酿酒酵母的温度敏感型cdc7突变可被DBF4基因抑制,该基因是G1/S细胞周期转换所必需的。
Temperature-sensitive cdc7 mutations of Saccharomyces cerevisiae are suppressed by the DBF4 gene, which is required for the G1/S cell cycle transition.
作者信息
Kitada K, Johnston L H, Sugino T, Sugino A
机构信息
Laboratory of Molecular Genetics, National Institute of Environmental Health Sciences, Research Triangle Park, North Carolina 27709.
出版信息
Genetics. 1992 May;131(1):21-9. doi: 10.1093/genetics/131.1.21.
Abstract
When present on a multicopy plasmid, a gene from a Saccharomyces cerevisiae genomic library suppresses the temperature-sensitive cdc7-1 mutation. The gene was identified as DBF4, which was previously isolated by complementation in dbf4-1 mutant cells and is required for the G1----S phase progression of the cell cycle. DBF4 has an open reading frame encoding 695 amino acid residues and the predicted molecular mass of the gene product is 80 kD. The suppression is allele-specific because a CDC7 deletion is not suppressed by DBF4. Suppression is mitosis-specific and the sporulation defect of cdc7 mutations is not suppressed by DBF4. Conversely, CDC7 on a multicopy plasmid suppresses the dbf4-1, -2, -3 and -4 mutations but not dbf4-5 and DBF4 deletion mutations. Furthermore, cdc7 mutations are incompatible with the temperature-sensitive dbf4 mutations. These results suggest that the CDC7 and DBF4 polypeptides interact directly or indirectly to permit initiation of yeast chromosome replication.
摘要
当存在于多拷贝质粒上时,来自酿酒酵母基因组文库的一个基因可抑制温度敏感型cdc7-1突变。该基因被鉴定为DBF4,它先前是通过在dbf4-1突变细胞中互补分离得到的,是细胞周期从G1期到S期进展所必需的。DBF4有一个编码695个氨基酸残基的开放阅读框,该基因产物的预测分子量为80 kD。这种抑制是等位基因特异性的,因为DBF4不能抑制CDC7缺失。抑制是有丝分裂特异性的,DBF4不能抑制cdc7突变的孢子形成缺陷。相反,多拷贝质粒上的CDC7可抑制dbf4-1、-2、-3和-4突变,但不能抑制dbf4-5和DBF4缺失突变。此外,cdc7突变与温度敏感型dbf4突变不相容。这些结果表明,CDC7和DBF4多肽直接或间接相互作用,以允许酵母染色体复制的起始。
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