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4. The CCAAT box-binding factor stimulates ammonium assimilation in Saccharomyces cerevisiae, defining a new cross-pathway regulation between nitrogen and carbon metabolisms

Author

Dang, V.-D., Bohn, C., Bolotin-Fukuhara, M., and Daignan-Fornier, B.

Subjects
Saccharomyces -- Genetic aspects, Microbial metabolism -- Genetic aspects, Biological sciences
Abstract

The GDH1 gene in Saccharomyces cerevisiae needs the CCAAT box-binding activator (HAP complex) for optimal expression. Expression of GDH1 is also controlled by the carbon source. Hence, expression is higher on lactate than on ethanol, glycerol or galactose. The hap2 mutation does not affect expression of other genes which control nitrogen metabolism. The function of the HAP complex in the gene expression regulation indicates a cross-pathway regulation between carbon and nitrogen metabolisms.

Published
1996

5. 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

6. Isolation and characterization of the Saccharomyces cerevisiae XPT1 gene encoding xanthine phosphoribosyl transferase

Author

Guetsova, M.L., Crother, T.R., Taylor, M.W., and Daignan-Fornier, B.

Subjects
Saccharomyces -- Genetic aspects, Xanthine -- Research, Transferases -- Research, Biological sciences
Abstract

Both hypoxanthine phosphoribosyl transferase (HPRT) and xanthine phosphoribosyl transferase XPRT activities from the wild-type and isogenic Saccharomyces cerevisiae XPT1 gene were assayed in crude extracts using 8-3H hypoxanthine and 14C xanthine as substrates. The HPRT activity was observed to the same in both the wild type and in the xpt1 strain. However, the XPRT activity in the xpt1 disrupted strain was 6% lesser than in the wild-type. These results suggest that XPT1 encodes XPRT in yeast.

Published
1999

7. 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
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9. Recherche d’une thérapie de la maladie de Lesch-Nyhan : identification de molécules « HPRT-like » issue d’un criblage virtuel et à haut débit

Author

Augé, F., primary, Petitgas, C., additional, Burgevin, M.-C., additional, Mockel, L., additional, Olivier-Bandini, A., additional, Gibert, J.-F., additional, Chesney, F., additional, Curet, O., additional, Daignan-fornier, B., additional, Pinson, B., additional, Ledroit, M., additional, and Ceballos-Picot, I., additional

Published
2016
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11. SCF-dependent degradation of Aah1p requires its interaction with the F-box protein Saf1p

Author

Escusa, S., Laporte, D., Massoni, A., Boucherie, H., Dautant, A., Daignan-Fornier, B., Grellety, Marie-Lise, Institut de biochimie et génétique cellulaires (IBGC), and Université Bordeaux Segalen - Bordeaux 2-Centre National de la Recherche Scientifique (CNRS)

Subjects
[SDV.BC]Life Sciences [q-bio]/Cellular Biology, [SDV.BC] Life Sciences [q-bio]/Cellular Biology, ComputingMilieux_MISCELLANEOUS
Abstract

International audience

Published
2007

12. The nucleotide sequence of Saccharomyces cerevisiae chromosome XV

Author

Dujon B, Albermann K, Aldea M, Alexandraki D, Ansorge W, Arino J, Vladimir Benes, Bohn C, Bolotin-Fukuhara M, Bordonné R, Boyer J, Camasses A, Casamayor A, Casas C, Chéret G, Cziepluch C, Daignan-Fornier B, Dv, Dang, de Haan M, Delius H, Durand P, Fairhead C, Feldmann H, Gaillon L, and Kleine K

Subjects
Open Reading Frames, Base Sequence, Saccharomyces cerevisiae, Chromosomes, Fungal, DNA, Fungal
Abstract

Chromosome XV was one of the last two chromosomes of Saccharomyces cerevisiae to be discovered. It is the third-largest yeast chromosome after chromosomes XII and IV, and is very similar in size to chromosome VII. It alone represents 9% of the yeast genome (8% if ribosomal DNA is included). When systematic sequencing of chromosome XV was started, 93 genes or markers were identified, and most of them were mapped. However, very little else was known about chromosome XV which, in contrast to shorter chromosomes, had not been the object of comprehensive genetic or molecular analysis. It was therefore decided to start sequencing chromosome XV only in the third phase of the European Yeast Genome Sequencing Programme, after experience was gained on chromosomes III, XI and II. The sequence of chromosome XV has been determined from a set of partly overlapping cosmid clones derived from a unique yeast strain, and physically mapped at 3.3-kilobase resolution before sequencing. As well as numerous new open reading frames (ORFs) and genes encoding tRNA or small RNA molecules, the sequence of 1,091,283 base pairs confirms the high proportion of orphan genes and reveals a number of ancestral and successive duplications with other yeast chromosomes.

Published
1997

16. 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

24. Role of adenosine kinase in <TOGGLE>Saccharomyces cerevisiae</TOGGLE>: identification of the ADO1 gene and study of the mutant phenotypes

Author

Lecoq, K., Belloc, I., Desgranges, C., and Daignan-Fornier, B.

Abstract

Sequencing of the Saccharomyces cerevisiae genome revealed an open reading frame (YJR105w) encoding a putative protein highly similar to adenosine kinases from other species. Disruption of this gene (renamed ADO1) affected utilization of S-adenosyl methionine (AdoMet) as a purine source and resulted in a severe reduction of adenosine kinase activity in crude extracts. Furthermore, knock-out of ADO1 led to adenosine excretion in the medium and resistance to the toxic adenosine analogue cordycepin. From these data we conclude that ADO1 encodes yeast adenosine kinase. We also show that ADO1 does not play a major role in adenine utilization in yeast and we propose that the physiological role of adenosine kinase in S. cerevisiae could primarily be to recycle adenosine produced by the methyl cycle. Copyright © 2001 John Wiley & Sons, Ltd.

Published
2001

25. Role of adenosine kinase in Saccharomyces cerevisiae: identification of the ADO1gene and study of the mutant phenotypes

Author

Lecoq, K., Belloc, I., Desgranges, C., and Daignan‐Fornier, B.

Abstract

Sequencing of the Saccharomyces cerevisiaegenome revealed an open reading frame (YJR105w) encoding a putative protein highly similar to adenosine kinases from other species. Disruption of this gene (renamed ADO1) affected utilization of S‐adenosyl methionine (AdoMet) as a purine source and resulted in a severe reduction of adenosine kinase activity in crude extracts. Furthermore, knock‐out of ADO1led to adenosine excretion in the medium and resistance to the toxic adenosine analogue cordycepin. From these data we conclude that ADO1encodes yeast adenosine kinase. We also show that ADO1does not play a major role in adenine utilization in yeast and we propose that the physiological role of adenosine kinase in S. cerevisiaecould primarily be to recycle adenosine produced by the methyl cycle. Copyright © 2001 John Wiley & Sons, Ltd.

Published
2001
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26. Highly conserved features of DNA binding between two divergent members of the Myb family of transcription factors.

Author

Pinson, B, Brendeford, E M, Gabrielsen, O S, and Daignan-Fornier, B

Abstract

Bas1p, a divergent yeast member of the Myb family of transcription factors, shares with the proteins of this family a highly conserved cysteine residue proposed to play a role in redox regulation. Substitutions of this residue in Bas1p (C153) allowed us to establish that, despite its very high conservation, it is not strictly required for Bas1p function: its substitution with a small hydrophobic residue led to a fully functional protein in vitro and in vivo. C153 was accessible to an alkylating agent in the free protein but was protected by prior exposure to DNA. The reactivity of cysteines in the first and third repeats was much lower than in the second repeat, suggesting a more accessible conformation of repeat 2. Proteolysis protection, fluorescence quenching and circular dichroism experiments further indicated that DNA binding induces structural changes making Bas1p less accessible to modifying agents. Altogether, our results strongly suggest that the second repeat of the DNA-binding domain of Bas1p behaves similarly to its Myb counterpart, i.e. a DNA-induced conformational change in the second repeat leads to formation of a full helix-turn-helix-related motif with the cysteine packed in the hydrophobic core of the repeat.

Published
2001
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27. Signaling through regulated transcription factor interaction: mapping of a regulatory interaction domain in the Myb-related Bas1p.

Author

Pinson, B, Kongsrud, T L, Ording, E, Johansen, L, Daignan-Fornier, B, and Gabrielsen, O S

Abstract

Gene activation in eukaryotes is inherently combinatorial depending on cooperation between different transcription factors. An example where this cooperation seems to be directly exploited for regulation is the Bas1p/Bas2p couple in yeast. Bas1p is a Myb-related transcription factor that acts together with the homeodomain-related Bas2p (Pho2p) to regulate purine and histidine biosynthesis genes in response to extracellular purine limitation. We show that fusion of the two factors abolished adenine repression, suggesting that what is regulated by adenine is the Bas1p-Bas2p interaction. Analysis of Bas1p deletions revealed a critical domain (Bas1p interaction and regulatory domain, BIRD) acting in two-hybrid assays as an adenine-dependent Bas1p-Bas2p interaction domain. BIRD had a dual function, as an internal repressor of a centrally located Bas1p transactivation domain on the ADE1 promoter and as a Bas2p-dependent activator on the HIS4 promoter. This promoter-dependent behavior reflected a differential binding to the two promoters in vivo. On ADE1 Bas1p bound the promoter efficiently by itself, but required adenine limitation and Bas2p interaction through BIRD for derepression. On HIS4 efficient promoter binding and derepression required both factors and adenine limitation. We propose a promoter-dependent model for adenine regulation in yeast based on controlled Bas1p-Bas2p interactions through BIRD and exploited differentially by the two promoters.

Published
2000
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28. Mutations in the yeast Myb-like protein Bas1p resulting in discrimination between promoters in vivo but notin vitro.

Author

Pinson, B, Sagot, I, Borne, F, Gabrielsen, O S, and Daignan-Fornier, B

Abstract

Bas1p is a yeast transcription factor that activates expression of purine and histidine biosynthesis genes in response to extracellular purine limitation. The N-terminal part of Bas1p contains an Myb-like DNA binding domain composed of three tryptophan-rich imperfect repeats. We show that mutating the conserved tryptophan residues in the DNA binding domain of Bas1p severely impairs in vivo activation of target genes and in vitro DNA binding of Bas1p. We also found that two mutations (H34L and W42A) in the first repeat make Bas1p discriminate between promoters in vivo . These two BAS1 mutants are able to activate expression of an HIS4-lacZ fusion but not that of ADE1-lacZ or ADE17-lacZ fusions. Surprisingly, these mutant proteins bind equally well to the three promoters in vitro , suggesting that the mutations affect the interaction of Bas1p with some promoter-specific factor(s) in vivo . By mutating a potential nucleotide binding site in the DNA binding domain of Bas1p, we also show that this motif does not play a major role in purine regulation of Bas1p activity. Finally, using a green fluorescence protein (GFP)-Bas1p fusion, we establish the strict nuclear localization of Bas1p and show that it is not affected by extracellular adenine.

Published
1998
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29. 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.

32. Proliferation/Quiescence: When to start? Where to stop? What to stock?

Author

Daignan-Fornier Bertrand and Sagot Isabelle

Subjects
Quiescence, Saccharomyces cerevisiae, Start point, Restriction point, starvation, cell cycle, metabolism, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Cytology, QH573-671
Abstract

Abstract The cell cycle is a tightly controlled series of events that ultimately lead to cell division. The literature deciphering the molecular processes involved in regulating the consecutive cell cycle steps is colossal. By contrast, much less is known about non-dividing cellular states, even if they concern the vast majority of cells, from prokaryotes to multi-cellular organisms. Indeed, cells decide to enter the division cycle only if conditions are favourable. Otherwise they may enter quiescence, a reversible non-dividing cellular state. Recent studies in yeast have shed new light on the transition between proliferation and quiescence, re-questioning the notion of cell cycle commitment. They also indicate a predominant role for cellular metabolic status as a major regulator of quiescence establishment and exit. Additionally, a growing body of evidence indicates that environmental conditions, and notably the availability of various nutrients, by impinging on specific metabolic routes, directly regulate specific cellular re-organization that occurs upon proliferation/quiescence transitions.

Published
2011
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33. Proliferation/quiescence: the controversial 'aller-retour'

Author

Sagot Isabelle and Daignan-Fornier Bertrand

Subjects
Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Cytology, QH573-671
Abstract

Abstract The vast majority of cells, from prokaryotes up to vertebrate organisms, spend most of their time in quiescence, a state defined as a temporary and reversible absence of proliferation. Establishing the quiescent state while maintaining the capacity to re-enter the proliferation cycle are critical for cell survival and must be tightly orchestrated to avoid pathological proliferation. Hence, studying the biology of quiescent cells is an exciting research field. Taking advantage of technical progress in genomic, transcriptomic and metabolomic, the nature of transitions between proliferation and quiescence have been recently re-visited in budding yeast. Together with new findings in cell biology, these studies resuscitate an old demon in the field: the controversial existence of a "quiescence program".

Published
2011
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34. Guanylic nucleotide starvation affects Saccharomyces cerevisiae mother-daughter separation and may be a signal for entry into quiescence

Author

Sagot Isabelle, Schaeffer Jacques, and Daignan-Fornier Bertrand

Subjects
Cytology, QH573-671
Abstract

Abstract Background Guanylic nucleotides are both macromolecules constituents and crucial regulators for a variety of cellular processes. Therefore, their intracellular concentration must be strictly controlled. Consistently both yeast and mammalian cells tightly correlate the transcription of genes encoding enzymes critical for guanylic nucleotides biosynthesis with the proliferation state of the cell population. Results To gain insight into the molecular relationships connecting intracellular guanylic nucleotide levels and cellular proliferation, we have studied the consequences of guanylic nucleotide limitation on Saccharomyces cerevisiae cell cycle progression. We first utilized mycophenolic acid, an immunosuppressive drug that specifically inhibits inosine monophosphate dehydrogenase, the enzyme catalyzing the first committed step in de novo GMP biosynthesis. To approach this system physiologically, we next developed yeast mutants for which the intracellular guanylic nucleotide pools can be modulated through changes of growth conditions. In both the pharmacological and genetic approaches, we found that guanylic nucleotide limitation generated a mother-daughter separation defect, characterized by cells with two unseparated daughters. We then showed that this separation defect resulted from cell wall perturbations but not from impaired cytokinesis. Importantly, cells with similar separation defects were found in a wild type untreated yeast population entering quiescence upon nutrient limitation. Conclusion Our results demonstrate that guanylic nucleotide limitation slows budding yeast cell cycle progression, with a severe pause in telophase. At the cellular level, guanylic nucleotide limitation causes the emergence of cells with two unseparated daughters. By fluorescence and electron microscopy, we demonstrate that this phenotype arises from defects in cell wall partition between mother and daughter cells. Because cells with two unseparated daughters are also observed in a wild type population entering quiescence, our results reinforce the hypothesis that guanylic nucleotide intracellular pools contribute to a signal regulating both cell proliferation and entry into quiescence.

Published
2005
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35. Critically assessing atavism, an evolution-centered and deterministic hypothesis on cancer.

Author

Daignan-Fornier B and Pradeu T

Subjects
Humans, Animals, Biological Evolution, Mutation, Cell Proliferation genetics, Neoplasms genetics, Neoplasms pathology
Abstract

Cancer is most commonly viewed as resulting from somatic mutations enhancing proliferation and invasion. Some hypotheses further propose that these new capacities reveal a breakdown of multicellularity allowing cancer cells to escape proliferation and cooperation control mechanisms that were implemented during evolution of multicellularity. Here we critically review one such hypothesis, named "atavism," which puts forward the idea that cancer results from the re-expression of normally repressed genes forming a program, or toolbox, inherited from unicellular or simple multicellular ancestors. This hypothesis places cancer in an interesting evolutionary perspective that has not been widely explored and deserves attention. Thinking about cancer within an evolutionary framework, especially the major transitions to multicellularity, offers particularly promising perspectives. It is therefore of the utmost important to analyze why one approach that tries to achieve this aim, the atavism hypothesis, has not so far emerged as a major theory on cancer. We outline the features of the atavism hypothesis that, would benefit from clarification and, if possible, unification., (© 2024 Wiley Periodicals LLC.)

Published
2024
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36. Reuniting philosophy and science to advance cancer research.

Author

Pradeu T, Daignan-Fornier B, Ewald A, Germain PL, Okasha S, Plutynski A, Benzekry S, Bertolaso M, Bissell M, Brown JS, Chin-Yee B, Chin-Yee I, Clevers H, Cognet L, Darrason M, Farge E, Feunteun J, Galon J, Giroux E, Green S, Gross F, Jaulin F, Knight R, Laconi E, Larmonier N, Maley C, Mantovani A, Moreau V, Nassoy P, Rondeau E, Santamaria D, Sawai CM, Seluanov A, Sepich-Poore GD, Sisirak V, Solary E, Yvonnet S, and Laplane L

Subjects
Research, Interdisciplinary Studies, Philosophy, Neoplasms
Abstract

Cancers rely on multiple, heterogeneous processes at different scales, pertaining to many biomedical fields. Therefore, understanding cancer is necessarily an interdisciplinary task that requires placing specialised experimental and clinical research into a broader conceptual, theoretical, and methodological framework. Without such a framework, oncology will collect piecemeal results, with scant dialogue between the different scientific communities studying cancer. We argue that one important way forward in service of a more successful dialogue is through greater integration of applied sciences (experimental and clinical) with conceptual and theoretical approaches, informed by philosophical methods. By way of illustration, we explore six central themes: (i) the role of mutations in cancer; (ii) the clonal evolution of cancer cells; (iii) the relationship between cancer and multicellularity; (iv) the tumour microenvironment; (v) the immune system; and (vi) stem cells. In each case, we examine open questions in the scientific literature through a philosophical methodology and show the benefit of such a synergy for the scientific and medical understanding of cancer., (© 2023 The Authors. Biological Reviews published by John Wiley & Sons Ltd on behalf of Cambridge Philosophical Society.)

Published
2023
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37. Purine Biosynthesis Pathways Are Required for Myogenesis in Xenopus laevis .

Author

Duperray M, Hardet F, Henriet E, Saint-Marc C, Boué-Grabot E, Daignan-Fornier B, Massé K, and Pinson B

Subjects
Animals, Xenopus laevis genetics, Muscle Development genetics, Muscle, Skeletal metabolism, Purines metabolism
Abstract

Purines are required for fundamental biological processes and alterations in their metabolism lead to severe genetic diseases associated with developmental defects whose etiology remains unclear. Here, we studied the developmental requirements for purine metabolism using the amphibian Xenopus laevis as a vertebrate model. We provide the first functional characterization of purine pathway genes and show that these genes are mainly expressed in nervous and muscular embryonic tissues. Morphants were generated to decipher the functions of these genes, with a focus on the adenylosuccinate lyase ( ADSL ), which is an enzyme required for both salvage and de novo purine pathways. adsl.L knockdown led to a severe reduction in the expression of the myogenic regulatory factors (MRFs: Myod1, Myf5 and Myogenin), thus resulting in defects in somite formation and, at later stages, the development and/or migration of both craniofacial and hypaxial muscle progenitors. The reduced expressions of hprt1.L and ppat , which are two genes specific to the salvage and de novo pathways, respectively, resulted in similar alterations. In conclusion, our data show for the first time that de novo and recycling purine pathways are essential for myogenesis and highlight new mechanisms in the regulation of MRF gene expression.

Published
2023
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38. On-demand utilization of phosphoribosyl pyrophosphate by downstream anabolic pathways.

Author

Pinson B, Moenner M, Saint-Marc C, Granger-Farbos A, and Daignan-Fornier B

Subjects
Humans, Bacteria, Pentose Phosphate Pathway, Ligases, Phosphoribosyl Pyrophosphate, Saccharomyces cerevisiae genetics
Abstract

The pentose phosphate pathway (PPP) is critical for anabolism and biomass production. Here we show that the essential function of PPP in yeast is the synthesis of phosphoribosyl pyrophosphate (PRPP) catalyzed by PRPP-synthetase. Using combinations of yeast mutants, we found that a mildly decreased synthesis of PRPP affects biomass production, resulting in reduced cell size, while a more severe decrease ends up affecting yeast doubling time. We establish that it is PRPP itself that is limiting in invalid PRPP-synthetase mutants and that the resulting metabolic and growth defect can be bypassed by proper supplementation of the medium with ribose-containing precursors or by the expression of bacterial or human PRPP-synthetase. In addition, using documented pathologic human hyperactive forms of PRPP-synthetase, we show that intracellular PRPP as well as its derived products can be increased in both human and yeast cells, and we describe the ensuing metabolic and physiological consequences. Finally, we found that PRPP consumption appears to take place "on demand" by the various PRPP-utilizing pathways, as shown by blocking or increasing the flux in specific PRPP-consuming metabolic routes. Overall, our work reveals important similarities between human and yeast for both synthesis and consumption of PRPP., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the content of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2023
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39. Quiescence Through the Prism of Evolution.

Author

Daignan-Fornier B, Laporte D, and Sagot I

Abstract

Being able to reproduce and survive is fundamental to all forms of life. In primitive unicellular organisms, the emergence of quiescence as a reversible proliferation arrest has most likely improved cell survival under unfavorable environmental conditions. During evolution, with the repeated appearances of multicellularity, several aspects of unicellular quiescence were conserved while new quiescent cell intrinsic abilities arose. We propose that the formation of a microenvironment by neighboring cells has allowed disconnecting quiescence from nutritional cues. In this new context, non-proliferative cells can stay metabolically active, potentially authorizing the emergence of new quiescent cell properties, and thereby favoring cell specialization. Through its co-evolution with cell specialization, quiescence may have been a key motor of the fascinating diversity of multicellular complexity., 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., (Copyright © 2021 Daignan-Fornier, Laporte and Sagot.)

Published
2021
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40. Genetic investigation of purine nucleotide imbalance in Saccharomyces cerevisiae.

Author

Saint-Marc C, Ceschin J, Almyre C, Pinson B, and Daignan-Fornier B

Subjects
Guanosine Triphosphate genetics, Humans, Nucleotides genetics, Phenotype, Saccharomyces cerevisiae genetics, AMP Deaminase genetics, Amino Acid Transport Systems genetics, Aminohydrolases genetics, Purine Nucleosides genetics, Saccharomyces cerevisiae Proteins genetics
Abstract

Because metabolism is a complex balanced process involving multiple enzymes, understanding how organisms compensate for transient or permanent metabolic imbalance is a challenging task that can be more easily achieved in simpler unicellular organisms. The metabolic balance results not only from the combination of individual enzymatic properties, regulation of enzyme abundance, but also from the architecture of the metabolic network offering multiple interconversion alternatives. Although metabolic networks are generally highly resilient to perturbations, metabolic imbalance resulting from enzymatic defect and specific environmental conditions can be designed experimentally and studied. Starting with a double amd1 aah1 mutant that severely and conditionally affects yeast growth, we carefully characterized the metabolic shuffle associated with this defect. We established that the GTP decrease resulting in an adenylic/guanylic nucleotide imbalance was responsible for the growth defect. Identification of several gene dosage suppressors revealed that TAT1, encoding an amino acid transporter, is a robust suppressor of the amd1 aah1 growth defect. We show that TAT1 suppression occurs through replenishment of the GTP pool in a process requiring the histidine biosynthesis pathway. Importantly, we establish that a tat1 mutant exhibits synthetic sickness when combined with an amd1 mutant and that both components of this synthetic phenotype can be suppressed by specific gene dosage suppressors. Together our data point to a strong phenotypic connection between amino acid uptake and GTP synthesis, a connection that could open perspectives for future treatment of related human defects, previously reported as etiologically highly conserved.

Published
2020
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41. Yeast Ppz1 protein phosphatase toxicity involves the alteration of multiple cellular targets.

Author

Velázquez D, Albacar M, Zhang C, Calafí C, López-Malo M, Torres-Torronteras J, Martí R, Kovalchuk SI, Pinson B, Jensen ON, Daignan-Fornier B, Casamayor A, and Ariño J

Subjects
Cell Cycle, DNA Damage, Phosphoprotein Phosphatases genetics, Phosphorylation, Reactive Oxygen Species, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development, Saccharomyces cerevisiae Proteins genetics, Gene Expression Regulation, Fungal, Metabolome, Phosphoprotein Phosphatases metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Transcriptome
Abstract

Control of the protein phosphorylation status is a major mechanism for regulation of cellular processes, and its alteration often lead to functional disorders. Ppz1, a protein phosphatase only found in fungi, is the most toxic protein when overexpressed in Saccharomyces cerevisiae. To investigate the molecular basis of this phenomenon, we carried out combined genome-wide transcriptomic and phosphoproteomic analyses. We have found that Ppz1 overexpression causes major changes in gene expression, affecting ~ 20% of the genome, together with oxidative stress and increase in total adenylate pools. Concurrently, we observe changes in the phosphorylation pattern of near 400 proteins (mainly dephosphorylated), including many proteins involved in mitotic cell cycle and bud emergence, rapid dephosphorylation of Snf1 and its downstream transcription factor Mig1, and phosphorylation of Hog1 and its downstream transcription factor Sko1. Deletion of HOG1 attenuates the growth defect of Ppz1-overexpressing cells, while that of SKO1 aggravates it. Our results demonstrate that Ppz1 overexpression has a widespread impact in the yeast cells and reveals new aspects of the regulation of the cell cycle.

Published
2020
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42. Structural basis for substrate selectivity and nucleophilic substitution mechanisms in human adenine phosphoribosyltransferase catalyzed reaction.

Author

Ozeir M, Huyet J, Burgevin MC, Pinson B, Chesney F, Remy JM, Siddiqi AR, Lupoli R, Pinon G, Saint-Marc C, Gibert JF, Morales R, Ceballos-Picot I, Barouki R, Daignan-Fornier B, Olivier-Bandini A, Augé F, and Nioche P

Subjects
Adenine chemistry, Adenine metabolism, Adenine Phosphoribosyltransferase chemistry, Biocatalysis, Crystallography, X-Ray, Humans, Kinetics, Models, Molecular, Protein Structure, Tertiary, Quantum Theory, Substrate Specificity, Adenine Phosphoribosyltransferase metabolism
Abstract

The reversible adenine phosphoribosyltransferase enzyme (APRT) is essential for purine homeostasis in prokaryotes and eukaryotes. In humans, APRT (hAPRT) is the only enzyme known to produce AMP in cells from dietary adenine. APRT can also process adenine analogs, which are involved in plant development or neuronal homeostasis. However, the molecular mechanism underlying substrate specificity of APRT and catalysis in both directions of the reaction remains poorly understood. Here we present the crystal structures of hAPRT complexed to three cellular nucleotide analogs (hypoxanthine, IMP, and GMP) that we compare with the phosphate-bound enzyme. We established that binding to hAPRT is substrate shape-specific in the forward reaction, whereas it is base-specific in the reverse reaction. Furthermore, a quantum mechanics/molecular mechanics (QM/MM) analysis suggests that the forward reaction is mainly a nucleophilic substitution of type 2 (S N 2) with a mix of S N 1-type molecular mechanism. Based on our structural analysis, a magnesium-assisted S N 2-type mechanism would be involved in the reverse reaction. These results provide a framework for understanding the molecular mechanism and substrate discrimination in both directions by APRTs. This knowledge can play an instrumental role in the design of inhibitors, such as antiparasitic agents, or adenine-based substrates., (© 2019 Ozeir et al.)

Published
2019
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43. Purine Homeostasis Is Necessary for Developmental Timing, Germline Maintenance and Muscle Integrity in Caenorhabditis elegans .

Author

Marsac R, Pinson B, Saint-Marc C, Olmedo M, Artal-Sanz M, Daignan-Fornier B, and Gomes JE

Subjects
Adenylosuccinate Lyase genetics, Animals, Caenorhabditis elegans genetics, Caenorhabditis elegans growth & development, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins genetics, Germ Cells cytology, Adenylosuccinate Lyase metabolism, Caenorhabditis elegans Proteins metabolism, Germ Cells metabolism, Homeostasis, Muscle, Skeletal metabolism, Purines metabolism
Abstract

Purine homeostasis is ensured through a metabolic network widely conserved from prokaryotes to humans. Purines can either be synthesized de novo , reused, or produced by interconversion of extant metabolites using the so-called recycling pathway. Although thoroughly characterized in microorganisms, such as yeast or bacteria, little is known about regulation of the purine biosynthesis network in metazoans. In humans, several diseases are linked to purine metabolism through as yet poorly understood etiologies. Particularly, the deficiency in adenylosuccinate lyase (ADSL)-an enzyme involved both in the purine de novo and recycling pathways-causes severe muscular and neuronal symptoms. In order to address the mechanisms underlying this deficiency, we established Caenorhabditis elegans as a metazoan model organism to study purine metabolism, while focusing on ADSL. We show that the purine biosynthesis network is functionally conserved in C. elegans Moreover, adsl-1 (the gene encoding ADSL in C. elegans ) is required for developmental timing, germline stem cell maintenance and muscle integrity. Importantly, these traits are not affected when solely the de novo pathway is abolished, and we present evidence that germline maintenance is linked specifically to ADSL activity in the recycling pathway. Hence, our results allow developmental and tissue specific phenotypes to be ascribed to separable steps of the purine metabolic network in an animal model., (Copyright © 2019 by the Genetics Society of America.)

Published
2019
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44. Dual control of NAD + synthesis by purine metabolites in yeast.

Author

Pinson B, Ceschin J, Saint-Marc C, and Daignan-Fornier B

Subjects
Adenine chemistry, Adenosine Triphosphate chemistry, Biomass, Chromatography, Liquid, Genotype, Homeodomain Proteins metabolism, Homeostasis, Niacin chemistry, Nicotinamide-Nucleotide Adenylyltransferase genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Trans-Activators metabolism, Transcription Factors metabolism, Fungal Proteins metabolism, Gene Expression Regulation, Neoplastic, NAD biosynthesis, Nicotinamide-Nucleotide Adenylyltransferase metabolism, Purines chemistry, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism
Abstract

Metabolism is a highly integrated process resulting in energy and biomass production. While individual metabolic routes are well characterized, the mechanisms ensuring crosstalk between pathways are poorly described, although they are crucial for homeostasis. Here, we establish a co-regulation of purine and pyridine metabolism in response to external adenine through two separable mechanisms. First, adenine depletion promotes transcriptional upregulation of the de novo NAD + biosynthesis genes by a mechanism requiring the key-purine intermediates ZMP/SZMP and the Bas1/Pho2 transcription factors. Second, adenine supplementation favors the pyridine salvage route resulting in an ATP-dependent increase of intracellular NAD + . This control operates at the level of the nicotinic acid mononucleotide adenylyl-transferase Nma1 and can be bypassed by overexpressing this enzyme. Therefore, in yeast, pyridine metabolism is under the dual control of ZMP/SZMP and ATP, revealing a much wider regulatory role for these intermediate metabolites in an integrated biosynthesis network., Competing Interests: BP, JC, CS, BD No competing interests declared, (© 2019, Pinson et al.)

Published
2019
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45. Metabolomics and proteomics identify the toxic form and the associated cellular binding targets of the anti-proliferative drug AICAR.

Author

Douillet DC, Pinson B, Ceschin J, Hürlimann HC, Saint-Marc C, Laporte D, Claverol S, Konrad M, Bonneu M, and Daignan-Fornier B

Subjects
Active Transport, Cell Nucleus drug effects, Aminoimidazole Carboxamide pharmacokinetics, Aminoimidazole Carboxamide pharmacology, Cell Nucleus chemistry, Cell Nucleus genetics, Chromatography, Affinity, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Aminoimidazole Carboxamide analogs & derivatives, Cell Nucleus metabolism, Cell Proliferation drug effects, Proteomics, Ribonucleotides pharmacokinetics, Ribonucleotides pharmacology, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism
Abstract

5-Aminoimidazole-4-carboxamide 1-β-d-ribofuranoside (AICAR, or acadesine) is a precursor of the monophosphate derivative 5-amino-4-imidazole carboxamide ribonucleoside 5'-phosphate (ZMP), an intermediate in de novo purine biosynthesis. AICAR proved to have promising anti-proliferative properties, although the molecular basis of its toxicity is poorly understood. To exert cytotoxicity, AICAR needs to be metabolized, but the AICAR-derived toxic metabolite was not identified. Here, we show that ZMP is the major toxic derivative of AICAR in yeast and establish that its metabolization to succinyl-ZMP, ZDP, or ZTP (di- and triphosphate derivatives of AICAR) strongly reduced its toxicity. Affinity chromatography identified 74 ZMP-binding proteins, including 41 that were found neither as AMP nor as AICAR or succinyl-ZMP binders. Overexpression of karyopherin-β Kap123, one of the ZMP-specific binders, partially rescued AICAR toxicity. Quantitative proteomic analyses revealed 57 proteins significantly less abundant on nuclei-enriched fractions from AICAR-fed cells, this effect being compensated by overexpression of KAP123 for 15 of them. These results reveal nuclear protein trafficking as a function affected by AICAR., (© 2019 Douillet et al.)

Published
2019
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46. Yeast to Study Human Purine Metabolism Diseases.

Author

Daignan-Fornier B and Pinson B

Subjects
Humans, Models, Biological, Purines biosynthesis, Sequence Homology, Amino Acid, Metabolic Diseases metabolism, Purines metabolism, Saccharomyces cerevisiae metabolism
Abstract

Purine nucleotides are involved in a multitude of cellular processes, and the dysfunction of purine metabolism has drastic physiological and pathological consequences. Accordingly, several genetic disorders associated with defective purine metabolism have been reported. The etiology of these diseases is poorly understood and simple model organisms, such as yeast, have proved valuable to provide a more comprehensive view of the metabolic consequences caused by the identified mutations. In this review, we present results obtained with the yeast Saccharomyces cerevisiae to exemplify how a eukaryotic unicellular organism can offer highly relevant information for identifying the molecular basis of complex human diseases. Overall, purine metabolism illustrates a remarkable conservation of genes, functions and phenotypes between humans and yeast.

Published
2019
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47. Multiple chemo-genetic interactions between a toxic metabolite and the ubiquitin pathway in yeast.

Author

Albrecht D, Hürlimann HC, Ceschin J, Saint-Marc C, Pinson B, and Daignan-Fornier B

Subjects
Aminoimidazole Carboxamide pharmacology, Ubiquitination genetics, Aminoimidazole Carboxamide analogs & derivatives, Gene Expression Regulation, Fungal drug effects, Ribonucleotides pharmacology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Ubiquitin genetics, Ubiquitin metabolism, Ubiquitination drug effects
Abstract

AICAR is the precursor of ZMP, a metabolite with antiproliferative properties in yeast and human. We aim at understanding how AICAR (and its active form ZMP) affects essential cellular processes. In this work, we found that ZMP accumulation is synthetic lethal with a hypomorphic allele of the ubiquitin-activating enzyme Uba1. A search for gene-dosage suppressors revealed that ubiquitin overexpression was sufficient to restore growth of the uba1 mutant upon AICAR treatment, suggesting that the ubiquitin pool is critical for cells to cope with AICAR. Accordingly, two mutants with constitutive low ubiquitin, ubp6 and doa1, were highly sensitive to AICAR, a phenotype that could be suppressed by ubiquitin overexpression. We established, by genetic means, that these new AICAR-sensitive mutants act in a different pathway from the rad6/bre1 mutants which were previously reported as sensitive to AICAR (Albrecht et al., Genetics 204:1447-1460, 2016). Two ubiquitin-conjugating enzymes (Ubc4 and Cdc34) and a ubiquitin ligase (Cdc4) were found to contribute to the ability of cells to cope with ZMP. This study illustrates the complexity of chemo-genetic interactions and shows how genetic analyses allow deciphering the implicated pathways, the individual gene effects, and their combined phenotypic contribution. Based on additivity and suppression patterns, we conclude that AICAR treatment shows synthetic interactions with distinct branches of the yeast ubiquitin pathway.

Published
2018
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48. Structural Insights into the Forward and Reverse Enzymatic Reactions in Human Adenine Phosphoribosyltransferase.

Author

Huyet J, Ozeir M, Burgevin MC, Pinson B, Chesney F, Remy JM, Siddiqi AR, Lupoli R, Pinon G, Saint-Marc C, Gibert JF, Morales R, Ceballos-Picot I, Barouki R, Daignan-Fornier B, Olivier-Bandini A, Augé F, and Nioche P

Subjects
Adenine Phosphoribosyltransferase chemistry, Adenine Phosphoribosyltransferase isolation & purification, Crystallography, X-Ray, Humans, Models, Molecular, Protein Conformation, Adenine Phosphoribosyltransferase metabolism
Abstract

Phosphoribosyltransferases catalyze the displacement of a PRPP α-1'-pyrophosphate to a nitrogen-containing nucleobase. How they control the balance of substrates/products binding and activities is poorly understood. Here, we investigated the human adenine phosphoribosyltransferase (hAPRT) that produces AMP in the purine salvage pathway. We show that a single oxygen atom from the Tyr105 side chain is responsible for selecting the active conformation of the 12 amino acid long catalytic loop. Using in vitro, cellular, and in crystallo approaches, we demonstrated that Tyr105 is key for the fine-tuning of the kinetic activity efficiencies of the forward and reverse reactions. Together, our results reveal an evolutionary pressure on the strictly conserved Tyr105 and on the dynamic motion of the flexible loop in phosphoribosyltransferases that is essential for purine biosynthesis in cells. These data also provide the framework for designing novel adenine derivatives that could modulate, through hAPRT, diseases-involved cellular pathways., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published
2018
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49. AICAR Antiproliferative Properties Involve the AMPK-Independent Activation of the Tumor Suppressors LATS 1 and 2.

Author

Philippe C, Pinson B, Dompierre J, Pantesco V, Viollet B, Daignan-Fornier B, and Moenner M

Subjects
Aminoimidazole Carboxamide pharmacology, Animals, Antineoplastic Agents pharmacology, Cell Proliferation genetics, Cells, Cultured, Epithelial Cells drug effects, Fibroblasts drug effects, Humans, Mice, Mice, Knockout, Phosphoproteins genetics, Signal Transduction drug effects, Signal Transduction genetics, Transcription Factors genetics, Transcription, Genetic drug effects, Transcription, Genetic genetics, Transcriptome drug effects, Transcriptome genetics, Up-Regulation drug effects, Up-Regulation genetics, AMP-Activated Protein Kinases genetics, Aminoimidazole Carboxamide analogs & derivatives, Cell Proliferation drug effects, Enzyme Activation drug effects, Protein Serine-Threonine Kinases genetics, Ribonucleosides pharmacology, Tumor Suppressor Proteins genetics
Abstract

AICAR (Acadesine) is a pharmacological precursor of purine nucleotide biosynthesis with anti-tumoral properties. Although recognized as an AMP mimetic activator of the protein kinase AMPK, the AICAR monophosphate derivative ZMP was also shown to mediate AMPK-independent effects. In order to unveil these AMPK-independent functions, we performed a transcriptomic analysis in AMPKα1/α2 double knockout murine embryonic cells. Kinetic analysis of the cellular response to AICAR revealed the up-regulation of the large tumor suppressor kinases (Lats) 1 and 2 transcripts, followed by the repression of numerous genes downstream of the transcriptional regulators Yap1 and Taz. This transcriptional signature, together with the observation of increased levels in phosphorylation of Lats1 and Yap1 proteins, suggested that the Hippo signaling pathway was activated by AICAR. This effect was observed in both fibroblasts and epithelial cells. Knockdown of Lats1/2 prevented the cytoplasmic delocalization of Yap1/Taz proteins in response to AICAR and conferred a higher resistance to the drug. These results indicate that activation of the most downstream steps of the Hippo cascade participates to the antiproliferative effects of AICAR., (Copyright © 2018 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2018
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50. Chemo-Genetic Interactions Between Histone Modification and the Antiproliferation Drug AICAR Are Conserved in Yeast and Humans.

Author

Albrecht D, Ceschin J, Dompierre J, Gueniot F, Pinson B, and Daignan-Fornier B

Subjects
Aminoimidazole Carboxamide pharmacology, Cyclins metabolism, DNA-Binding Proteins metabolism, HCT116 Cells, Histone-Lysine N-Methyltransferase metabolism, Humans, Neoplasm Proteins metabolism, Protein Binding drug effects, Protein Processing, Post-Translational genetics, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae Proteins metabolism, Tripeptidyl-Peptidase 1, Aminoimidazole Carboxamide analogs & derivatives, Antineoplastic Agents pharmacology, Evolution, Molecular, Histones metabolism, Protein Processing, Post-Translational drug effects, Ribonucleotides pharmacology, Saccharomyces cerevisiae genetics
Abstract

Identifying synthetic lethal interactions has emerged as a promising new therapeutic approach aimed at targeting cancer cells directly. Here, we used the yeast Saccharomyces cerevisiae as a simple eukaryotic model to screen for mutations resulting in a synthetic lethality with 5-amino-4-imidazole carboxamide ribonucleoside (AICAR) treatment. Indeed, AICAR has been reported to inhibit the proliferation of multiple cancer cell lines. Here, we found that loss of several histone-modifying enzymes, including Bre1 (histone H2B ubiquitination) and Set1 (histone H3 lysine 4 methylation), greatly enhanced AICAR inhibition on growth via the combined effects of both the drug and mutations on G1 cyclins. Our results point to AICAR impacting on Cln3 subcellular localization and at the Cln1 protein level, while the bre1 or set1 deletion affected CLN1 and CLN2 expression. As a consequence, AICAR and bre1/set1 deletions jointly affected all three G1 cyclins (Cln1, Cln2, and Cln3), leading to a condition known to result in synthetic lethality. Significantly, these chemo-genetic synthetic interactions were conserved in human HCT116 cells. Indeed, knock-down of RNF40, ASH2L, and KMT2D/MLL2 induced a highly significant increase in AICAR sensitivity. Given that KMT2D/MLL2 is mutated at high frequency in a variety of cancers, this synthetic lethal interaction has an interesting therapeutic potential., (Copyright © 2016 by the Genetics Society of America.)

Published
2016
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