“Start” Mutants of Saccharomyces cerevisiae Are Suppressed in Carbon Catabolite-Derepressing Medium

Temperature-sensitive cell division “start” mutants cdc28, cdc36, cdc37, and cdc39 of the yeast Saccharomyces cerevisiae arrested cell division in the G1 phase of the cell cycle in glucose medium. I report here that cdc28, cdc36, and cdc39 mutants were suppressed when grown in carbon catabolite-derepressing medium.     

“Sleeping Beauty”: Quiescence in Saccharomyces cerevisiae

The cells of organisms as diverse as bacteria and humans can enter stable, nonproliferating quiescent states. Quiescent cells of eukaryotic and prokaryotic microorganisms can survive for long periods without nutrients. This alternative state of cells is still poorly understood, yet much benefit is to be gained by understanding it both scientifically and with reference to human health. Here, we review our knowledge of one “model” quiescent cell population, in cultures of yeast grown to stationary phase in rich media. We outline the importance of understanding quiescence, summarize the properties of quiescent yeast cells, and clarify some definitions of the state. We propose that the processes by which a cell enters into, maintains viability in, and exits from quiescence are best viewed as an environmentally triggered cycle: the cell quiescence cycle. We synthesize what is known about the mechanisms by which yeast cells enter into quiescence, including the possible roles of the protein kinase A, TOR, protein kinase C, and Snf1p pathways. We also discuss selected mechanisms by which quiescent cells maintain viability, including metabolism, protein modification, and redox homeostasis. Finally, we outline what is known about the process by which cells exit from quiescence when nutrients again become available.     

Induction of Respiratory-Deficient Nonchromosomal “Petites” of Saccharomyces cerevisiae by Sodium Dodecyl Sulfate

Nonchromosomal “petites” can be produced in Saccharomyces cerevisiae by treatment with sodium dodecyl sulfate, an anionic surface active agent.     

“Killer Character” of Saccharomyces cerevisiae: Curing by Growth at Elevated Temperature

Normal "killer" strains of Saccharomyces cerevisiae, when grown at 37 to 40 C, produce almost exclusively nonkiller cells due to loss or mutation of at least part of the non-chromosomal killer genome.     

Genetic Control of “Flor” Formation by Saccharomyces

The results described indicate that in Saccharomyces sp. the formation of "flor" is under the control of a single Mendelian gene for which is proposed the symbol "Fl."     

“整合物种概念”和“分化路上的物种”

已有的各个物种概念对物种的认识类似盲人摸象, 只包含了物种的某一个方面; 而一个分化后期的成熟物种应涵盖了所有的物种概念。但是, 尚未到达分化后期的物种往往又已开始新一轮的物种分化; 自然中存在的多数“物种”处于分化路上。这种循环往复连续分化产生的物种, 存在种间生殖隔离不彻底、基因流频繁发生、网状进化突出等现象。此外, 对于不同的物种对, 最早开始分化的基因以及不同物种概念所要求的条件的分化顺序不是统一的, 而是随机的。定义一个适合所有“分化路上的物种”概念存在较大困难。但是, 应采用尽可能多的物种概念来界定分化路上的物种、发表新种和进行分类处理; 也应承认种间可能广泛存在不完全的生殖隔离和有限的基因流, 即有不属于两个物种群体的杂交或回交个体的存在。这样划分的物种比只依据一个物种概念认定的物种具有更高的客观性和科学性。     

A “New” low incidence “Hutterite” blood group antigen waldner (Wda)

A “new” red cell antigen has been found so far only in members of Hutterite kindreds with the surname Waldner. The antigen, Wd^a, is inherited as an autosomal dominant and is not part of the ABO, Chido, Colton, Dombrock, Duffy, Kidd, MN, P, or Rh blood group systems.     

Segregational Respiratory-Deficient Mutants of a “Petite Negative” Yeast Schizosaccharomyces pombe 972h−

No viable respiratory-deficient mutants of Schizosaccharomyces pombe 972h(-) could be obtained by acriflavine and ethidium bromide treatments. These mutagens induce 15 to 70% of microcolonies which, after a growth-lag of a few days, further develop into normal, respiratory-competent colonies. These results suggest that unstable petites were induced. Segregational respiratory-deficient mutants resistant to cobalt sulfate inhibition were isolated. Some of these strains are deficient in cytochrome a + a(3) and respire at low rates. The morphology of their mitochondrial membranes is modified: either the cristae are absent or they show aberrant concentric or tubular structures. Segregational mutants resistant to the respiratory inhibitors, 2,4-dinitrophenol or decamethylene diguanidine, were obtained. Neither mitochondrial structure nor function seems to be modified in these mutants. A segregational mutant resistant to benzimidazole inhibition does not grow on glycerol, although neither growth on glucose nor respiration appear to be affected.     

Leakage of Periplasmic Enzymes by Mutants of Escherichia coli and Salmonella typhimurium: Isolation of “Periplasmic Leaky” Mutants

Mutants of Escherichia coli and Salmonella typhimurium were selected on the basis of their spontaneous leakage of ribonuclease I. The mutants also leaked several other periplasmic enzymes into the medium during active growth but did not leak the intracellular enzymes glucose-6-phosphate dehydrogenase or phosphoglucose isomerase.