有丝分裂细胞周期突变体cdc4对酵母减数分裂的影响。

Effects of the mitotic cell-cycle mutation cdc4 on yeast meiosis.

作者信息

Simchen G, Hirschberg J

出版信息

Genetics. 1977 May;86(1):57-72. doi: 10.1093/genetics/86.1.57.

DOI:10.1093/genetics/86.1.57

PMID:328339

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1213672/

Abstract

The mitotic cell-cycle mutation cdc4 has been reported to block the initiation of nuclear DNA replication and the separation of spindle plaques after their replication. Meiosis in cdc4/cdc4 diploids is normal at the permissive temperature (25 degrees) and is arrested at the first division (one-nucleus stage) at the restrictive temperature (34 degrees or 36 degrees). Arrested cells at 34 degrees show a high degree of commitment to recombination (at least 50% of the controls) but no haploidization, while cells arrested at 36 degrees are not committed to recombination. Meiotic cells arrested at 34 degrees show a delayed and reduced synthesis of DNA (at most 40% of the control), at least half of which is probably mitochondrial. It is suggested that recombination commitment does not depend on the completion of nuclear premeiotic DNA replication in sporulation medium.--Transfer of cdc4/cdc4 cells to the restrictive temperature at the onset of sporulation produces a uniform phenotype of arrest at a 1-nucleus morphology. On the other hand, shifts of the meiotic cells to the restrictive temperature at later times produce two additional phenotypes of arrest, thus suggesting that the function of cdc4 is required at several points in meiosis (at least at three different times).

摘要

有报道称，有丝分裂细胞周期突变体cdc4会阻断核DNA复制的起始以及纺锤体斑复制后的分离。在允许温度（25摄氏度）下，cdc4/cdc4二倍体中的减数分裂是正常的，而在限制温度（34摄氏度或36摄氏度）下则会在第一次分裂（单核期）时停滞。在34摄氏度下停滞的细胞对重组有高度的倾向（至少是对照的50%），但不会发生单倍体化，而在36摄氏度下停滞的细胞则没有重组倾向。在34摄氏度下停滞的减数分裂细胞显示出DNA合成延迟且减少（最多为对照的40%），其中至少一半可能是线粒体DNA。这表明在孢子形成培养基中，重组倾向并不依赖于核减数分裂前DNA复制的完成。——在孢子形成开始时将cdc4/cdc4细胞转移到限制温度会产生统一的表型，即停滞在单核形态。另一方面，减数分裂细胞在后期转移到限制温度会产生另外两种停滞表型，因此表明cdc4的功能在减数分裂的几个阶段都是必需的（至少在三个不同的时间）。

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