大肠杆菌中D-环丝氨酸抑制作用及抗性的动力学和遗传学分析
Kinetic and genetic analyses of D-cycloserine inhibition and resistance in Escherichia coli.
作者信息
Curtiss R, Charamella L J, Berg C M, Harris P E
出版信息
J Bacteriol. 1965 Nov;90(5):1238-50. doi: 10.1128/jb.90.5.1238-1250.1965.
Curtiss, Roy, III (Oak Ridge National Laboratory, Oak Ridge, Tenn.), Leigh J. Charamella, Claire M. Berg, and Paula E. Harris. Kinetic and genetic analyses of d-cycloserine inhibition and resistance in Escherichia coli. J. Bacteriol. 90:1238-1250.1965.-Wild-type cells of Escherichia coli growing at 37 C in mineral salts-glucose medium with vigorous aeration were lysed at maximal exponential rates by 10(-4) to 10(-2)md-cycloserine. At concentrations above 2 x 10(-2)m, d-cycloserine was bacteriostatic. Low levels of d-cycloserine (10(-5)m) and pencillin G (10 units per ml) interacted synergistically to cause a rapid exponential rate of lysis. Spontaneous mutations to d-cycloserine resistance occurred in discrete steps at frequencies of 10(-6) to 10(-7) for each step. First-, second-, and third-step d-cycloserine-resistant mutants were lysed at maximal exponential rates by d-cycloserine concentrations of 10(-3), 3 x 10(-3), and 5 x 10(-3)m, respectively. d-Alanine, l-alanine, and dl-alanyl-dl-alanine reversed d-cycloserine-induced lysis, in that order of effectiveness. On the basis of these observations, a d-cycloserine-enrichment cycling technique was developed for isolation of auxotrophic mutants. d-Cycloserine at 2 x 10(-3)m was as efficient as penicillin G (1,000 units per ml) for mutant enrichment in E. coli and should be useful for isolation of mutants in penicillin-resistant microorganisms. Bacterial conjugation experiments indicated that all three mutations conferring d-cycloserine resistance were linked to the met(1) locus. Transduction experiments showed that the mutation conferring first-step resistance was at least 0.5 min away from the mutations conferring second- and third-step resistance. The latter two mutations possibly occurred in the same gene, since they were sometimes carried in the same transducing phage. Studies on expression of d-cycloserine resistance indicated that these mutations were neither dominant nor recessive to each other nor to the d-cycloserine-sensitivity allele. Each allelic state exerted its influence on the phenotype independently of the others. These results are discussed in terms of the known inhibition of alanine racemase and d-alanyl-d-alanine synthetase by d-cycloserine.
柯蒂斯,罗伊,三世(田纳西州橡树岭国家实验室),利·J·查拉梅拉,克莱尔·M·伯格,以及宝拉·E·哈里斯。大肠杆菌中d - 环丝氨酸抑制作用及抗性的动力学和遗传学分析。《细菌学杂志》90:1238 - 1250。1965年。——在37℃下于矿物盐 - 葡萄糖培养基中剧烈通气培养的大肠杆菌野生型细胞,在最大指数生长速率时被10⁻⁴至10⁻²摩尔的d - 环丝氨酸裂解。浓度高于2×10⁻²摩尔时,d - 环丝氨酸具有抑菌作用。低水平的d - 环丝氨酸(10⁻⁵摩尔)和青霉素G(每毫升10单位)协同作用,导致快速的指数裂解速率。对d - 环丝氨酸抗性的自发突变以离散步骤发生,每个步骤的频率为10⁻⁶至10⁻⁷。第一步、第二步和第三步d - 环丝氨酸抗性突变体分别在d - 环丝氨酸浓度为10⁻³、3×10⁻³和5×10⁻³摩尔时以最大指数速率被裂解。d - 丙氨酸、l - 丙氨酸和dl - 丙氨酰 - dl - 丙氨酸按有效顺序逆转了d - 环丝氨酸诱导的裂解。基于这些观察结果,开发了一种d - 环丝氨酸富集循环技术用于分离营养缺陷型突变体。2×10⁻³摩尔的d - 环丝氨酸在大肠杆菌中富集突变体的效率与青霉素G(每毫升1000单位)相同,并且应该可用于分离对青霉素耐药的微生物中的突变体。细菌接合实验表明,赋予d - 环丝氨酸抗性的所有三个突变都与met(1)位点连锁。转导实验表明,赋予第一步抗性的突变与赋予第二步和第三步抗性的突变至少相距0.5分钟。后两个突变可能发生在同一个基因中,因为它们有时携带在同一个转导噬菌体中。对d - 环丝氨酸抗性表达的研究表明,这些突变彼此之间以及与d - 环丝氨酸敏感性等位基因既不是显性也不是隐性的。每个等位基因状态独立于其他状态对表型产生影响。根据已知的d - 环丝氨酸对丙氨酸消旋酶和d - 丙氨酰 - d - 丙氨酸合成酶的抑制作用对这些结果进行了讨论。
Zotero 插件