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大肠杆菌K-12的D-丝氨酸脱氨酶系统中的阳性对照。

Positive control in the D-serine deaminase system of Escherichia coli K-12.

作者信息

Bloom F R, McFall E, Young M C, Carothers A M

出版信息

J Bacteriol. 1975 Mar;121(3):1092-101. doi: 10.1128/jb.121.3.1092-1101.1975.

DOI:10.1128/jb.121.3.1092-1101.1975
PMID:1090589
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC246040/
Abstract

Two new types of D-serine deaminase (Dsdase)-negative mutants have been isolated and characterized. The first fails to synthesize a functional dsdC gene product as a result of dsdC- (regulator negative) mutations. The mutations lie in the dsdC region, are cis and trans recessive to dsdC+, and give rise to revertants of novel regulatory phenotype. The second class consists of Dsdase-negative lysogens in which the phenotype is the result of the integration of lambdac1857 Sam7 into the dsdC region. Lambda lysates derived from two of the Dsdase-negative lysogens can transduce the structural gene for Dsdase (dsdA) but not the dsdC region. The dsdC+ gene product had no repressor effect on constitutive synthesis in a strain containing a dsdO (initiator constitutive) and a dsdC- mutation. These and other findings indicate that control of Dsdase synthesis is strictly positive. The partial trans effect of the dsdC+ gene product on constitutive synthesis in dsdCc (regulator constitutive) strains can thus be explained by "subunit mixing" between active dsdCc subunits and dsdC+ subunits which are inactive in the absence of the inducer, D-serine. The order of genes in the dsd region is supN-dsdC-dsdP-dsdA-aroC.

摘要

已分离并鉴定出两种新型的D-丝氨酸脱氨酶(Dsdase)阴性突变体。第一种由于dsdC-(调节因子阴性)突变而无法合成功能性的dsdC基因产物。这些突变位于dsdC区域,对dsdC+呈顺式和反式隐性,并产生具有新调节表型的回复体。第二类由Dsdase阴性溶原菌组成,其表型是λc1857 Sam7整合到dsdC区域的结果。从两种Dsdase阴性溶原菌获得的λ裂解物可以转导Dsdase的结构基因(dsdA),但不能转导dsdC区域。在含有dsdO(起始组成型)和dsdC-突变的菌株中,dsdC+基因产物对组成型合成没有阻遏作用。这些以及其他发现表明,Dsdase合成的控制是严格正向的。dsdC+基因产物对dsdCc(调节因子组成型)菌株中组成型合成的部分反式效应因此可以通过活性dsdCc亚基与在没有诱导剂D-丝氨酸时无活性的dsdC+亚基之间的“亚基混合”来解释。dsd区域中的基因顺序是supN-dsdC-dsdP-dsdA-aroC。

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