Your search keyword '"Reiné J"' showing total 38 results

1. Neutrophil function is impaired in paediatric patients with malignancy and may be a useful clinical marker

Author

Reiné, J., Cooper, K., Sewell, A., Lyall, J., Thorbinson, C., Hincks, E., Ferreira, D. M., Pizer, B., and Morton, B.

Published

2020

2. Agglutination by anti-capsular polysaccharide antibody is associated with protection against experimental human pneumococcal carriage

Author

Mitsi, E., Roche, A.M., Reiné, J., Zangari, T., Owugha, J.T., Pennington, S.H., Gritzfeld, J.F., Wright, A.D., Collins, A.M., van Selm, S., de Jonge, M.I., Gordon, S.B., Weiser, J.N., and Ferreira, D.M.

Published

2017

3. The whole blood phagocytosis assay: a clinically relevant test of neutrophil function and dysfunction in community-acquired pneumonia

Author

Reiné, J., Rylance, J., Ferreira, D. M., Pennington, S. H., Welters, I. D., Parker, R., and Morton, B.

Published

2020

4. Human alveolar macrophages predominately express combined classical M1 and M2 surface markers in steady state

Author

Mitsi, Elena, Kamng’ona, Raphael, Rylance, Jamie, Solórzano, Carla, Jesus Reiné, J., Mwandumba, Henry C., Ferreira, Daniela M., and Jambo, Kondwani C.

Published

2018

5. Experimental human pneumococcal colonization in older adults is feasible and safe, not immunogenic

Author

Adler, H, primary, German, EL, primary, Mitsi, E, primary, Nikolaou, E, primary, Pojar, S, primary, Hales, Caroline, primary, Robinson, R, primary, Connor, V, primary, Hill, H, primary, Hyder-Wright, AD, primary, Lazarova, L, primary, Lowe, C, primary, Smith, EL, primary, Wheeler, I, primary, Zaidi, SR, primary, Jochems, SP, primary, Loukov, D, primary, Reiné, J, primary, Solórzano-Gonzalez, C, primary, de Gorguette d'Argoeuves, P, primary, Jones, T, primary, Goldblatt, D, primary, Chen, T, primary, Aston, SJ, primary, French, N, primary, Collins, AM, primary, Gordon, SB, primary, Ferreira, DM, primary, and Rylance, J, primary

Published

2021

6. Nonspecific effects of oral vaccination with live-attenuated Salmonella Typhi strain Ty21a

Author

Pennington, S. H., Ferreira, D. M., Caamaño-Gutiérrez, E., Reiné, J., Hewitt, C., Hyder-Wright, A. D., Gordon, S. B., and Gordon, M. A.

Subjects

Adult, CD4-Positive T-Lymphocytes, Male, Immunology, Polysaccharides, Bacterial, Typhoid-Paratyphoid Vaccines, Vaccination, SciAdv r-articles, Administration, Oral, Middle Aged, Salmonella typhi, Vaccines, Attenuated, Healthy Volunteers, Monocytes, Young Adult, Cytokines, Humans, Female, Typhoid Fever, Research Articles, Research Article

Abstract

Vaccination with weakened strains of Salmonella may protect against other infections., Epidemiological and immunological evidence suggests that some vaccines can reduce all-cause mortality through nonspecific changes made to innate immune cells. Here, we present the first data to describe the nonspecific immunological impact of oral vaccination with live-attenuated Salmonella Typhi strain Ty21a. We vaccinated healthy adults with Ty21a and assessed aspects of innate and adaptive immunity over the course of 6 months. Changes to monocyte phenotype/function were observed for at least 3 months. Changes to innate and adaptive immune cell cytokine production in response to stimulation with vaccine and unrelated nonvaccine antigens were observed over the 6-month study period. The changes that we have observed could influence susceptibility to infection through altered immune responses mounted to subsequently encountered pathogens. These changes could influence all-cause mortality.

Published

2019

7. Cerebral palsy in Morocco: state of affairs and challenges

Author

Najib Kissani, Reine Joephane Bikouta Ouadika, Hafid Arabi, Saloua Khalfaoui, and Youness Abdelfettah

Subjects

cerebral palsy, disability, morocco, Medicine, Pediatrics, RJ1-570

Abstract

Cerebral palsy (CP) constitutes a major public health problem in Morocco; there is a lack of prevalence and incidence studies. Objectives. The aim of our work is to study and analyze the epidemiological profile of disability, list the challenges and pitfalls concerning the management of CP in Morocco and developing countries, and highlight practical recommendations for health policymakers in terms of CP in particular and disability in general. Material and methods. Authors performed a literature search using MEDLINE, EMBASE, SCIENCE DIRECT, and Google scholar, but also searched in international and local journals to identify articles that examined CP in Morocco. Combination of keywords, such as “Cerebral Palsy” “disability” and “nervous system”, and matching it with “Morocco”, or other developing countries. Outcomes. There are an unsatisfactory number of specialists in physical medicine, lack of good collaboration between specialists involved in CP management and physiotherapists. This situation is more pronounced in small cities and rural areas. However, in Morocco compared to other developing countries, as in Sub-Saharan Africa, the situation is much better. Conclusion. CP is becoming a priority of Moroccan ministry of health and ministry of social affairs and huge improvements are made, mainly in university hospitals, the use of new techniques and reducing the management gap of regional hospitals, and rural areas with the recent use of telerehabilitation.

Published

2022

8. ESICM LIVES 2016: part one: Milan, Italy. 1-5 October 2016

Author

Bos, L., Schouten, L., van Vught, L., Wiewel, M., Ong, D., Cremer, O., Artigas, A., Martin-Loeches, I., Hoogendijk, A., van der Poll, T., Horn, J., Juffermans, N., Schultz, M., de Prost, N., Pham, T., Carteaux, G., Dessap, A. Mekontso, Brun-Buisson, C., Fan, E., Bellani, G., Laffey, J., Mercat, A., Brochard, L., Maitre, B., Howells, P. A., Thickett, D. R., Knox, C., Park, D. P., Gao, F., Tucker, O., Whitehouse, T., McAuley, D. F., Perkins, G. D., Pisani, L., Roozeman, J. P., Simonis, F. D., Giangregorio, A., Schouten, L. R., Van der Hoeven, S. M., Neto, A. Serpa, Festic, E., Dondorp, A. M., Grasso, S., Bos, L. D., Schultz, M. J., Koster-Brouwer, M., Verboom, D., Scicluna, B., van de Groep, K., Frencken, J., Bonten, M., Ko, J. I., Kim, K. S., Suh, G. J., Kwon, W. Y., Kim, K., Shin, J. H., Ranzani, O. T., Prina, E., Menendez, R., Ceccato, A., Mendez, R., Cilloniz, C., Gabarrus, A., Ferrer, M., Torres, A., Urbano, A., Zhang, L. A., Swigon, D., Pike, F., Parker, R. S., Clermont, G., Scheer, C., Kuhn, S. O., Modler, A., Vollmer, M., Fuchs, C., Hahnenkamp, K., Rehberg, S., Gründling, M., Taggu, A., Darang, N., Öveges, N., László, I., Tánczos, K., Németh, M., Lebák, G., Tudor, B., Érces, D., Kaszaki, J., Huber, W., Trásy, D., Molnár, Z., Ferrara, G., Edul, V. S. Kanoore, Canales, H. S., Martins, E., Canullán, C., Murias, G., Pozo, M. O., Eguillor, J. F. Caminos, Buscetti, M. G., Ince, C., Dubin, A., Aya, H. D., Rhodes, A., Fletcher, N., Grounds, R. M., Cecconi, M., Jacquet-Lagrèze, M., Riche, M., Schweizer, R., Portran, P., Fornier, W., Lilot, M., Neidecker, J., Fellahi, J. L., Escoresca-Ortega, A., Gutiérrez-Pizarraya, A., Charris-Castro, L., Corcia-Palomo, Y., Fernandez-Delgado, E., Garnacho-Montero, J., Roger, C., Muller, L., Elotmani, L., Lipman, J., Lefrant, J. Y., Roberts, J. A., Muñoz-Bermúdez, R., Samper, M., Climent, C., Vasco, F., Sara, V., Luque, S., Campillo, N., Cerrato, S. Grau, Masclans, J. R., Alvarez-Lerma, F., Brugger, S. Carvalho, Jimenez, G. Jimenez, Torner, M. Miralbés, Cabello, J. Trujillano, Garrido, B. Balsera, Casals, X. Nuvials, Gaite, F. Barcenilla, Vidal, M. Vallverdú, Martínez, M. Palomar, Gusarov, V., Shilkin, D., Dementienko, M., Nesterova, E., Lashenkova, N., Kuzovlev, A., Zamyatin, M., Demoule, A., Carreira, S., Lavault, S., Palancca, O., Morawiec, E., Mayaux, J., Arnulf, I., Similowski, T., Rasmussen, B. S., Maltesen, R. G., Hanifa, M., Pedersen, S., Kristensen, S. R., Wimmer, R., Panigada, M., Bassi, G. Li, Kolobow, T., Zanella, A., Cressoni, M., Berra, L., Parrini, V., Kandil, H., Salati, G., Livigni, S., Amatu, A., Andreotti, A., Tagliaferri, F., Moise, G., Mercurio, G., Costa, A., Vezzani, A., Lindau, S., Babel, J., Cavana, M., Consonni, D., Pesenti, A., Gattinoni, L., Mansouri, P., Zand, F., Zahed, L., Dehghanrad, F., Bahrani, M., Ghorbani, M., Cambiaghi, B., Moerer, O., Mauri, T., Kunze-Szikszay, N., Ritter, C., Quintel, M., Vilander, L. M., Kaunisto, M. A., Vaara, S. T., Pettilä, V., Mulier, J. L. G. Haitsma, Rozemeijer, S., Spoelstra-de Man, A. M. E., Elbers, P. E., Tuinman, P. R., de Waard, M. C., Oudemans-van Straaten, H. M., Liberatore, A. M. A., Souza, R. B., Martins, A. M. C. R. P. F., Vieira, J. C. F., Koh, I. H. J., Martínez, M. Galindo, Sánchez, R. Jiménez, Gascón, L. Martínez, Mulero, M. D. Rodríguez, Freire, A. Ortín, Muñoz, A. Ojados, Acebes, S. Rebollo, Martínez, Á. Fernández, Aliaga, S. Moreno, Para, L. Herrera, Payá, J. Murcia, Mulero, F. Rodríguez, Guerci, P., Ince, Y., Heeman, P., Ergin, B., Uz, Z., Massey, M., Papatella, R., Bulent, E., Toraman, F., Longbottom, E. R., Torrance, H. D., Owen, H. C., Hinds, C. J., Pearse, R. M., O’Dywer, M. J., Trogrlic, Z., van der Jagt, M., Lingsma, H., Ponssen, H. H., Schoonderbeek, J. F., Schreiner, F., Verbrugge, S. J., Duran, S., van Achterberg, T., Bakker, J., Gommers, D. A. M. P. J., Ista, E., Krajčová, A., Waldauf, P., Duška, F., Shah, A., Roy, N., McKechnie, S., Doree, C., Fisher, S., Stanworth, S. J., Jensen, J. F., Overgaard, D., Bestle, M. H., Christensen, D. F., Egerod, I., Pivkina, A., Zhivotneva, I., Pasko, N., Alklit, A., Hansen, R. L., Knudsen, H., Grode, L. B., Hravnak, M., Chen, L., Dubrawski, A., Pinsky, M. R., Parry, S. M., Knight, L. D., Connolly, B. C., Baldwin, C. E., Puthucheary, Z. A., Denehy, L., Hart, N., Morris, P. E., Mortimore, J., Granger, C. L., Jensen, H. I., Piers, R., Van den Bulcke, B., Malmgren, J., Metaxa, V., Reyners, A. K., Darmon, M., Rusinova, K., Talmor, D., Meert, A. P., Cancelliere, L., Zubek, L., Maia, P., Michalsen, A., Decruyenaere, J., Kompanje, E., Vanheule, S., Azoulay, E., Vansteelandt, S., Benoit, D., Ryan, C., Dawson, D., Ball, J., Noone, K., Aisling, B., Prudden, S., Ntantana, A., Matamis, D., Savvidou, S., Giannakou, M., Gouva, M., Nakos, G., Koulouras, V., Aron, J., Lumley, G., Milliken, D., Dhadwal, K., McGrath, B. A., Lynch, S. J., Bovento, B., Sharpe, G., Grainger, E., Pieri-Davies, S., Wallace, S., McGrath, B., Jung, M., Cho, J., Park, H., Suh, G., Kousha, O., Paddle, J., Gripenberg, L. Gamrin, Rehal, M. Sundström, Wernerman, J., Rooyackers, O., de Grooth, H. J., Choo, W. P., Spoelstra-de Man, A. M., Swart, E. L., Talan, L., Güven, G., Altıntas, N. D., Padar, M., Uusvel, G., Starkopf, L., Starkopf, J., Blaser, A. Reintam, Kalaiselvan, M. S., Arunkumar, A. S., Renuka, M. K., Shivkumar, R. L., Volbeda, M., ten Kate, D., Hoekstra, M., van der Maaten, J. M., Nijsten, M. W., Komaromi, A., Norberg, Å., Smedberg, M., Mori, M., Pettersson, L., Theodorakopoulou, M., Christodoulopoulou, T., Diamantakis, A., Frantzeskaki, F., Kontogiorgi, M., Chrysanthopoulou, E., Lygnos, M., Diakaki, C., Armaganidis, A., Gundogan, K., Dogan, E., Coskun, R., Muhtaroglu, S., Sungur, M., Ziegler, T., Guven, M., Kleyman, A., Khaliq, W., Andreas, D., Singer, M., Meierhans, R., Schuepbach, R., De Brito-Ashurst, I., Sabetian, G., Nikandish, R., Hagar, F., Masjedi, M., Maghsudi, B., Vazin, A., Asadpour, E., Kao, K. C., Chiu, L. C., Hung, C. Y., Chang, C. H., Li, S. H., Hu, H. C., El Maraghi, S., Ali, M., Rageb, D., Helmy, M., Marin-Corral, J., Vilà, C., Vàzquez, A., Martín-Loeches, I., Díaz, E., Yébenes, J. C., Rodriguez, A., Álvarez-Lerma, F., Varga, N., Cortina-Gutiérrez, A., Dono, L., Martínez-Martínez, M., Maldonado, C., Papiol, E., Pérez-Carrasco, M., Ferrer, R., Nweze, K., Morton, B., Welters, I., Houard, M., Voisin, B., Ledoux, G., Six, S., Jaillette, E., Nseir, S., Romdhani, S., Bouneb, R., Loghmari, D., Aicha, N. Ben, Ayachi, J., Meddeb, K., Chouchène, I., Khedher, A., Boussarsar, M., Chan, K. S., Yu, W. L., Nolla, J., Vidaur, L., Bonastre, J., Suberbiola, B., Guerrero, J. E., Coll, N. Ramon, Jiménez, G. Jiménez, Calero, J. Codina, García, M., de la Torre, M. C., Vendrell, E., Palomera, E., Güell, E., Serra-Prat, M., Bermejo-Martín, J. F., Almirall, J., Tomas, E., Escoval, A., Froe, F., Pereira, M. H. Vitoria, Velez, N., Viegas, E., Filipe, E., Groves, C., Reay, M., Ballin, A., Facchin, F., Sartori, G., Zarantonello, F., Campello, E., Radu, C. M., Rossi, S., Ori, C., Simioni, P., Umei, N., Shingo, I., Santos, A. C., Candeias, C., Moniz, I., Marçal, R., e Silva, Z. Costa, Ribeiro, J. M., Georger, J. F., Ponthus, J. P., Tchir, M., Amilien, V., Ayoub, M., Barsam, E., Martucci, G., Panarello, G., Tuzzolino, F., Capitanio, G., Ferrazza, V., Carollo, T., Giovanni, L., Arcadipane, A., Sánchez, M. López, González-Gay, M. A., Díaz, F. J. Llorca, López, M. I. Rubio, Zogheib, E., Villeret, L., Nader, J., Bernasinski, M., Besserve, P., Caus, T., Dupont, H., Morimont, P., Habran, S., Hubert, R., Desaive, T., Blaffart, F., Janssen, N., Guiot, J., Pironet, A., Dauby, P., Lambermont, B., Pettenuzzo, T., Citton, G., Kirakli, C., Ediboglu, O., Ataman, S., Yarici, M., Tuksavul, F., Keating, S., Gibson, A., Gilles, M., Dunn, M., Price, G., Young, N., Remeta, P., Bishop, P., Zamora, M. D. Fernández, Muñoz-Bono, J., Curiel-Balsera, E., Aguilar-Alonso, E., Hinojosa, R., Gordillo-Brenes, A., Arboleda-Sánchez, J. A., Skorniakov, I., Vikulova, D., Whiteley, C., Shaikh, O., Jones, A., Ostermann, M., Forni, L., Scott, M., Sahatjian, J., Linde-Zwirble, W., Hansell, D., Laoveeravat, P., Srisawat, N., Kongwibulwut, M., Peerapornrattana, S., Suwachittanont, N., Wirotwan, T. O., Chatkaew, P., Saeyub, P., Latthaprecha, K., Tiranathanagul, K., Eiam-ong, S., Kellum, J. A., Berthelsen, R. E., Perner, A., Jensen, A. E. K., Jensen, J. U., Gebhard, D. J., Price, J., Kennedy, C. E., Akcan-Arikan, A., Kang, Y. R., Nakamae, M. N., Hamed, K., Khaled, M. M., Soliman, R. Aly, Mokhtar, M. Sherif, Seller-Pérez, G., Arias-Verdú, D., Llopar-Valdor, E., De-Diós-Chacón, I., Quesada-García, G., Herrera-Gutierrez, M. E., Hafes, R., Carroll, G., Doherty, P., Wright, C., Vera, I. G. Guerra, Ralston, M., Gemmell, M. L., MacKay, A., Black, E., Docking, R. I., Appleton, R., Ralston, M. R., Gemmell, L., Mackay, A., Röttgering, J. G., Elbers, P. W. G., Mejeni, N., Nsiala, J., Kilembe, A., Akilimali, P., Thomas, G., Andersson, A. E., Fagerdahl, A. M., Knudsen, V., Cheikh, A. Ben, Hamdaoui, Y., Guiga, A., Fraj, N., Sma, N., Chouchene, I., Bouafia, N., Amirian, A., Ziaian, B., Fleischmann, C., Thomas-Rueddel, D. O., Schettler, A., Schwarzkopf, D., Stacke, A., Reinhart, K., Martins, A., Sousa, P., Snell, G., Matsa, R., Paary, T. T. S., Cavalheiro, A. M., Rocha, L. L., Vallone, C. S., Tonilo, A., Lobato, M. D. S., Malheiro, D. T., Sussumo, G., Lucino, N. M., Rosenthal, V. D., Dashti, A. Sanaei, Yousefipour, A., Goodall, J. R., Williamson, M., Tant, E., Thomas, N., Balci, C., Gonen, C., Haftacı, E., Gurarda, H., Karaca, E., Paldusová, B., Zýková, I., Šímová, D., Houston, S., D’Antona, L., Lloyd, J., Garnelo-Rey, V., Sosic, M., Sotosek-Tokmazic, V., Kuharic, J., Antoncic, I., Dunatov, S., Sustic, A., Chong, C. T., Sim, M., Lyovarin, T., Díaz, F. M. Acosta, Galdó, S. Narbona, Garach, M. Muñoz, Romero, O. Moreno, Bailón, A. M. Pérez, Pinel, A. Carranza, Colmenero, M., Gritsan, A., Gazenkampf, A., Korchagin, E., Dovbish, N., Lee, R. M., Lim, M. P. P., Lim, B. C. L., See, J. J., Assis, R., Filipe, F., Lopes, N., Pessoa, L., Pereira, T., Catorze, N., Aydogan, M. S., Aldasoro, C., Marchio, P., Jorda, A., Mauricio, M. D., Guerra-Ojeda, S., Gimeno-Raga, M., Colque-Cano, M., Bertomeu-Artecero, A., Aldasoro, M., Valles, S. L., Tonon, D., Triglia, T., Martin, J. C., Alessi, M. C., Bruder, N., Garrigue, P., Velly, L., Spina, S., Scaravilli, V., Marzorati, C., Colombo, E., Savo, D., Vargiolu, A., Cavenaghi, G., Citerio, G., Andrade, A. H. V., Bulgarelli, P., Araujo, J. A. P., Gonzalez, V., Souza, V. A., Massant, C., Filho, C. A. C. Abreu, Morbeck, R. A., Burgo, L. E., van Groenendael, R., van Eijk, L. T., Leijte, G. P., Koeneman, B., Kox, M., Pickkers, P., García-de la Torre, A., de la Torre-Prados, M., Fernández-Porcel, A., Rueda-Molina, C., Nuevo-Ortega, P., Tsvetanova-Spasova, T., Cámara-Sola, E., García-Alcántara, A., Salido-Díaz, L., Liao, X., Feng, T., Zhang, J., Cao, X., Wu, Q., Xie, Z., Li, H., Kang, Y., Winkler, M. S., Nierhaus, A., Mudersbach, E., Bauer, A., Robbe, L., Zahrte, C., Schwedhelm, E., Kluge, S., Zöllner, C., Mitsi, E., Pennington, S. H., Reine, J., Wright, A. D., Parker, R., Welters, I. D., Blakey, J. D., Rajam, G., Ades, E. W., Ferreira, D. M., Wang, D., Kadioglu, A., Gordon, S. B., Koch, R., Rahamat-Langedoen, J., Schloesser, J., de Jonge, M., Bringue, J., Guillamat-Prats, R., Torrents, E., Martinez, M. L., Camprubí-Rimblas, M., Blanch, L., Park, S. Y., Park, Y. B., Song, D. K., Shrestha, S., Park, S. H., Koh, Y., Park, M. J., Hong, C. W., Lesur, O., Coquerel, D., Sainsily, X., Cote, J., Söllradl, T., Murza, A., Dumont, L., Dumaine, R., Grandbois, M., Sarret, P., Marsault, E., Salvail, D., Auger-Messier, M., Chagnon, F., Lauretta, M. P., Greco, E., Dyson, A., Preau, S., Ambler, M., Sigurta, A., Saeed, S., Sarıca, L. Topcu, Zibandeh, N., Genc, D., Gul, F., Akkoc, T., Kombak, E., Cinel, L., Cinel, I., Pollen, S. J., Arulkumaran, N., Warnes, G., Pennington, D. J., Brohi, K., O’Dwyer, M. J., Kim, H. Y., Na, S., Kim, J., Chang, Y. F., Chao, A., Shih, P. Y., Lee, C. T., Yeh, Y. C., Chen, L. W., Adriaanse, M., Rietdijk, W., Funcke, S., Sauerlaender, S., Saugel, B., Pinnschmidt, H., Reuter, D. A., Nitzschke, R., Perbet, S., Biboulet, C., Lenoire, A., Bourdeaux, D., Pereira, B., Plaud, B., Bazin, J. E., Sautou, V., Mebazaa, A., Constantin, J. M., Legrand, M., Boyko, Y., Jennum, P., Nikolic, M., Oerding, H., Holst, R., Toft, P., Nedergaard, H. K., Haberlandt, T., Park, S., Kim, S., Cho, Y. J., Lim, Y. J., Chan, A., Tang, S., Nunes, S. L., Forsberg, S., Blomqvist, H., Berggren, L., Sörberg, M., Sarapohja, T., Wickerts, C. J., Hofhuis, J. G. M., Rose, L., Blackwood, B., Akerman, E., Mcgaughey, J., Fossum, M., Foss, H., Georgiou, E., Graff, H. J., Kalafati, M., Sperlinga, R., Schafer, A., Wojnicka, A. G., Spronk, P. E., Khalili, F., Afshari, R., Khodaei, H. Haddad, Javadpour, S., Petramfar, P., Nasimi, S., Tabei, H., Gunther, A., Hansen, J. O., Sackey, P., Storm, H., Bernhardsson, J., Sundin, Ø., Bjärtå, A., Bienert, A., Smuszkiewicz, P., Wiczling, P., Przybylowski, K., Borsuk, A., Trojanowska, I., Matysiak, J., Kokot, Z., Paterska, M., Grzeskowiak, E., Messina, A., Bonicolini, E., Colombo, D., Moro, G., Romagnoli, S., De Gaudio, A. R., Corte, F. Della, Romano, S. M., Silversides, J. A., Major, E., Mann, E. E., Ferguson, A. J., Mcauley, D. F., Marshall, J. C., Diaz-Rodriguez, J. A., Silva-Medina, R., Gomez-Sandoval, E., Gomez-Gonzalez, N., Soriano-Orozco, R., Gonzalez-Carrillo, P. L., Hernández-Flores, M., Pilarczyk, K., Lubarksi, J., Wendt, D., Dusse, F., Günter, J., Huschens, B., Demircioglu, E., Jakob, H., Palmaccio, A., Dell’Anna, A. M., Grieco, D. L., Torrini, F., Iaquaniello, C., Bongiovanni, F., Antonelli, M., Toscani, L., Antonakaki, D., Bastoni, D., Jozwiak, M., Depret, F., Teboul, J. L., Alphonsine, J., Lai, C., Richard, C., Monnet, X., Demeter, G., Kertmegi, I., Hasanin, A., Lotfy, A., El-adawy, A., Nassar, H., Mahmoud, S., Abougabal, A., Mukhtar, A., Quinty, F., Habchi, S., Luzi, A., Antok, E., Hernandez, G., Lara, B., Enberg, L., Ortega, M., Leon, P., Kripper, C., Aguilera, P., Kattan, E., Lehmann, M., Sakka, S., Bein, B., Schmid, R. M., Preti, J., Creteur, J., Herpain, A., Marc, J., Trojette, F., Bar, S., Kontar, L., Titeca, D., Richecoeur, J., Gelee, B., Verrier, N., Mercier, R., Lorne, E., Maizel, J., Slama, M., Abdelfattah, M. E., Eladawy, A., Elsayed, M. A. Ali, Montenegro, A. Pedraza, Zepeda, E. Monares, Granillo, J. Franco, Sánchez, J. S. Aguirre, Alejo, G. Camarena, Cabrera, A. Rugerio, Montoya, A. A. Tanaka, Lee, C., Hatib, F., Cannesson, M., Theerawit, P., Morasert, T., Sutherasan, Y., Zani, G., Mescolini, S., Diamanti, M., Righetti, R., Scaramuzza, A., Papetti, M., Terenzoni, M., Gecele, C., Fusari, M., Hakim, K. A., Chaari, A., Ismail, M., Elsaka, A. H., Mahmoud, T. M., Bousselmi, K., Kauts, V., Casey, W. F., Hutchings, S. D., Naumann, D., Wendon, J., Watts, S., Kirkman, E., Jian, Z., Buddi, S., Settels, J., Bertini, P., Guarracino, F., Trepte, C., Richter, P., Haas, S. A., Eichhorn, V., Kubitz, J. C., Soliman, M. S., Hamimy, W. I., Fouad, A. Z., Mukhtar, A. M., Charlton, M., Tonks, L., Mclelland, L., Coats, T. J., Thompson, J. P., Sims, M. R., Williams, D., Roushdy, D. Z., Soliman, R. A., Nahas, R. A., Arafa, M. Y., Hung, W. T., Chiang, C. C., Huang, W. C., Lin, K. C., Lin, S. C., Cheng, C. C., Kang, P. L., Wann, S. R., Mar, G. Y., Liu, C. P., Carranza, M. Lopez, Fernandez, H. Sancho, Roman, J. A. Sanchez, Lucena, F., Garcia, A. Campanario, Vazquez, A. Loza, Serrano, A. Lesmes, Moreira, L. Sayagues, Vidal-Perez, R., Herranz, U. Anido, Acuna, J. M. Garcia, Gil, C. Pena, Allut, J. L. Garcia, Sedes, P. Rascado, Lopez, C. Martin, Paz, E. Saborido, Rodriguez, C. Galban, Gonzalez-Juanatey, J. R., Vallejo-Baez, A., de la Torre-Prados, M. V., Marharaj, R., Gervasio, K., Bottiroli, M., Mondino, M., De Caria, D., Calini, A., Montrasio, E., Milazzo, F., Gagliardone, M. P., Vallejo-Báez, A., Anido, U., Cheikh-Bouhlel, M., Dela Cruz, M. P. R. D. L., Bernardo, J. M., Galfo, F., Marino, A., Chao, C. C., Hou, P., Hung, C. C., Chiang, C. H., Liou, Y. J., Hung, S. M., Lin, Y. S., Kuo, F. Y., Chiou, K. R., Chen, C. J., Yan, L. S., Liu, C. Y., Wang, H. H., Chen, H. L., Ho, C. K., Grewal, S., Gopal, S., Corbett, C., Wilson, A., Capps, J., Ayoub, W., Lomas, A., Ghani, S., Moore, J., Atkinson, D., Sharman, M., Swinnen, W., Pauwels, J., Mignolet, K., Pannier, E., Koch, A., Sarens, T., Temmerman, W., Elmenshawy, A. M., Fayed, A. M., Elboriuny, M., Hamdy, E., Zakaria, E., Falk, A. C., Petosic, A., Olafsen, K., Wøien, H., Flaatten, H., Sunde, K., Agra, J. J. Cáceres, Cabrera, J. L. Santana, Santana, J. D. Martín, Alzola, L. Melián, Pérez, H. Rodríguez, Pires, T. Castro, Calderón, H., Pereira, A., Castro, S., Granja, C., Norkiene, I., Urbanaviciute, I., Kezyte, G., Ringaitiene, D., Jovaisa, T., Vogel, G., Johansson, U. B., Sandgren, A., Svensen, C., Joelsson-Alm, E., Leite, M. A., Murbach, L. D., Osaku, E. F., Costa, C. R. L. M., Pelenz, M., Neitzke, N. M., Moraes, M. M., Jaskowiak, J. L., Silva, M. M. M., Zaponi, R. S., Abentroth, L. R. L., Ogasawara, S. M., Jorge, A. C., Duarte, P. A. D., Barreto, J., Duarte, S. T., Taba, S., Miglioranza, D., Gund, D. P., Lordani, C. F., Vollmer, H., Gager, M., Waldmann, C., Mazzeo, A. T., Tesio, R., Filippini, C., Vallero, M. E., Giolitti, C., Caccia, S., Medugno, M., Tenaglia, T., Rosato, R., Mastromauro, I., Brazzi, L., Terragni, P. P., Urbino, R., Fanelli, V., Ranieri, V. M., Mascia, L., Ballantyne, J., Paton, L., Perez-Teran, P., Roca, O., Ruiz-Rodriguez, J. C., Zapatero, A., Serra, J., Bianzina, S., Cornara, P., Rodi, G., Tavazzi, G., Pozzi, M., Iotti, G. A., Mojoli, F., Braschi, A., Vishnu, A., Buche, D., Pande, R., Moolenaar, D. L. J., Bakhshi-Raiez, F., Dongelmans, D. A., de Keizer, N. F., de Lange, D. W., Fernández, I. Fuentes, Baño, D. Martínez, Moreno, J. L. Buendía, Rubio, R. Jara, Scott, J., Phelan, D., Morely, D., O’Flynn, J., Stapleton, P., Lynch, M., Marsh, B., Carton, E., O’Loughlin, C., Cheng, K. C., Sung, M. I., Elghonemi, M. O., Saleh, M. H., Meyhoff, T. S., Krag, M., Hjortrup, P. B., Møller, M. H., Öhman, T., Sigmundsson, T., Redondo, E., Hallbäck, M., Suarez-Sipmann, F., Björne, H., Sander, C. Hällsjö, Chiumello, D., Chiurazzi, C., Brioni, M., Algieri, I., Guanziroli, M., Vergani, G., Tonetti, T., Tomic, I., Colombo, A., Crimella, F., Carlesso, E., Gasparovic, V., El-Sherif, R., Al-Basser, M. Abd, Raafat, A., El-Sherif, A., Schouten, L. R. A., Cremer, O. L., Ong, D. S. Y., Amoruso, G., Cinnella, G., Bos, L. D. J., Schmidle, P., Findeisen, M., Hoppmann, P., Jaitner, J., Brettner, F., Lahmer, T., Rajagopalan, G., Bansal, V., Frank, R., Hinds, R., Levitt, J., Siddiqui, S., Gilbert, J. P., Sim, K., Wang, C. H., Li, I. J., Tang, W. R., Persona, P., De Cassai, A., Franco, M., Goffi, A., Ruiz, B. Llorente, Varas, J. Lujan, Montero, R. Molina, Delgado, C. Pintado, Navarrete, O., Mezquita, M. Vazquez, Peces, E. Alonso, Nakamura, M. A. M., Hajjar, L. A., Galas, F. R. B. G., Ortiz, T. A., Amato, M. B. P., Bitker, L., Costes, N., Le Bars, D., Lavenne, F., Mojgan, D., Richard, J. C., Massari, D., Gotti, M., Cadringher, P., Zerman, A., Türkoğlu, M., Arık, G., Yıldırım, F., Güllü, Z., Kara, I., Boyacı, N., Aydoğan, B. Basarık, Gaygısız, Ü., Gönderen, K., Aygencel, G., Aydoğdu, M., Ülger, Z., Gürsel, G., Riera, J., Toral, C. Maldonado, Mazo, C., Martínez, M., Baldirà, J., Lagunes, L., Roman, A., Deu, M., Rello, J., Levine, D. J., Mohus, R. M., Askim, Å., Paulsen, J., Mehl, A., Dewan, A. T., Damås, J. K., Solligård, E., Åsvold, B. O., DeWan, A., Aktepe, O., Kara, A., Yeter, H., Topeli, A., Norrenberg, M., Devroey, M., Khader, H., Preiser, J. C., Tang, Z., Qiu, C., Tong, L., Cai, C., Apostolopoulou, O., Moon, J. Y., Park, M. R., Kwon, I. S., Chon, G. R., Ahn, J. Y., Kwon, S. J., Chang, Y. J., Lee, J. Y., Yoon, S. Y., Lee, J. W., Kostalas, M., Mckinlay, J., Kooner, G., Dudas, G., Horton, A., Kerr, C., Karanjia, N., Creagh-Brown, B., Altintas, N. D., Izdes, S., Keremoglu, O., Alkan, A., Neselioglu, S., Erel, O., Tardif, N., Gustafsson, T., MacEachern, K. N., Traille, M., Bromberg, I., Lapinsky, S. E., Moore, M. J., García-Garmendia, J. L., Villarrasa-Clemente, F., Maroto-Monserrat, F., Rufo-Tejeiro, O., Jorge-Amigo, V., Sánchez-Santamaría, M., Colón-Pallarés, C., Barrero-Almodóvar, A., Gallego-Lara, S., Anthon, C. T., Müller, R. B., Haase, N., Møller, K., Wetterslev, J., Nakanishi, M., Kuriyama, A., Fukuoka, T., Abd el Halim, M. A., Elsaid hafez, M. H., Moktar, A. M., Elazizy, H. M., Hakim, K. Abdel, Elbahr, M., Mahmoud, T., Khalil, E., Casey, W., Zaky, S. H., Rizk, A., Ahmed, R., Ospina-Tascón, G. A., Marin, A. F. Garcia, Echeverry, G. J., Bermudez, W. F., Madriñan-Navia, H. J., Valencia, J. D., Quiñonez, E., Marulanda, A., Arango-Dávila, C. A., Bruhn, A., De Backer, D., Cortes, D. Orbegozo, Su, F., Vincent, J. L., Tullo, L., Mirabella, L., Di Molfetta, P., Dambrosio, M., Lujan, C. Villavicencio, irigoyen, J. Leache, Cartanya ferré, M., García, R. Carbonell, Ahmed, M., El Ayashi, M., Ayman, E., Salem, M., Fathy, S., Zaghlol, A., Arzapalo, M. F. Aguilar, Valsø, Å., Rustøen, T., Schou-Bredal, I., Skogstad, L., Tøien, K., Padilla, C., Palmeiro, Y., Egbaria, W., Kigli, R., Maertens, B., Blot, K., Blot, S., Santana-Santos, E., dos Santos, E. R., Ferretti-Rebustini, R. E. D. L., dos Santos, R. D. C. C. D. O., Verardino, R. G. S., Bortolotto, L. A., Doyle, A. M., Naldrett, I., Tillman, J., Price, S., Pearson, P., Greaves, J., Goodall, D., Berry, A., Richardson, A., Odundo, G. O., Omengo, P., Obonyo, P., Chanzu, N. M., Kleinpell, R., Sarris, S. J., Nedved, P., Heitschmidt, M., Ben-Ghezala, H., Snouda, S., Djobbi, S., Adhikari, N. K. J., Leasa, D., Fergusson, D., Mckim, D. A., Weblin, J., McWilliams, D., Doesburg, F., Cnossen, F., Dieperink, W., Bult, W., Nijsten, M. W. N., Galvez-Blanco, G. A., Guzman, C. I. Olvera, Stroud, J. Santos, Thomson, R., Llaurado-Serra, M., Lobo-Civico, A., Pi-Guerrero, M., Blanco-Sanchez, I., Piñol-Tena, A., Paños-Espinosa, C., Alabart-Segura, Y., Coloma-Gomez, B., Fernandez-Blanco, A., Braga-Dias, F., Treso-Geira, M., Valeiras-Valero, A., Martinez-Reyes, L., Sandiumenge, A., Jimenez-Herrera, M. F., Prada, R., Juárez, P., Argandoña, R., Díaz, J. J., Ramirez, C. Sánchez, Saavedra, P., Santana, S. Ruiz, Obukhova, O., Kashiya, S., Kurmukov, I. A., Pronina, A. M., Simeone, P., Puybasset, L., Auzias, G., Coulon, O., Lesimple, B., Torkomian, G., Bartkowska-Sniatkowska, A., Szerkus, O., Siluk, D., Bartkowiak-Wieczorek, J., Rosada-Kurasinska, J., Warzybok, J., Kaliszan, R., Caballero, C. Hernandez, Roberts, S., Isgro, G., Hall, D., Guillaume, G., Passouant, O., Dumas, F., Bougouin, W., Champigneulle, B., Arnaout, M., Chelly, J., Chiche, J. D., Varenne, O., Mira, J. P., Marijon, E., Cariou, A., Beerepoot, M., Touw, H. R., Parlevliet, K., Boer, C., Elbers, P. W., Reina, Á. J. Roldán, Palomo, Y. Corcia, Bermúdez, R. Martín, Villén, L. Martín, García, I. Palacios, Izurieta, J. R. Naranjo, Bernal, J. B. Pérez, Jiménez, F. J. Jiménez, Cota-Delgado, F., Kaneko, T., Tanaka, H., Kamikawa, M., Karashima, R., Iwashita, S., Irie, H., Kasaoka, S., Arola, O., Laitio, R., Saraste, A., Airaksinen, J., Pietilä, M., Hynninen, M., Wennervirta, J., Bäcklund, M., Ylikoski, E., Silvasti, P., Nukarinen, E., Grönlund, J., Harjola, V. P., Niiranen, J., Korpi, K., Varpula, M., Roine, R. O., Laitio, T., Salah, S., Hassen, B. G., Fehmi, A. Mohamed, Hsu, Y. C., Barea-Mendoza, J., García-Fuentes, C., Castillo-Jaramillo, M., Dominguez-Aguado, H., Viejo-Moreno, R., Terceros-Almanza, L., Aznárez, S. Bermejo, Mudarra-Reche, C., Xu, W., Chico-Fernández, M., Montejo-González, J. C., Crewdson, K., Thomas, M., Merghani, M., Fenner, L., Morgan, P., Lockey, D., van Lieshout, E. J., Oomen, B., Binnekade, J. M., de Haan, R. J., Juffermans, N. P., Vroom, M. B., Algarte, R., Martínez, L., Sánchez, B., Romero, I., Martínez, F., Quintana, S., Trenado, J., Sheikh, O., Pogson, D., Clinton, R., Riccio, F., Arthur, A., Young, L., Sinclair, A., Markopoulou, D., Venetsanou, K., Filippou, L., Salla, E., Stratouli, S., Alamanos, I., Guirgis, A. H., Rodriguez, R. Gutiérrez, Lorente, M. J. Furones, Guarasa, I. Macias, Ukere, A., Meisner, S., Greiwe, G., Opitz, B., Benten, D., Nashan, B., Fischer, L., Trepte, C. J. C., Behem, C. R., Ana, B., Vazir, A., Gibson, D., Hadavi, M. R., alam, M. Riahi, Sasani, M. R., Parenti, N., Agrusta, F., Palazzi, C., Pifferi, B., Sganzerla, R., Tagliazucchi, F., Luciani, A., Möller, M., Müller-Engelmann, J., Montag, G., Adams, P., Lange, C., Neuzner, J., Gradaus, R., Wodack, K. H., Thürk, F., Waldmann, A. D., Grässler, M. F., Nishimoto, S., Böhm, S. H., Kaniusas, E., Trepte, C. J., Wallin, M., Sipman, F. Suarez, Oldner, A., Colinas, L., Vicho, R., Serna, M., Cuena, R., Canabal, A., Etman, M., El Bahr, M., El Sakka, A., Arali, A., Bond, O., De Santis, P., Iesu, E., Franchi, F., Scolletta, S., Taccone, F. S., Marutyan, Z., Hamidova, L., Shakotko, A., Movsisyan, V., Uysupova, I., Evdokimov, A., Petrikov, S., Calvo, F. J. Redondo, Bejarano, N., Baladron, V., Villazala, R., Redondo, J., Padilla, D., Villarejo, P., Gomez-Gonzalez, C., Mas-Font, S., Puppo-Moreno, A., Herrera-Gutierrez, M., Garcia-Garcia, M., Aldunate-Calvo, S., Plata-Menchaca, E. P., Pérez-Fernández, X. L., Estruch, M., Betbese-Roig, A., Campos, P. Cárdenas, Lora, M. Rojas, Gaibor, N. D. Toapanta, Medina, R. S. Contreras, Sanguino, V. D. Gumucio, Casanova, E. J., Riera, J. Sabater, Kritmetapak, K., Peerapornratana, S., Kittiskulnam, P., Dissayabutra, T., Susantithapong, P., Praditpornsilpa, K., Tungsanga, K., Eiam-Ong, S., Winkelmann, T., Busch, T., Meixensberger, J., Bercker, S., Cabeza, E. M. Flores, Sánchez, M. Sánchez, Giménez, N. Cáceres, Melón, C. Gutierrez, de Lucas, E. Herrero, Estañ, P. Millán, Bernal, M. Hernández, de Lorenzo y Mateos, A. Garcia, Specht, P. A. C., Balik, M., Zakharchenko, M., Los, F., Brodska, H., de Tymowski, C., Augustin, P., Desmard, M., Montravers, P., Stapel, S. N., de Boer, R., Oudemans, H. M., Hollinger, A., Schweingruber, T., Jockers, F., Dickenmann, M., Siegemund, M., Runciman, N., Alban, L., Turrini, C., Sasso, T., Langer, T., Taccone, P., Marenghi, C., Grasselli, G., Wibart, P., Reginault, T., Garcia, M., Barbrel, B., Benard, A., Bader, C., Vargas, F., Bui, H. N., Hilbert, G., Simón, J. M. Serrano, Sánchez, P. Carmona, Ferrón, F. Ruiz, de Acilu, M. García, Marin, J., Antonia, V., Ruano, L., Monica, M., Hong, G., Kim, D. H., Kim, Y. S., Park, J. S., Jee, Y. K., xiang, Z. Yu, Jia-xing, W., dan, W. Xiao, long, N. Wen, Yu, W., Yan, Z., Cheng, X., Kobayashi, T., Onodera, Y., Akimoto, R., Sugiura, A., Suzuki, H., Iwabuchi, M., Nakane, M., Kawamae, K., Sanchez, P. Carmona, Rodriguez, M. D. Bautista, Delgado, M. Rodriguez, Sánchez, V. Martínez de Pinillos, Gómez, A. Mula, Beuret, P., Fortes, C., Lauer, M., Reboul, M., Chakarian, J. C., Fabre, X., Philippon-Jouve, B., Devillez, S., Clerc, M., Rittayamai, N., Sklar, M., Dres, M., Rauseo, M., Campbell, C., West, B., Tullis, D. E., Okada, M., Ahmad, N., Wood, M., Glossop, A., Lucas, J. Higuera, Ortiz, A. Blandino, Alonso, D. Cabestrero, De Pablo Sánchez, R., González, L. Rey, Costa, R., Spinazzola, G., Pizza, A., Ferrone, G., Rossi, M., Conti, G., Ribeiro, H., Alves, J., Sousa, M., Reis, P., Socolovsky, C. S., Cauley, R. P., Frankel, J. E., Beam, A. L., Olaniran, K. O., Gibbons, F. K., Christopher, K. B., Pennington, J., Zolfaghari, P., King, H. S., Kong, H. H. Y., Shum, H. P., Yan, W. W., Kaymak, C., Okumus, N., Sari, A., Erdogdu, B., Aksun, S., Basar, H., Ozcan, A., Ozcan, N., Oztuna, D., Malmgren, J. A., Lundin, S., Torén, K., Eckerström, M., Wallin, A., Waldenström, A. C., Riccio, F. C., Antonio, A. C. P., Leivas, A. F., Kenji, F., James, E., Jonnada, S., Gerrard, C. S., Jones, N., Salciccioli, J. D., Marshall, D. C., Komorowski, M., Hartley, A., Sykes, M. C., Goodson, R., Shalhoub, J., Villanueva, J. R. Fernández, Garda, R. Fernández, Lago, A. M. López, Ruiz, E. Rodríguez, Vaquero, R. Hernández, Rodríguez, C. Galbán, Pérez, E. Varo, Hilasque, C., Oliva, I., Sirgo, G., Martin, M. C., Olona, M., Gilavert, M. C., Bodí, M., Ebm, C., Aggarwal, G., Huddart, S., Quiney, N., Fernandes, S. M., Silva, J. Santos, Gouveia, J., Silva, D., Marques, R., Bento, H., Alvarez, A., Silva, Z. Costa, Diaz, D. Díaz, Martínez, M. Villanova, Herrejon, E. Palencia, de la Gandara, A. Martinez, Gonzalo, G., Lopez, M. A., de Gopegui Miguelena, P. Ruíz, Matilla, C. I. Bernal, Chueca, P. Sánchez, Longares, M. D. C. Rodríguez, Abril, R. Ramos, Aguilar, A. L. Ruíz, de Murillas, R. Garrido López, Fernández, R. Fernández, Laborías, P. Morales, Castellanos, M. A. Díaz, Laborías, M. E. Morales, Park, J., Woo, S., West, T., Powell, E., Rimmer, A., Orford, C., Williams, J., de Gopegui Miguelena, P. Ruiz, Bourne, R. S., Shulman, R., Tomlin, M., Mills, G. H., Borthwick, M., Berry, W., Huertas, D. García, Manzano, F., Villagrán-Ramírez, F., Ruiz-Perea, A., Rodríguez-Mejías, C., Santiago-Ruiz, F., Colmenero-Ruiz, M., König, C., Matt, B., Kortgen, A., Hartog, C. S., Wong, A., Balan, C., Barker, G., Tachaboon, S., Paratz, J., Kayambu, G., Boots, R., Vlasenko, R., Gromova, E., Loginov, S., Kiselevskiy, M., Dolgikova, Y., Tang, K. B., Chau, C. M., Lam, K. N., Gil, E., Suh, G. Y., Park, C. M., Chung, C. R., Lai, C. H., Cheng, Y. J., Colella, V., Zarrillo, N., D’Amico, M., Forfori, F., Pezza, B., Laddomada, T., Beltramelli, V., Pizzaballa, M. L., Doronzio, A., Balicco, B., Kiers, D., van der Heijden, W., Gerretsen, J., de Mast, Q., el Messaoudi, S., Rongen, G., Gomes, M., Riksen, N. P., Kashiwagi, Y., Hayashi, K., Inagaki, Y., Fujita, S., Blet, A., Sadoune, M., Lemarié, J., Bihry, N., Bern, R., Polidano, E., Merval, R., Launay, J. M., Lévy, B., Samuel, J. L., Hartmann, J., Harm, S., and Weber, V.

Published

2016

9. Inflammation of the nasal mucosa is associated with susceptibility to experimental pneumococcal challenge in older adults.

Author

Urban BC, Gonçalves ANA, Loukov D, Passos FM, Reiné J, Gonzalez-Dias P, Solórzano C, Mitsi E, Nikolaou E, O'Connor D, Collins AM, Adler H, Pollard A, Rylance J, Gordon SB, Jochems SP, Nakaya HI, and Ferreira DM

Subjects

Humans, Aged, Disease Susceptibility, Male, Female, Adult, Chemokine CXCL9 metabolism, Chemokine CXCL9 genetics, Chemokine CXCL10 metabolism, Inflammation immunology, Neutrophils immunology, Age Factors, Middle Aged, Neutrophil Activation, Aging immunology, Monocytes immunology, Young Adult, Aged, 80 and over, Nasal Mucosa immunology, Nasal Mucosa microbiology, Streptococcus pneumoniae immunology, Streptococcus pneumoniae physiology, Pneumococcal Infections immunology, Pneumococcal Infections microbiology

Abstract

Streptococcus pneumoniae colonization in the upper respiratory tract is linked to pneumococcal disease development, predominantly affecting young children and older adults. As the global population ages and comorbidities increase, there is a heightened concern about this infection. We investigated the immunological responses of older adults to pneumococcal-controlled human infection by analyzing the cellular composition and gene expression in the nasal mucosa. Our comparative analysis with data from a concurrent study in younger adults revealed distinct gene expression patterns in older individuals susceptible to colonization, highlighted by neutrophil activation and elevated levels of CXCL9 and CXCL10. Unlike younger adults challenged with pneumococcus, older adults did not show recruitment of monocytes into the nasal mucosa following nasal colonization. However, older adults who were protected from colonization showed increased degranulation of cluster of differentiation 8+ T cells, both before and after pneumococcal challenge. These findings suggest age-associated cellular changes, in particular enhanced mucosal inflammation, that may predispose older adults to pneumococcal colonization., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

10. RSV and rhinovirus increase pneumococcal carriage acquisition and density, whereas nasal inflammation is associated with bacterial shedding.

Author

Mitsi E, Nikolaou E, Goncalves A, Blizard A, Hill H, Farrar M, Hyder-Wright A, Akeju O, Hamilton J, Howard A, Elterish F, Solorzano C, Robinson R, Reiné J, Collins AM, Gordon SB, Moxon RE, Weiser JN, Bogaert D, and Ferreira DM

Subjects

Humans, Adult, Male, Female, Young Adult, Bacterial Load, Middle Aged, Inflammation, Respiratory Syncytial Viruses physiology, Respiratory Tract Infections microbiology, Respiratory Tract Infections virology, Adolescent, Nasopharynx microbiology, Nasopharynx virology, Rhinovirus physiology, Streptococcus pneumoniae, Pneumococcal Infections microbiology, Picornaviridae Infections virology, Picornaviridae Infections microbiology, Carrier State microbiology, Respiratory Syncytial Virus Infections virology, Coinfection microbiology, Coinfection virology, Bacterial Shedding

Abstract

Epidemiological studies report the impact of co-infection with pneumococcus and respiratory viruses upon disease rates and outcomes, but their effect on pneumococcal carriage acquisition and bacterial load is scarcely described. Here, we assess this by combining natural viral infection with controlled human pneumococcal infection in 581 healthy adults screened for upper respiratory tract viral infection before intranasal pneumococcal challenge. Across all adults, respiratory syncytial virus (RSV) and rhinovirus asymptomatic infection confer a substantial increase in secondary infection with pneumococcus. RSV also has a major impact on pneumococcal density up to 9 days post challenge. We also study rates and kinetics of bacterial shedding through the nose and oral route in a subset. High levels of pneumococcal colonization density and nasal inflammation are strongly correlated with increased odds of nasal shedding as opposed to cough shedding. Protection against respiratory viral infections and control of pneumococcal density may contribute to preventing pneumococcal disease and reducing bacterial spread., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

11. Tetanus-diphtheria vaccine can prime SARS-CoV-2 cross-reactive T cells.

Author

Fernandez SA, Pelaez-Prestel HF, Fiyouzi T, Gomez-Perosanz M, Reiné J, and Reche PA

Subjects

Humans, Tetanus Toxoid immunology, Animals, Mice, Female, COVID-19 Vaccines immunology, Male, Adult, Spike Glycoprotein, Coronavirus immunology, Middle Aged, Cross Reactions immunology, SARS-CoV-2 immunology, CD8-Positive T-Lymphocytes immunology, Epitopes, T-Lymphocyte immunology, COVID-19 immunology, COVID-19 prevention & control

Abstract

Vaccines containing tetanus-diphtheria antigens have been postulated to induce cross-reactive immunity to severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), which could protect against coronavirus disease (COVID-19). In this work, we investigated the capacity of Tetanus-diphtheria (Td) vaccine to prime existing T cell immunity to SARS-CoV-2. To that end, we first collected known SARS-CoV-2 specific CD8 + T cell epitopes targeted during the course of SARS-CoV-2 infection in humans and identified as potentially cross-reactive with Td vaccine those sharing similarity with tetanus-diphtheria vaccine antigens, as judged by Levenshtein edit distances (≤ 20% edits per epitope sequence). As a result, we selected 25 potentially cross-reactive SARS-CoV-2 specific CD8 + T cell epitopes with high population coverage that were assembled into a synthetic peptide pool (TDX pool). Using peripheral blood mononuclear cells, we first determined by intracellular IFNγ staining assays existing CD8 + T cell recall responses to the TDX pool and to other peptide pools, including overlapping peptide pools covering SARS-CoV-2 Spike protein and Nucleocapsid phosphoprotein (NP). In the studied subjects, CD8 + T cell recall responses to Spike and TDX peptide pools were dominant and comparable, while recall responses to NP peptide pool were less frequent and weaker. Subsequently, we studied responses to the same peptides using antigen-inexperienced naive T cells primed/stimulated in vitro with Td vaccine. Priming stimulations were carried out by co-culturing naive T cells with autologous irradiated peripheral mononuclear cells in the presence of Td vaccine, IL-2, IL-7 and IL-15. Interestingly, naive CD8 + T cells stimulated/primed with Td vaccine responded strongly and specifically to the TDX pool, not to other SARS-CoV-2 peptide pools. Finally, we show that Td-immunization of C57BL/6J mice elicited T cells cross-reactive with the TDX pool. Collectively, our findings support that tetanus-diphtheria vaccines can prime SARS-CoV-2 cross-reactive T cells and likely contribute to shape the T cell responses to the virus., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Fernandez, Pelaez-Prestel, Fiyouzi, Gomez-Perosanz, Reiné and Reche.)

Published

2024

12. Experimental pneumococcal carriage in people living with HIV in Malawi: the first controlled human infection model in a key at-risk population.

Author

Doherty K, Dula D, Chirwa A, Nsomba E, Nkhoma VS, Toto N, Chikaonda T, Kamng'ona R, Phiri J, Reiné J, Ndaferankhande J, Makhaza L, Banda P, Jambo K, Ferreira DM, and Gordon SB

Abstract

Background: As well as suffering a high burden of pneumococcal disease people living with HIV (PLHIV) may contribute to community transmission in sub-Saharan African (sSA) settings. Pneumococcal vaccination is not currently offered to PLHIV in sSA but may prevent disease and reduce transmission. More evidence of vaccine effectiveness against carriage in PLHIV is needed. An Experimental Human Pneumococcal Carriage model (EHPC) has been safely and acceptably used in healthy adults in Malawi to evaluate pneumococcal vaccines against carriage and to identify immune correlates of protection from carriage. This study will establish the same model in PLHIV and will be the first controlled human infection model (CHIM) in this key population. Methods: Healthy participants with and without HIV will be inoculated intranasally with Streptococcus pneumoniae serotype 6B. Sequential cohorts will be challenged with increasing doses to determine the optimal safe challenge dose to establish experimental carriage. Nasal fluid, nasal mucosal, and blood samples will be taken before inoculation and on days 2, 7, 14, and 21 following inoculation to measure pneumococcal carriage density and identify immune correlates of protection from carriage. The vast majority of natural pneumococcal carriage events in PLHIV do not result in invasive disease and no invasive disease is expected in this study. However, robust participant safety monitoring is designed to identify signs of invasive disease early should they develop, and to implement treatment immediately. Participants will complete a Likert-style questionnaire at study-end to establish acceptability. Interpretations: We expect the EHPC model to be safely and acceptably implemented in PLHIV. The CHIM can then be used to accelerate pneumococcal vaccine evaluations in this population, and an evidence-based pneumococcal vaccination policy for PLHIV in sSA., Competing Interests: No competing interests were disclosed., (Copyright: © 2024 Doherty K et al.)

Published

2024

13. Antibody and B-cell Immune Responses Against Bordetella Pertussis Following Infection and Immunization.

Author

Abu-Raya B, Esser MJ, Nakabembe E, Reiné J, Amaral K, Diks AM, Imede E, Way SS, Harandi AM, Gorringe A, Le Doare K, Halperin SA, Berkowska MA, and Sadarangani M

Subjects

Humans, Infant, Immunity, Immunization, Vaccine Development, Antibodies, Bacterial immunology, Bordetella pertussis immunology, Pertussis Vaccine immunology, Whooping Cough immunology

Abstract

Neither immunization nor recovery from natural infection provides life-long protection against Bordetella pertussis. Replacement of a whole-cell pertussis (wP) vaccine with an acellular pertussis (aP) vaccine, mutations in B. pertussis strains, and better diagnostic techniques, contribute to resurgence of number of cases especially in young infants. Development of new immunization strategies relies on a comprehensive understanding of immune system responses to infection and immunization and how triggering these immune components would ensure protective immunity. In this review, we assess how B cells, and their secretory products, antibodies, respond to B. pertussis infection, current and novel vaccines and highlight similarities and differences in these responses. We first focus on antibody-mediated immunity. We discuss antibody (sub)classes, elaborate on antibody avidity, ability to neutralize pertussis toxin, and summarize different effector functions, i.e. ability to activate complement, promote phagocytosis and activate NK cells. We then discuss challenges and opportunities in studying B-cell immunity. We highlight shared and unique aspects of B-cell and plasma cell responses to infection and immunization, and discuss how responses to novel immunization strategies better resemble those triggered by a natural infection (i.e., by triggering responses in mucosa and production of IgA). With this comprehensive review, we aim to shed some new light on the role of B cells and antibodies in the pertussis immunity to guide new vaccine development., Competing Interests: Declaration of Competing Interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: ‘BA has received honoraria for participation in meetings organized by Sanofi, relating to pertussis and RSV. MS has been an investigator on projects funded by GlaxoSmithKline, Merck, Moderna, Pfizer, Sanofi-Pasteur, Seqirus, Symvivo and VBI Vaccines. All funds have been paid to his institute, and he has not received any personal payments. SH has been an investigator on projects funded by GlaxoSmithKline, Merck, Moderna, Pfizer, Sanofi-Pasteur, Seqirus, CanSino, Entos, and VBI Vaccines. All funds have been paid to his institute, and he has not received any personal payments.’., (Copyright © 2023 Elsevier Ltd. All rights reserved.)

Published

2023

14. Respiratory mucosal immune memory to SARS-CoV-2 after infection and vaccination.

Author

Mitsi E, Diniz MO, Reiné J, Collins AM, Robinson RE, Hyder-Wright A, Farrar M, Liatsikos K, Hamilton J, Onyema O, Urban BC, Solórzano C, Belij-Rammerstorfer S, Sheehan E, Lambe T, Draper SJ, Weiskopf D, Sette A, Maini MK, and Ferreira DM

Subjects

Animals, Humans, SARS-CoV-2, Respiratory Mucosa, Vaccination, Antibodies, Viral, Spike Glycoprotein, Coronavirus, Immunologic Memory, COVID-19 prevention & control

Abstract

Respiratory mucosal immunity induced by vaccination is vital for protection from coronavirus infection in animal models. In humans, the capacity of peripheral vaccination to generate sustained immunity in the lung mucosa, and how this is influenced by prior SARS-CoV-2 infection, is unknown. Here we show using bronchoalveolar lavage samples that donors with history of both infection and vaccination have more airway mucosal SARS-CoV-2 antibodies and memory B cells than those only vaccinated. Infection also induces populations of airway spike-specific memory CD4+ and CD8+ T cells that are not expanded by vaccination alone. Airway mucosal T cells induced by infection have a distinct hierarchy of antigen specificity compared to the periphery. Spike-specific T cells persist in the lung mucosa for 7 months after the last immunising event. Thus, peripheral vaccination alone does not appear to induce durable lung mucosal immunity against SARS-CoV-2, supporting an argument for the need for vaccines targeting the airways., (© 2023. The Author(s).)

Published

2023

15. A Randomized Controlled Clinical Trial of Nasal Immunization with Live Virulence Attenuated Streptococcus pneumoniae Strains Using Human Infection Challenge.

Author

Hill H, Mitsi E, Nikolaou E, Blizard A, Pojar S, Howard A, Hyder-Wright A, Devin J, Reiné J, Robinson R, Solórzano C, Jochems SP, Kenny-Nyazika T, Ramos-Sevillano E, Weight CM, Myerscough C, McLenaghan D, Morton B, Gibbons E, Farrar M, Randles V, Burhan H, Chen T, Shandling AD, Campo JJ, Heyderman RS, Gordon SB, Brown JS, Collins AM, and Ferreira DM

Subjects

Adult, Humans, Virulence, Nose, Immunization, Antibodies, Bacterial, Immunoglobulin G, Pneumococcal Vaccines therapeutic use, Streptococcus pneumoniae, Pneumococcal Infections prevention & control

Abstract

Rationale: Pneumococcal pneumonia remains a global health problem. Pneumococcal colonization increases local and systemic protective immunity, suggesting that nasal administration of live attenuated Streptococcus pneumoniae (Spn) strains could help prevent infections. Objectives: We used a controlled human infection model to investigate whether nasopharyngeal colonization with attenuated S. pneumoniae strains protected against recolonization with wild-type (WT) Spn (SpnWT). Methods: Healthy adults aged 18-50 years were randomized (1:1:1:1) for nasal administration twice (at a 2-wk interval) with saline solution, WT Spn6B (BHN418), or one of two genetically modified Spn6B strains, SpnA1 ( Δfhs/piaA ) or SpnA3 ( ΔproABC/piaA ) (Stage I). After 6 months, participants were challenged with SpnWT to assess protection against the homologous serotype (Stage II). Measurements and Main Results: 125 participants completed both study stages per intention to treat. No serious adverse events were reported. In Stage I, colonization rates were similar among groups: SpnWT, 58.1% (18 of 31); SpnA1, 60% (18 of 30); and SpnA3, 59.4% (19 of 32). Anti-Spn nasal IgG levels after colonization were similar in all groups, whereas serum IgG responses were higher in the SpnWT and SpnA1 groups than in the SpnA3 group. In colonized individuals, increases in IgG responses were identified against 197 Spn protein antigens and serotype 6 capsular polysaccharide using a pangenome array. Participants given SpnWT or SpnA1 in Stage I were partially protected against homologous challenge with SpnWT (29% and 30% recolonization rates, respectively) at stage II, whereas those exposed to SpnA3 achieved a recolonization rate similar to that in the control group (50% vs. 47%, respectively). Conclusions: Nasal colonization with genetically modified live attenuated Spn was safe and induced protection against recolonization, suggesting that nasal administration of live attenuated Spn could be an effective strategy for preventing pneumococcal infections. Clinical trial registered with the ISRCTN registry (ISRCTN22467293).

Published

2023

16. Detection of SARS-CoV-2 infection by saliva and nasopharyngeal sampling in frontline healthcare workers: An observational cohort study.

Author

Walker NF, Byrne RL, Howard A, Nikolaou E, Farrar M, Glynn S, Cheliotis KS, Cubas Atienzar AI, Davies K, Reiné J, Rashid-Gardner Z, German EL, Solórzano C, Blandamer T, Hitchins L, Myerscough C, Gessner BD, Begier E, Collins AM, Beadsworth M, Todd S, Hill H, Houlihan CF, Nastouli E, Adams ER, Mitsi E, and Ferreira DM

Subjects

Humans, SARS-CoV-2, Cohort Studies, Retrospective Studies, State Medicine, Health Personnel, Specimen Handling, Nasopharynx, Saliva, COVID-19 diagnosis

Abstract

Background: The SARS-CoV-2 pandemic has caused an unprecedented strain on healthcare systems worldwide, including the United Kingdom National Health Service (NHS). We conducted an observational cohort study of SARS-CoV-2 infection in frontline healthcare workers (HCW) working in an acute NHS Trust during the first wave of the pandemic, to answer emerging questions surrounding SARS-CoV-2 infection, diagnosis, transmission and control., Methods: Using self-collected weekly saliva and twice weekly combined oropharyngeal/nasopharyngeal (OP/NP) samples, in addition to self-assessed symptom profiles and isolation behaviours, we retrospectively compared SARS-CoV-2 detection by RT-qPCR of saliva and OP/NP samples. We report the association with contemporaneous symptoms and isolation behaviour., Results: Over a 12-week period from 30th March 2020, 40·0% (n = 34/85, 95% confidence interval 31·3-51·8%) HCW had evidence of SARS-CoV-2 infection by surveillance OP/NP swab and/or saliva sample. Symptoms were reported by 47·1% (n = 40) and self-isolation by 25·9% (n = 22) participants. Only 44.1% (n = 15/34) participants with SARS-CoV-2 infection reported any symptoms within 14 days of a positive result and only 29·4% (n = 10/34) reported self-isolation periods. Overall agreement between paired saliva and OP/NP swabs was 93·4% (n = 211/226 pairs) but rates of positive concordance were low. In paired samples with at least one positive result, 35·0% (n = 7/20) were positive exclusively by OP/NP swab, 40·0% (n = 8/20) exclusively by saliva and in only 25·0% (n = 5/20) were the OP/NP and saliva result both positive., Conclusions: HCW are a potential source of SARS-CoV-2 transmission in hospitals and symptom screening will identify the minority of infections. Without routine asymptomatic SARS-CoV-2 screening, it is likely that HCW with SARS-CoV-2 infection would continue to attend work. Saliva, in addition to OP/NP swab testing, facilitated ascertainment of symptomatic and asymptomatic SARS-CoV-2 infections. Combined saliva and OP/NP swab sampling would improve detection of SARS-CoV-2 for surveillance and is recommended for a high sensitivity strategy., Competing Interests: EB and BDG hold Pfizer stock as Pfizer employees. No other relationships or activities exist that could appear to have influenced the submitted work. Sources of grant funding are stated (see Financial Disclosures) and affiliations given for each author., (Copyright: © 2023 Walker et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

17. Human Infection Challenge with Serotype 3 Pneumococcus.

Author

Robinson RE, Mitsi E, Nikolaou E, Pojar S, Chen T, Reiné J, Nyazika TK, Court J, Davies K, Farrar M, Gonzalez-Dias P, Hamilton J, Hill H, Hitchins L, Howard A, Hyder-Wright A, Lesosky M, Liatsikos K, Matope A, McLenaghan D, Myerscough C, Murphy A, Solórzano C, Wang D, Burhan H, Gautam M, Begier E, Theilacker C, Beavon R, Anderson AS, Gessner BD, Gordon SB, Collins AM, and Ferreira DM

Subjects

Humans, Child, Infant, Young Adult, Adult, Serogroup, Carrier State, Pneumococcal Vaccines therapeutic use, Nasopharynx microbiology, Anti-Bacterial Agents therapeutic use, Anti-Bacterial Agents pharmacology, Streptococcus pneumoniae, Pneumococcal Infections prevention & control

Abstract

Rationale: Streptococcus pneumoniae serotype 3 (SPN3) is a cause of invasive pneumococcal disease and associated with low carriage rates. Following the introduction of pediatric 13-valent pneumococcal conjugate vaccine (PCV13) programs, SPN3 declines are less than other vaccine serotypes and incidence has increased in some populations coincident with a shift in predominant circulating SPN3 clade, from I to II. A human challenge model provides an effective means for assessing the impact of PCV13 on SPN3 in the upper airway. Objectives: To establish SPN3's ability to colonize the nasopharynx using different inoculum clades and doses, and the safety of an SPN3 challenge model. Methods: In a human challenge study involving three well-characterized and antibiotic-sensitive SPN3 isolates (PFESP306 [clade Ia], PFESP231 [no clade], and PFESP505 [clade II]), inoculum doses (10,000, 20,000, 80,000, and 160,000 cfu/100 μl) were escalated until maximal colonization rates were achieved, with concurrent acceptable safety. Measurement and Main Results: Presence and density of experimental SPN3 nasopharyngeal colonization in nasal wash samples, assessed using microbiological culture and molecular methods, on Days 2, 7, and 14 postinoculation. A total of 96 healthy participants (median age 21, interquartile range 19-25) were inoculated ( n  = 6-10 per dose group, 10 groups). Colonization rates ranged from 30.0-70.0% varying with dose and isolate. 30.0% (29/96) reported mild symptoms (82.8% [24/29] developed a sore throat); one developed otitis media requiring antibiotics. No serious adverse events occurred. Conclusions: An SPN3 human challenge model is feasible and safe with comparable carriage rates to an established Serotype 6B human challenge model. SPN3 carriage may cause mild upper respiratory symptoms.

Published

2022

18. Targeted Transcriptomic Screen of Pneumococcal Genes Expressed during Murine and Human Infection.

Author

Basset A, Wall E, Mitsi E, Deshusses C, Daly R, Pojar S, Reiné J, Guerra-Assuncao JA, Denis B, Jochems SP, Heyderman R, Brown J, Lu YJ, Ferreira DM, and Malley R

Subjects

Animals, Bacterial Proteins genetics, Humans, Mice, Nasopharynx microbiology, Pneumococcal Vaccines genetics, Serogroup, Streptococcus pneumoniae genetics, Transcriptome, Vaccines, Conjugate, Pneumococcal Infections microbiology

Abstract

The advent of pneumococcal conjugate vaccines led to the near disappearance of most of the included serotypes in high-income settings but also the rise of nonvaccine-type colonization and disease. Alternative strategies, using genetically conserved proteins as antigens, have been evaluated preclinically and clinically for years, so far unsuccessfully. One possible explanation for the failure of these efforts is that the choice of antigens may not have been sufficiently guided by an understanding of the gene expression pattern in the context of infection. Here, we present a targeted transcriptomic analysis of 160 pneumococcal genes encoding bacterial surface-exposed proteins in mouse models, human colonization, and human meningitis. We present the overlap of these different transcriptomic profiles. We identify two bacterial genes that are highly expressed in the context of mouse and human infection: SP_0282, an IID component of a mannose phosphotransferase system (PTS), and SP_1739, encoding RNase Y. We show that these two proteins can confer protection against pneumococcal nasopharyngeal colonization and intraperitoneal challenge in a murine model and generate opsonophagocytic antibodies. This study emphasizes and confirms the importance of studies of pneumococcal gene expression of bacterial surface proteins during human infection and colonization and may pave the way for the selection of a protein-based vaccine candidate.

Published

2022

19. Innate and adaptive nasal mucosal immune responses following experimental human pneumococcal colonization.

Author

Jochems SP, de Ruiter K, Solórzano C, Voskamp A, Mitsi E, Nikolaou E, Carniel BF, Pojar S, German EL, Reiné J, Soares-Schanoski A, Hill H, Robinson R, Hyder-Wright AD, Weight CM, Durrenberger PF, Heyderman RS, Gordon SB, Smits HH, Urban BC, Rylance J, Collins AM, Wilkie MD, Lazarova L, Leong SC, Yazdanbakhsh M, and Ferreira DM

Published

2022

20. Influence of sex, season and environmental air quality on experimental human pneumococcal carriage acquisition: a retrospective cohort analysis.

Author

Cheliotis KS, Jewell CP, Solórzano C, Urban B, Collins AM, Mitsi E, Pojar S, Nikolaou E, German EL, Reiné J, Gordon SB, Jochems SP, Rylance J, and Ferreira DM

Abstract

Streptococcus pneumoniae (pneumococcus) is the most commonly identified bacterial cause of pneumonia and the leading infectious cause of death in children under 5 years of age worldwide. Pneumococcal disease follows a seasonal pattern with increased incidence during winter. Pneumonia burden is also associated with poor air quality. Nasopharyngeal carriage of the bacterium is a pre-requisite of invasive disease. We aimed to determine if susceptibility to nasopharyngeal pneumococcal carriage varied by season and which environmental factors might explain such variation. We also evaluated the influence of sex on susceptibility of carriage. We collated data from five studies in which human volunteers underwent intranasal pneumococcal challenge. Generalised linear mixed-effects models were used to identify factors associated with altered risk of carriage acquisition, specifically climate and air-quality data. During 2011-2017, 374 healthy adults were challenged with type 6B pneumococcus. Odds of carriage were significantly lower in males (OR, 0.61; 95% CI, 0.40-0.92; p=0.02), and higher with cooler temperatures (OR, 0.79; 95% CI, 0.63-0.99; p=0.04). Likelihood of carriage was also associated with lower concentrations of local fine particulate matter concentrations (PM 2.5 ) and increased local rainfall. In contrast to epidemiological series, experimental challenge allowed us to test propensity to acquisition during controlled exposures; immunological explanations for sex and climatic differences should be sought., Competing Interests: Conflict of interest: C.P. Jewell reports support received for the present manuscript from K.S. Cheliotis (PhD student writing; no payments received directly) and D.M. Ferreira (unfunded collaborator); grants or contracts received from MRC (DRUM and JUNIPER Consortia) EPSRC (Bayes4Health programme and COVID-19 stochastic modelling grants, NERC (COVID-19 wastewater monitoring), The Dogs Trust (clinical disease surveillance grant), BBSRC (EEID elimination of disease grant) and the Wellcome Trust (GEM software grant), outside the submitted work; and participation on the ONS Covid Infection Survey Advisory Board (unfunded) and SPI-M-O Covid Modelling Subcommittee (unfunded), outside the submitted work. B. Urban reports grants or contracts from EDCTP, Royal Society and Pfizer, outside the submitted work; and is an Inner Board Member of the Irish Research Council. A.M. Collins reports receiving grants or contracts from Sanofi, Pfizer and Unilever, outside the submitted work; consulting fees received from Sanofi, outside the submitted work; payment or honoraria for lectures, presentations, speakers’ bureaus, manuscript writing or educational events received from Pfizer, GSK and MSD, outside the submitted work; support for attending meetings and/or travel received from GSK, outside the submitted work; and participation on a data safety monitoring or advisory board for Neisseria for S'ton UK, outside the submitted work. E. Nikolaou reports grants or contracts from Sanofi, the LSTM and Wellcome Trust Director's catalyst fund, outside the submitted work. J. Rylance reports grants or contracts received from Wellcome Trust and NIHR, outside the submitted work; consulting fees received from Sanofi, outside the submitted work; and participation on the “Preventing Pneumo” trial steering committee. D.M. Ferreira reports support for the present manuscript from MRC grant MR/M011569/1, and Bill and Melinda Gates Foundation OPP1117728; grants or contracts received from Pfizer, MSD and Sanofi, outside the submitted work; and membership of the Human Infection Challenge Network for Vaccine Development and the BactiVac network (Accelerating Bacterial Vaccines). The remaining authors have nothing to disclose., (Copyright ©The authors 2022.)

Published

2022

21. Streptococcus pneumoniae colonization associates with impaired adaptive immune responses against SARS-CoV-2.

Author

Mitsi E, Reiné J, Urban BC, Solórzano C, Nikolaou E, Hyder-Wright AD, Pojar S, Howard A, Hitchins L, Glynn S, Farrar MC, Liatsikos K, Collins AM, Walker NF, Hill HC, German EL, Cheliotis KS, Byrne RL, Williams CT, Cubas-Atienzar AI, Fletcher TE, Adams ER, Draper SJ, Pulido D, Beavon R, Theilacker C, Begier E, Jodar L, Gessner BD, and Ferreira DM

Subjects

Health Personnel, Humans, Immunity, Streptococcus pneumoniae, COVID-19, SARS-CoV-2

Abstract

BackgroundAlthough recent epidemiological data suggest that pneumococci may contribute to the risk of SARS-CoV-2 disease, cases of coinfection with Streptococcus pneumoniae in patients with coronavirus disease 2019 (COVID-19) during hospitalization have been reported infrequently. This apparent contradiction may be explained by interactions of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and pneumococci in the upper airway, resulting in the escape of SARS-CoV-2 from protective host immune responses.MethodsHere, we investigated the relationship of these 2 respiratory pathogens in 2 distinct cohorts of health care workers with asymptomatic or mildly symptomatic SARS-CoV-2 infection identified by systematic screening and patients with moderate to severe disease who presented to the hospital. We assessed the effect of coinfection on host antibody, cellular, and inflammatory responses to the virus.ResultsIn both cohorts, pneumococcal colonization was associated with diminished antiviral immune responses, which primarily affected mucosal IgA levels among individuals with mild or asymptomatic infection and cellular memory responses in infected patients.ConclusionOur findings suggest that S. pneumoniae impair host immunity to SARS-CoV-2 and raise the question of whether pneumococcal carriage also enables immune escape of other respiratory viruses and facilitates reinfection.Trial registrationISRCTN89159899 (FASTER study) and ClinicalTrials.gov NCT03502291 (LAIV study).

Published

2022

22. Experimental Human Pneumococcal Colonization in Older Adults Is Feasible and Safe, Not Immunogenic.

Author

Adler H, German EL, Mitsi E, Nikolaou E, Pojar S, Hales C, Robinson R, Connor V, Hill H, Hyder-Wright AD, Lazarova L, Lowe C, Smith EL, Wheeler I, Zaidi SR, Jochems SP, Loukov D, Reiné J, Solórzano-Gonzalez C, de Gorguette d'Argoeuves P, Jones T, Goldblatt D, Chen T, Aston SJ, French N, Collins AM, Gordon SB, Ferreira DM, and Rylance J

Subjects

Age Factors, Aged, Aged, 80 and over, Asymptomatic Infections, Culture Techniques, Feasibility Studies, Female, Humans, Immunity, Humoral immunology, Immunoglobulin G immunology, Male, Middle Aged, Nasal Cavity, Nasal Lavage Fluid, Pneumococcal Infections prevention & control, Pneumococcal Vaccines therapeutic use, Antibodies, Bacterial immunology, Carrier State immunology, Pneumococcal Infections immunology, Streptococcus pneumoniae immunology

Abstract

Rationale: Pneumococcal colonization is key to the pathogenesis of invasive disease but is also immunogenic in young adults, protecting against recolonization. Colonization is rarely detected in older adults, despite high rates of pneumococcal disease. Objectives: To establish experimental human pneumococcal colonization in healthy adults aged 50-84 years, to measure the immune response to pneumococcal challenge, and to assess the protective effect of prior colonization against autologous strain rechallenge. Methods: Sixty-four participants were inoculated with Streptococcus pneumoniae (serotype 6B; 80,000 cfu in each nostril). Colonization was determined by bacterial culture of nasal wash, and humoral immune responses were assessed by anticapsular and antiprotein IgG concentrations. Measurements and Main Results: Experimental colonization was established in 39% of participants (25/64) with no adverse events. Colonization occurred in 47% (9/19) of participants aged 50-59 compared with 21% (3/14) in those aged ≥70 years. Previous pneumococcal polysaccharide vaccination did not protect against colonization. Colonization did not confer serotype-specific immune boosting, with a geometric mean titer (95% confidence interval) of 2.7 μg/ml (1.9-3.8) before the challenge versus 3.0 (1.9-4.7) 4 weeks after colonization ( P  = 0.53). Furthermore, pneumococcal challenge without colonization led to a drop in specific antibody concentrations from 2.8 μg/ml (2.0-3.9) to 2.2 μg/ml (1.6-3.0) after the challenge ( P  = 0.006). Antiprotein antibody concentrations increased after successful colonization. Rechallenge with the same strain after a median of 8.5 months (interquartile range, 6.7-10.1) led to recolonization in 5/16 (31%). Conclusions: In older adults, experimental pneumococcal colonization is feasible and safe but demonstrates different immunological outcomes compared with younger adults in previous studies.

Published

2021

23. Pneumococcal colonization impairs mucosal immune responses to live attenuated influenza vaccine.

Author

Carniel BF, Marcon F, Rylance J, German EL, Zaidi S, Reiné J, Negera E, Nikolaou E, Pojar S, Solórzano C, Collins AM, Connor V, Bogaert D, Gordon SB, Nakaya HI, Ferreira DM, Jochems SP, and Mitsi E

Subjects

Adaptive Immunity, Adolescent, Adult, Antibodies, Viral blood, CD4-Positive T-Lymphocytes, CD8-Positive T-Lymphocytes, Cytokines, Double-Blind Method, Female, Humans, Immunoglobulin A immunology, Influenza, Human immunology, Lung immunology, Male, Middle Aged, Nasopharynx immunology, Orthomyxoviridae Infections prevention & control, Streptococcus pneumoniae, Young Adult, Immunity, Mucosal, Influenza Vaccines immunology, Pneumococcal Vaccines immunology, Vaccines, Attenuated immunology

Abstract

Influenza virus infections affect millions of people annually, and current available vaccines provide varying rates of protection. However, the way in which the nasal microbiota, particularly established pneumococcal colonization, shape the response to influenza vaccination is not yet fully understood. In this study, we inoculated healthy adults with live Streptococcus pneumoniae and vaccinated them 3 days later with either tetravalent-inactivated influenza vaccine (TIV) or live attenuated influenza vaccine (LAIV). Vaccine-induced immune responses were assessed in nose, blood, and lung. Nasal pneumococcal colonization had no impact upon TIV-induced antibody responses to influenza, which manifested in all compartments. However, experimentally induced pneumococcal colonization dampened LAIV-mediated mucosal antibody responses, primarily IgA in the nose and IgG in the lung. Pulmonary influenza-specific cellular responses were more apparent in the LAIV group compared with either the TIV or an unvaccinated group. These results indicate that TIV and LAIV elicit differential immunity to adults and that LAIV immunogenicity is diminished by the nasal presence of S. pneumoniae. Therefore, nasopharyngeal pneumococcal colonization may affect LAIV efficacy.

Published

2021

24. Experimental Human Challenge Defines Distinct Pneumococcal Kinetic Profiles and Mucosal Responses between Colonized and Non-Colonized Adults.

Author

Nikolaou E, Jochems SP, Mitsi E, Pojar S, Blizard A, Reiné J, Solórzano C, Negera E, Carniel B, Soares-Schanoski A, Connor V, Adler H, Zaidi SR, Hales C, Hill H, Hyder-Wright A, Gordon SB, Rylance J, and Ferreira DM

Subjects

Adolescent, Adult, Animals, Cytokines, Host-Pathogen Interactions, Humans, Kinetics, Mice, Middle Aged, Neutrophils, Nose microbiology, Pneumococcal Vaccines immunology, Pneumonia, Pneumococcal immunology, Pneumonia, Pneumococcal microbiology, Respiratory System immunology, Saliva microbiology, Streptococcus pneumoniae genetics, Streptococcus pneumoniae isolation & purification, Young Adult, Pneumococcal Infections microbiology, Respiratory System microbiology, Streptococcus pneumoniae growth & development, Streptococcus pneumoniae immunology

Abstract

Colonization of the upper respiratory tract with Streptococcus pneumoniae is the precursor of pneumococcal pneumonia and invasive disease. Following exposure, however, it is unclear which human immune mechanisms determine whether a pathogen will colonize. We used a human challenge model to investigate host-pathogen interactions in the first hours and days following intranasal exposure to Streptococcus pneumoniae Using a novel home sampling method, we measured early immune responses and bacterial density dynamics in the nose and saliva after volunteers were experimentally exposed to pneumococcus. Here, we show that nasal colonization can take up to 24 h to become established. Also, the following two distinct bacterial clearance profiles were associated with protection: nasal clearers with immediate clearance of bacteria in the nose by the activity of pre-existent mucosal neutrophils and saliva clearers with detectable pneumococcus in saliva at 1 h post challenge and delayed clearance mediated by an inflammatory response and increased neutrophil activity 24 h post bacterial encounter. This study describes, for the first time, how colonization with a bacterium is established in humans, signifying that the correlates of protection against pneumococcal colonization, which can be used to inform design and testing of novel vaccine candidates, could be valid for subsets of protected individuals. IMPORTANCE Occurrence of lower respiratory tract infections requires prior colonization of the upper respiratory tract with a pathogen. Most bacterial infection and colonization studies have been performed in murine and in vitro models due to the current invasive sampling methodology of the upper respiratory tract, both of which poorly reflect the complexity of host-pathogen interactions in the human nose. Self-collecting saliva and nasal lining fluid at home is a fast, low-cost, noninvasive, high-frequency sampling platform for continuous monitoring of bacterial encounter at defined time points relative to exposure. Our study demonstrates for the first time that, in humans, there are distinct profiles of pneumococcal colonization kinetics, distinguished by speed of appearance in saliva, local phagocytic function, and acute mucosal inflammatory responses, which may either recruit or activate neutrophils. These data are important for the design and testing of novel vaccine candidates., (Copyright © 2021 Nikolaou et al.)

Published

2021

25. Isolation of an antimicrobial-resistant, biofilm-forming, Klebsiella grimontii isolate from a reusable water bottle.

Author

Hubbard ATM, Newire E, Botelho J, Reiné J, Wright E, Murphy EA, Hutton W, and Roberts AP

Subjects

Amoxicillin pharmacology, Ampicillin pharmacology, Anti-Bacterial Agents pharmacology, Fosfomycin pharmacology, Genome, Bacterial genetics, Humans, Klebsiella classification, Microbial Sensitivity Tests, Polypropylenes, Polystyrenes, Virulence Factors genetics, Water Microbiology, Whole Genome Sequencing, beta-Lactamases genetics, Biofilms growth & development, Drinking Water microbiology, Drug Resistance, Multiple, Bacterial genetics, Klebsiella genetics, Klebsiella isolation & purification

Abstract

A reusable water bottle was swabbed as part of the citizen science project "Swab and Send," and a Klebsiella grimontii isolate was recovered on chromogenic agar and designated SS141. Whole-genome sequencing of SS141 showed it has the potential to be a human pathogen as it contains the biosynthetic gene cluster for the potent cytotoxin, kleboxymycin, and genes for other virulence factors. The genome also contains the antibiotic-resistant genes, bla OXY-6-4 , and a variant of fosA, which is likely to explain the observed resistance to ampicillin, amoxicillin, and fosfomycin. We have also shown that SS141 forms biofilms on both polystyrene and polypropylene surfaces, providing a reasonable explanation for its ability to colonize a reusable water bottle. With the increasing use of reusable water bottles as an alternative to disposables and a strong forecast for growth in this industry over the next decade, this study highlights the need for cleanliness comparable to other reusable culinary items., (© 2020 The Authors. MicrobiologyOpen published by John Wiley & Sons Ltd.)

Published

2020

26. Symptoms associated with influenza vaccination and experimental human pneumococcal colonisation of the nasopharynx.

Author

Hales C, Jochems SP, Robinson R, Solórzano C, Carniel B, Pojar S, Reiné J, German EL, Nikolaou E, Mitsi E, Hyder-Wright AD, Hill H, Adler H, Connor V, Zaidi S, Lowe C, Fan X, Wang D, Gordon SB, Rylance J, and Ferreira DM

Subjects

Adult, Coinfection microbiology, Coinfection virology, Double-Blind Method, Humans, Influenza Vaccines classification, Time Factors, Vaccination, Vaccines, Attenuated administration & dosage, Vaccines, Inactivated administration & dosage, Influenza Vaccines administration & dosage, Influenza, Human prevention & control, Nasopharynx microbiology, Streptococcus pneumoniae pathogenicity

Abstract

Background: Nasopharyngeal colonisation by S. pneumoniae is a prerequisite for invasive pneumococcal infections. Influenza co-infection leads to increased susceptibility to secondary pneumonia and mortality during influenza epidemics. Increased bacterial load and impaired immune responses to pneumococcus caused by influenza play a role in this increased susceptibility. Using an Experimental Human Challenge Model and influenza vaccines, we examined symptoms experienced by healthy adults during nasal co-infection with S. pneumoniae and live attenuated influenza virus., Methods: Randomised, blinded administration of Live Attenuated Influenza Vaccine (LAIV) or Tetravalent Inactivated Influenza Vaccine (TIV) either preceded bacterial inoculation or followed it, separated by a 3-day interval. The presence and density of S. pneumoniae was determined from nasal washes. Participants completed a symptom questionnaire from the first intervention until 6 days post second intervention., Results: The timing and type of influenza vaccination and presence of S. pneumoniae in the nasopharynx significantly affected symptom reporting. In the study where influenza vaccination preceded bacterial inoculation: nasal symptoms were less common in the LAIV group than the TIV group (OR 0.57, p < 0.01); with colonisation status only affecting the TIV group where more symptoms were reported by colonised participants compared to non-colonised participants following inoculation (n = 12/23 [52.17%] vs n = 13/38 [34.21%], respectively; p < 0.05). In the study where influenza vaccination followed bacterial inoculation: no difference was seen in the symptoms reported between the LAIV and TIV groups following inoculation and subsequent vaccination; and symptoms were unaffected by colonisation status., Conclusion: Symptoms experienced during live viral vaccination and bacterial co-infection in the nasopharynx are directly affected by the precedence of the pathogen acquisition. Symptoms were directly affected by nasal pneumococcal colonisation but only when TIV was given prior to bacterial exposure., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2020

27. Nasal Pneumococcal Density Is Associated with Microaspiration and Heightened Human Alveolar Macrophage Responsiveness to Bacterial Pathogens.

Author

Mitsi E, Carniel B, Reiné J, Rylance J, Zaidi S, Soares-Schanoski A, Connor V, Collins AM, Schlitzer A, Nikolaou E, Solórzano C, Pojar S, Hill H, Hyder-Wright AD, Jambo KC, Oggioni MR, De Ste Croix M, Gordon SB, Jochems SP, and Ferreira DM

Subjects

Adolescent, Adult, Bacteria immunology, Humans, Middle Aged, Respiratory Aspiration, Young Adult, Macrophages, Alveolar immunology, Nasopharynx microbiology, Nose microbiology, Streptococcus pneumoniae isolation & purification

Abstract

Rationale: Pneumococcal pneumonia remains a global health problem. Colonization of the nasopharynx with Streptococcus pneumoniae (Spn), although a prerequisite of infection, is the main source of exposure and immunological boosting in children and adults. However, our knowledge of how nasal colonization impacts on the lung cells, especially on the predominant alveolar macrophage (AM) population, is limited. Objectives: Using a controlled human infection model to achieve nasal colonization with 6B serotype, we investigated the effect of Spn colonization on lung cells. Methods: We collected BAL from healthy pneumococcal-challenged participants aged 18-49 years. Confocal microscopy and molecular and classical microbiology were used to investigate microaspiration and pneumococcal presence in the lower airways. AM opsonophagocytic capacity was assessed by functional assays in vitro , whereas flow cytometry and transcriptomic analysis were used to assess further changes on the lung cellular populations. Measurements and Main Results: AMs from Spn-colonized individuals exhibited increased opsonophagocytosis to pneumococcus (11.4% median increase) for approximately 3 months after experimental pneumococcal colonization. AMs also had increased responses against other bacterial pathogens. Pneumococcal DNA detected in the BAL samples of Spn-colonized individuals were positively correlated with nasal pneumococcal density ( r  = 0.71; P  = 0.029). Similarly, AM-heightened opsonophagocytic capacity was correlated with nasopharyngeal pneumococcal density ( r  = 0.61, P  = 0.025). Conclusions: Our findings demonstrate that nasal colonization with pneumococcus and microaspiration prime AMs, leading to brisker responsiveness to both pneumococcus and unrelated bacterial pathogens. The relative abundance of AMs in the alveolar spaces, alongside their potential for nonspecific protection, render them an attractive target for novel vaccines.

Published

2020

28. Minimally Invasive Nasal Sampling in Children Offers Accurate Pneumococcal Colonization Detection.

Author

Nikolaou E, Blizard A, Pojar S, Mitsi E, German EL, Reiné J, Hill H, McNamara PS, Collins AM, Ferreira DM, and Jochems SP

Subjects

Bacteriological Techniques methods, Child, Preschool, Humans, Infant, Nose microbiology, Pneumococcal Infections microbiology, Reproducibility of Results, Sensitivity and Specificity, Carrier State microbiology, Pneumococcal Infections diagnosis, Reagent Strips, Specimen Handling instrumentation, Specimen Handling methods, Streptococcus pneumoniae isolation & purification

Abstract

Nasopharyngeal colonization of potential respiratory pathogens such as Streptococcus pneumoniae is the major source of transmission and precursor of invasive disease. Swabbing deeply the nasopharynx, which is currently recommended by World Health Organization, provides accurate pneumococcal detection but is unpleasant. We showed that nasal lining fluid filter strips offer equal detection sensitivity.

Published

2019

29. Innate and adaptive nasal mucosal immune responses following experimental human pneumococcal colonization.

Author

Jochems SP, de Ruiter K, Solórzano C, Voskamp A, Mitsi E, Nikolaou E, Carniel BF, Pojar S, German EL, Reiné J, Soares-Schanoski A, Hill H, Robinson R, Hyder-Wright AD, Weight CM, Durrenberger PF, Heyderman RS, Gordon SB, Smits HH, Urban BC, Rylance J, Collins AM, Wilkie MD, Lazarova L, Leong SC, Yazdanbakhsh M, and Ferreira DM

Subjects

Adult, B-Lymphocytes immunology, B-Lymphocytes pathology, CD8-Positive T-Lymphocytes immunology, CD8-Positive T-Lymphocytes pathology, Female, Humans, Male, Adaptive Immunity, Immunity, Innate, Immunity, Mucosal, Nasal Mucosa immunology, Nasal Mucosa microbiology, Nasal Mucosa pathology, Pneumococcal Infections immunology, Pneumococcal Infections pathology, Streptococcus pneumoniae immunology

Abstract

Streptococcus pneumoniae (Spn) is a common cause of respiratory infection, but also frequently colonizes the nasopharynx in the absence of disease. We used mass cytometry to study immune cells from nasal biopsy samples collected following experimental human pneumococcal challenge in order to identify immunological mechanisms of control of Spn colonization. Using 37 markers, we characterized 293 nasal immune cell clusters, of which 7 were associated with Spn colonization. B cell and CD8+CD161+ T cell clusters were significantly lower in colonized than in non-colonized subjects. By following a second cohort before and after pneumococcal challenge we observed that B cells were depleted from the nasal mucosa upon Spn colonization. This associated with an expansion of Spn polysaccharide-specific and total plasmablasts in blood. Moreover, increased responses of blood mucosal associated invariant T (MAIT) cells against in vitro stimulation with pneumococcus prior to challenge associated with protection against establishment of Spn colonization and with increased mucosal MAIT cell populations. These results implicate MAIT cells in the protection against pneumococcal colonization and demonstrate that colonization affects mucosal and circulating B cell populations.

Published

2019

30. Microinvasion by Streptococcus pneumoniae induces epithelial innate immunity during colonisation at the human mucosal surface.

Author

Weight CM, Venturini C, Pojar S, Jochems SP, Reiné J, Nikolaou E, Solórzano C, Noursadeghi M, Brown JS, Ferreira DM, and Heyderman RS

Subjects

Adult, Carrier State microbiology, Epithelial Cells immunology, Epithelial Cells microbiology, Female, Healthy Volunteers, Humans, Immunity, Innate, Male, Middle Aged, Nasopharynx microbiology, Pneumococcal Infections microbiology, Respiratory Mucosa microbiology, Streptococcus pneumoniae pathogenicity, Young Adult, Carrier State immunology, Nasopharynx immunology, Pneumococcal Infections immunology, Respiratory Mucosa immunology, Streptococcus pneumoniae immunology

Abstract

Control of Streptococcus pneumoniae colonisation at human mucosal surfaces is critical to reducing the burden of pneumonia and invasive pneumococcal disease, interrupting transmission, and achieving herd protection. Here, we use an experimental human pneumococcal carriage model (EHPC) to show that S. pneumoniae colonisation is associated with epithelial surface adherence, micro-colony formation and invasion, without overt disease. Interactions between different strains and the epithelium shaped the host transcriptomic response in vitro. Using epithelial modules from a human epithelial cell model that recapitulates our in vivo findings, comprising of innate signalling and regulatory pathways, inflammatory mediators, cellular metabolism and stress response genes, we find that inflammation in the EHPC model is most prominent around the time of bacterial clearance. Our results indicate that, rather than being confined to the epithelial surface and the overlying mucus layer, the pneumococcus undergoes micro-invasion of the epithelium that enhances inflammatory and innate immune responses associated with clearance.

Published

2019

31. Inflammation induced by influenza virus impairs human innate immune control of pneumococcus.

Author

Jochems SP, Marcon F, Carniel BF, Holloway M, Mitsi E, Smith E, Gritzfeld JF, Solórzano C, Reiné J, Pojar S, Nikolaou E, German EL, Hyder-Wright A, Hill H, Hales C, de Steenhuijsen Piters WAA, Bogaert D, Adler H, Zaidi S, Connor V, Gordon SB, Rylance J, Nakaya HI, and Ferreira DM

Subjects

Chemokine CXCL10 immunology, Chemotaxis, Leukocyte immunology, Double-Blind Method, Humans, Immunity, Innate immunology, Inflammation immunology, Monocytes immunology, Neutrophils immunology, Streptococcus pneumoniae, Coinfection immunology, Influenza, Human immunology, Nasal Mucosa immunology, Pneumococcal Infections immunology

Abstract

Colonization of the upper respiratory tract by pneumococcus is important both as a determinant of disease and for transmission into the population. The immunological mechanisms that contain pneumococcus during colonization are well studied in mice but remain unclear in humans. Loss of this control of pneumococcus following infection with influenza virus is associated with secondary bacterial pneumonia. We used a human challenge model with type 6B pneumococcus to show that acquisition of pneumococcus induced early degranulation of resident neutrophils and recruitment of monocytes to the nose. Monocyte function was associated with the clearance of pneumococcus. Prior nasal infection with live attenuated influenza virus induced inflammation, impaired innate immune function and altered genome-wide nasal gene responses to the carriage of pneumococcus. Levels of the cytokine CXCL10, promoted by viral infection, at the time pneumococcus was encountered were positively associated with bacterial load.

Published

2018

32. Longevity of duodenal and peripheral T-cell and humoral responses to live-attenuated Salmonella Typhi strain Ty21a.

Author

Pennington SH, Ferreira DM, Reiné J, Nyirenda TS, Thompson AL, Hancock CA, Wright AD, Gordon SB, and Gordon MA

Subjects

Adult, Enzyme-Linked Immunosorbent Assay, Female, Healthy Volunteers, Humans, Immunity, Humoral, Immunoglobulin A blood, Immunoglobulin G blood, Male, Time Factors, Typhoid-Paratyphoid Vaccines administration & dosage, Young Adult, Duodenum immunology, Immunity, Cellular, Immunity, Mucosal, Salmonella typhi immunology, T-Lymphocytes immunology, Typhoid-Paratyphoid Vaccines immunology

Abstract

Background: We have previously demonstrated that polyfunctional Ty21a-responsive CD4 + and CD8 + T cells are generated at the duodenal mucosa 18 days following vaccination with live-attenuated S. Typhi (Ty21a). The longevity of cellular responses has been assessed in peripheral blood, but persistence of duodenal responses is unknown., Methods: We vaccinated eight healthy adults with Ty21a. Peripheral blood and duodenal samples were acquired after a median of 1.5 years (ranging from 1.1 to 3.7 years) following vaccination. Cellular responses were assessed in peripheral blood and at the duodenal mucosa by flow cytometry. Levels of IgG and IgA were also assessed in peripheral blood by enzyme-linked immunosorbent assay., Results: No T-cell responses were observed at the duodenal mucosa, but CD4 + T-cell responses to Ty21a and FliC were observed in peripheral blood. Peripheral anti-lipopolysaccharide IgG and IgA responses were also observed. Early immunoglobulin responses were not associated with the persistence of long-term cellular immune responses., Conclusions: Early T-cell responses which we have previously observed at the duodenal mucosa 18 days following oral vaccination with Ty21a could not be detected at a median of 1.5 years. Peripheral responses were observed at this time. Immunoglobulin responses observed shortly after vaccination were not associated with cellular immune responses at 1.5 years, suggesting that the persistence of cellular immunity is not associated with the strength of the initial humoral response to vaccination., (Copyright © 2018 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2018

33. Single use and conventional bronchoscopes for Broncho alveolar lavage (BAL) in research: a comparative study (NCT 02515591).

Author

Zaidi SR, Collins AM, Mitsi E, Reiné J, Davies K, Wright AD, Owugha J, Fitzgerald R, Ganguli A, Gordon SB, Ferreira DM, and Rylance J

Subjects

Adult, Bronchoalveolar Lavage Fluid cytology, Cell Survival, Cross Infection prevention & control, Disposable Equipment, Durable Medical Equipment, Female, Healthy Volunteers, Humans, Male, Prospective Studies, Young Adult, Biomedical Research instrumentation, Bronchoalveolar Lavage instrumentation, Bronchoscopes

Abstract

Background: Broncho alveolar lavage (BAL) is widely used for investigative research to study innate, cellular and humoral immune responses, and in early phase drug trials. Conventional (multiple use) flexible bronchoscopes have time and monetary costs associated with cleaning, and carries a small risk of cross infection. Single use bronchoscopes may provide an alternative, but have not been evaluated in this context., Methods: Healthy volunteers underwent bronchoscopy at a day-case clinical research unit using the Ambu® aScope TM single-use flexible intubation bronchoscope. Broncho alveolar lavage was performed from a sub segmental bronchus within the right middle lobe; a total of 200 ml of warmed normal saline was instilled then aspirated using handheld suction. BAL volume yield, cell yield and viability were recorded., Results: Ten volunteers, (mean age 23 years, six male) participated. Bronchoscopies were carried out by one of two senior bronchoscopists, experienced in the technique of obtaining BAL for research purposes. The results were compared to 50 (mean age 23, 14 male) procedures performed using the conventional scope by the same two bronchoscopists. The total volume yield was significantly higher in the disposable group median 152 ml (IQR 141-166 ml) as compared to conventional 124 ml (110-135 ml), p = <0.01. The total cell yield and viability were similar in both groups, with no significant differences., Conclusions: With single use bronchoscopes, we achieved a larger BAL volume yield than conventional bronchoscopes, with comparable cell yield and viability. Better volume yields can potentially reduce post procedure side effects such as pleuritic chest pain and cough. The risk of cross infection can be eliminated, providing reassurance to researchers and participants. Reduced maintenance requirements can be cost effective. These could potentially be used for early phase drug development studies., Trial Registration: This trial was registered prospectively in July 2015 with the National Clinical Trials register, with the following registration number assigned: NCT 02515591 .

Published

2017

34. Novel Analysis of Immune Cells from Nasal Microbiopsy Demonstrates Reliable, Reproducible Data for Immune Populations, and Superior Cytokine Detection Compared to Nasal Wash.

Author

Jochems SP, Piddock K, Rylance J, Adler H, Carniel BF, Collins A, Gritzfeld JF, Hancock C, Hill H, Reiné J, Seddon A, Solórzano C, Sunny S, Trimble A, Wright AD, Zaidi S, Gordon SB, and Ferreira DM

Subjects

Adolescent, Adult, Flow Cytometry, Humans, Middle Aged, Nasal Mucosa immunology, Nasal Mucosa metabolism, Reproducibility of Results, Young Adult, Cytokines metabolism, Nasal Mucosa microbiology

Abstract

The morbidity and mortality related to respiratory tract diseases is enormous, with hundreds of millions of individuals afflicted and four million people dying each year. Understanding the immunological processes in the mucosa that govern outcome following pathogenic encounter could lead to novel therapies. There is a need to study responses at mucosal surfaces in humans for two reasons: (i) Immunological findings in mice, or other animals, often fail to translate to humans. (ii) Compartmentalization of the immune system dictates a need to study sites where pathogens reside. In this manuscript, we describe two novel non-invasive nasal mucosal microsampling techniques and their use for measuring immunological parameters: 1) using nasal curettes to collect cells from the inferior turbinate and; 2) absorptive matrices to collect nasal lining fluid. Both techniques were well tolerated and yielded reproducible and robust data. We demonstrated differences in immune populations and activation state in nasal mucosa compared to blood as well as compared to nasopharyngeal lumen in healthy adults. We also found superior cytokine detection with absorptive matrices compared to nasal wash. These techniques are promising new tools that will facilitate studies of the immunological signatures underlying susceptibility and resistance to respiratory infections., Competing Interests: The authors have declared that no competing interests exist.

Published

2017

35. Augmented Passive Immunotherapy with P4 Peptide Improves Phagocyte Activity in Severe Sepsis.

Author

Morton B, Mitsi E, Pennington SH, Reiné J, Wright AD, Parker R, Welters ID, Blakey JD, Rajam G, Ades EW, Ferreira DM, Wang D, Kadioglu A, and Gordon SB

Subjects

Aged, Female, Flow Cytometry, Humans, Male, Middle Aged, Neutrophils immunology, Neutrophils metabolism, Phagocytes drug effects, Phagocytosis drug effects, Prospective Studies, Sepsis metabolism, Streptococcus pneumoniae immunology, Immunization, Passive methods, Oligopeptides therapeutic use, Sepsis drug therapy

Abstract

Introduction: Antimicrobial resistance threatens to undermine treatment of severe infection; new therapeutic strategies are urgently needed. Preclinical work shows that augmented passive immunotherapy with P4 peptide increases phagocytic activity and shows promise as a novel therapeutic strategy. Our aim was to determine ex vivo P4 activity in a target population of patients admitted to critical care with severe infection., Methods: We prospectively recruited UK critical care unit patients with severe sepsis and observed clinical course (≥3 months postdischarge). Blood samples were taken in early (≤48 h postdiagnosis, n = 54), latent (7 days postdiagnosis, n = 39), and convalescent (3-6 months postdiagnosis, n = 18) phases of disease. The primary outcome measure was killing of opsonized Streptococcus pneumoniae by neutrophils with and without P4 peptide stimulation. We also used a flow cytometric whole blood phagocytosis assay to determine phagocyte association and oxidation of intraphagosomal reporter beads., Results: P4 peptide increased neutrophil killing of opsonized pneumococci by 8.6% (confidence interval 6.35-10.76, P < 0.001) in all phases of sepsis, independent of infection source and microbiological status. This represented a 54.9% increase in bacterial killing compared with unstimulated neutrophils (15.6%) in early phase samples. Similarly, P4 peptide treatment significantly increased neutrophil and monocyte intraphagosomal reporter bead association and oxidation, independent of infection source., Conclusions: We have extended preclinical work to demonstrate that P4 peptide significantly increases phagocytosis and bacterial killing in samples from a target patient population with severe sepsis. This study supports the rationale for augmented passive immunotherapy as a therapeutic strategy in severe sepsis.

Published

2016

36. A leaky mutation in CD3D differentially affects αβ and γδ T cells and leads to a Tαβ-Tγδ+B+NK+ human SCID.

Author

Gil J, Busto EM, Garcillán B, Chean C, García-Rodríguez MC, Díaz-Alderete A, Navarro J, Reiné J, Mencía A, Gurbindo D, Beléndez C, Gordillo I, Duchniewicz M, Höhne K, García-Sánchez F, Fernández-Cruz E, López-Granados E, Schamel WW, Moreno-Pelayo MA, Recio MJ, and Regueiro JR

Subjects

Animals, B-Lymphocytes immunology, Base Sequence, DNA Mutational Analysis, Female, Humans, Infant, Killer Cells, Natural immunology, Male, Mice, Pedigree, RNA Splice Sites genetics, Receptors, Antigen, T-Cell, alpha-beta metabolism, Receptors, Antigen, T-Cell, gamma-delta metabolism, Severe Combined Immunodeficiency etiology, CD3 Complex genetics, Mutation, Severe Combined Immunodeficiency genetics, Severe Combined Immunodeficiency immunology, T-Lymphocyte Subsets immunology

Abstract

T cells recognize antigens via their cell surface TCR and are classified as either αβ or γδ depending on the variable chains in their TCR, α and β or γ and δ, respectively. Both αβ and γδ TCRs also contain several invariant chains, including CD3δ, which support surface TCR expression and transduce the TCR signal. Mutations in variable chains would be expected to affect a single T cell lineage, while mutations in the invariant chains would affect all T cells. Consistent with this, all CD3δ-deficient patients described to date showed a complete block in T cell development. However, CD3δ-KO mice have an αβ T cell-specific defect. Here, we report 2 unrelated cases of SCID with a selective block in αβ but not in γδ T cell development, associated with a new splicing mutation in the CD3D gene. The patients' T cells showed reduced CD3D transcripts, CD3δ proteins, surface TCR, and early TCR signaling. Their lymph nodes showed severe T cell depletion, recent thymus emigrants in peripheral blood were strongly decreased, and the scant αβ T cells were oligoclonal. T cell-dependent B cell functions were also impaired, despite the presence of normal B cell numbers. Strikingly, despite the specific loss of αβ T cells, surface TCR expression was more reduced in γδ than in αβ T cells. Analysis of individuals with this CD3D mutation thus demonstrates the contrasting CD3δ requirements for αβ versus γδ T cell development and TCR expression in humans and highlights the diagnostic and clinical relevance of studying both TCR isotypes when a T cell defect is suspected.

Published

2011

37. CD3γ-independent pathways in TCR-mediated signaling in mature T and iNKT lymphocytes.

Author

Reiné J, Busto EM, Muñoz-Ruiz M, Rossi NE, Rodríguez-Fernández JL, Martínez-Naves E, Regueiro JR, and Recio MJ

Subjects

Adult, Animals, CD3 Complex genetics, CD3 Complex metabolism, Cell Line, Transformed, Cell Proliferation drug effects, Cells, Cultured, Female, Flow Cytometry, Galactosylceramides immunology, Galactosylceramides pharmacology, Humans, Immunoblotting, Male, Mice, Mice, Knockout, Mutation, Natural Killer T-Cells metabolism, Phosphorylation, Receptor-CD3 Complex, Antigen, T-Cell immunology, Receptor-CD3 Complex, Antigen, T-Cell metabolism, Receptors, Antigen, T-Cell metabolism, Receptors, Antigen, T-Cell, alpha-beta immunology, Receptors, Antigen, T-Cell, alpha-beta metabolism, T-Lymphocytes drug effects, T-Lymphocytes metabolism, Young Adult, CD3 Complex immunology, Natural Killer T-Cells immunology, Receptors, Antigen, T-Cell immunology, Signal Transduction immunology, T-Lymphocytes immunology

Abstract

Antigen recognition by T-lymphocytes through the T-cell antigen receptor, TCR-CD3, is a central event in the initiation of an immune response. CD3 proteins may have redundant as well as specific contributions to the intracellular propagation of TCR-mediated signals. However, to date, the relative role that each CD3 chain plays in signaling is controversial. In order to examine the roles of CD3γ chain in TCR signaling, we analyzed proximal and distal signaling events in human CD3γ(-/-) primary and Herpesvirus saimiri (HVS)-transformed T cells. Following TCR-CD3 engagement, certain early TCR signaling pathways (ZAP-70, ERK, p38 and mTORC2 phosphorylation, and actin polymerization) were comparable with control HVS-transformed T cells. However, other signaling pathways were affected, such TCRζ phosphorylation, indicating that the CD3γ chain contributes to improve TCR signaling efficiency and survival. On the other hand, CD3γ(-/-) primary invariant NKT cells (iNKT cells) showed a normal expansion in response to alpha-galactosylceramide (α-GalCer) and TCRVβ11(bright) iNKT cells were preferentially selected in this in vitro culture system, perhaps as a consequence of selective events in the thymus. Our results collectively indicate that a TCR lacking CD3γ can propagate a number of signals through the remaining invariant chains, likely the homologous CD3δ chain, which replaces it at the mutant TCR., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

38. Differential antibody binding to the surface alphabetaTCR.CD3 complex of CD4+ and CD8+ T lymphocytes is conserved in mammals and associated with differential glycosylation.

Author

Rossi NE, Reiné J, Pineda-Lezamit M, Pulgar M, Meza NW, Swamy M, Risueno R, Schamel WW, Bonay P, Fernández-Malavé E, and Regueiro JR

Subjects

Adult, Animals, Antibody Affinity immunology, Evolution, Molecular, Glycosylation, Humans, Immunosuppression Therapy, Jurkat Cells, Lectins pharmacology, Membrane Glycoproteins immunology, Mice, Mice, Inbred C57BL, Mice, Knockout, Primates, Protein Binding drug effects, Protein Binding immunology, Receptor-CD3 Complex, Antigen, T-Cell immunology, Sensitivity and Specificity, T-Lymphocyte Subsets immunology, Antibodies, Monoclonal metabolism, CD4 Antigens, CD8 Antigens, Membrane Glycoproteins metabolism, Receptor-CD3 Complex, Antigen, T-Cell metabolism, T-Lymphocyte Subsets metabolism

Abstract

We have previously shown that the surface alphabeta T cell antigen receptor (TCR).CD3 complex borne by human CD4(+) and CD8(+) T lymphocytes can be distinguished using mAbs. Using two unrelated sets of antibodies, we have now extended this finding to the surface alphabetaTCR.CD3 of seven additional mammalian species (six non-human primates and the mouse). We have also produced data supporting that differential glycosylation of the two main T cell subsets is involved in the observed TCR.CD3 antibody-binding differences in humans. First, we show differential lectin binding to human CD4(+) versus CD8(+) T lymphocytes, particularly with galectin 7. Second, we show that certain lectins can compete differentially with CD3 mAb binding to human primary CD4(+) and CD8(+) T lymphocytes. Third, N-glycan disruption using swainsonine was shown to increase mAb binding to the alphabetaTCR.CD3. We conclude that the differential antibody binding to the surface alphabetaTCR.CD3 complex of primary CD4(+) and CD8(+) T lymphocytes is phylogenetically conserved and associated with differential glycosylation. The differences may be exploited for therapeutic purposes, such as T cell lineage-specific immunosuppression of graft rejection. Also, the impact of glycosylation on CD3 antibody binding requires a cautious interpretation of CD3 expression levels and T cell numbers in clinical diagnosis.

Published

2008