Your search keyword '"Messenguy, F."' showing total 126 results

1. Cloning arg3, the Gene for Ornithine Carbamoyltransferase from Saccharomyces cerevisiae: Expression in Escherichia coli Requires Secondary Mutations; Production of Plasmid β -lactamase in Yeast

Author

Crabeel, M., Messenguy, F., Lacroute, F., and Glansdorff, N.

Published

1981

2. Role of RNA surveillance proteins Upf1/CpaR, Upf2 and Upf3 in the translational regulation of yeast CPA1 gene

Author

Messenguy, F., Vierendeels, F., Piérard, A., and Delbecq, P.

Published

2002

3. Integration of the multiple controls regulating the expression of the arginase gene CAR1 of Saccharomyces cerevisiae in response to different nitrogen signals: role of Gln3p, ArgRp-Mcm1p, and Ume6p

Author

Dubois, E. and Messenguy, F.

Published

1997

4. Pleiotropic function of ArgRIIIp (Arg82p), one of the regulators of arginine metabolism in Saccharomyces cerevisiae. Role in expression of cell-type-specific genes

Author

Dubois, E. and Messenguy, F.

Published

1994

5. Characterization of the yeast ARG5,6 gene: determination of the nucleotide sequence, analysis of the control region and of ARG5,6 transcript

Author

Boonchird, C., Messenguy, F., and Dubois, E.

Published

1991

6. The complete DNA sequence of yeast chromosome III

Author

Oliver, S.G., van der Aart, Q.J.M., Agostoni-Carbone, M.L., Aigle, M., Alberghina, L., Alexandraki, D., Antoine, G., Anwar, R., Ballesta, J.P.G., Benit, P., Berben, G., Bergantino, E., Biteau, N., Bolle, P.A., Bolotin-Fukuhara, M., Brown, A., Brown, A.J.P., Buhler, J.M., Carcano, C., Carignani, G., Cederberg, H., Chanet, R., Contreras, R., Crouzet, M., Daignan-Fornier, B., Defoor, E., Delgado, M., Demolder, J., Doira, C., Dubois, E., Dujon, B., Dusterhoft, A., Erdmann, D., Esteban, M., Fabre, F., Fairhead, C., Faye, G., Feldmann, H., Fiers, W., Francingues-Gaillard, M.C., Franco, L., Frontali, L., Fukuhara, H., Fuller, L.J., Galland, P., Gent, M.E., Gigot, D., Gilliquet, V., Glansdorff, N., Goffeau, A., Grenson, M., Grisanti, P., Grivell, L.A., de Haan, M., Haasemann, M., Hatat, D., Hoenicka, J., Hegemann, J., Herbert, C.J., Hilger, F., Hohmann, S., Hollenberg, C.P., Huse, K., Iborra, F., Indge, K.J., Isono, K., Jacq, C., Jacquet, M., James, C.M., Jauniaux, J.C., Jia, Y., Jimenez, A., Kelly, A., Kleinhans, U., Kreisl, P., Lanfranchi, G., Lewis, C., van der Linden, C.G., Lucchini, G., Lutzenkirchen, K., Maat, M.J., Mallet, L., Mannhaupt, G., Martegani, E., Mathieu, A., Maurer, C.T.C., McConnell, D., McKee, R.A., Messenguy, F., Mewes, H.W., Molemans, F., Montague, M.A., Muzi Falconi, M., Navas, L., Newlon, C.S., Noone, D., Pallier, C., Panzeri, L., Pearson, B.M., Perea, J., Philippsen, P., Pierard, A., Planta, R.J., Plevani, P., Poetsch, B., Pohl, F., Purnelle, B., Ramezani Rad, M., Rasmussen, S.W., Raynal, A., Remacha, M., Richterich, P., Roberts, A.B., Rodriguez, F., Sanz, E., Schaaff-Gerstenschlager, I., Scherens, B., Schweitzer, B., Shu, Y., Skala, J., Slonimski, P.P., Sor, F., Soustelle, C., Spiegelberg, R., Stateva, L.I., Steensma, H.Y., Steiner, S., Thierry, A., Thireos, G., Tzermia, M., Urrestarazu, L.A., Valle, G., Vetter, I., van Vliet-Reedijk, J.C., Voet, M., Volckaert, G., Vreken, P., Wang, H., Warmington, J.R., von Wettstein, D., Wicksteed, B.L., Wilson, C., Wurst, H., Xu, G., Yoshikawa, A., Zimmermann, F.K., and Sgouros, J.G.

Subjects

Saccharomyces -- Genetic aspects, Nucleotide sequence -- Research, Plant chromosomes -- Research, Genomes -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation

Published

1992

7. Mechanism of Interaction between Arginase and Ornithine Transcarbamoyl Transferase of Saccharomyces cerevisiae

Author

Wiame, J. M., Messenguy, F., Penninckx, M., Wieland, O., editor, Helmreich, E., editor, and Holzer, H., editor

Published

1972

8. The Yeast Genome Directory

Author

Goffeau, A., Aert, R., Agostini-Carbone, M. L., Ahmed, A., Aigle, M., Alberghina, L., Albermann, K., Albers, M., Aldea, M., Alexandraki, D., Aljinovic, G., Allen, E., Alt-Mörbe, J., André, B., Andrews, S., Ansorge, W., Antoine, G., Anwar, R., Aparicio, A., Araujo, R., Arino, J., Arnold, F., Arroyo, J., Aviles, E., Backes, U., Baclet, M. C., Badcock, K., Bahr, A., Baladron, V., Ballesta, J. P. G., Bankier, A. T., Banrevi, A., Bargues, M., Baron, L., Barreiros, T., Barrell, B. G., Barthe, C., Barton, A. B., Baur, A., Bécam, A.-M., Becker, A., Becker, I., Beinhauer, J., Benes, V., Benit, P., Berben, G., Bergantino, E., Bergez, P., Berno, A., Bertani, I., Biteau, N., Bjourson, A. J., Blöcker, H., Blugeon, C., Bohn, C., Boles, E., Bolle, P. A., Bolotin-Fukuhara, M., Bordonné, R., Boskovic, J., Bossier, P., Botstein, D., Bou, G., Bowman, S., Boyer, J., Brandt, P., Brandt, T., Brendel, M., Brennan, T., Brinkman, R., Brown, A., Brown, A. J. P., Brown, D., Brückner, M., Bruschi, C. V., Buhler, J. M., Buitrago, M. J., Bussereau, F., Bussey, H., Camasses, A., Carcano, C., Carignani, G., Carpenter, J., Casamayor, A., Casas, C., Castagnoli, L., Cederberg, H., Cerdan, E., Chalwatzis, N., Chanet, R., Chen, E., Chéret, G., Cherry, J. M., Chillingworth, T., Christiansen, C., Chuat, J.-C., Chung, E., Churcher, C., Churcher, C. M., Clark, M. W., Clemente, M. L., Coblenz, A., Coglievina, M., Coissac, E., Colleaux, L., Connor, R., Contreras, R., Cooper, J., Copsey, T., Coster, F., Coster, R., Couch, J., Crouzet, M., Cziepluch, C., Daignan-Fornier, B., Dal Paro, F., Dang, D. V., D’Angelo, M., Davies, C. J., Davis, K., Davis, R. W., De Antoni, A., Dear, S., Dedman, K., Defoor, E., De Haan, M., Delaveau, Th., Del Bino, S., Delgado, M., Delius, H., Delneri, D., Del Rey, F., Demolder, J., Démolis, N., Devlin, K., de Wergifosse, P., Dietrich, F. S., Ding, H., Dion, C., Dipaolo, T., Doignon, F., Doira, C., Domdey, H., Dover, J., Du, Z., Dubois, E., Dujon, B., Duncan, M., Durand, P., Düsterhöft, A., Düsterhus, S., Eki, T., El Bakkoury, M., Eide, L. G., Entian, K.-D., Eraso, P., Erdmann, D., Erfle, H., Escribano, V., Esteban, M., Fabiani, L., Fabre, F., Fairhead, C., Fartmann, B., Favello, A., Faye, G., Feldmann, H., Fernandes, L., Feroli, F., Feuermann, M., Fiedler, T., Fiers, W., Fleig, U. N., Flöth, M., Fobo, G. M., Fortin, N., Foury, F., Francingues-Gaillard, M. C., Franco, L., Fraser, A., Friesen, J.D., Fritz, C., Frontali, L., Fukuhara, H., Fulton, L., Fuller, L. J., Gabel, C., Gaillardin, C., Gaillon, L., Galibert, F., Galisson, F., Galland, P., Gamo, F.-J., Gancedo, C., Garcia-Cantalejo, J. M., García-Gonzalez, M. I., Garcia-Ramirez, J. J., García-Saéz, M., Gassenhuber, H., Gatius, M., Gattung, S., Geisel, C., Gent, M. E., Gentles, S., Ghazvini, M., Gigot, D., Gilliquet, V., Glansdorff, N., Gómez-Peris, A., Gonzaléz, A., Goulding, S. E., Granotier, C., Greco, T., Grenson, M., Grisanti, P., Grivell, L. A., Grothues, D., Gueldener, U., Guerreiro, P., Guzman, E., Haasemann, M., Habbig, B., Hagiwara, H., Hall, J., Hallsworth, K., Hamlin, N., Hand, N. J., Hanemann, V., Hani, J., Hankeln, T., Hansen, M., Harris, D., Harris, D. E., Hartzell, G., Hatat, D., Hattenhorst, U., Hawkins, J., Hebling, U., Hegemann, J., Hein, C., Hennemann, A., Hennessy, K., Herbert, C. J., Hernandez, K., Hernando, Y., Herrero, E., Heumann, K., Heuss- Neitzel, D., Hewitt, N., Hiesel, R., Hilbert, H., Hilger, F., Hillier, L., Ho, C., Hoenicka, J., Hofmann, B., Hoheisel, J., Hohmann, S., Hollenberg, C. P., Holmstrøm, K., Horaitis, O., Horsnell, T. S., Huang, M.-E., Hughes, B., Hunicke-Smith, S., Hunt, S., Hunt, S. E., Huse, K., Hyman, R. W., Iborra, F., Indge, K. J., Iraqui Houssaini, I., Isono, K., Jacq, C., Jacquet, M., Jacquier, A., Jagels, K., Jäger, W., James, C. M., Jauniaux, J. C., Jia, Y., Jier, M., Jimenez, A., Johnson, D., Johnston, L., Johnston, M., Jones, M., Jonniaux, J.-L., Kaback, D. B., Kallesøe, T., Kalman, S., Kalogeropoulos, A., Karpfinger-Hartl, L., Kashkari, D., Katsoulou, C., Kayser, A., Kelly, A., Keng, T., Keuchel, H., Kiesau, P., Kirchrath, L., Kirsten, J., Kleine, K., Kleinhans, U., Klima, R., Komp, C., Kordes, E., Korol, S., Kötter, P., Krämer, C., Kramer, B., Kreisl, P., Kucaba, T., Kuester, H., Kurdi, O., Laamanen, P., Lafuente, M. J., Landt, O., Lanfranchi, G., Langston, Y., Lashkari, D., Latreille, P., Lauquin, G., Le, T., Legrain, P., Legros, Y., Lepingle, A., Lesveque, H., Leuther, H., Lew, H., Lewis, C., Li, Z. Y., Liebl, S., Lin, A., Lin, D., Logghe, M., Lohan, A. J. E., Louis, E. J., Lucchini, G., Lutzenkirchen, K., Lyck, R., Lye, G., Maarse, A. C., Maat, M. J., Macri, C., Madania, A., Maftahi, M., Maia e Silva, A., Maillier, E., Mallet, L., Mannhaupt, G., Manus, V., Marathe, R., Marck, C., Marconi, A., Mardis, E., Martegani, E., Martin, R., Mathieu, A., Maurer, C. T. C., Mazón, M. J., Mazzoni, C., McConnell, D., McDonald, S., McKee, R. A., McReynolds, A. D. K., Melchioretto, P., Menezes, S., Messenguy, F., Mewes, H. W., Michaux, G., Miller, N., Minenkova, O., Miosga, T., Mirtipati, S., Möller-Rieker, S., Möstl, D., Molemans, F., Monnet, A., Monnier, A-L., Montague, M. A., Moro, M., Mosedale, D., Möstl, D., Moule, S., Mouser, L., Murakami, Y., Müller-Auer, S., Mulligan, J., Murphy, L., Muzi Falconi, M., Naitou, M., Nakahara, K., Namath, A., Nasr, F., Navas, L., Nawrocki, A., Nelson, J., Nentwich, U., Netter, P., Neu, R., Newlon, C. S., Nhan, M., Nicaud, J.-M., Niedenthal, R. K., Nombela, C., Noone, D., Norgren, R., Nußbaumer, B., Obermaier, B., Odell, C., Öfner, P., Oh, C., Oliver, K., Oliver, S. G., Ouellette, B. F., Ozawa, M., Paces, V., Pallier, C., Pandolfo, D., Panzeri, L., Paoluzi, S., Parle-Mcdermott, A. G., Pascolo, S., Patricio, N., Pauley, A., Paulin, L., Pearson, B. M., Pearson, D., Peluso, D., Perea, J., Pérez-Alonso, M., Pérez-Ortin, J. E., Perrin, A., Petel, F. X., Pettersson, B., Pfeiffer, F., Philippsen, P., Piérard, A., Piravandi, E., Planta, R. J., Plevani, P., Poch, O., Poetsch, B., Pohl, F. M., Pohl, T. M., Pöhlmann, R., Poirey, R., Portetelle, D., Portillo, F., Potier, S., Proft, M., Prydz, H., Pujol, A., Purnelle, B., Puzos, V., Rajandream, M. A., Ramezani Rad, M., Rasmussen, S. W., Raynal, A., Rechmann, S., Remacha, M., Revuelta, J. L., Rice, P., Richard, G-F., Richterich, P., Rieger, M., Rifken, L., Riles, L., Rinaldi, T., Rinke, M., Roberts, A. B., Roberts, D., Rodriguez, F., Rodriguez-Belmonte, E., Rodriguez-Pousada, C., Rodriguez-Torres, A. M., Rose, M., Rossau, R., Rowley, N., Rupp, T., Ruzzi, M., Saeger, W., Saiz, J. E., Saliola, M., Salom, D., Saluz, H. P., Sánchez-Perez, M., Santos, M. A., Sanz, E., Sanz, J. E., Saren, A.-M., Sartorello, F., Sasanuma, M., Sasanuma, S-I., Scarcez, T., Schaaf-Gerstenschläger, I., Schäfer, B., Schäfer, M., Scharfe, M., Scherens, B., Schroff, N., Sen-Gupta, M., Shibata, T., Schmidheini, T., Schmidt, E. R., Schneider, C., Scholler, P., Schramm, S., Schreer, A., Schröder, M., Schwager, C., Schwarz, S., Schwarzlose, C., Schweitzer, B., Schweizer, M., Sdicu, A-M., Sehl, P., Sensen, C., Sgouros, J. G., Shogren, T., Shore, L., Shu, Y., Skala, J., Skelton, J., Slonimski, P. P., Smit, P. H. M., Smith, V., Soares, H., Soeda, E., Soler-Mira, A., Sor, F., Soriano, N., Souciet, J. L., Soustelle, C., Spiegelberg, R., Stateva, L. I., Steensma, H. Y., Stegemann, J., Steiner, S., Stellyes, L., Sterky, F., Storms, R. K., St. Peter, H., Stucka, R., Taich, A., Talla, E., Tarassov, I., Tashiro, H., Taylor, P., Teodoru, C., Tettelin, H., Thierry, A., Thireos, G., Tobiasch, E., Tovan, D., Trevaskis, E., Tsuchiya, Y., Tzermia, M., Uhlen, M., Underwood, A., Unseld, M., Urbanus, J. H. M., Urrestarazu, A., Ushinsky, S., Valens, M., Valle, G., Van Broekhoven, A., Vandenbol, M., Van Der Aart, Q. J. M., Van Der Linden, C. G., Van Dyck, L., Vanoni, M., Van Vliet-Reedijk, J. C., Vassarotti, A., Vaudin, M., Vaughan, K., Verhasselt, P., Vetter, I., Vierendeels, F., Vignati, D., Vilela, C., Vissers, S., Vleck, C., Vo, D. T., Vo, D. H., Voet, M., Volckaert, G., Von Wettstein, D., Voss, H., Vreken, P., Wagner, G., Walsh, S. V., Wambutt, R., Wang, H., Wang, Y., Warmington, J. R., Waterston, R., Watson, M. D., Weber, N., Wedler, E., Wedler, H., Wei, Y., Whitehead, S., Wicksteed, B. L., Wiemann, S., Wilcox, L., Wilson, C., Wilson, R., Winant, A., Winnett, E., Winsor, B., Wipfli, P., Wölfl, S., Wohldman, P., Wolf, K., Wolfe, K. H., Wright, L. F., Wurst, H., Xu, G., Yamasaki, M., Yelton, M. A., Yokohama, K., Yoshikawa, A., Yuping, S., Zaccaria, P., Zagulski, M., Zimmermann, F. K., Zimmermann, J., Zimmermann, M., Zhong, W-W., Zollner, A., and Zumstein, E.

Published

1997

9. The nucleotide sequence of Saccharomyces cerevisiae chromosome XII

Author

Mark Johnston, Hillier, L., Riles, L., Albermann, K., André, B., Ansorge, W., Benes, V., Brückner, M., Delius, H., Dubois, E., Düsterhöft, A., Entian, K. -D, Floeth, M., Goffeau, A., Hebling, U., Heumann, K., Heuss-Neitzel, D., Hilbert, H., Hilger, F., Kleine, K., Kötter, P., Louis, E. J., Messenguy, F., Mewes, H. W., Miosga, T., Möstl, D., Müller-Auer, S., Nentwich, U., Obermaier, B., Piravandi, E., Pohl, T. M., Portetelle, D., Purnelle, B., Rechmann, S., Rieger, M., Rinke, M., Rose, M., Scharfe, M., Scherens, B., Scholler, P., Schwager, C., Schwarz, S., Underwood, A. P., Urrestarazu, L. A., Vandenbol, M., Verhasselt, P., Vierendeels, F., Voet, M., Volckaert, G., Voss, H., Wambutt, R., Wedler, E., Wedler, H., Zimmermann, F. K., Zollner, A., Hani, J., and Hoheisel, J. D.

Subjects

Base Sequence, Molecular Sequence Data, Saccharomyces cerevisiae, Chromosomes, Fungal, DNA, Fungal, Article

Abstract

The yeast Saccharomyces cerevisiae is the pre-eminent organism for the study of basic functions of eukaryotic cells(1). All of the genes of this simple eukaryotic cell have recently been revealed by an international collaborative effort to determine the complete DNA sequence of its nuclear genome. Here we describe some of the features of chromosome XII.

Published

1997

10. The complete sequence of the yeast chromosome III

Author

Oliver, S. G., van der Aart, Q. J. M., Agostoni Carbone, M. L., Aigle, M., Alberghina, L., Alexandraki, D., Antoine, G., Anwar, R., Ballesta, J. P. G., Benit, P., Berben, G., Bergantino, Elisabetta, Biteau, N., Bolle, P. A., Bolotin Fukuhara, M., Brown, A., Brown, A. J. P., Buhler, J. M., Carcano, C., Carignani, G., Cederberg, H., Chanet, R., Contreras, R., Crouzet, M., Daignan Fornier, B., Defoor, E., Delgado, M., Demolder, J., Doira, C., Dubois, E., Dujon, B., Dusterhoft, A., Erdmann, D., Esteban, M., Fabre, F., Fairhead, C., Faye, G., Feldmann, H., Fiers, W., Francingues Gaillard, M. C., Franco, L., Frontali, L., Fukuhara, H., Fuller, L. J., Galland, P., Gent, M. E., Gigot, D., Gilliquet, V., Glansdorff, N., Goffeau, A., Grenson, M., Grisanti, P., Grivell, L. A., de Haan, M., Haasemann, M., Hatat, D., Hoenicka, J., Hegemann, J., Herbert, C. J., Hilger, F., Hohmann, S., Hollenberg, C. P., Huse, K., Iborra, F., Indje, K. J., Isono, K., Jacq, C., Jacquet, M., James, C. M., Jauniaux, J. C., Jia, Y., Jimenez, A., Kelly, A., Kleinhans, U., Kreisl, P., Lanfranchi, Gerolamo, Lewis, C, Vanderlinden, C. G., Lucchini, G., Lutzenkirchen, K, Maat, M. J., Mallet, L., Mannhaupet, G., Martegani, E., Mathieu, A., Maurer, C. T. C., Mcconnell, D., Mckee, R. A., Messenguy, F., Mewes, H. W., Molemans, F., Montague, M. A., Muzi Falconi, M., Navas, L., Newlon, C. S., Noone, D., Pallier, C., Panzeri, L., Pearson, B. M., Perea, J., Philippsen, P., Pierard, A., Planta, R. J., Plevani, P., Poetsch, B., Pohl, F., Purnelle, B., Ramezani Rad, M., Rasmussen, S. W., Raynal, A., Remacha, M., Richterich, P., Roberts, A. B., Rodriguez, F., Sanz, E., Schaaff Gerstenschlager, I., Scherens, B., Schweitzer, B., Shu, Y., Skala, J., Slonimski, P. P., Sor, F., Soustelle, C., Spiegelberg, R., Stateva, L. I., Steensma, S., Steiner, H. Y., Thierry, A., Thireos, G., Tzermia, M., Urrestarazu, L. A., Valle, Giorgio, Vetter, I., van Vliet Reedijk, J. C., Voet, M., Volckaert, G., Vreken, P., Wang, H., Warmington, J. R., von Wettstein, D., Wicksteed, B. L., Wilson, C., Wurst, H., Xu, G., Yoshikawa, A., Zimmermann, F. K., and Sgouros, J. G.

Published

1992

11. The nucleotide sequence of Saccharomyces cerevisiae chromosome XIV and its evolutionary implications

Author

Philippsen, P., primary, Kleine, K., additional, Pöhlmann, R., additional, Düsterhöft, A., additional, Hamberg, K., additional, Hegemann, J. H., additional, Obermaier, B., additional, Urrestarazu, L. A., additional, Aert, R., additional, Albermann, K., additional, Altmann, R., additional, André, B., additional, Baladron, V., additional, Ballesta, J. P. G., additional, Bécam, A.-M., additional, Beinhauer, J., additional, Boskovic, J., additional, Buitrago, M. J., additional, Bussereau, F., additional, Coster, F., additional, Crouzet, M., additional, D’Angelo, M., additional, Dal Pero, F., additional, De Antoni, A., additional, Del Rey, F., additional, Doignon, F., additional, Domdey, H., additional, Dubois, E., additional, Fiedler, T., additional, Fleig, U., additional, Floeth, M., additional, Fritz, C., additional, Gaillardin, C., additional, Garcia-Cantalejo, J. M., additional, N Glansdorff, N., additional, Goffeau, A., additional, Gueldener, U., additional, Herbert, C., additional, Heumann, K., additional, Heuss-Neitzel, D., additional, Hilbert, H., additional, Hinni, K., additional, Iraqui Houssaini, I., additional, Jacquet, M., additional, Jimenez, A., additional, Jonniaux, J.-L., additional, Karpfinger, L., additional, Lanfranchi, G., additional, Lepingle, A., additional, Levesque, H., additional, Lyck, R., additional, Maftahi, M., additional, Mallet, L., additional, Maurer, K. C. T., additional, Messenguy, F., additional, Mewes, H. W., additional, Möstl, D., additional, Nasr, F., additional, Nicaud, J.-M., additional, Niedenthal, R. K., additional, Pandolfo, D., additional, Piérard, A., additional, Piravandi, E., additional, Planta, R. J., additional, Pohl, T. M., additional, Purnelle, B., additional, Rebischung, C., additional, Remacha, M., additional, Revuelta, J. L., additional, Rinke, M., additional, Saiz, J. E., additional, Sartorello, F., additional, Scherens, B., additional, Sen-Gupta, M., additional, Soler-Mira, A., additional, Urbanus, J. H. M., additional, Valle, G., additional, Van Dyck, L., additional, Verhasselt, P., additional, Vierendeels, F., additional, Vissers, S., additional, Voet, M., additional, Volckaert, G., additional, Wach, A., additional, Wambutt, R., additional, Wedler, H., additional, Zollner, A., additional, and Hani, J., additional

Published

1997

12. Cloning and sequencing ofSchizosaccharomyces pombe car1 gene encoding arginase. Expression of the arginine anabolic and catabolic genes in response to arginine and related metabolites

Author

Van Huffel, C., primary, Dubois, E., additional, and Messenguy, F., additional

Published

1994

13. A segment of mRNA encoding the leader peptide of the CPA1 gene confers repression by arginine on a heterologous yeast gene transcript

Author

Delbecq, P, primary, Werner, M, additional, Feller, A, additional, Filipkowski, R K, additional, Messenguy, F, additional, and Piérard, A, additional

Published

1994

14. UME6 is a key regulator of nitrogen repression and meiotic development.

Author

Strich, R, primary, Surosky, R T, additional, Steber, C, additional, Dubois, E, additional, Messenguy, F, additional, and Esposito, R E, additional

Published

1994

15. Genetic evidence for a role for MCM1 in the regulation of arginine metabolism in Saccharomyces cerevisiae.

Author

Messenguy, F, primary and Dubois, E, additional

Published

1993

16. The complete sequence of a 9,543 bp segment on the left arm of chromosome III reveals five open reading frames including glucokinase and the protein disulfide isomerase

Author

Scherens, B., primary, Messenguy, F., additional, Gigot, D., additional, and Dubois, E., additional

Published

1992

17. Determination of the DNA-binding sequences of ARGR proteins to arginine anabolic and catabolic promoters.

Author

Messenguy, F, primary, Dubois, E, additional, and Boonchird, C, additional

Published

1991

18. Dissection of the bifunctional ARGRII protein involved in the regulation of arginine anabolic and catabolic pathways

Author

Qui, H F, primary, Dubois, E, additional, and Messenguy, F, additional

Published

1991

19. In vitro studies of the binding of the ARGR proteins to the ARG5,6 promoter.

Author

Dubois, E, primary and Messenguy, F, additional

Published

1991

20. III. Yeast sequencing reports. Determination of the sequence of the yeastYCL313 gene localized on chromosome III. Homology with the protein disulfide isomerase (PDI gene product) of other organisms

Author

Scherens, B., primary, Dubois, E., additional, and Messenguy, F., additional

Published

1991

21. Cloning and sequencing of Schizosaccharomyces pombe car1 gene encoding arginase. Expression of the arginine anabolic and catabolic genes in response to arginine and related metabolites.

Author

Van Huffel, C., Dubois, E., and Messenguy, F.

Published

1994

22. III. Yeast sequencing reports. Determination of the sequence of the yeast YCL313 gene localized on chromosome III. Homology with the protein disulfide isomerase (PDI gene product) of other organisms.

Author

Scherens, B., Dubois, E., and Messenguy, F.

Published

1991

23. Inositol polyphosphate kinase activity of Arg82/ArgRIII is not required for the regulation of the arginine metabolism in yeast

Author

Dubois, E., Dewaste, V., Erneux, C., and Messenguy, F.

Published

2000

24. Control‐mechanisms acting at the transcriptional and post‐transcriptional levels are involved in the synthesis of the arginine pathway carbamoylphosphate synthase of yeast.

Author

Messenguy, F., Feller, A., Crabeel, M., and Piérard, A.

Abstract

In Saccharomyces cerevisiae, the synthesis of the arginine pathway enzyme carbamoylphosphate synthase (CPSase A) is subject to two control mechanisms. One mechanism, the general control of amino acid biosynthesis, influences the expression of both CPA1 and CPA2 genes, the structural genes for the two subunits of the enzyme. The second mechanism, the specific control of arginine biosynthesis, only affects the expression of CPA1. To study these mechanisms in more detail, we have cloned the CPA1 and CPA2 genes and used their DNA to measure the CPA1 and CPA2 mRNA content of cells grown under various conditions. A close coordination was observed in the variation of the levels of CPA1 and CPA2 mRNAs and polypeptide products under conditions where the general control of amino acid biosynthesis operates. In contrast, little correlation was found between the levels of CPA1 mRNA and the corresponding protein for conditions affecting repression by arginine: the total amplitude of variation was 6‐fold higher for the CPA1 protein than for the CPA1 messenger transcript. Such findings are consistent with the conclusion that the general control operates at the transcriptional level and that the specific arginine control acts primarily at a post‐transcriptional level.

Published

1983

25. Cloning arg3, the gene for ornithine carbamoyltransferase from Saccharomyces cerevisiae: expression in Escherichia coli requires secondary mutations; production of plasmid beta-lactamase in yeast.

Author

Crabeel, M, Messenguy, F, Lacroute, F, and Glansdorff, N

Abstract

The yeast arg3 gene, coding for ornithine carbamoyltransferase (carbamoylphosphate:L-ornithine carbamoyltransferase, EC 2.1.3.3), has been cloned on a hybrid pBR322-2-micrometers plasmid. The cloned gene gives a normal regulatory response in yeast. It is not expressed at 35 degrees C when a mutation preventing mRNA export from the nucleus at this temperature is included in the genetic make-up of the carrier strain. In Escherichia coli, no functional expression can be observed from the native yeast arg3 gene. The study of a mutant plasmid (M1) producing low levels of yeast carbamoyltransferase in E. coli has permitted the localization and orientation of arg3 on the plasmid. The mutation involved is a deletion that alters the regulatory response of arg3 in yeast. The plasmid bla gene produces detectable amounts of beta-lactamase (penicillin amido-beta-lactamhydrolase, EC 3.5.2.6) in yeast: the data provide an estimate of the beta-lactamase activity associated with one exemplar of the plasmid expressing arg3 (0.6 units).

Published

1981

26. General amino acid control and specific arginine repression in Saccharomyces cerevisiae: physical study of the bifunctional regulatory region of the ARG3 gene

Author

Crabeel, M, Huygen, R, Verschueren, K, Messenguy, F, Tinel, K, Cunin, R, and Glansdorff, N

Abstract

To characterize further the regulatory mechanism modulating the expression of the Saccharomyces cerevisiae ARG3 gene, i.e., the specific repression by arginine and the general amino acid control, we analyzed by deletion the region upstream of that gene, determined the nucleotide sequence of operator-constitutive-like mutations affecting the specific regulation, and examined the behavior of an ARG3-galK fusion engineered at the initiating codon of ARG3. Similarly to what was observed in previous studies on the HIS3 and HIS4 genes, our data show that the general regulation acts as a positive control and that a sequence containing the nucleotide TGACTC, between positions -364 and -282 upstream of the transcription start, functions as a regulatory target site. This sequence contains the most proximal of the two TGACTC boxes identified in front of ARG3. While the general control appears to modulate transcription efficiency, the specific repression by arginine displays a posttranscriptional component (F. Messenguy and E. Dubois, Mol. Gen. Genet. 189:148-156, 1983). Our deletion and gene fusion analyses confirm that the specific and general controls operate independently of each other and assign the site responsible for arginine-specific repression to between positions -170 and +22. In keeping with this assignment, the two operator-constitutive-like mutations were localized at positions -80 and -46, respectively, and thus in a region which is not transcribed. We discuss a hypothesis accounting for the involvement of untranscribed DNA in a posttranscriptional control.

Published

1985

27. Regulation of arginine biosynthesis in Saccharomyces cerevisiae: isolation of a cis-dominant, constitutive mutant for ornithine carbamoyltransferase synthesis

Author

Messenguy, F

Abstract

A cis-dominant mutation linked to argF, the structural gene specifying ornithine carbamoyltransferase, and affecting the control of the synthesis of this enzyme has been obtained. The level of ornithine carbamoyltransferase in this mutation is depressed and less repressible by addition of L-arginine than it is in the wild-type strain. Of 38 tetrads analyzed, resulting from a cross of a strain harboring this mutation with a strain carrying an argF- mutation, none was a tetratype or a nonparental ditype. This operator mutation helps to define a negative mode of control of the synthesis of the arginine biosynthetic enzymes, as had been suggested earlier upon the isolation of argRI- (arg80), argRII- (arg81), and argRIII- (arg82) specific regulatory mutations.

Published

1976

28. Evidence that specific and "general" control of ornithine carbamoyltransferase production occurs at the level of transcription in Saccharomyces cerevisiae

Author

Messenguy, F and Cooper, T G

Abstract

Ornithine carbamoyltransferase synthesis is subject to two major regulatory systems in Saccharomyces cerevisiae. One system is specific for the arginine biosynthetic enzymes, whereas the other appears to be general, acting on a variety of other amino acid pathways as well. We observed that the synthetic capacity for continued ornithine carbamoyltransferase synthesis had the same short half-life (ca. 5 to 7 min) whether repression of enzyme production was brought about by action of the specific or general control system. We present evidence suggesting that both control systems regulate accumulation or ornithine carbamoyltransferase-specific synthetic capacity, rather than modulating its expression.

Published

1977

29. Complete DNA sequence of yeast chromosome II

Author

Feldmann, H., Aigle, M., Aljinovic, G., André, B., Baclet, M. C., Barthe, C., Baur, A., Bécam, A. -M, Biteau, N., Boles, E., Brandt, T., Brendel, M., Brückner, M., Bussereau, F., Christiansen, C., Contreras, R., Crouzet, M., Cziepluch, C., Démolis, N., Delaveau, Th, Doignon, F., Domdey, H., Düsterhus, S., Dubois, E., Dujon, B., El Bakkoury, M., Entian, K. -D, Feuermann, M., Fiers, W., Fobo, G. M., Fritz, C., Gassenhuber, H., Glansdorff, N., Goffeau, A., Grivell, L. A., Haan, M., Hein, C., Herbert, C. J., Hollenberg, C. P., Holmstrøm, K., Jacq, C., Jacquet, M., Jauniaux, J. C., Jonniaux, J. -L, Kallesøe, T., Kiesau, P., Kirchrath, L., Kötter, P., Korol, S., Liebl, S., Logghe, M., Lohan, A. J. E., Louis, E. J., Li, Z. Y., Maat, M. J., Mallet, L., Mannhaupt, G., Messenguy, F., Miosga, T., Molemans, F., Müller, S., Nasr, F., Obermaier, B., Perea, J., Piérard, A., Piravandi, E., Pohl, F. M., Pohl, T. M., Potier, S., Markus Proft, Purnelle, B., Ramezani Rad, M., Rieger, M., Rose, M., Schaaff-Gerstenschläger, I., Scherens, B., Schwarzlose, C., Skala, J., Slonimski, P. P., Smits, P. H. M., Souciet, J. L., Steensma, H. Y., Stucka, R., Urrestarazu, A., Aart, Q. J. M., Dyck, L., Vassarotti, A., Vetter, I., Vierendeels, F., Vissers, S., Wagner, G., Wergifosse, P., Wolfe, K. H., Zagulski, M., Zimmermann, F. K., Mewes, H. W., Kleine, K., and Molecular Biology and Microbial Food Safety (SILS, FNWI)

30. The complete DNA sequence of yeast chromosome III

Author

Oliver, S. G., Aart, Q. J. M., Agostoni-Carbone, M. L., Aigle, M., Alberghina, L., Alexandraki, D., Antoine, G., Anwar, R., Ballesta, J. P. G., Benit, P., Berben, G., Bergantino, E., Biteau, N., Bolle, P. A., Bolotin-Fukuhara, M., Brown, A., Brown, A. J. P., Buhler, J. M., Carcano, C., Carignani, G., Cederberg, H., Chanet, R., Contreras, R., Crouzet, M., Daignan-Fornier, B., Defoor, E., Delgado, M., Demolder, J., Doira, C., Dubois, E., Dujon, B., Dusterhoft, A., Erdmann, D., Esteban, M., Fabre, F., Fairhead, C., Faye, G., Feldmann, H., Fiers, W., Francingues-Gaillard, M. C., Franco, L., Frontali, L., Fukuhara, H., Fuller, L. J., Galland, P., Gent, M. E., Gigot, D., Gilliquet, V., Glansdorff, N., Goffeau, A., Grenson, M., Grisanti, P., Grivell, L. A., Haan, M., Haasemann, M., Hatat, D., Hoenicka, J., Hegemann, J., Herbert, C. J., Hilger, F., Hohmann, S., Hollenberg, C. P., Huse, K., Iborra, F., Indge, K. J., Isono, K., Jacq, C., Jacquet, M., James, C. M., Jauniaux, J. C., Jia, Y., Jimenez, A., Kelly, A., Kleinhans, U., Kreisl, P., Lanfranchi, G., Lewis, C., Linden, C. G., Lucchini, G., Lutzenkirchen, K., Maat, M. J., Mallet, L., Mannhaupt, G., Martegani, E., Mathieu, A., Maurer, C. T. C., Mcconnell, D., Mckee, R. A., Messenguy, F., Mewes, H. W., Molemans, F., Montague, M. A., Falconi, M. M., Navas, L., Newlon, C. S., Noone, D., Pallier, C., Panzeri, L., and Pearson, B. M.

31. The control of ornithinetranscarbamylase activity by arginase in Saccharomyces cerevisiae

Author

Messenguy, F., primary and Wiame, J.-M., additional

Published

1969

32. Identification of direct and indirect targets of the Gln3 and Gat1 activators by transcriptional profiling in response to nitrogen availability in the short and long term.

Author

Scherens B, Feller A, Vierendeels F, Messenguy F, and Dubois E

Subjects

Binding Sites, GATA Transcription Factors metabolism, Gene Expression Regulation, Fungal, Glutamine metabolism, Glutathione Peroxidase, Oligonucleotide Array Sequence Analysis, Prions physiology, Proline metabolism, Promoter Regions, Genetic, Ribosomal Proteins genetics, Saccharomyces cerevisiae metabolism, Sirolimus pharmacology, GATA Transcription Factors physiology, Gene Expression Profiling, Nitrogen metabolism, Repressor Proteins physiology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins physiology, Transcription Factors physiology

Abstract

Nitrogen catabolite repression (NCR) consists in the specific inhibition of transcriptional activation of genes encoding the permeases and catabolic enzymes needed to degrade poor nitrogen sources. Under nitrogen limitation or rapamycin treatment, NCR genes are activated by Gln3 or Gat1, or by both factors. To compare the sets of genes responding to rapamycin or to nitrogen limitation, we used DNA microarrays to establishing the expression profiles of a wild type strain, and of a double gln3Delta-gat1Delta strain, grown on glutamine, after addition of rapamycin, on proline, or after a shift from glutamine to proline. Analysis of microarray data revealed 392 genes whose expression was dependent on the nitrogen source quality. 91 genes were activated in a GATA factor-dependent manner in all growth conditions, suggesting a direct role of Gln3 and Gat1 in their expression. Other genes were only transiently up-regulated (stress-responsive genes) or down-regulated (genes encoding ribosomal proteins and translational factors) upon nitrogen limitation, and this regulation was delayed in a gln3Delta-gat1Delta strain. Repression of amino acid and nucleotide biosynthetic genes after a nitrogen shift did not depend on Gcn4. Several transporter genes were repressed as a consequence of enhanced levels of NCR-responsive permeases present at the plasma membrane.

Published

2006

33. Role of MADS box proteins and their cofactors in combinatorial control of gene expression and cell development.

Author

Messenguy F and Dubois E

Subjects

Amino Acid Sequence, Animals, Arabidopsis genetics, Arabidopsis growth & development, Base Sequence, Cell Division genetics, Eukaryotic Cells cytology, Humans, MADS Domain Proteins chemistry, MADS Domain Proteins physiology, Models, Genetic, Molecular Sequence Data, Protein Binding, Protein Structure, Tertiary, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development, Sequence Homology, Amino Acid, Sequence Homology, Nucleic Acid, Signal Transduction genetics, Eukaryotic Cells metabolism, Gene Expression Regulation, MADS Domain Proteins genetics

Abstract

In all organisms, correct development, growth and function depends on the precise and integrated control of the expression of their genes. Often, gene regulation depends upon the cooperative binding of proteins to DNA and upon protein-protein interactions. Eukaryotes have widely exploited combinatorial strategies to create gene regulatory networks. MADS box proteins constitute the perfect example of cellular coordinators. These proteins belong to a large family of transcription factors present in most eukaryotic organisms and are involved in diverse and important biological functions. MADS box proteins are combinatorial transcription factors in that they often derive their regulatory specificity from other DNA binding or accessory factors. This review is aimed at analyzing how MADS box proteins combine with a variety of cofactors to achieve functional diversity.

Published

2003

34. Arg82p is a bifunctional protein whose inositol polyphosphate kinase activity is essential for nitrogen and PHO gene expression but not for Mcm1p chaperoning in yeast.

Author

El Alami M, Messenguy F, Scherens B, and Dubois E

Subjects

Genes, Reporter, Oligonucleotide Array Sequence Analysis, Phosphotransferases (Phosphate Group Acceptor), Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Transcriptional Activation, Two-Hybrid System Techniques, Gene Expression Regulation, Fungal, Inositol Phosphates metabolism, Nitrogen metabolism, Phosphotransferases (Alcohol Group Acceptor) metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

In Saccharomyces cerevisiae, the synthesis of inositol pyrophosphates is essential for vacuole biogenesis and the cell's response to certain environmental stresses. The kinase activity of Arg82p and Kcs1p is required for the production of soluble inositol phosphates. To define physiologically relevant targets of the catalytic products of Arg82p and Kcs1p, we used DNA microarray technology. In arg82delta or kcs1delta cells, we observed a derepressed expression of genes regulated by phosphate (PHO) on high phosphate medium and a strong decrease in the expression of genes regulated by the quality of nitrogen source (NCR). Arg82p and Kcs1p are required for activation of NCR-regulated genes in response to nitrogen availability, mainly through Nil1p, and for repression of PHO genes by phosphate. Only the catalytic activity of both kinases was required for PHO gene repression by phosphate and for NCR gene activation in response to nitrogen availability, indicating a role for inositol pyrophosphates in these controls. Arg82p also controls expression of arginine-responsive genes by interacting with Arg80p and Mcm1p, and expression of Mcm1-dependent genes by interacting with Mcm1p. We show here that Mcm1p and Arg80p chaperoning by Arg82p does not involve the inositol polyphosphate kinase activity of Arg82p, but requires its polyaspartate domain. Our results indicate that Arg82p is a bifunctional protein whose inositol kinase activity plays a role in multiple signalling cascades, and whose acidic domain protects two MADS-box proteins against degradation.

Published

2003

35. Yeast epiarginase regulation, an enzyme-enzyme activity control: identification of residues of ornithine carbamoyltransferase and arginase responsible for enzyme catalytic and regulatory activities.

Author

El Alami M, Dubois E, Oudjama Y, Tricot C, Wouters J, Stalon V, and Messenguy F

Subjects

Amino Acid Sequence, Binding Sites, Catalysis, Catalytic Domain, Chromatography, Gel, DNA metabolism, Dose-Response Relationship, Drug, Fungal Proteins chemistry, Fungal Proteins metabolism, Gene Deletion, Kinetics, Lysine chemistry, Models, Molecular, Molecular Sequence Data, Mutation, Ornithine pharmacology, Plasmids metabolism, Point Mutation, Promoter Regions, Genetic, Protein Binding, Protein Conformation, Protein Structure, Tertiary, Recombinant Fusion Proteins chemistry, Temperature, Two-Hybrid System Techniques, Arginase chemistry, Gene Expression Regulation, Enzymologic, Gene Expression Regulation, Fungal, Ornithine Carbamoyltransferase chemistry, Yeasts enzymology

Abstract

In the presence of ornithine and arginine, ornithine carbamoyltransferase (OTCase) and arginase form a one-to-one enzyme complex in which the activity of OTCase is inhibited whereas arginase remains catalytically active. The mechanism by which these nonallosteric enzymes form a stable complex triggered by the binding of their respective substrates raises the question of how such a cooperative association is induced. Analyses of mutations in both enzymes identify residues that are required for their association, some of them being important for catalysis. In arginase, two cysteines at the C terminus of the protein are crucial for its epiarginase function but not for its catalytic activity and trimeric structure. In OTCase, mutations of putative ornithine binding residues, Asp-182, Asn-184, Asn-185, Cys-289, and Glu-256 greatly reduced the affinity for ornithine and impaired the interaction with arginase. The four lysine residues located in the SMG loop, Lys-260, Lys-263, Lys-265, and Lys-268, also play an important role in mediating the sensitivity of OTCase to ornithine and to arginase and appear to be involved in transducing and enhancing the signal given by ornithine for the closure of the catalytic domain.

Published

2003

36. Swapping functional specificity of a MADS box protein: residues required for Arg80 regulation of arginine metabolism.

Author

Jamai A, Dubois E, Vershon AK, and Messenguy F

Subjects

Amino Acid Sequence, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Genetic Complementation Test, Humans, MADS Domain Proteins chemistry, MADS Domain Proteins metabolism, Models, Molecular, Molecular Sequence Data, Mutation, Protein Binding, Protein Structure, Secondary, Protein Structure, Tertiary, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Sequence Alignment, Transcription Factors genetics, Transcription Factors metabolism, Two-Hybrid System Techniques, Arginine metabolism, MADS Domain Proteins genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

Arg80 and Mcm1, two members of the MADS box family of DNA-binding proteins, regulate the metabolism of arginine in association with Arg81, the arginine sensor. In spite of the high degree of sequence conservation between the MADS box domains of the Arg80 and Mcm1 proteins (56 of 81 amino acids), these domains are not interchangeable. To determine which amino acids define the specificity of Arg80, we swapped the amino acids in each secondary-structure element of the Arg80 MADS box domain with the corresponding amino acids of Mcm1 and assayed the ability of these chimeras to regulate arginine-metabolic genes in place of the wild-type Arg80. Also performed was the converse experiment in which each variant residue in the Mcm1 MADS box domain was swapped with the corresponding residue of Arg80 in the context of an Arg80-Mcm1 fusion protein. We show that multiple regions of Arg80 are important for its function. Interestingly, the residues which have important roles in determining the specificity of Arg80 are not those which could contact the DNA but are residues that are likely to be involved in protein interactions. Many of these residues are clustered on one side of the protein, which could serve as an interface for interaction with Arg81 or Mcm1. This interface is distinct from the region used by the Mcm1 and human serum response factor MADS box proteins to interact with their cofactors. It is possible that this alternative interface is used by other MADS box proteins to interact with their cofactors.

Published

2002

37. In Saccharomyces cerevisiae, the inositol polyphosphate kinase activity of Kcs1p is required for resistance to salt stress, cell wall integrity, and vacuolar morphogenesis.

Author

Dubois E, Scherens B, Vierendeels F, Ho MM, Messenguy F, and Shears SB

Subjects

Cell Wall physiology, Fungal Proteins chemistry, Inositol Phosphates biosynthesis, Morphogenesis, Phosphotransferases (Phosphate Group Acceptor), Saccharomyces cerevisiae physiology, Fungal Proteins physiology, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins, Sodium Chloride pharmacology, Vacuoles physiology

Abstract

A problem for inositol signaling is to understand the significance of the kinases that convert inositol hexakisphosphate to diphosphoinositol polyphosphates. This kinase activity is catalyzed by Kcs1p in the yeast Saccharomyces cerevisiae. A kcs1Delta yeast strain that was transformed with a specifically "kinase-dead" kcs1p mutant did not synthesize diphosphoinositol polyphosphates, and the cells contained a fragmented vacuolar compartment. Biogenesis of the yeast vacuole also required another functional domain in Kcs1p, which contains two leucine heptad repeats. The kinase activity of Kcs1p was also found to sustain cell growth and integrity of the cell wall and to promote adaptive responses to salt stress. Thus, the synthesis of diphosphoinositol polyphosphates has wide ranging physiological significance. Furthermore, we showed that these phenotypic responses to Kcs1p deletion also arise when synthesis of precursor material for the diphosphoinositol polyphosphates is blocked in arg82Delta cells. This metabolic block was partially bypassed, and the phenotype was partially rescued, when Kcs1p was overexpressed in the arg82Delta cells. This was due, in part, to the ability of Kcs1p to phosphorylate a wider range of substrates than previously appreciated. Our results show that diphosphoinositol polyphosphate synthase activity is essential for biogenesis of the yeast vacuole and the cell's responses to certain environmental stresses.

Published

2002

38. Functional analysis of the leader peptide of the yeast gene CPA1 and heterologous regulation by other fungal peptides.

Author

Delbecq P, Calvo O, Filipkowski RK, Piérard A, and Messenguy F

Subjects

Amino Acid Sequence, Base Sequence, DNA, Fungal genetics, DNA, Fungal isolation & purification, Fungal Proteins biosynthesis, Molecular Sequence Data, Protein Biosynthesis, RNA, Fungal biosynthesis, RNA, Fungal genetics, RNA, Messenger biosynthesis, RNA, Messenger genetics, Saccharomyces cerevisiae drug effects, Sequence Deletion, Sequence Homology, Amino Acid, Transcription, Genetic, Aspergillus nidulans genetics, Carbamoyl-Phosphate Synthase (Glutamine-Hydrolyzing), Fungal Proteins genetics, Gene Expression Regulation, Fungal physiology, Genes, Fungal physiology, Neurospora crassa genetics, Protein Sorting Signals genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins

Abstract

The 25-amino-acid leader peptide present at the 5' end of yeast CPA1 mRNA is responsible for the translational repression of that gene by arginine. We show here that the active domain of the yeast peptide is highly specific and extends over amino acids 6-23. The region between amino acids 6-21 is well conserved between similar peptides present upstream of CPA1-homologous genes in other fungi. The Neurospora crassa arg-2 peptide represses the expression of CPA1, whereas the peptide from Aspergillus nidulans has only a weak regulatory effect. Such results suggest that the N- and C-terminal amino acids of the peptide may influence its regulatory activity. We also show that the transcription start sites of CPA1 are not modified when the cells are grown in the presence of arginine, nor in a strain carrying an inactive peptide.

Published

2000

39. In Saccharomyces cerevisiae, expression of arginine catabolic genes CAR1 and CAR2 in response to exogenous nitrogen availability is mediated by the Ume6 (CargRI)-Sin3 (CargRII)-Rpd3 (CargRIII) complex.

Author

Messenguy F, Vierendeels F, Scherens B, and Dubois E

Subjects

Bacterial Proteins metabolism, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Enzyme Induction, Fungal Proteins genetics, Gene Expression Regulation, Bacterial, Histone Deacetylases genetics, Histone Deacetylases metabolism, Membrane Proteins genetics, Minichromosome Maintenance 1 Protein, Nitrogen deficiency, Protein Binding, Repressor Proteins metabolism, Sequence Deletion, Transcription Factors genetics, Transcription Factors metabolism, Arginase genetics, Arginine metabolism, Genes, Fungal, Ornithine-Oxo-Acid Transaminase genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins

Abstract

The products of three genes named CARGRI, CARGRII, and CARGRIII were shown to repress the expression of CAR1 and CAR2 genes, involved in arginine catabolism. CARGRI is identical to UME6 and encodes a regulator of early meiotic genes. In this work we identify CARGRII as SIN3 and CARGRIII as RPD3. The associated gene products are components of a high-molecular-weight complex with histone deacetylase activity and are recruited by Ume6 to promoters containing a URS1 sequence. Sap30, another component of this complex, is also required to repress CAR1 expression. This histone deacetylase complex prevents the synthesis of the two arginine catabolic enzymes, arginase (CAR1) and ornithine transaminase (CAR2), as long as exogenous nitrogen is available. Upon nitrogen depletion, repression at URS1 is released and Ume6 interacts with ArgRI and ArgRII, two proteins involved in arginine-dependent activation of CAR1 and CAR2, leading to high levels of the two catabolic enzymes despite a low cytosolic arginine pool. Our data also show that the deletion of the UME6 gene impairs cell growth more strongly than the deletion of the SIN3 or RPD3 gene, especially in the Sigma1278b background.

Published

2000

40. ArgRII, a component of the ArgR-Mcm1 complex involved in the control of arginine metabolism in Saccharomyces cerevisiae, is the sensor of arginine.

Author

Amar N, Messenguy F, El Bakkoury M, and Dubois E

Subjects

Amino Acid Sequence, Base Sequence, Binding Sites, DNA-Binding Proteins genetics, Fungal Proteins genetics, Minichromosome Maintenance 1 Protein, Molecular Sequence Data, Mutation, Sequence Alignment, Transcription Factors genetics, Arginine metabolism, DNA-Binding Proteins metabolism, Fungal Proteins metabolism, Repressor Proteins, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins, Transcription Factors metabolism

Abstract

Repression of arginine anabolic genes and induction of arginine catabolic genes are mediated by a three-component protein complex, interacting with specific DNA sequences in the presence of arginine. Although ArgRI and Mcm1, two MADS-box proteins, and ArgRII, a zinc cluster protein, contain putative DNA binding domains, alone they are unable to bind the arginine boxes in vitro. Using purified glutathione S-transferase fusion proteins, we demonstrate that ArgRI and ArgRII1-180 or Mcm1 and ArgRII1-180 are able to reconstitute an arginine-dependent binding activity in mobility shift analysis. Binding efficiency is enhanced when the three recombinant proteins are present simultaneously. At physiological concentration, the full-length ArgRII is required to fulfill its functions; however, when ArgRII is overexpressed, the first 180 amino acids are sufficient to interact with ArgRI, Mcm1, and arginine, leading to the formation of an ArgR-Mcm1-DNA complex. Several lines of evidence indicate that ArgRII is the sensor of the effector arginine and that the binding site of arginine would be the region downstream from the zinc cluster, sharing some identity with the arginine binding domain of bacterial arginine repressors.

Published

2000

41. Recruitment of the yeast MADS-box proteins, ArgRI and Mcm1 by the pleiotropic factor ArgRIII is required for their stability.

Author

El Bakkoury M, Dubois E, and Messenguy F

Subjects

Amino Acid Sequence, Base Sequence, DNA Primers, DNA-Binding Proteins genetics, Fungal Proteins chemistry, Fungal Proteins genetics, Minichromosome Maintenance 1 Protein, Molecular Sequence Data, Mutagenesis, Site-Directed, Protein Binding, Sequence Homology, Amino Acid, Transcription Factors genetics, Arginine metabolism, DNA-Binding Proteins metabolism, Fungal Proteins metabolism, Phosphotransferases (Alcohol Group Acceptor), Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins, Transcription Factors metabolism

Abstract

Regulation of arginine metabolism requires the integrity of four regulatory proteins, ArgRI, ArgRII, ArgRIII and Mcm1. To characterize further the interactions between the different proteins, we used the two-hybrid system, which showed that ArgRI and Mcm1 interact together, and with ArgRII and ArgRIII, without an arginine requirement. To define the interacting domains of ArgRI and Mcm1 with ArgRIII, we fused portions of ArgRI and Mcm1 to the DNA-binding domain of Gal4 (GBD) and created mutations in GBD-ArgRI and GBD-Mcm1. The putative alpha helix present in the MADS-box domain of ArgRI and Mcm1 is their major region of interaction with ArgRIII. Interactions between the two MADS-box proteins and ArgRIII were confirmed using affinity chromatography. The requirement for ArgRIII in the control of arginine metabolism can be bypassed in vitro as well as in vivo by overproducing ArgRI or Mcm1, which indicates that ArgRIII is not present in the protein complex formed with the 'arginine boxes'. We show that the impairment of arginine regulation in an argRIII deletant strain is a result of a lack of stability of ArgRI and Mcm1. A mutation in ArgRI, impairing its interaction with ArgRIII, leads to an unstable ArgRI protein in a wild-type strain. ArgRIII integrity is crucial for Mcm1 function, as shown by the marked decreased expression of five genes controlled by Mcm1. However, ArgRIII is likely to recruit other proteins in the yeast cell, as overexpression of Mcm1 does not compensate some physiological defects observed in an argRIII deletant strain.

Published

2000

42. The nucleotide sequence of Saccharomyces cerevisiae chromosome XII.

Author

Johnston M, Hillier L, Riles L, Albermann K, André B, Ansorge W, Benes V, Brückner M, Delius H, Dubois E, Düsterhöft A, Entian KD, Floeth M, Goffeau A, Hebling U, Heumann K, Heuss-Neitzel D, Hilbert H, Hilger F, Kleine K, Kötter P, Louis EJ, Messenguy F, Mewes HW, and Hoheisel JD

Subjects

Base Sequence, DNA, Fungal, Molecular Sequence Data, Chromosomes, Fungal, Saccharomyces cerevisiae genetics

Abstract

The yeast Saccharomyces cerevisiae is the pre-eminent organism for the study of basic functions of eukaryotic cells. All of the genes of this simple eukaryotic cell have recently been revealed by an international collaborative effort to determine the complete DNA sequence of its nuclear genome. Here we describe some of the features of chromosome XII.

Published

1997

43. Complete DNA sequence of yeast chromosome II.

Author

Feldmann H, Aigle M, Aljinovic G, André B, Baclet MC, Barthe C, Baur A, Bécam AM, Biteau N, Boles E, Brandt T, Brendel M, Brückner M, Bussereau F, Christiansen C, Contreras R, Crouzet M, Cziepluch C, Démolis N, Delaveau T, Doignon F, Domdey H, Düsterhus S, Dubois E, Dujon B, El Bakkoury M, Entian KD, Feurmann M, Fiers W, Fobo GM, Fritz C, Gassenhuber H, Glandsdorff N, Goffeau A, Grivell LA, de Haan M, Hein C, Herbert CJ, Hollenberg CP, Holmstrøm K, Jacq C, Jacquet M, Jauniaux JC, Jonniaux JL, Kallesøe T, Kiesau P, Kirchrath L, Kötter P, Korol S, Liebl S, Logghe M, Lohan AJ, Louis EJ, Li ZY, Maat MJ, Mallet L, Mannhaupt G, Messenguy F, Miosga T, Molemans F, Müller S, Nasr F, Obermaier B, Perea J, Piérard A, Piravandi E, Pohl FM, Pohl TM, Potier S, Proft M, Purnelle B, Ramezani Rad M, Rieger M, Rose M, Schaaff-Gerstenschläger I, Scherens B, Schwarzlose C, Skala J, Slonimski PP, Smits PH, Souciet JL, Steensma HY, Stucka R, Urrestarazu A, van der Aart QJ, van Dyck L, Vassarotti A, Vetter I, Vierendeels F, Vissers S, Wagner G, de Wergifosse P, Wolfe KH, Zagulski M, Zimmermann FK, Mewes HW, and Kleine K

Subjects

Base Composition, Base Sequence, Cloning, Molecular, Cosmids genetics, Molecular Sequence Data, Open Reading Frames, Quality Control, Repetitive Sequences, Nucleic Acid, Reproducibility of Results, Sequence Analysis, DNA, Sequence Homology, Amino Acid, Telomere genetics, Chromosome Mapping methods, Chromosomes, Fungal genetics, DNA, Fungal genetics, Genes, Fungal genetics, Saccharomyces cerevisiae genetics

Abstract

In the framework of the EU genome-sequencing programmes, the complete DNA sequence of the yeast Saccharomyces cerevisiae chromosome II (807 188 bp) has been determined. At present, this is the largest eukaryotic chromosome entirely sequenced. A total of 410 open reading frames (ORFs) were identified, covering 72% of the sequence. Similarity searches revealed that 124 ORFs (30%) correspond to genes of known function, 51 ORFs (12.5%) appear to be homologues of genes whose functions are known, 52 others (12.5%) have homologues the functions of which are not well defined and another 33 of the novel putative genes (8%) exhibit a degree of similarity which is insufficient to confidently assign function. Of the genes on chromosome II, 37-45% are thus of unpredicted function. Among the novel putative genes, we found several that are related to genes that perform differentiated functions in multicellular organisms of are involved in malignancy. In addition to a compact arrangement of potential protein coding sequences, the analysis of this chromosome confirmed general chromosome patterns but also revealed particular novel features of chromosomal organization. Alternating regional variations in average base composition correlate with variations in local gene density along chromosome II, as observed in chromosomes XI and III. We propose that functional ARS elements are preferably located in the AT-rich regions that have a spacing of approximately 110 kb. Similarly, the 13 tRNA genes and the three Ty elements of chromosome II are found in AT-rich regions. In chromosome II, the distribution of coding sequences between the two strands is biased, with a ratio of 1.3:1. An interesting aspect regarding the evolution of the eukaryotic genome is the finding that chromosome II has a high degree of internal genetic redundancy, amounting to 16% of the coding capacity.

Published

1994

44. Sequencing and functional analysis of a 32,560 bp segment on the left arm of yeast chromosome II. Identification of 26 open reading frames, including the KIP1 and SEC17 genes.

Author

Scherens B, el Bakkoury M, Vierendeels F, Dubois E, and Messenguy F

Subjects

Amino Acid Sequence, Animals, Base Sequence, Chromosomes, Fungal, DNA, Fungal genetics, Fungal Proteins, Microtubule-Associated Proteins, Molecular Motor Proteins, Molecular Sequence Data, Open Reading Frames, Phosphoprotein Phosphatases genetics, Rats, Restriction Mapping, Sequence Homology, Amino Acid, Transcription, Genetic, Zinc Fingers genetics, Genes, Fungal, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins

Abstract

We report here the DNA sequence of a segment (alpha 1006.13: YBLO5) of chromosome II of Saccharomyces cerevisiae, extending over 32.5 kb. The segment contains 26 open reading frames (ORFs) from YBLO501 to YBLO526. YBL0505 corresponds to the SEC17 gene and YBL0521 to the KIP1 gene. YBL0516 contains an intron, YBL0513 shows homology with the RAT protein phosphatase and YBL0526 contains a zinc-finger motif. Disruption of 14 genes by insertion of a URA3 cassette has been performed and these mutants were analysed for their mating and sporulation ability, and for their growth on different carbon sources. YBL0515 and YBL0526 ORFs seem to be involved in the sporulation process.

Published

1993

45. Cloning and sequencing of arg3 and arg11 genes of Schizosaccharomyces pombe on a 10-kb DNA fragment. Heterologous expression and mitochondrial targeting of their translation products.

Author

Van Huffel C, Dubois E, and Messenguy F

Subjects

Amino Acid Sequence, Arginine metabolism, Base Sequence, Blotting, Northern, Cloning, Molecular, DNA, Fungal genetics, Genes, Fungal, Humans, Molecular Sequence Data, Plasmids, Promoter Regions, Genetic, RNA, Fungal genetics, Restriction Mapping, Saccharomyces cerevisiae genetics, Schizosaccharomyces metabolism, Sequence Homology, Nucleic Acid, Aldehyde Oxidoreductases genetics, Mitochondria metabolism, Ornithine Carbamoyltransferase genetics, Phosphotransferases genetics, Phosphotransferases (Carboxyl Group Acceptor), Protein Biosynthesis, Schizosaccharomyces genetics

Abstract

The Schizosaccharomyces pombe arginine anabolic genes encoding ornithine carbamoyltransferase (arg3) and acetylglutamate kinase/acetylglutamyl-phosphate reductase (arg11) were cloned by functional complementation of S. pombe arg3 and arg11 mutant strains from S. pombe DNA genomic libraries. Restriction analysis and sequencing of the two clones showed that both genes are located on a common DNA fragment. The arg3 gene encodes a 327-amino-acid polypeptide presenting a strong identity to Saccharomyces cerevisiae and human ornithine carbamoyltransferases. The arg11 gene encodes a 884-amino-acid polypeptide. The acetylglutamate kinase and acetylglutamate-phosphate reductase domains have been defined by their identity with the S. cerevisiae ARG5,6 protein. The cloned arg11 gene from S. pombe does not complement an arg5,6 mutation in S. cerevisiae, nor does the ARG5,6 gene complement the S. pombe arg11- mutation. In contrast, both ornithine-carbamoyltransferase-encoding genes function in S. pombe. However, the S. pombe arg3 gene complements only weakly an arg3 S. cerevisiae strain, which is in agreement with the low level of expression of the S. pombe gene in S. cerevisiae. The subcellular localization of both ornithine carbamoyltransferases in the two yeasts indicates that, in contrast to the S. pombe enzyme, more than 95% of the S. cerevisiae enzyme remains in the S. pombe cytoplasm. The low expression of S. pombe ornithine carbamoyltransferases in S. cerevisiae did not allow its localization. The promoters of S. pombe arg3 and arg11 genes do not present striking similarities among themselves nor with the promoters of the equivalent genes of S. cerevisiae.

Published

1992

46. Determination of amino acid sequences involved in the processing of the ARG5/ARG6 precursor in Saccharomyces cerevisiae.

Author

Boonchird C, Messenguy F, and Dubois E

Subjects

Amino Acid Sequence, Base Sequence, Enzyme Precursors genetics, Escherichia coli enzymology, Escherichia coli genetics, Genes, Bacterial, Mitochondria enzymology, Molecular Sequence Data, Mutagenesis, Site-Directed, Oligonucleotide Probes, Plasmids, Protein Sorting Signals genetics, Saccharomyces cerevisiae enzymology, Sequence Homology, Nucleic Acid, Aldehyde Oxidoreductases genetics, Phosphotransferases genetics, Phosphotransferases (Carboxyl Group Acceptor), Protein Processing, Post-Translational, Saccharomyces cerevisiae genetics

Abstract

In Saccharomyces cerevisiae, the ARG5/ARG6 locus encodes both acetylglutamate kinase and acetylglutamyl-phosphate reductase, localized in the mitochondria. Genetic analysis, determination of the nucleotide sequence of the ARG5/ARG6 gene and identification of the transcript indicate that it encodes a single translation product containing two enzyme activities. However, analysis of cellular extracts revealed that the activities are completely separable. In this work, we define different domains in the ARG5/ARG6 polypeptide; a mitochondrial target sequence and the acetylglutamate-kinase and acetylglutamyl-phosphate-reductase domains. We show that deletions in the N-terminal end of the protein and point mutations in the junction region between the acetylglutamate-kinase and acetylglutamyl-phosphate-reductase domains lead to the accumulation of large precursor. Our data support the idea that import of the ARG5/ARG6 precursor into the mitochondria is required for its processing into two mature enzymes.

Published

1991

47. Determination of the sequence of the yeast YCL313 gene localized on chromosome III. Homology with the protein disulfide isomerase (PDI gene product) of other organisms.

Author

Scherens B, Dubois E, and Messenguy F

Subjects

Amino Acid Sequence, Animals, Base Sequence, Blotting, Northern, Cloning, Molecular, Molecular Sequence Data, Mutagenesis, Insertional, Open Reading Frames, Protein Conformation, Protein Disulfide-Isomerases, Rats, Saccharomyces cerevisiae enzymology, Sequence Homology, Nucleic Acid, Transformation, Genetic, Isomerases genetics, Saccharomyces cerevisiae genetics

Abstract

We have determined the nucleotide sequence of the YCL313 gene as part of the YIp5 A1G clone localized on the left arm of chromosome III. This YCL313 gene encodes a protein of 522 amino acids (MW 58.3 kDa) which has large homologies with the human, mouse, chicken, bovine and rat PDI gene products. In these organisms the PDI gene encodes the protein disulfide isomerase (EC 5.3.4.1) also called S-S rearrangase, an enzyme that catalyses the rearrangements of S-S bonds in proteins. This enzyme is probably involved in protein folding within the lumen of the endoplasmic reticulum. These sequence homologies suggest that YCL313 is the yeast equivalent of the PDI gene. Gene disruption of YCL313 leads to a lethal phenotype indicating that this gene is essential for cell survival.

Published

1991

48. Induction of "General Control" and thermotolerance in cdc mutants of Saccharomyces cerevisiae.

Author

Messenguy F and Scherens B

Subjects

DNA-Binding Proteins genetics, Gene Expression Regulation, Fungal, Genotype, Phenotype, Saccharomyces cerevisiae growth & development, Temperature, Transcription, Genetic, Fungal Proteins genetics, Protein Kinases, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins, Transcription Factors genetics

Abstract

In Saccharomyces cerevisiae starvation for a single amino acid activates the transcription of a set of genes belonging to different amino acid biosynthetic pathways (General Control, GC). We show that mutants affected in GC regulation are also affected in their response to thermal stress. Moreover, growth conditions that are known to induce heat shock proteins induce the GC response. However, unlike heat shock proteins, the transcriptional activator of GC, GCN4, is not induced after a short exposure to heat, and in gcn mutant strains induction of heat resistance is normal.

Published

1990

49. Functional analysis of ARGRI and ARGRIII regulatory proteins involved in the regulation of arginine metabolism in Saccharomyces cerevisiae.

Author

Qiu HF, Dubois E, Broën P, and Messenguy F

Subjects

Arginase metabolism, Base Sequence, Chromosome Deletion, Cloning, Molecular, DNA, Fungal, Fungal Proteins genetics, Genes, Fungal, Genetic Complementation Test, Molecular Sequence Data, Mutation, Ornithine Carbamoyltransferase metabolism, Plasmids, Restriction Mapping, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development, Sequence Homology, Nucleic Acid, Arginine metabolism, DNA-Binding Proteins, Fungal Proteins metabolism, Phosphotransferases (Alcohol Group Acceptor), Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins, Transcription Factors

Abstract

We present here a functional analysis of ARGRI and ARGRIII regulatory proteins which are involved together with ARGRII in specific regulation of arginine anabolic and catabolic pathways. Unlike ARGRII, ARGRI and ARGRIII have no transcriptional activation capacity. The first 60 amino acids of ARGRI (out of 177) are dispensable for its activity. The functional domain of the protein is located in the region of homology with MCM1 and SRF proteins. ARGRIII contains in its C-terminal portion a stretch of 17 aspartate residues which are indispensable for arginine regulation. Gene disruption of the ARGRIII gene impairs the growth of the mutant on rich medium, showing that ARGRIII has a pleiotropic role in the cell.

Published

1990

50. The regulation of arginine biosynthesis in Saccharomyces cerevisiae. The specificity of argR- mutations and the general control of amino-acid biosynthesis.

Author

Delforge J, Messenguy F, and Wiame JM

Subjects

Ammonia metabolism, Argininosuccinate Lyase metabolism, Genotype, Ornithine Carbamoyltransferase metabolism, Species Specificity, Amino Acids biosynthesis, Arginine biosynthesis, Mutation, Saccharomyces cerevisiae metabolism

Abstract

The regulation of arginine biosynthetic enzymes in yeast is subjected to a double control. One level of arginine enzyme synthesis is under the control of an apo-repressor, called ARGR. ARGR molecules control specifically the arginine pathway. A second level of control of arginine biosynthesis has been disclosed. It also controls tryptophan, histidine, lysine, isoleucine-valine and probably many more biosyntheses. The general mechanism is turned on in leaky mutants in any of the amino acid pathways mentioned above.

Published

1975