超广谱β-内酰胺酶CTX-M-9介导的头孢他啶耐药性演变预测
Prediction of the evolution of ceftazidime resistance in extended-spectrum beta-lactamase CTX-M-9.
作者信息
Delmas J, Robin F, Carvalho F, Mongaret C, Bonnet R
机构信息
Laboratoire de Bactériologie, Faculté de Médecine, Centre Hospitalo-Universitaire, Clermont-Ferrand, France.
出版信息
Antimicrob Agents Chemother. 2006 Feb;50(2):731-8. doi: 10.1128/AAC.50.2.731-738.2006.
Abstract
A random mutagenesis technique was used to predict the evolutionary potential of beta-lactamase CTX-M-9 toward the acquisition of improved catalytic activity against ceftazidime. Thirty CTX-M mutants were obtained during three rounds of mutagenesis. These mutants conferred 1- to 128-fold-higher MICs of ceftazidime than the parental enzyme CTX-M-9. The CTX-M mutants contained one to six amino acid substitutions. Mutants harbored the substitutions Asp240Gly and Pro167Ser, which were previously observed in clinical CTX-M enzymes. Additional substitutions, notably Arg164His, Asp179Gly, and Arg276Ser, were observed near the active site. The kinetic constants of the three most active mutants revealed two distinct ways of improving catalytic efficiency against ceftazidime. One enzyme had a 17-fold-higher k(cat) value than CTX-M-9 against ceftazidime. The other two had 75- to 300-fold-lower Km values than CTX-M-9 against ceftazidime. The current emergence of CTX-M beta-lactamases with improved activity against ceftazidime may therefore be the beginning of an evolutionary process which might subsequently generate a great diversity of CTX-M-type ceftazidimases.
摘要
一种随机诱变技术被用于预测β-内酰胺酶CTX-M-9获得针对头孢他啶更高催化活性的进化潜力。在三轮诱变过程中获得了30个CTX-M突变体。这些突变体对头孢他啶的最低抑菌浓度(MIC)比亲本酶CTX-M-9高1至128倍。CTX-M突变体包含1至6个氨基酸替换。突变体含有Asp240Gly和Pro167Ser替换,这在临床CTX-M酶中曾被观察到。在活性位点附近还观察到其他替换,特别是Arg164His、Asp179Gly和Arg276Ser。三个活性最高的突变体的动力学常数揭示了提高针对头孢他啶催化效率的两种不同方式。一种酶针对头孢他啶的催化常数(k(cat))值比CTX-M-9高17倍。另外两种酶针对头孢他啶的米氏常数(Km)值比CTX-M-9低75至300倍。因此,目前具有针对头孢他啶更高活性的CTX-Mβ-内酰胺酶的出现可能是一个进化过程的开端,该过程随后可能产生大量不同类型的CTX-M型头孢他啶酶。
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