Lu N T, Pedersen P L
Department of Biological Chemistry, Johns Hopkins University, School of Medicine, 725 North Wolfe Street, Baltimore, Maryland, 21205-2185, USA.
Arch Biochem Biophys. 2000 Mar 1;375(1):7-20. doi: 10.1006/abbi.1999.1656.
The cystic fibrosis transmembrane conductance regulator (CFTR) is known to function as a regulated chloride channel and, when genetically impaired, to cause the disease cystic fibrosis. The novel studies reported here were undertaken to gain greater molecular insight into possible interactions among CFTR's soluble domains, which include two nucleotide binding domains (NBF1 and NBF2) and a regulatory domain (R). The NBF1+R and NBF2 regions of CFTR were highly expressed in Escherichia coli, purified to near homogeneity under denaturing conditions, and refolded. Both refolded proteins bound TNP-ATP and TNP-ADP, which could be readily replaced with ATP. Four different approaches were then used to determine whether the NBF1+R and NBF2 proteins interact. First, the purified NBF2 protein was labeled near its C-terminus with a fluorescent probe, 7-diethyl amino-3-(4'-maleimidylphenyl)-4-methylcoumarin (CPM). Addition of the unlabeled NBF1+R to the CPM-labeled NBF2 caused a red-shift in lambda(max) of the CPM fluorescence, consistent with a direct interaction between the two proteins. Second, when the NBF1+R protein, the NBF2 protein, and a mixture of the two proteins were folded separately and analyzed by molecular sieve chomatography, the mixture was found to elute prior to either NBF1+R or NBF2. Third, na-tive-PAGE gel studies revealed that the mixture of the NBF1+R and NBF2 domains migrated as a single band with an R(F) value between that of NBF1+R and NBF2. Fourth, trypsin digestion of a mixture of the NBF1+R and NBF2 proteins occurred at a slower rate than that for the individual proteins. Finally, studies were carried out to determine whether an NBF1+R/NBF2 interaction could be demonstrated after expressing one of the two proteins in soluble, native form, thus avoiding the inclusion body, denaturation, and renaturation approach. Specifically, the NBF1+R protein was overexpressed in E. coli in fusion with glutathione-S-transferase near a thrombin cleavage site. Following binding of the GST-(NBF1+R) fusion protein to a GST Sepharose affinity column, added NBF2 was shown to bind and then to coelute with NBF1+R upon addition of glutathione or thrombin. Collectively, these experiments demonstrate that CFTR's NBF1+R region and its NBF2 domain, after folding separately as distinct units, have a strong propensity to interact and that this interaction is stable in the absence of added nucleotides or exogenously induced phosphorylation. These findings, together with the additional observation that the NBF1+R/NBF2 interaction induces a change in the C-terminus of NBF2, which resides within the C-terminal region of CFTR, may have important implications not only for the function of CFTR per se, but its interaction with other proteins.
已知囊性纤维化跨膜传导调节因子(CFTR)作为一种受调控的氯离子通道发挥作用,当其基因受损时会引发囊性纤维化疾病。本文报道的新研究旨在更深入地从分子层面了解CFTR可溶性结构域之间可能的相互作用,这些可溶性结构域包括两个核苷酸结合结构域(NBF1和NBF2)和一个调节结构域(R)。CFTR的NBF1 + R和NBF2区域在大肠杆菌中高表达,在变性条件下纯化至接近均一状态,然后进行复性。两种复性后的蛋白质都能结合TNP - ATP和TNP - ADP,且它们很容易被ATP取代。接着采用了四种不同方法来确定NBF1 + R和NBF2蛋白是否相互作用。首先,用荧光探针7 - 二乙氨基 - 3 -(4'-马来酰亚胺基苯基)- 4 - 甲基香豆素(CPM)在纯化的NBF2蛋白的C末端附近进行标记。将未标记的NBF1 + R添加到CPM标记的NBF2中会导致CPM荧光的最大波长发生红移,这与两种蛋白质之间的直接相互作用一致。其次,当NBF1 + R蛋白、NBF2蛋白以及两者的混合物分别折叠并通过分子筛色谱分析时,发现混合物的洗脱时间比NBF1 + R或NBF2都要早。第三,非变性聚丙烯酰胺凝胶研究表明,NBF1 + R和NBF2结构域的混合物迁移时呈现为一条单一的条带,其R(F)值介于NBF1 + R和NBF2之间。第四,对NBF1 + R和NBF2蛋白混合物进行胰蛋白酶消化的速率比单独的蛋白质要慢。最后,开展研究以确定在以可溶的天然形式表达两种蛋白质之一后,是否能证明NBF1 + R/NBF2相互作用,从而避免包涵体、变性和复性过程。具体而言,NBF1 + R蛋白在大肠杆菌中与谷胱甘肽 - S - 转移酶在凝血酶切割位点附近融合过表达。在将GST -(NBF1 + R)融合蛋白与GST琼脂糖亲和柱结合后,添加的NBF2被证明能够结合,然后在添加谷胱甘肽或凝血酶时与NBF1 + R一起洗脱。总的来说,这些实验表明CFTR的NBF1 + R区域及其NBF2结构域在分别折叠成不同单元后,具有很强的相互作用倾向,并且这种相互作用在没有添加核苷酸或外源诱导磷酸化的情况下是稳定的。这些发现,连同另外的观察结果,即NBF1 + R/NBF2相互作用会导致位于CFTR C末端区域内的NBF2的C末端发生变化,可能不仅对CFTR本身的功能,而且对其与其他蛋白质的相互作用都具有重要意义。
