小孔区域的替换会干扰头孢吡肟通过大肠杆菌外膜孔蛋白F通道的扩散。
Substitutions in the eyelet region disrupt cefepime diffusion through the Escherichia coli OmpF channel.
作者信息
Simonet V, Malléa M, Pagès J M
机构信息
CJF 9606, Faculté de Médecine, 13385 Marseille Cedex 05, France.
出版信息
Antimicrob Agents Chemother. 2000 Feb;44(2):311-5. doi: 10.1128/AAC.44.2.311-315.2000.
Abstract
The Escherichia coli OmpF porin is a nonspecific channel involved in the membrane translocation of small hydrophilic molecules and especially in the passage of beta-lactam antibiotics. In order to understand the dynamic of charged-compound uptake through bacterial porins, specific charges located in the E. coli OmpF channel were mutated. Substitutions G119D and G119E, inserting a protruding acidic side chain into the pore, decreased cephalosporin and colicin susceptibilities. Cefepime diffusion was drastically altered by these mutations. Conversely, substitutions R132A and R132D, changing a residue located in the positively charged cluster, increased the rate of cephalosporin uptake without modifying colicin sensitivity. Modelling approaches suggest that G119E generates a transverse hydrogen bond dividing the pore, while the two R132 substitutions stretch the channel size. These charge alterations located in the constriction area have differential effects on cephalosporin diffusion and substantially modify the profile of antibiotic susceptibility.
摘要
大肠杆菌外膜孔蛋白F(OmpF)是一种非特异性通道,参与小的亲水分子的膜转运,尤其涉及β-内酰胺类抗生素的通过。为了了解带电化合物通过细菌孔蛋白的摄取动态,对位于大肠杆菌OmpF通道中的特定电荷进行了突变。G119D和G119E替换,即在孔中插入一个突出的酸性侧链,降低了头孢菌素和大肠杆菌素的敏感性。这些突变极大地改变了头孢吡肟的扩散。相反,R132A和R132D替换,改变了位于带正电荷簇中的一个残基,提高了头孢菌素的摄取速率,而不改变大肠杆菌素敏感性。建模方法表明,G119E产生了一个横向氢键将孔分开,而两个R132替换则扩大了通道尺寸。位于收缩区的这些电荷改变对头孢菌素扩散有不同影响,并显著改变抗生素敏感性谱。
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