Диссертация (1145828), страница 23
Текст из файла (страница 23)
— T. 584,№ 11. — C. 2387-92.122176.Michaelis S., Herskowitz I. The a-factor pheromone of Saccharomyces cerevisiae isessential for mating // Mol Cell Biol. — 1988. — T. 8, № 3. — C. 1309-18.177.Fujimura H. Identification and characterization of a mutation affecting the division arrestsignaling of the pheromone response pathway in Saccharomyces cerevisiae // Genetics. — 1990.— T. 124, № 2. — C.
275-82.178.O'Reilly N., Charbin A., Lopez-Serra L., Uhlmann F. Facile synthesis of budding yeast a-factor and its use to synchronize cells of alpha mating type // Yeast. — 2012. — T. 29, № 6. —C. 233-40.179.Koc A., Wheeler L. J., Mathews C. K., Merrill G. F. Hydroxyurea arrests DNAreplication by a mechanism that preserves basal dNTP pools // J Biol Chem. — 2004. — T. 279,№ 1. — C. 223-30.180.Northam M. R., Robinson H. A., Kochenova O. V., Shcherbakova P.
V. Participation ofDNA polymerase zeta in replication of undamaged DNA in Saccharomyces cerevisiae //Genetics. — 2010. — T. 184, № 1. — C. 27-42.181.Jacobs C. W., Adams A. E., Szaniszlo P. J., Pringle J. R. Functions of microtubules in theSaccharomyces cerevisiae cell cycle // J Cell Biol. — 1988. — T.
107, № 4. — C. 1409-26.182.Argueso J. L., Westmoreland J., Mieczkowski P. A., Gawel M., Petes T. D., Resnick M.A. Double-strand breaks associated with repetitive DNA can reshape the genome // Proc NatlAcad Sci U S A. — 2008. — T. 105, № 33. — C. 11845-50.183.Reed S.
I., Wittenberg C. Mitotic role for the Cdc28 protein kinase of Saccharomycescerevisiae // Proc Natl Acad Sci U S A. — 1990. — T. 87, № 15. — C. 5697-701.184.Reed S. I. The selection of S. cerevisiae mutants defective in the start event of celldivision // Genetics. — 1980. — T. 95, № 3. — C. 561-77.185.Mendenhall M. D., Hodge A. E. Regulation of Cdc28 cyclin-dependent protein kinaseactivity during the cell cycle of the yeast Saccharomyces cerevisiae // Microbiol Mol Biol Rev.— 1998.
— T. 62, № 4. — C. 1191-243.186.Surana U., Robitsch H., Price C., Schuster T., Fitch I., Futcher A. B., Nasmyth K. Therole of CDC28 and cyclins during mitosis in the budding yeast S. cerevisiae // Cell. — 1991. —T. 65, № 1. — C. 145-61.187.Lew D. J., Reed S. I. Morphogenesis in the yeast cell cycle: regulation by Cdc28 andcyclins // J Cell Biol. — 1993. — T. 120, № 6. — C.
1305-20.188.Lew D. J., Reed S. I. Cell cycle control of morphogenesis in budding yeast // Curr OpinGenet Dev. — 1995. — T. 5, № 1. — C. 17-23.123189.Cid V. J., Adamikova L., Sanchez M., Molina M., Nombela C. Cell cycle control ofseptin ring dynamics in the budding yeast // Microbiology. — 2001. — T.
147, № Pt 6. — C.1437-50.190.Yu L., Qi M., Sheff M. A., Elion E. A. Counteractive control of polarized morphogenesisduring mating by mitogen-activated protein kinase Fus3 and G1 cyclin-dependent kinase // MolBiol Cell. — 2008. — T. 19, № 4. — C. 1739-52.191.Goranov A. I., Cook M., Ricicova M., Ben-Ari G., Gonzalez C., Hansen C., Tyers M.,Amon A. The rate of cell growth is governed by cell cycle stage // Genes Dev. — 2009. — T. 23,№ 12. — C. 1408-22.192.Goranov A. I., Gulati A., Dephoure N., Takahara T., Maeda T., Gygi S. P., Manalis S.,Amon A. Changes in cell morphology are coordinated with cell growth through the TORC1pathway // Curr Biol.
— 2013. — T. 23, № 14. — C. 1269-79.193.Neutzner A., Youle R. J. Instability of the mitofusin Fzo1 regulates mitochondrialmorphology during the mating response of the yeast Saccharomyces cerevisiae // J Biol Chem.— 2005. — T. 280, № 19. — C. 18598-603.194.Raboy B., Marom A., Dor Y., Kulka R. G. Heat-induced cell cycle arrest ofSaccharomyces cerevisiae: involvement of the RAD6/UBC2 and WSC2 genes in its reversal //Mol Microbiol. — 1999. — T. 32, № 4.
— C. 729-39.195.Shin D. Y., Matsumoto K., Iida H., Uno I., Ishikawa T. Heat shock response ofSaccharomyces cerevisiae mutants altered in cyclic AMP-dependent protein phosphorylation //Mol Cell Biol. — 1987. — T. 7, № 1. — C. 244-50.196.Barnes C. A., Johnston G.
C., Singer R. A. Thermotolerance is independent of inductionof the full spectrum of heat shock proteins and of cell cycle blockage in the yeast Saccharomycescerevisiae // J Bacteriol. — 1990. — T. 172, № 8. — C. 4352-8.197.Rowley A., Johnston G. C., Butler B., Werner-Washburne M., Singer R. A. Heat shock-mediated cell cycle blockage and G1 cyclin expression in the yeast Saccharomyces cerevisiae //Mol Cell Biol. — 1993. — T.
13, № 2. — C. 1034-41.198.Zierhut C., Diffley J. F. Break dosage, cell cycle stage and DNA replication influenceDNA double strand break response // EMBO J. — 2008. — T. 27, № 13. — C. 1875-85.199.Haracska L., Prakash S., Prakash L. Yeast DNA polymerase zeta is an efficient extenderof primer ends opposite from 7,8-dihydro-8-Oxoguanine and O6-methylguanine // Mol Cell Biol.— 2003. — T. 23, № 4.
— C. 1453-9.200.Waters L. S., Minesinger B. K., Wiltrout M. E., D'Souza S., Woodruff R. V., Walker G.C. Eukaryotic translesion polymerases and their roles and regulation in DNA damage tolerance //Microbiol Mol Biol Rev. — 2009. — T. 73, № 1. — C. 134-54.124201.Johnson R. E., Prakash S., Prakash L. Efficient bypass of a thymine-thymine dimer byyeast DNA polymerase, Poleta // Science. — 1999. — T. 283, № 5404. — C. 1001-4.202.Yu S. L., Johnson R.
E., Prakash S., Prakash L. Requirement of DNA polymerase eta forerror-free bypass of UV-induced CC and TC photoproducts // Mol Cell Biol. — 2001. — T. 21,№ 1. — C. 185-8.203.Trincao J., Johnson R. E., Escalante C. R., Prakash S., Prakash L., Aggarwal A. K.Structure of the catalytic core of S. cerevisiae DNA polymerase eta: implications for translesionDNA synthesis // Mol Cell. — 2001. — T.
8, № 2. — C. 417-26.204.Nelson J. R., Lawrence C. W., Hinkle D. C. Thymine-thymine dimer bypass by yeastDNA polymerase zeta // Science. — 1996. — T. 272, № 5268. — C. 1646-9.205.Stone J. E., Kumar D., Binz S. K., Inase A., Iwai S., Chabes A., Burgers P. M., Kunkel T.A. Lesion bypass by S. cerevisiae Pol zeta alone // DNA Repair (Amst). — 2011. — T. 10, № 8.— C. 826-34.206.Ikehata H., Ono T.
The mechanisms of UV mutagenesis // J Radiat Res. — 2011. — T.52, № 2. — C. 115-25.207.Swanson R. L., Morey N. J., Doetsch P. W., Jinks-Robertson S. Overlapping specificitiesof base excision repair, nucleotide excision repair, recombination, and translesion synthesispathways for DNA base damage in Saccharomyces cerevisiae // Mol Cell Biol. — 1999. — T.19, № 4. — C. 2929-35.208.Li X., Heyer W. D.
Homologous recombination in DNA repair and DNA damagetolerance // Cell Res. — 2008. — T. 18, № 1. — C. 99-113.209.Izhar L., Ziv O., Cohen I. S., Geacintov N. E., Livneh Z. Genomic assay reveals toleranceof DNA damage by both translesion DNA synthesis and homology-dependent repair inmammalian cells // Proc Natl Acad Sci U S A.
— 2013. — T. 110, № 16. — C. E1462-9.210.Zhang H., Lawrence C. W. The error-free component of the RAD6/RAD18 DNA damagetolerance pathway of budding yeast employs sister-strand recombination // Proc Natl Acad Sci US A. — 2005. — T.
102, № 44. — C. 15954-9.211.Daley J. M., Palmbos P. L., Wu D., Wilson T. E. Nonhomologous end joining in yeast //Annu Rev Genet. — 2005. — T. 39. — C. 431-51.212.Shrivastav M., De Haro L. P., Nickoloff J. A. Regulation of DNA double-strand breakrepair pathway choice // Cell Res. — 2008. — T. 18, № 1. — C. 134-47.213.Shibata A., Conrad S., Birraux J., Geuting V., Barton O., Ismail A., Kakarougkas A.,Meek K., Taucher-Scholz G., Lobrich M., Jeggo P. A. Factors determining DNA double-strandbreak repair pathway choice in G2 phase // EMBO J.
— 2011. — T. 30, № 6. — C. 1079-92.125214.Shcherbakova P. V., Noskov V. N., Pshenichnov M. R., Pavlov Y. I. Base analog 6-N-hydroxylaminopurine mutagenesis in the yeast Saccharomyces cerevisiae is controlled byreplicative DNA polymerases // Mutat Res. — 1996. — T. 369, № 1-2. — C. 33-44.215.Sabouri N., Viberg J., Goyal D. K., Johansson E., Chabes A. Evidence for lesion bypassby yeast replicative DNA polymerases during DNA damage // Nucleic Acids Res.
— 2008. — T.36, № 17. — C. 5660-7.216.Durand-Dubief M., Svensson J. P., Persson J., Ekwall K. Topoisomerases, chromatin andtranscription termination // Transcription. — 2011. — T. 2, № 2. — C. 66-70.217.Wang J. C. Cellular roles of DNA topoisomerases: a molecular perspective // Nat RevMol Cell Biol. — 2002. — T. 3, № 6. — C. 430-40.218.Sollier J., Stork C. T., Garcia-Rubio M. L., Paulsen R. D., Aguilera A., Cimprich K. A.Transcription-coupled nucleotide excision repair factors promote R-loop-induced genomeinstability // Mol Cell.