Wei Yi, Liu Jun, Ma Yanhe, Krulwich Terry A
Department of Pharmacology and Systems Therapeutics, Mount Sinai School of Medicine, New York, NY 10029, USA.
Institute of Microbiology, Chinese Academy of Sciences, Beijing 100080, People's Republic of China.
Microbiology (Reading). 2007 Jul;153(Pt 7):2168-2179. doi: 10.1099/mic.0.2007/007450-0.
Attempts to identify members of the antiporter complement of the alkali- and saline-adapted soda lake alkaliphile Alkalimonas amylolytica N10 have used screens of DNA libraries in antiporter-deficient Escherichia coli KNabc. Earlier screens used Na(+) or Li(+) for selection but only identified one NhaD-type antiporter whose properties were inconsistent with a robust role in pH homeostasis. Here, new screens using elevated pH for selection identified three other putative antiporter genes that conferred resistance to pH >or=8.5 as well as Na(+) resistance. The three predicted gene products were in the calcium/cation antiporter (CaCA), cation/proton antiporter-2 (CPA2) and cation/proton antiporter-1 (CPA1) families of membrane transporters, and were designated Aa-CaxA, Aa-KefB and Aa-NhaP respectively, reflecting homology within those families. Aa-CaxA conferred the poorest Na(+) resistance and also conferred modest Ca(2+) resistance. Aa-KefB and Aa-NhaP inhibited growth of a K(+) uptake-deficient E. coli mutant (TK2420), suggesting that they catalysed K(+) efflux. For Aa-NhaP, the reversibility of the growth inhibition by high K(+) concentrations depended upon an organic nitrogen source, e.g. glutamine, rather than ammonium. This suggests that as well as K(+) efflux is catalysed by Aa-NhaP. Vesicles of E. coli KNabc expressing Aa-NhaP, which conferred the strongest alkali resistance, exhibited K(+)/H(+) antiport activity in a pH range from 7.5 to 9.5, and with an apparent K(m) for K(+) of 0.5 mM at pH 8.0. The properties of this antiporter are consistent with the possibility that this soda lake alkaliphile uses K(+)( )/H(+) antiport as part of its alkaline pH homeostasis mechanism and part of its capacity to reduce potentially toxic accumulation of cytoplasmic K(+) or respectively, under conditions of high osmolarity or active amino acid catabolism.
为鉴定适应碱和盐的苏打湖嗜碱菌解淀粉碱单胞菌N10的反向转运蛋白成员,研究人员利用缺乏反向转运蛋白的大肠杆菌KNabc中的DNA文库进行筛选。早期筛选使用Na(+)或Li(+)进行选择,但仅鉴定出一种NhaD型反向转运蛋白,其特性与在pH稳态中发挥强大作用不一致。在此,使用升高的pH进行选择的新筛选鉴定出另外三个推定的反向转运蛋白基因,这些基因赋予对pH≥8.5的抗性以及Na(+)抗性。这三个预测的基因产物分别属于膜转运蛋白的钙/阳离子反向转运蛋白(CaCA)、阳离子/质子反向转运蛋白-2(CPA2)和阳离子/质子反向转运蛋白-1(CPA1)家族,分别命名为Aa-CaxA、Aa-KefB和Aa-NhaP,反映了这些家族内的同源性。Aa-CaxA赋予的Na(+)抗性最差,也赋予适度的Ca(2+)抗性。Aa-KefB和Aa-NhaP抑制K(+)摄取缺陷型大肠杆菌突变体(TK2420)的生长,表明它们催化K(+)外流。对于Aa-NhaP,高K(+)浓度对生长的抑制作用的可逆性取决于有机氮源,例如谷氨酰胺,而不是铵。这表明Aa-NhaP除了催化K(+)外流外。表达Aa-NhaP的大肠杆菌KNabc囊泡表现出最强的耐碱性,在pH范围为7.5至9.5内具有K(+)/H(+)反向转运活性,在pH 8.0时K(+)的表观K(m)为0.5 mM。这种反向转运蛋白 的特性与这种苏打湖嗜碱菌在高渗透压或活跃氨基酸分解代谢条件下,利用K(+)( )/H(+)反向转运作为其碱性pH稳态机制的一部分以及减少细胞质K(+)潜在毒性积累能力的一部分的可能性一致。