EM, Manon S, Manov I, Mao K, Mao X, Mao Z, Marambaud P, Marazziti D, Marcel YL, Marchbank K, Marchetti P, Marciniak SJ, Marcondes M, Mardi M, Marfe G, Mariño G, Markaki M, Marten MR, Martin SJ, Martinand-Mari C, Martinet W, Martinez-Vicente M, Masini M, Matarrese P, Matsuo S, Matteoni R, Mayer A, Mazure NM, McConkey DJ, McConnell MJ, McDermott C, McDonald C, McInerney GM, McKenna SL, McLaughlin B, McLean PJ, McMaster CR, McQuibban GA, Meijer AJ, Meisler MH, Meléndez A, Melia TJ, Melino G, Mena MA, Menendez JA, Menna-Barreto RF, Menon MB, Menzies FM, Mercer CA, Merighi A, Merry DE, Meschini S, Meyer CG, Meyer TF, Miao CY, Miao JY, Michels PA, Michiels C, Mijaljica D, Milojkovic A, Minucci S, Miracco C, Miranti CK, Mitroulis I, Miyazawa K, Mizushima N, Mograbi B, Mohseni S, Molero X, Mollereau B, Mollinedo F, Momoi T, Monastyrska I, Monick MM, Monteiro MJ, Moore MN, Mora R, Moreau K, Moreira PI, Moriyasu Y, Moscat J, Mostowy S, Mottram JC, Motyl T, Moussa CE, Müller S, Muller S, Münger K, Münz C, Murphy LO, Murphy ME, Musarò A, Mysorekar I, Nagata E, Nagata K, Nahimana A, Nair U, Nakagawa T, Nakahira K, Nakano H, Nakatogawa H, Nanjundan M, Naqvi NI, Narendra DP, Narita M, Navarro M, Nawrocki ST, Nazarko TY, Nemchenko A, Netea MG, Neufeld TP, Ney PA, Nezis IP, Nguyen HP, Nie D, Nishino I, Nislow C, Nixon RA, Noda T, Noegel AA, Nogalska A, Noguchi S, Notterpek L, Novak I, Nozaki T, Nukina N, Nürnberger T, Nyfeler B, Obara K, Oberley TD, Oddo S, Ogawa M, Ohashi T, Okamoto K, Oleinick NL, Oliver FJ, Olsen LJ, Olsson S, Opota O, Osborne TF, Ostrander GK, Otsu K, Ou JH, Ouimet M, Overholtzer M, Ozpolat B, Paganetti P, Pagnini U, Pallet N, Palmer GE, Palumbo C, Pan T, Panaretakis T, Pandey UB, Papackova Z, Papassideri I, Paris I, Park J, Park OK, Parys JB, Parzych KR, Patschan S, Patterson C, Pattingre S, Pawelek JM, Peng J, Perlmutter DH, Perrotta I, Perry G, Pervaiz S, Peter M, Peters GJ, Petersen M, Petrovski G, Phang JM, Piacentini M, Pierre P, Pierrefite-Carle V, Pierron G, Pinkas-Kramarski R, Piras A, Piri N, Platanias LC, Pöggeler S, Poirot M, Poletti A, Poüs C, Pozuelo-Rubio M, Prætorius-Ibba M, Prasad A, Prescott M, Priault M, Produit-Zengaffinen N, Progulske-Fox A, Proikas-Cezanne T, Przedborski S, Przyklenk K, Puertollano R, Puyal J, Qian SB, Qin L, Qin ZH, Quaggin SE, Raben N, Rabinowich H, Rabkin SW, Rahman I, Rami A, Ramm G, Randall G, Randow F, Rao VA, Rathmell JC, Ravikumar B, Ray SK, Reed BH, Reed JC, Reggiori F, Régnier-Vigouroux A, Reichert AS, Reiners JJ Jr, Reiter RJ, Ren J, Revuelta JL, Rhodes CJ, Ritis K, Rizzo E, Robbins J, Roberge M, Roca H, Roccheri MC, Rocchi S, Rodemann HP, Rodríguez de Córdoba S, Rohrer B, Roninson IB, Rosen K, Rost-Roszkowska MM, Rouis M, Rouschop KM, Rovetta F, Rubin BP, Rubinsztein DC, Ruckdeschel K, Rucker EB 3rd, Rudich A, Rudolf E, Ruiz-Opazo N, Russo R, Rusten TE, Ryan KM, Ryter SW, Sabatini DM, Sadoshima J, Saha T, Saitoh T, Sakagami H, Sakai Y, Salekdeh GH, Salomoni P, Salvaterra PM, Salvesen G, Salvioli R, Sanchez AM, Sánchez-Alcázar JA, Sánchez-Prieto R, Sandri M, Sankar U, Sansanwal P, Santambrogio L, Saran S, Sarkar S, Sarwal M, Sasakawa C, Sasnauskiene A, Sass M, Sato K, Sato M, Schapira AH, Scharl M, Schätzl HM, Scheper W, Schiaffino S, Schneider C, Schneider ME, Schneider-Stock R, Schoenlein PV, Schorderet DF, Schüller C, Schwartz GK, Scorrano L, Sealy L, Seglen PO, Segura-Aguilar J, Seiliez I, Seleverstov O, Sell C, Seo JB, Separovic D, Setaluri V, Setoguchi T, Settembre C, Shacka JJ, Shanmugam M, Shapiro IM, Shaulian E, Shaw RJ, Shelhamer JH, Shen HM, Shen WC, Sheng ZH, Shi Y, Shibuya K, Shidoji Y, Shieh JJ, Shih CM, Shimada Y, Shimizu S, Shintani T, Shirihai OS, Shore GC, Sibirny AA, Sidhu SB, Sikorska B, Silva-Zacarin EC, Simmons A, Simon AK, Simon HU, Simone C, Simonsen A, Sinclair DA, Singh R, Sinha D, Sinicrope FA, Sirko A, Siu PM, Sivridis E, Skop V, Skulachev VP, Slack RS, Smaili SS, Smith DR, Soengas MS, Soldati T, Song X, Sood AK, Soong TW, Sotgia F, Spector SA, Spies CD, Springer W, Srinivasula SM, Stefanis L, Steffan JS, Stendel R, Stenmark H, Stephanou A, Stern ST, Sternberg C, Stork B, Strålfors P, Subauste CS, Sui X, Sulzer D, Sun J, Sun SY, Sun ZJ, Sung JJ, Suzuki K, Suzuki T, Swanson MS, Swanton C, Sweeney ST, Sy LK, Szabadkai G, Tabas I, Taegtmeyer H, Tafani M, Takács-Vellai K, Takano Y, Takegawa K, Takemura G, Takeshita F, Talbot NJ, Tan KS, Tanaka K, Tanaka K, Tang D, Tang D, Tanida I, Tannous BA, Tavernarakis N, Taylor GS, Taylor GA, Taylor JP, Terada LS, Terman A, Tettamanti G, Thevissen K, Thompson CB, Thorburn A, Thumm M, Tian F, Tian Y, Tocchini-Valentini G, Tolkovsky AM, Tomino Y, Tönges L, Tooze SA, Tournier C, Tower J, Towns R, Trajkovic V, Travassos LH, Tsai TF, Tschan MP, Tsubata T, Tsung A, Turk B, Turner LS, Tyagi SC, Uchiyama Y, Ueno T, Umekawa M, Umemiya-Shirafuji R, Unni VK, Vaccaro MI, Valente EM, Van den Berghe G, van der Klei IJ, van Doorn W, van Dyk LF, van Egmond M, van Grunsven LA, Vandenabeele P, Vandenberghe WP, Vanhorebeek I, Vaquero EC, Velasco G, Vellai T, Vicencio JM, Vierstra RD, Vila M, Vindis C, Viola G, Viscomi MT, Voitsekhovskaja OV, von Haefen C, Votruba M, Wada K, Wade-Martins R, Walker CL, Walsh CM, Walter J, Wan XB, Wang A, Wang C, Wang D, Wang F, Wang F, Wang G, Wang H, Wang HG, Wang HD, Wang J, Wang K, Wang M, Wang RC, Wang X, Wang X, Wang YJ, Wang Y, Wang Z, Wang ZC, Wang Z, Wansink DG, Ward DM, Watada H, Waters SL, Webster P, Wei L, Weihl CC, Weiss WA, Welford SM, Wen LP, Whitehouse CA, Whitton JL, Whitworth AJ, Wileman T, Wiley JW, Wilkinson S, Willbold D, Williams RL, Williamson PR, Wouters BG, Wu C, Wu DC, Wu WK, Wyttenbach A, Xavier RJ, Xi Z, Xia P, Xiao G, Xie Z, Xie Z, Xu DZ, Xu J, Xu L, Xu X, Yamamoto A, Yamamoto A, Yamashina S, Yamashita M, Yan X, Yanagida M, Yang DS, Yang E, Yang JM, Yang SY, Yang W, Yang WY, Yang Z, Yao MC, Yao TP, Yeganeh B, Yen WL, Yin JJ, Yin XM, Yoo OJ, Yoon G, Yoon SY, Yorimitsu T, Yoshikawa Y, Yoshimori T, Yoshimoto K, You HJ, Youle RJ, Younes A, Yu L, Yu L, Yu SW, Yu WH, Yuan ZM, Yue Z, Yun CH, Yuzaki M, Zabirnyk O, Silva-Zacarin E, Zacks D, Zacksenhaus E, Zaffaroni N, Zakeri Z, Zeh HJ 3rd, Zeitlin SO, Zhang H, Zhang HL, Zhang J, Zhang JP, Zhang L, Zhang L, Zhang MY, Zhang XD, Zhao M, Zhao YF, Zhao Y, Zhao ZJ, Zheng X, Zhivotovsky B, Zhong Q, Zhou CZ, Zhu C, Zhu WG, Zhu XF, Zhu X, Zhu Y, Zoladek T, Zong WX, Zorzano A, Zschocke J, and Zuckerbraun B

Subjects

Animals, Humans, Models, Biological, Autophagy genetics, Biological Assay methods

Abstract

In 2008 we published the first set of guidelines for standardizing research in autophagy. Since then, research on this topic has continued to accelerate, and many new scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Accordingly, it is important to update these guidelines for monitoring autophagy in different organisms. Various reviews have described the range of assays that have been used for this purpose. Nevertheless, there continues to be confusion regarding acceptable methods to measure autophagy, especially in multicellular eukaryotes. A key point that needs to be emphasized is that there is a difference between measurements that monitor the numbers or volume of autophagic elements (e.g., autophagosomes or autolysosomes) at any stage of the autophagic process vs. those that measure flux through the autophagy pathway (i.e., the complete process); thus, a block in macroautophagy that results in autophagosome accumulation needs to be differentiated from stimuli that result in increased autophagic activity, defined as increased autophagy induction coupled with increased delivery to, and degradation within, lysosomes (in most higher eukaryotes and some protists such as Dictyostelium) or the vacuole (in plants and fungi). In other words, it is especially important that investigators new to the field understand that the appearance of more autophagosomes does not necessarily equate with more autophagy. In fact, in many cases, autophagosomes accumulate because of a block in trafficking to lysosomes without a concomitant change in autophagosome biogenesis, whereas an increase in autolysosomes may reflect a reduction in degradative activity. Here, we present a set of guidelines for the selection and interpretation of methods for use by investigators who aim to examine macroautophagy and related processes, as well as for reviewers who need to provide realistic and reasonable critiques of papers that are focused on these processes. These guidelines are not meant to be a formulaic set of rules, because the appropriate assays depend in part on the question being asked and the system being used. In addition, we emphasize that no individual assay is guaranteed to be the most appropriate one in every situation, and we strongly recommend the use of multiple assays to monitor autophagy. In these guidelines, we consider these various methods of assessing autophagy and what information can, or cannot, be obtained from them. Finally, by discussing the merits and limits of particular autophagy assays, we hope to encourage technical innovation in the field.

Published

2012

27. Proteolytic action of kallikrein-related peptidase 7 produces unique active matrix metalloproteinase-9 lacking the C-terminal hemopexin domains.

Author

Ramani VC, Kaushal GP, and Haun RS

Subjects

Breast Neoplasms metabolism, Cell Line, Tumor, Enzyme Activation, Enzyme Precursors chemistry, Enzyme Precursors metabolism, Female, Gelatinases chemistry, Gelatinases metabolism, Hemopexin chemistry, Hemopexin metabolism, Humans, Matrix Metalloproteinase 2 chemistry, Matrix Metalloproteinase 2 metabolism, Matrix Metalloproteinase 9 chemistry, Peptide Fragments chemistry, Peptide Fragments metabolism, Protein Structure, Tertiary, Substrate Specificity, Kallikreins metabolism, Matrix Metalloproteinase 9 metabolism

Abstract

The gelatinases, matrix metalloproteinase (MMP)-9 and -2, are produced as latent, inactive enzymes that can be proteolytically activated by a number of proteases. In many normal and pathological conditions, where the expression of MMPs is deregulated, changes in the expression of other proteases have also been reported. Human kallikrein-related peptidase 7 (KLK7), a chymotryptic-like serine protease, is overexpressed in many different types of neoplastic conditions, which have also been shown to express high levels of both MMP-9 and -2. Since the activation of MMPs by KLK7 has never been examined, we sought to determine whether KLK7 can activate these MMPs. To test this hypothesis KLK7 was incubated with the recombinant MMPs and the products of the reaction were analyzed for their activity. Incubation of proMMP-9 with KLK7 resulted in the production of a novel truncated, active MMP-9 lacking the C-terminal hemopexin domains. In contrast, KLK7 degraded, but did not activate, proMMP-2. The novel activation of proMMP-9 by KLK7 was further confirmed using conditioned medium prepared from an MMP-9-expressing cell line, MDA-MMP-9. Our results clearly establish that KLK7 activates proMMP-9 to produce a novel truncated, active MMP-9 product not generated by other proteases. These findings suggest that KLK7 may play an important role in the activation of MMP-9 in tumors that express high levels of both these proteases and the resulting truncated MMP may possess altered substrate specificities compared with full-length MMP-9 activated by other proteases., (2011 Elsevier B.V. All rights reserved.)

Published

2011

28. Actinonin, a meprin A inhibitor, protects the renal microcirculation during sepsis.

Author

Wang Z, Herzog C, Kaushal GP, Gokden N, and Mayeux PR

Subjects

Animals, Hydroxamic Acids pharmacology, Interleukin-1beta, Kidney blood supply, Kidney physiopathology, Metalloendopeptidases metabolism, Mice, Sepsis drug therapy, Sepsis metabolism, Anti-Bacterial Agents pharmacology, Metalloendopeptidases antagonists & inhibitors, Microcirculation drug effects, Renal Circulation drug effects, Sepsis physiopathology

Abstract

Sepsis-induced acute kidney injury occurs in 20% to 50% of septic patients and nearly doubles the mortality rate of sepsis. Because treatment in the septic patient is usually begun only after the onset of symptoms, therapy that is effective even when delayed would have the greatest impact on patient survival. The metalloproteinase meprin A, an oligomeric complex made of α- and β-subunits, is highly expressed at the brush-border membranes of the kidney and capable of degrading numerous substrates including extracellular matrix proteins and cytokines. The goal of the present study was to compare the therapeutic potential of actinonin, an inhibitor of meprin A, when administered before and after the onset of sepsis. Mice were treated with actinonin at 30 min before or 7 h after induction of sepsis by cecal ligation and puncture (CLP). Intravital videomicroscopy was used to image renal peritubular capillary perfusion and reactive nitrogen species. Actinonin treatment 30 min before CLP reduced IL-1β levels and prevented the fall in renal capillary perfusion at 7 and 18 h. Actinonin also prevented the fall in renal capillary perfusion even when administered at 7 h after CLP. In addition, even late administration of actinonin preserved renal morphology and lowered blood urea nitrogen and serum creatinine concentrations. These data suggest that agents such as actinonin should be evaluated further as possible therapeutic agents because targeting both the early systemic and later organ-damaging effects of sepsis should have the highest likelihood of success.

Published

2011

29. Proteasome inhibitors prevent cisplatin-induced mitochondrial release of apoptosis-inducing factor and markedly ameliorate cisplatin nephrotoxicity.

Author

Liu L, Yang C, Herzog C, Seth R, and Kaushal GP

Subjects

Animals, Antineoplastic Agents adverse effects, Blotting, Western, Cisplatin adverse effects, Immunoprecipitation, Kidney pathology, LLC-PK1 Cells, Male, Mice, Mice, Inbred C57BL, Protease Inhibitors adverse effects, Swine, Antineoplastic Agents pharmacology, Cisplatin pharmacology, Kidney drug effects, Mitochondria drug effects, Protease Inhibitors pharmacology, Proteasome Inhibitors

Abstract

We demonstrate the effect of proteasome inhibitors in mitochondrial release of apoptosis-inducing factor (AIF) in cisplatin-exposed renal tubular epithelial cells (LLC-PK(1) cells) and in a model of cisplatin nephrotoxicity. Immunofluorescence and subcellular fractionation studies revealed cisplatin-induced translocation of AIF from the mitochondria to nucleus. Mcl-1, a pro-survival member of the Bcl-2 family, is rapidly eliminated on exposure of renal cells to cisplatin. Proteasome inhibitors PS-341 and MG-132 blocked cisplatin-induced Mcl-1 depletion and markedly prevented mitochondrial release of AIF. PS-341 and MG132 also blocked cisplatin-induced activation of executioner caspases and apoptosis. These studies suggest that proteasome inhibitors prevent cisplatin-induced caspase-dependent and -independent pathways. Overexpression of Mcl-1 was effective in blocking cisplatin-induced cytochrome c and AIF release from the mitochondria. Downregulation of Mcl-1 by small interfering RNA promoted Bax activation and cytochrome c and AIF release, suggesting that cisplatin-induced Mcl-1 depletion and associated Bax activation are involved in the release of AIF. Expression of AIF protein in the mouse was highest in the kidney compared to the heart, brain, intestine, liver, lung, muscle, and spleen. In an in vivo model of cisplatin nephrotoxicity, proteasome inhibitor MG-132 prevented mitochondrial release of AIF and markedly attenuated acute kidney injury as assessed by renal function and histology. These studies provide evidence for the first time that the proteasome inhibitors prevent cisplatin-induced mitochondrial release of AIF, provide cellular protection, and markedly ameliorate cisplatin-induced acute kidney injury. Thus, AIF is an important therapeutic target in cisplatin nephrotoxicity and cisplatin-induced depletion of Mcl-1 is an important pathway involved in AIF release.

Published

2010

30. Deletion of LOX-1 attenuates renal injury following angiotensin II infusion.

Author

Hu C, Kang BY, Megyesi J, Kaushal GP, Safirstein RL, and Mehta JL

Subjects

Animals, Blood Pressure drug effects, Connective Tissue Growth Factor genetics, Extracellular Signal-Regulated MAP Kinases physiology, Fibrosis, Hypertension pathology, Male, Mice, Mice, Inbred C57BL, Nitric Oxide Synthase Type III genetics, Receptor, Angiotensin, Type 1 genetics, p38 Mitogen-Activated Protein Kinases physiology, Angiotensin III toxicity, Kidney pathology, Scavenger Receptors, Class E physiology

Abstract

Angiotensin II upregulates the expression of LOX-1, a recently identified oxidized low-density lipoprotein receptor controlled by redox state which in turn upregulates angiotensin II activity on its activation. To test whether interruption of this positive feedback loop might reduce angiotensin II-induced hypertension and subsequent renal injury, we studied LOX-1 knockout mice. After infusion with angiotensin II for 4 weeks systolic blood pressure gradually increased in the wild-type mice; this rise was significantly attenuated in the LOX-1 knockout mice. Along with the rise in systolic blood pressure, renal function (blood urea nitrogen and creatinine) decreased in the wild-type mice, but the deterioration of function was significantly less in the LOX-1 knockout mice. Glomerulosclerosis, arteriolar sclerosis, tubulointerstitial damage, and renal collagen accumulation were all significantly less in the LOX-1 knockout mice. The reduction in collagen formation was accompanied by a decrease in connective tissue growth factor mRNA, angiotensin type 1 receptor expression, and phosphorylation of p38 and p44/42 mitogen-activated protein kinases. Expression of endothelial nitric oxide synthase was increased in the kidneys of the LOX-1 knockout mice compared to the wild-type mice. Overall, our study suggests that LOX-1 is a key modulator in the development of angiotensin II-induced hypertension and subsequent renal damage.

Published

2009

31. Meprin A and meprin alpha generate biologically functional IL-1beta from pro-IL-1beta.

Author

Herzog C, Haun RS, Kaushal V, Mayeux PR, Shah SV, and Kaushal GP

Subjects

Amino Acid Sequence, Animals, Disease Models, Animal, Hydroxamic Acids pharmacology, Interleukin-1beta antagonists & inhibitors, Interleukin-1beta pharmacology, Kidney Cortex enzymology, Metalloendopeptidases antagonists & inhibitors, Metalloendopeptidases genetics, Metalloendopeptidases isolation & purification, Mice, Molecular Sequence Data, Rats, Recombinant Proteins antagonists & inhibitors, Recombinant Proteins genetics, Recombinant Proteins metabolism, T-Lymphocytes, Helper-Inducer drug effects, T-Lymphocytes, Helper-Inducer immunology, Interleukin-1 metabolism, Interleukin-1beta biosynthesis, Metalloendopeptidases metabolism, Protein Precursors metabolism, Sepsis enzymology, Sepsis immunology

Abstract

The present study demonstrates that both oligomeric metalloendopeptidase meprin A purified from kidney cortex and recombinant meprin alpha are capable of generating biologically active IL-1beta from its precursor pro-IL-1beta. Amino-acid sequencing analysis reveals that meprin A and meprin alpha cleave pro-IL-1beta at the His(115)-Asp(116) bond, which is one amino acid N-terminal to the caspase-1 cleavage site and five amino acids C-terminal to the meprin beta site. The biological activity of the pro-IL-1beta cleaved product produced by meprin A, determined by proliferative response of helper T-cells, was 3-fold higher to that of the IL-1beta product produced by meprin beta or caspase-1. In a mouse model of sepsis induced by cecal ligation puncture that results in elevated levels of serum IL-1beta, meprin inhibitor actinonin significantly reduces levels of serum IL-1beta. Meprin A and meprin alpha may therefore play a critical role in the production of active IL-1beta during inflammation and tissue injury.

Published

2009

32. Autophagy delays apoptosis in renal tubular epithelial cells in cisplatin cytotoxicity.

Author

Kaushal GP, Kaushal V, Herzog C, and Yang C

Subjects

Animals, Apoptosis physiology, Autophagy physiology, Humans, Kidney Diseases chemically induced, Kidney Diseases pathology, Time Factors, Antineoplastic Agents toxicity, Apoptosis drug effects, Autophagy drug effects, Cisplatin toxicity, Epithelial Cells drug effects, Epithelial Cells pathology, Kidney Tubules drug effects, Kidney Tubules pathology

Abstract

One of the major side effects of cisplatin chemotherapy is toxic acute kidney injury due to preferential accumulation of cisplatin in renal proximal tubule epithelial cells and the subsequent injury to these cells. Apoptosis is known as a major mechanism of cisplatin-induced cell death in renal tubular cells. We have also recently demonstrated that autophagy induction is an immediate response of renal tubular epithelial cell exposure to cisplatin. Inhibition of cisplatin-induced autophagy blocks the formation of autophagosomes and enhances cisplatin-induced caspase-3, -6, and -7 activation, nuclear fragmentation and apoptosis. The switch from autophagy to apoptosis by autophagic inhibitors suggests that autophagy induction was responsible for a pre-apoptotic lag phase observed on exposure of renal tubular cells to cisplatin. Our studies provide evidence that autophagy induction in response to cisplatin mounts an adaptive response that suppresses and delays apoptosis. The beneficial effect of autophagy has a potential clinical significance in minimizing or preventing cisplatin nephrotoxicity.

Published

2008

33. Autophagy is associated with apoptosis in cisplatin injury to renal tubular epithelial cells.

Author

Yang C, Kaushal V, Shah SV, and Kaushal GP

Subjects

Adenine analogs & derivatives, Adenine pharmacology, Animals, Antineoplastic Agents toxicity, Caspases metabolism, Cell Line, Epithelial Cells drug effects, Kidney Tubules drug effects, LLC-PK1 Cells, Swine, Autophagy drug effects, Cisplatin toxicity, Epithelial Cells pathology, Kidney Tubules pathology

Abstract

Autophagy has emerged as another major "programmed" mechanism to control life and death much like "programmed cell death" is for apoptosis in eukaryotes. We examined the expression of autophagic proteins and formation of autophagosomes during progression of cisplatin injury to renal tubular epithelial cells (RTEC). Autophagy was detected as early as 2-4 h after cisplatin exposure as indicated by induction of LC3-I, conversion of LC3-I to LC3-II protein, and upregulation of Beclin 1 and Atg5, essential markers of autophagy. The appearance of cisplatin-induced punctated staining of autophagosome-associated LC3-II upon GFP-LC3 transfection in RTEC provided further evidence for autophagy. The autophagy inhibitor 3-methyladenine blocked punctated staining of autophagosomes. The staining of normal cells with acridine orange displayed green fluorescence with cytoplasmic and nuclear components in normal cells but displayed considerable red fluorescence in cisplatin-treated cells, suggesting formation of numerous acidic autophagolysosomal vacuoles. Autophagy inhibitors LY294002 or 3-methyladenine or wortmannin inhibited the formation of autophagosomes but induced apoptosis after 2-4 h of cisplatin treatment as indicated by caspase-3/7 and -6 activation, nuclear fragmentation, and cell death. This switch from autophagy to apoptosis by autophagic inhibitors further suggests that the preapoptotic lag phase after treatment with cisplatin is mediated by autophagy. At later stages of cisplatin injury, apoptosis was also found to be associated with autophagy, as autophagic inhibitors and inactivation of autophagy proteins Beclin 1 and Atg5 enhanced activation of caspases and apoptosis. Our results demonstrate that induction of autophagy mounts an adaptive response, suppresses cisplatin-induced apoptosis, and prolongs survival of RTEC.

Published

2008

34. Transcriptional activation of caspase-6 and -7 genes by cisplatin-induced p53 and its functional significance in cisplatin nephrotoxicity.

Author

Yang C, Kaushal V, Haun RS, Seth R, Shah SV, and Kaushal GP

Subjects

Animals, Apoptosis, Caspase 6 biosynthesis, Caspase 7 biosynthesis, Caspase Inhibitors, Caspases biosynthesis, Caspases genetics, Cell Line, Tumor, Cells, Cultured, Humans, Kidney drug effects, Kidney enzymology, Kidney Tubules cytology, Kidney Tubules metabolism, Mice, Mice, Knockout, RNA, Messenger biosynthesis, Renal Insufficiency chemically induced, Tumor Suppressor Protein p53 antagonists & inhibitors, Tumor Suppressor Protein p53 genetics, Antineoplastic Agents toxicity, Caspase 6 genetics, Caspase 7 genetics, Cisplatin toxicity, Kidney Tubules drug effects, Transcriptional Activation, Tumor Suppressor Protein p53 metabolism

Abstract

This study examined the role of cisplatin-induced p53 activation in regulation of caspases and cellular injury during cisplatin nephrotoxicity. The executioner caspase-6 and -7 but not caspase-3 were identified as transcriptional targets of p53 in cisplatin injury as revealed by chromatin immunoprecipitation, a reporter gene and electrophoretic mobility shift assays, and real-time PCR following overexpression and inhibition of p53. DNA binding by p53 involved the first introns of the human and mouse caspase-7 gene and the mouse caspase-6 gene. Studies in human kidney, breast, ovary, colon, and prostate tumor cell lines also validated these findings. Treatment of p53 (-/-) cells with cisplatin did not induce caspase-6 and -7 expression and subsequent activation. In caspase-3 (-/-) cells, inhibition of caspase-6 and -7 activations markedly prevented cisplatin-induced cell death. In an in vivo model of cisplatin nephrotoxicity inhibition of p53 activation by a p53 inhibitor suppressed transactivation of the caspase-6 and -7 genes and prevented renal failure. p53 (-/-) mice were resistant to cisplatin nephrotoxicity as assessed by renal function and histology. These studies provide first evidence for p53-dependent transcriptional control of the caspase-6 and -7 genes and its functional significance in cisplatin injury to renal cells and functional implication of cisplatin-induced p53 induction in vitro and in vivo in cisplatin nephrotoxicity.

Published

2008

35. Mcl-1 is downregulated in cisplatin-induced apoptosis, and proteasome inhibitors restore Mcl-1 and promote survival in renal tubular epithelial cells.

Author

Yang C, Kaushal V, Shah SV, and Kaushal GP

Subjects

Animals, Caspase 3 metabolism, Cell Survival drug effects, Fluorescent Antibody Technique, Kidney Tubules drug effects, LLC-PK1 Cells, Myeloid Cell Leukemia Sequence 1 Protein, Reverse Transcriptase Polymerase Chain Reaction, Swine, Antineoplastic Agents toxicity, Apoptosis drug effects, Cisplatin toxicity, Epithelial Cells drug effects, Kidney Tubules cytology, Neoplasm Proteins biosynthesis, Proteasome Inhibitors, Proto-Oncogene Proteins c-bcl-2 biosynthesis

Abstract

Mcl-1 is an antiapoptotic member of the Bcl-2 family that plays an important role in cell survival. We demonstrate that proteasome-dependent regulation of Mcl-1 plays a critical role in renal tubular epithelial cell injury from cisplatin. Protein levels of Mcl-1 rapidly declined in a time-dependent manner following cisplatin treatment of LLC-PK(1) cells. However, mRNA levels of Mcl-1 were not altered following cisplatin treatment. Expression of other antiapoptotic members of the Bcl-2 family such as Bcl-2 and BclxL was not affected by cisplatin treatment. Cisplatin-induced loss of Mcl-1 occurs at the same time as the mitochondrial release of cytochrome c, activation of caspase-3, and initiation of apoptosis. Treatment of cells with cycloheximide, a protein synthesis inhibitor, revealed rapid turnover of Mcl-1. In addition, treatment with cycloheximide in the presence or absence of cisplatin demonstrated that cisplatin-induced loss of Mcl-1 results from posttranslational degradation rather than transcriptional inhibition. Overexpression of Mcl-1 protected cells from cisplatin-induced caspase-3 activation and apoptosis. Preincubating cells with the proteasome inhibitor MG-132 or lactacystin not only restored cisplatin-induced loss of Mcl-1 but also resulted in an accumulation of Mcl-1 that exceeded basal levels; however, Bcl-2 and BclxL levels did not change in response to MG-132 or lactacystin. The proteasome inhibitors effectively blocked cisplatin-induced mitochondrial release of cytochrome c, caspase-3 activation, and apoptosis. These studies suggest that proteasome regulation of Mcl-1 is crucial in the cisplatin-induced apoptosis via the mitochondrial apoptotic pathway and that Mcl-1 is an important therapeutic target in cisplatin injury to renal tubular epithelial cells.

Published

2007

36. Role of meprin A in renal tubular epithelial cell injury.

Author

Herzog C, Seth R, Shah SV, and Kaushal GP

Subjects

Acute Disease, Animals, Apoptosis drug effects, Cisplatin, Hepatitis A Virus Cellular Receptor 1, Hydroxamic Acids pharmacology, Kidney drug effects, Kidney pathology, Kidney physiopathology, Kidney Diseases chemically induced, Kidney Diseases physiopathology, Leukocytes pathology, Membrane Glycoproteins metabolism, Metalloendopeptidases antagonists & inhibitors, Metalloendopeptidases deficiency, Metalloendopeptidases urine, Mice, Mice, Inbred C57BL, Mice, Knockout, Microvilli metabolism, Protein Isoforms urine, Receptors, Virus metabolism, Tissue Distribution, Kidney Diseases enzymology, Kidney Diseases pathology, Kidney Tubules enzymology, Kidney Tubules pathology, Metalloendopeptidases metabolism

Abstract

Meprins are zinc-dependent metalloproteinases that are highly expressed in the brush-border membranes of both the kidney and the intestines. Meprins are capable of proteolytically degrading extracellular matrix proteins, proteolytically processing bioactive proteins, and play a role in inflammatory processes. In this study, the function of meprin A in the acute kidney injury (AKI) model of cisplatin nephrotoxicity was examined. Normal linear localization of meprin A in the brush border membranes of proximal tubules was altered in AKI. The meprin A alpha-subunit was detected in the urine of both control and cisplatin-treated mice. A cleaved product of the meprin A beta-subunit, undetected in the urine of control mice, was found to be significantly increased in the urine during the progression of cisplatin nephrotoxicity. The excretion of this beta-fragment was found to be before the rise in serum creatinine and blood urea nitrogen (BUN) suggesting usefulness as a biomarker for AKI. Pretreatment of mice with a meprin A inhibitor afforded protection from cisplatin nephrotoxicity as reflected by significant decreases in serum creatinine, BUN, and the excretion of kidney injury molecule-1. These decreases in serum and urine biomarkers were accompanied by significant decreases in histologic markers such as leukocyte infiltration and apoptosis. Meprin A appears to be an important therapeutic target and urinary excretion appears to be a potential biomarker of AKI.

Published

2007

37. Disruption of renal peritubular blood flow in lipopolysaccharide-induced renal failure: role of nitric oxide and caspases.

Author

Tiwari MM, Brock RW, Megyesi JK, Kaushal GP, and Mayeux PR

Subjects

Acute Kidney Injury chemically induced, Acute Kidney Injury pathology, Acute Kidney Injury prevention & control, Amino Acid Chloromethyl Ketones pharmacology, Animals, Apoptosis drug effects, Apoptosis physiology, Caspase Inhibitors, Disease Models, Animal, Enzyme Activation, Interferon-gamma blood, Kidney Cortex blood supply, Kidney Cortex pathology, Lipopolysaccharides, Lysine analogs & derivatives, Lysine pharmacology, Male, Mice, Mice, Inbred C57BL, Nitric Oxide Synthase Type II antagonists & inhibitors, Tumor Necrosis Factor-alpha analysis, Acute Kidney Injury physiopathology, Caspases physiology, Nitric Oxide physiology, Renal Circulation physiology

Abstract

Acute renal failure (ARF) is a frequent and serious complication of endotoxemia caused by lipopolysaccharide (LPS) and contributes significantly to mortality. The present studies were undertaken to examine the roles of nitric oxide (NO) and caspase activation on renal peritubular blood flow and apoptosis in a murine model of LPS-induced ARF. Male C57BL/6 mice treated with LPS (Escherichia coli) at a dose of 10 mg/kg developed ARF at 18 h. Renal failure was associated with a significant decrease in peritubular capillary perfusion. Vessels with no flow increased from 7 +/- 3% in the saline group to 30 +/- 4% in the LPS group (P < 0.01). Both the inducible NO synthase inhibitor L-N(6)-1-iminoethyl-lysine (L-NIL) and the nonselective caspase inhibitor benzyloxycarbonyl-Val-Ala-Asp fluoromethylketone (Z-VAD) prevented renal failure and reversed perfusion deficits. Renal failure was also associated with an increase in renal caspase-3 activity and an increase in renal apoptosis. Both L-NIL and Z-VAD prevented these changes. LPS caused an increase in NO production that was blocked by L-NIL but not by Z-VAD. Taken together, these data suggest NO-mediated activation of renal caspases and the resulting disruption in peritubular blood flow are an important mechanism of LPS-induced ARF.

Published

2005

38. Fibrate prevents cisplatin-induced proximal tubule cell death.

Author

Nagothu KK, Bhatt R, Kaushal GP, and Portilla D

Subjects

Acute Kidney Injury chemically induced, Acute Kidney Injury prevention & control, Animals, Apoptosis drug effects, Bezafibrate metabolism, Caspase 3, Caspases metabolism, Cytochromes c metabolism, Drug Interactions, Fatty Acids, Nonesterified metabolism, Hypolipidemic Agents metabolism, Kidney Tubules, Proximal cytology, LLC-PK1 Cells, Ligands, Mitochondria metabolism, Oxidation-Reduction drug effects, PPAR alpha metabolism, Swine, bcl-2-Associated X Protein metabolism, Antineoplastic Agents toxicity, Bezafibrate pharmacology, Cisplatin toxicity, Hypolipidemic Agents pharmacology, Kidney Tubules, Proximal drug effects

Abstract

Background: In previous studies we have shown that cisplatin inhibits peroxisome proliferator-activated receptor-alpha (PPAR-alpha) activity and consequently fatty acid oxidation, and these events precede proximal tubule cell death. In addition the use of fibrate class of PPAR-alpha ligands ameliorate renal function by preventing both inhibition of fatty acid oxidation and proximal tubule cell death., Methods: LLC-PK1 cells were treated with cisplatin and apoptosis was established by the presence of nuclear fragmentation and by cell cycle analysis. Proximal tubular cells treated with cisplatin and bezafibrate were subjected to sub cellular fractionation and the presence of Bax, Bcl-2, cytochrome c, and active caspase-3 in the cytosolic and mitochondrial membrane fractions was determined by Western blot analysis. PPAR-alpha activity was measured by determining luciferase activity after transfection of LLC-PK1 cells with TK-Luc 3x PPAR response elements (PPRE), and the accumulation of nonesterified free fatty acids was measured in lysates obtained from cells treated with cisplatin and bezafibrate., Results: Incubation of LLC-PK1 cells with 25 micromol/L cisplatin for 18 hours induced 41.5% apoptosis measured by cell cycle analysis. Cisplatin-induced apoptosis was significantly suppressed by bezafibrate, a fibrate class of PPAR-alpha ligand. Bezafibrate treatment of LLC-PK1 cells prevented cisplatin-induced translocation of proapoptotic Bax from the cytosol to the mitochondrial fraction, and increased the expression of antiapoptotic molecule Bcl-2. Cisplatin-induced inhibition of PPAR-alpha activity was accompanied by increased accumulation of nonesterified free fatty acids. Pretreatment with bezafibrate prevented both the inhibition of PPAR-alpha activity and the accumulation of nonesterified free fatty acids induced by cisplatin. Finally, bezafibrate prevented cisplatin-induced release of cytochrome c from the mitochondria to the cytosol, and the cleavage of procaspase-3 to active caspase-3., Conclusion: Bezafibrate treatment inhibits cisplatin-mediated tubular injury by preventing the activation of various cellular mechanisms that lead to proximal tubule cell death. These findings support our previous observations where the use of fibrates represents a novel strategy to ameliorate proximal tubule cell death in cisplatin-induced acute renal failure.

Published

2005

39. Generation of biologically active interleukin-1beta by meprin B.

Author

Herzog C, Kaushal GP, and Haun RS

Subjects

Amino Acid Sequence, Binding Sites, Blotting, Western, Caspase 1 chemistry, Caspase 1 metabolism, Cell Line, Cysteine Endopeptidases metabolism, Cytokines metabolism, Electrophoresis, Polyacrylamide Gel, Genetic Vectors, Glycosylation, Humans, Inflammation, Interleukin-1 chemistry, Ions, Leukocytes metabolism, Mass Spectrometry, Molecular Sequence Data, Protein Structure, Tertiary, Recombinant Proteins chemistry, Sequence Homology, Amino Acid, T-Lymphocytes, Helper-Inducer metabolism, Time Factors, Interleukin-1 metabolism, Metalloendopeptidases metabolism

Abstract

Interleukin-1beta (IL-1beta) is a proinflammatory cytokine that is synthesized as an inactive precursor molecule that must be proteolytically processed to generate the biologically active form. Maturation of the precursor is primarily performed by caspase-1, an intracellular cysteine protease; however, processing by other proteases has been described. Meprins are cell surface and secreted metalloproteases expressed by renal and intestinal brush-border membranes, leukocytes, and cancer cells. In this study we show that purified recombinant meprin B can process the interleukin-1beta precursor to a biologically active form. Amino-terminal sequencing and mass spectrometry analysis of the product of digestion by activated meprin B determined that proteolytic cleavage resulted in an additional six amino acids relative to the site utilized by caspase-1. The biological activity of the meprin B-cleaved cytokine was confirmed by measuring the proliferative response of helper T-cells. These results suggest that meprin may play an important role in activation of this proinflammatory cytokine in various pathophysiological conditions.

Published

2005

40. p53-dependent caspase-2 activation in mitochondrial release of apoptosis-inducing factor and its role in renal tubular epithelial cell injury.

Author

Seth R, Yang C, Kaushal V, Shah SV, and Kaushal GP

Subjects

Amino Acid Chloromethyl Ketones metabolism, Animals, Antineoplastic Agents toxicity, Apoptosis Inducing Factor, Benzothiazoles, Carrier Proteins genetics, Carrier Proteins metabolism, Caspase 2, Caspase 3, Caspase Inhibitors, Caspases genetics, Cell Nucleus metabolism, Cisplatin toxicity, Cysteine Proteinase Inhibitors metabolism, Death Domain Receptor Signaling Adaptor Proteins, Enzyme Activation, Epithelial Cells drug effects, Epithelial Cells metabolism, Flavoproteins genetics, Membrane Proteins genetics, Mice, Mice, Knockout, RNA, Small Interfering genetics, RNA, Small Interfering metabolism, Thiazoles metabolism, Toluene analogs & derivatives, Toluene metabolism, Tumor Suppressor Protein p53 antagonists & inhibitors, Tumor Suppressor Protein p53 genetics, Caspases metabolism, Epithelial Cells pathology, Flavoproteins metabolism, Kidney Tubules cytology, Membrane Proteins metabolism, Mitochondria metabolism, Tumor Suppressor Protein p53 metabolism

Abstract

We demonstrate the role of p53-mediated caspase-2 activation in the mitochondrial release of apoptosis-inducing factor (AIF) in cisplatin-treated renal tubular epithelial cells. Gene silencing of AIF with its small interfering RNA (siRNA) suppressed cisplatin-induced AIF expression and provided a marked protection against cell death. Subcellular fractionation and immunofluorescence studies revealed cisplatin-induced translocation of AIF from the mitochondria to the nuclei. Pancaspase inhibitor benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone or p53 inhibitor pifithrin-alpha markedly prevented mitochondrial release of AIF, suggesting that caspases and p53 are involved in this release. Caspase-2 and -3 that were predominantly activated in response to cisplatin provided a unique model to study the role of these caspases in AIF release. Cisplatin-treated caspase-3 (+/+) and caspase-3 (-/-) cells exhibited similar AIF translocation to the nuclei, suggesting that caspase-3 does not affect AIF translocation, and thus, caspase-2 may be involved in the translocation. Caspase-2 inhibitor benzyloxycarbonyl-Val-Asp-Val-Ala-Asp-fluoromethylketone or down-regulation of caspase-2 by its siRNA significantly prevented translocation of AIF. Caspase-2 activation was a critical response from p53, which was markedly induced and phosphorylated in cisplatin-treated cells. Overexpression of p53 not only resulted in caspase-2 activation but also mitochondrial release of AIF. The p53 inhibitor pifithrin-alpha or p53 siRNA prevented both cisplatin-induced caspase-2 activation and mitochondrial release of AIF. Caspase-2 activation was dependent on the p53-responsive gene, PIDD, a death domain-containing protein that was induced by cisplatin in a p53-dependent manner. These results suggest that caspase-2 activation mediated by p53 is an important pathway involved in the mitochondrial release of AIF in response to cisplatin injury.

Published

2005

41. Regulation of caspase-3 and -9 activation in oxidant stress to RTE by forkhead transcription factors, Bcl-2 proteins, and MAP kinases.

Author

Kaushal GP, Liu L, Kaushal V, Hong X, Melnyk O, Seth R, Safirstein R, and Shah SV

Subjects

Carrier Proteins metabolism, Caspase 3, Caspase 9, Cell Death, Cell Line, Cell Survival, DNA-Binding Proteins, Enzyme Activation drug effects, Enzyme Inhibitors pharmacology, Fluorescent Antibody Technique, Hydrogen Peroxide pharmacology, Kidney Tubules enzymology, Phosphoinositide-3 Kinase Inhibitors, Phosphorylation, Protein Serine-Threonine Kinases metabolism, Proto-Oncogene Proteins metabolism, Proto-Oncogene Proteins c-akt, Transcription Factors, Transfection, bcl-Associated Death Protein, Caspases metabolism, Kidney Tubules cytology, Mitogen-Activated Protein Kinases pharmacology, Oxidative Stress, Proto-Oncogene Proteins c-bcl-2 pharmacology

Abstract

Cytotoxicity to renal tubular epithelial cells (RTE) is dependent on the relative response of cell survival and cell death signals triggered by the injury. Forkhead transcription factors, Bcl-2 family member Bad, and mitogen-activated protein kinases are regulated by phosphorylation that plays crucial roles in determining cell fate. We examined the role of phosphorylation of these proteins in regulation of H(2)O(2)-induced caspase activation in RTE. The phosphorylation of FKHR, FKHRL, and Bcl-2 family member Bad was markedly increased in response to oxidant injury, and this increase was associated with elevated levels of basal phosphorylation of Akt/protein kinase B. Phosphoinositol (PI) 3-kinase inhibitors abolished this phosphorylation and also decreased expression of antiapoptotic proteins Bcl-2 and BclxL. Inhibition of phosphorylation of forkhead proteins resulted in a marked increase in the proapoptotic protein Bim. These downstream effects of PI 3-kinase inhibition promoted the oxidant-induced activation of caspase-3 and -9, but not caspase-8 and -1. The impact of enhanced activation of caspases by PI 3-kinase inhibition was reflected on accelerated oxidant-induced cell death. Oxidant stress also induced marked phosphorylation of ERK1/2, P38, and JNK kinases. Inhibition of ERK1/2 phosphorylation but not P38 and JNK kinase increased caspase-3 and -9 activation; however, this activation was far less than induced by inhibition of Akt phosphorylation. Thus the Akt-mediated phosphorylation pathway, ERK signaling, and the antiapoptotic Bcl-2 proteins distinctly regulate caspase activation during oxidant injury to RTE. These studies suggest that enhancing renal-specific survival signals may lead to preservation of renal function during oxidant injury.

Published

2004

42. Differential toxicity of anthracyclines on cultured endothelial cells.

Author

Kaushal V, Kaushal GP, and Mehta P

Subjects

Anthracyclines metabolism, Caspase 3, Caspases metabolism, Cell Survival drug effects, DNA Fragmentation drug effects, Endothelium, Vascular drug effects, Humans, Time Factors, Tumor Suppressor Protein p53 metabolism, Anthracyclines toxicity, Endothelial Cells drug effects

Abstract

Anthracyclines are known for their endothelial toxicity. Newer derivatives may have fewer toxic effects on endothelium. The authors therefore evaluated the effects of doxorubicin, doxorubicin analogs (daunorubicin, idarubicin), and pegylated liposomal doxorubicin (doxil) in human coronary artery endothelial cells (HCAECs). Endothelial viability did not change significantly with doxil, but was decreased with doxorubicin, daunorubicin, or idamycin. Similarly caspase-3 activity was significantly elevated in HCAECs treated with doxorubicin, daunorubicin, and idamycin. In contrast, doxil did not cause significant increase in caspase activity. The authors also characterized the levels of antiapoptotic and prosurvival proteins using Western blot analysis. There was no significant difference in the expression levels of Bcl-2, Bax, and phospho-Akt in endothelial cells treated with anthracycline derivatives. However, the expression levels of Mcl-l protein were unaltered in endothelial cells treated with doxil but were significantly decreased when treated with other anthracycline analogs. Doxil minimally affected the expression levels of p53, whereas other anthracyclines induced p53 protein levels to a significant level, resulting in endothelial cell apoptosis. The authors conclude that the liposomal anthracycline protects endothelial cells from injury by preventing caspase-3 activation and maintaining the expression of antiapoptotic molecule Mcl-1.

Published

2004

43. Apoptotic pathways in ischemic acute renal failure.

Author

Kaushal GP, Basnakian AG, and Shah SV

Subjects

Animals, Caspases metabolism, Endonucleases metabolism, Humans, Kidney enzymology, Kidney pathology, Acute Kidney Injury metabolism, Acute Kidney Injury pathology, Apoptosis, Ischemia metabolism, Ischemia pathology

Abstract

The study of cell death has emerged as an important and exciting area of research in cell biology. Although two kinds of cell death, apoptosis and necrosis, are recognized, one of the major advances in our understanding of cell death has been the recognition that the pathways traditionally associated with apoptosis may be very critical in the form of cell injury associated with necrosis. Renal tubular epithelial cell injury from ischemia has been generally regarded as a result of necrotic form of cell death. We briefly describe recent evidence indicating that pathways generally associated with apoptosis, including endonuclease activation, role of mitochondria and caspases, are important in renal tubular injury. It is likely that the cascades that lead to apoptotic or necrotic mode of cell death are activated almost simultaneously and may share some common pathways.

Published

2004

44. Onychomycosis in central India: a clinicoetiologic correlation.

Author

Garg A, Venkatesh V, Singh M, Pathak KP, Kaushal GP, and Agrawal SK

Subjects

Adolescent, Adult, Aged, Child, Female, Humans, India, Male, Middle Aged, Fungi isolation & purification, Onychomycosis microbiology

Abstract

Background: Onychomycosis is mainly caused by dermatophytes, but yeasts and nondermatophyte molds have also been implicated, giving rise to diverse clinical presentations. The etiological agents of the disease may show geographic variation. The aim of the present study was to isolate the causative pathogens and to determine the various clinical patterns of onychomycosis in central India., Methods: The study population comprised 90 patients with onychomycosis. Nail samples were collected for direct microscopic examination and culture. Clinical patterns were noted and correlated with causative pathogens., Results: The male : female ratio was 3:1 and the mean age was 29.40 +/- 13.61 years. Fingernails were involved in 60%, toenails in 26.67% and both fingernails and toenails in 13.34% of the 90 patients. The clinical types noted were distolateral subungual onychomycosis (64.44%), total dystrophic onychomycosis (17.78%), proximal subungual onychomycosis with paronychia (12.2%), proximal subungual onychomycosis without paronychia (4.44%) and superficial white onychomycosis (1.11%). Dermatophytes were the most common pathogens isolated, being found in 24 patients (26.36%) [Tricophyton rubrum (23.07%), Tricophyton verrucosum (2.22%) and Epidermophyton floccosum (1.11%)], followed by Candida albicans, which was found in 22 patients (24.27%). Thirty-six (39.58%) nondermatophyte molds were isolated from 29 patients. Of these 29 cases, six were associated with Tricophyton rubrum, which was considered the primary pathogen., Conclusions: Distolateral subungual onychomycosis was the most common clinical presentation; however, total dystrophic onychomycosis and proximal subungual onychomycosis were not uncommon in this part of India. Tricophyton rubrum and Candida albicans were the major pathogens. The clinicoetiologic correlation revealed that a single pathogen could give rise to more than one clinical type.

Published

2004

45. Antibody response to crude cell lysate of propionibacterium acnes and induction of pro-inflammatory cytokines in patients with acne and normal healthy subjects.

Author

Basal E, Jain A, and Kaushal GP

Subjects

Acne Vulgaris microbiology, Adolescent, Adult, Antibodies, Bacterial blood, Antigens, Bacterial immunology, Antigens, Bacterial isolation & purification, Bacterial Proteins immunology, Bacterial Proteins isolation & purification, Blotting, Western, Enzyme-Linked Immunosorbent Assay, Female, Humans, Interleukin-8 analysis, Leukocytes, Mononuclear metabolism, Male, Propionibacterium acnes isolation & purification, Skin microbiology, Tumor Necrosis Factor-alpha analysis, Acne Vulgaris immunology, Cytokines analysis, Propionibacterium acnes immunology, Propionibacterium acnes pathogenicity

Abstract

Propionibacterium acnes (P. acnes) plays an important role in the disease pathogenesis of acne vulgaris, a disorder of pilosebaceous follicles, seen primarily in the adolescent age group. In the present study, the presence of antibodies against P. acnes (MTCC1951) were detected in acne patient (n=50) and disease free controls (n=25) using dot-ELISA and Western blot assay. The ability of P. acnes to induce pro-inflammatory cytokines by human peripheral blood mononuclear cells (PBMCs), obtained from acne patients and healthy subjects, were also analysed. The patients (n=26) who were culture positive for skin swab culture, were found to have a more advanced disease and higher antibody titres (1:4000 to > 1:16000) compared to the P. acnes negative patients (n=24) and normal controls (n=25). An analysis of patients' sera by western blot assay recognized a number of antigenic components of P. acnes, ranging from 29 to 205 kDa. The major reactive component was an approximately 96 kDa polypeptide, which was recognised in 92% (24 of 26) of the patients sera. Further, the P. acnes culture supernatant, crude cell lysate and heat killed P. acnes whole cells, obtained from 72-h incubation culture, were observed to be able to induce significant amounts of IL-8 and tumor necrosis factor alpha (TNF-alpha) by the PBMCs in both the healthy subjects and patients, as analysed by cytokine-ELISA. The levels of cytokines were significantly higher in the patients than the healthy subjects. A major 96 kDa polypeptide reactant was eluted from the gel and was found to cause dose dependent stimulation of the productions of IL-8 and TNF-alpha. Thus, the above results suggest that both humoral and pro-inflammatory responses play major roles in the pathogenesis of acne.

Published

2004

46. Alemtuzumab (CAMPATH 1H) does not kill chronic lymphocytic leukemia cells in serum free medium.

Author

Zent CS, Chen JB, Kurten RC, Kaushal GP, Lacy HM, and Schichman SA

Subjects

Alemtuzumab, Antibodies, Monoclonal, Humanized, Cell Line, Tumor, Chlorambucil pharmacology, Complement System Proteins physiology, Culture Media, Serum-Free, Humans, Immunoglobulin Fab Fragments pharmacology, Leukemia, Lymphocytic, Chronic, B-Cell pathology, Vidarabine pharmacology, Antibodies, Monoclonal pharmacology, Antibodies, Neoplasm pharmacology, Antineoplastic Agents pharmacology, Apoptosis drug effects, Leukemia, Lymphocytic, Chronic, B-Cell drug therapy, Vidarabine analogs & derivatives

Abstract

The mechanism of action of alemtuzumab (CAMPATH 1H) in chronic lymphocytic leukemia (CLL) is uncertain. We tested the hypothesis that alemtuzumab alone can induce apoptosis in cultured CLL cells. Purified peripheral blood B-lymphocytes from CLL patients were treated in serum free medium (AIM-V). There was minimal spontaneous apoptosis in untreated cells. Alemtuzumab ligation did not alter the membrane distribution of CD52 in single cells but many cells formed transient, small, tightly adherent clusters. Alemtuzumab alone did not induce apoptosis. In contrast, alemtuzumab plus complement was rapidly cytotoxic. We conclude that alemtuzumab does not cause apoptosis in purified CLL B cells cultured in serum free medium.

Published

2004

47. Thalidomide protects endothelial cells from doxorubicin-induced apoptosis but alters cell morphology.

Author

Kaushal V, Kaushal GP, Melkaveri SN, and Mehta P

Subjects

Angiogenesis Inhibitors pharmacology, Caspase 3, Caspases metabolism, Cell Size drug effects, Cell Survival drug effects, Cells, Cultured, Coronary Vessels cytology, Drug Antagonism, Humans, Receptor, PAR-1 analysis, Receptor, PAR-1 drug effects, Thrombophilia chemically induced, Apoptosis drug effects, Doxorubicin pharmacology, Endothelium, Vascular cytology, Endothelium, Vascular drug effects, Thalidomide pharmacology

Abstract

Antiangiogenesis agents are now being used in clinical trials to reduce the risk of recurrence of cancer. Several of these agents, however, are associated with thrombosis, especially when used in combination with chemotherapy. Antiangiogenesis and thrombosis are both endothelial-related activities, and we therefore evaluated one presumed antiangiogenesis agent (thalidomide) on intact cultured endothelial cells, and on cultured endothelial cells injured by preincubation with doxorubicin. We evaluated cell viability, caspase-3 activation, morphology of cells using light microscopy, and protease activated receptor-1 (PAR-l) expression. In our experiments, doxorubicin induced a dose- and incubation time-dependent and caspase-3-mediated apoptosis of endothelial cells. Thalidomide alone caused no changes in intact endothelial cells in terms of morphology, cell viability or activation of caspase-3. In contrast, when thalidomide was added to doxorubicin-injured endothelial cells, there was protection from cell death, increase in viability of endothelial cells, induction of differentiation and formation of neotubules. Doxorubicin reduced the expression of thrombin receptor, PAR-1, as evaluated by immunostaining and flow cytometry. Thalidomide did not alter PAR-1 expression in untreated cells but restored its expression reduced by doxorubicin. These findings suggest that thalidomide may be procoagulant, not by enhancing doxorubicin-mediated endothelial cell injury, but by altering the expression of PAR-1 on injured endothelium and resulting in endothelial dysfunction, which may explain hypercoagulability in patients treated with chemotherapy followed by thalidomide.

Published

2004

48. Role of caspases in renal tubular epithelial cell injury.

Author

Kaushal GP

Subjects

Cell Death physiology, Humans, Kidney Tubules physiology, Signal Transduction physiology, Apoptosis physiology, Caspases physiology, Epithelial Cells physiology, Kidney Tubules pathology

Abstract

The regulation of cell death has been investigated in a number of clinical disorders including renal ischemic and toxic acute renal failure. Caspases play a crucial role in the execution or final phase of cell death by cleaving and inactivating various structural and functional intracellular proteins that are essential for cell survival and proliferation. Evidence is now emerging to implicate the caspase pathway in a variety of renal diseases including the pathogenesis of acute renal failure. Among the 14 known members of the caspase family thus far identified several executioner caspases including caspases-3, -6, and -7 and the proinflammatory caspase including caspase-1 may participate in the final degradation of intracellular proteins. The activation of these caspases is regulated by the receptor- and mitochondrial-mediated cell signaling pathways as well as by the endoplasmic reticulum stress response. While the role of some caspases in renal injury is emerging, the roles of various proinflammatory and other executioner caspases remain to be determined. Although many pro- and anti-apoptotic molecules that act upstream of caspase activation have been identified, their regulation is yet to be determined in the pathogenesis of renal injury. A precise description of caspase-mediated cell death pathway and regulation of caspase activation is, therefore, critical to the understanding of the mechanism of renal injury and to the development of therapeutic targets that prevent renal diseases and preserve renal function.

Published

2003

49. The JNK, ERK and p53 pathways play distinct roles in apoptosis mediated by the antitumor agents vinblastine, doxorubicin, and etoposide.

Author

Brantley-Finley C, Lyle CS, Du L, Goodwin ME, Hall T, Szwedo D, Kaushal GP, and Chambers TC

Subjects

Doxorubicin pharmacology, Enzyme Activation, Etoposide pharmacology, Gene Expression drug effects, Humans, JNK Mitogen-Activated Protein Kinases, Kinetics, Mitogen-Activated Protein Kinases antagonists & inhibitors, Phosphorylation drug effects, Signal Transduction drug effects, Transcription Factor AP-1 metabolism, Tumor Cells, Cultured, Vinblastine pharmacology, Antineoplastic Agents, Phytogenic pharmacology, Apoptosis, Mitogen-Activated Protein Kinases metabolism, Tumor Suppressor Protein p53 metabolism

Abstract

Assessment of specific apoptosis and survival pathways implicated in anticancer drug action is important for understanding drug mechanisms and modes of resistance in order to improve the benefits of chemotherapy. In order to better examine the role of mitogen-activated protein kinases, including JNK and ERK, as well as the tumor suppressor p53, in the response of tumor cells to chemotherapy, we compared the effects on these pathways of three structurally and functionally distinct antitumor agents. Drug concentrations equal to 50 times the concentration required to reduce cell proliferation by 50% were used. Vinblastine, doxorubicin, or etoposide (VP-16) induced apoptotic cell death in KB-3 carcinoma cells, with similar kinetic profiles of PARP cleavage, caspase 3 activation, and mitochondrial cytochrome c release. All three drugs strongly activated JNK, but only vinblastine induced c-Jun phosphorylation and AP-1 activation. Inhibition of JNK by SP600125 protected cells from drug-induced cytotoxicity. Vinblastine caused inactivation of ERK whereas ERK was unaffected in cells exposed to doxorubicin or VP-16. Inhibition of ERK signaling by the MEK inhibitor, U0126, potentiated the cytotoxic effects of vinblastine and doxorubicin, but not that of VP-16. Vinblastine induced p53 downregulation, and chemical inhibition of p53 potentiated vinblastine-induced cell death, suggesting a protective effect of p53. In contrast, doxorubicin and VP-16 induced p53, and inhibition of p53 decreased drug-induced cell death, suggesting a pro-apoptotic role for p53. These results highlight the differential roles played by several key signal transduction pathways in the mechanisms of action of key antitumor agents, and suggest ways to specifically potentiate their effects in a context-dependent manner. In addition, the novel finding that JNK activation can occur without c-Jun phosphorylation or AP-1 activation has important implications for our understanding of JNK function.

Published

2003

50. Apoptotic pathways of oxidative damage to renal tubular epithelial cells.

Author

Basnakian AG, Kaushal GP, and Shah SV

Subjects

Animals, Caspase Inhibitors, Caspases metabolism, Cisplatin toxicity, Endonucleases antagonists & inhibitors, Endonucleases metabolism, Enzyme Activation, Enzyme Inhibitors pharmacology, Epithelial Cells drug effects, Epithelial Cells metabolism, Gentamicins toxicity, Glycerol toxicity, Humans, Hypoxia metabolism, Kidney Tubules cytology, Kidney Tubules drug effects, Reactive Oxygen Species antagonists & inhibitors, Reactive Oxygen Species metabolism, Apoptosis physiology, Kidney Tubules metabolism, Oxidative Stress physiology

Abstract

Toxic renal failure induced by gentamicin, glycerol, or cisplatin, as well as ischemic renal failure in vivo and hypoxia/reoxygenation of tubular epithelial cells in vitro, induces the production of reactive oxygen metabolites (ROM). Generation of ROM is responsible for the induction of tubular epithelial cell death, which is mediated by caspases and/or endonucleases. Scavenging of ROM protects tubular epithelium from caspase and endonuclease activation and from cell death. Thus, the inhibition of ROM production combined with the pharmacological control of caspase and endonuclease pathways may provide future modalities in the prevention or treatment of acute renal failure in humans.

Published

2002