Genetic Control of the Cell-Division Cycle in Yeast, I. Detection of Mutants

Hartwell, Leland H.; Culotti, Joseph G.; Reid, Brian J.

doi:10.1073/pnas.66.2.352

Cited by 691 publications

(619 citation statements)

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“…The tightly regulated progression through the cell cycle is brought about by periodic activation of cyclin and cyclindependent kinases (CDKs). The independent discoveries of cyclins in sea urchin oocytes, along with the simultaneous identification of maturation-promoting factors in frog oocytes and of CDC proteins in Saccharomyces cerevisiae, converged to give rise to the present-day concepts of cyclin-CDK complexes (Hartwell et al, 1970;Masui and Markert, 1971;Evans et al, 1983). The seminal discovery of cyclin/CDK complexes is believed to be at the core of understanding cellular proliferation controls.…”

Section: Intracellular Redox State and Cell Cycle Proteinsmentioning

confidence: 99%

A redox cycle within the cell cycle: ring in the old with the new

2006

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In recent years, the intracellular oxidation-reduction (redox) state has gained increasing attention as a critical mediator of cell signaling, gene expression changes and proliferation. This review discusses the evidence for a redox cycle (i.e., fluctuation in the cellular redox state) regulating the cell cycle. The presence of redox-sensitive motifs (cysteine residues, metal co-factors in kinases and phosphatases) in several cell cycle regulatory proteins indicate periodic oscillations in intracellular redox state could play a central role in regulating progression from G 0 /G 1 to S to G 2 and M cell cycle phases. Fluctuations in the intracellular redox state during cell cycle progression could represent a fundamental mechanism linking oxidative metabolic processes to cell cycle regulatory processes. Proliferative disorders are central to a variety of human pathophysiological conditions thought to involve oxidative stress. Therefore, a more complete understanding of redox control of the cell cycle could provide a biochemical rationale for manipulating aberrant cell proliferation.

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Section: Intracellular Redox State and Cell Cycle Proteinsmentioning

confidence: 99%

A redox cycle within the cell cycle: ring in the old with the new

2006

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“…In the yeast S. cerevisiae, although SDC25 and CDC25 are two related genes, the CDC25 gene product appears to be the determinant GEF for growth because mutations lead to a Gl arrest (Hartwell et al, 1973). The SDC25 gene is dispensable under usual growth conditions and the absence of a detectable phenotype associated with deletion of the gene did not reveal its biological function (Damak et al, 1991).…”

Section: Introductionmentioning

confidence: 99%

SDC25, a dispensable Ras guanine nucleotide exchange factor of Saccharomyces cerevisiae differs from CDC25 by its regulation.

Boy‐Marcotte

Ikonomi

Jacquet

1996

MBoC

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“…A very similar series of events occurs in all eukaryotes, with the obvious exception of bud emergence. Because of the fundamental biological importance of cell cycle progression and its importance in both human development and diseases such as cancer, identification of the molecular determinants of specific stages of the eukaryotic cell cycle has been a subject of intense study for several decades.The morphological landmarks of the cell cycle stages in budding yeast, most notably the size of the bud relative to the size of the mother cell, allows the identification of mutants blocked at specific stages of the cell cycle and thereby forms the basis for the classic cell cycle screens (Hartwell et al, 1970;Culotti and Hartwell, 1971;Hartwell, 1971aHartwell, , 1971bHartwell, , 1973Moir et al, 1982). These genetic screens, using conditional temperature-sensitive mutants, identified more than 50 genes that are required for specific stages in the cell division cycle and so were termed CDC genes.…”

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confidence: 99%

A Survey of Essential Gene Function in the Yeast Cell Division Cycle

Peña‐Castillo

Mnaimneh

et al. 2006

MBoC

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Mutations impacting specific stages of cell growth and division have provided a foundation for dissecting mechanisms that underlie cell cycle progression. We have undertaken an objective examination of the yeast cell cycle through flow cytometric analysis of DNA content in TetO 7 promoter mutant strains representing 75% of all essential yeast genes. More than 65% of the strains displayed specific alterations in DNA content, suggesting that reduced function of an essential gene in most cases impairs progression through a specific stage of the cell cycle. Because of the large number of essential genes required for protein biosynthesis, G1 accumulation was the most common phenotype observed in our analysis. In contrast, relatively few mutants displayed S-phase delay, and most of these were defective in genes required for DNA replication or nucleotide metabolism. G2 accumulation appeared to arise from a variety of defects. In addition to providing a global view of the diversity of essential cellular processes that influence cell cycle progression, these data also provided predictions regarding the functions of individual genes: we identified four new genes involved in protein trafficking (NUS1, PHS1, PGA2, PGA3), and we found that CSE1 and SMC4 are important for DNA replication. INTRODUCTIONCell division is a fundamental biological process that in all organisms consists of a series of closely coordinated events. In the budding yeast Saccharomyces cerevisiae, the cell division cycle begins with an initial growth phase, G1, during which time the cell increases in mass and volume. The transition from G1 into S phase is marked by progression through Start (the point of commitment to cell division), initiation of nuclear DNA synthesis, and the emergence of a bud that will form the new daughter cell. S phase is followed by a second growth phase, G2, which is in turn followed by nuclear division, and then cell separation. A very similar series of events occurs in all eukaryotes, with the obvious exception of bud emergence. Because of the fundamental biological importance of cell cycle progression and its importance in both human development and diseases such as cancer, identification of the molecular determinants of specific stages of the eukaryotic cell cycle has been a subject of intense study for several decades.The morphological landmarks of the cell cycle stages in budding yeast, most notably the size of the bud relative to the size of the mother cell, allows the identification of mutants blocked at specific stages of the cell cycle and thereby forms the basis for the classic cell cycle screens (Hartwell et al., 1970;Culotti and Hartwell, 1971;Hartwell, 1971aHartwell, , 1971bHartwell, , 1973Moir et al., 1982). These genetic screens, using conditional temperature-sensitive mutants, identified more than 50 genes that are required for specific stages in the cell division cycle and so were termed CDC genes. On average 4.6 alleles were identified for each CDC gene in the original screens, suggesting the number of cdc mutan...

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Genetic Control of the Cell-Division Cycle in Yeast, I. Detection of Mutants

Cited by 691 publications

References 3 publications

A redox cycle within the cell cycle: ring in the old with the new

A redox cycle within the cell cycle: ring in the old with the new

SDC25, a dispensable Ras guanine nucleotide exchange factor of Saccharomyces cerevisiae differs from CDC25 by its regulation.

A Survey of Essential Gene Function in the Yeast Cell Division Cycle

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