Kim J, Adhya S, Garges S
Laboratory of Molecular Biology, National Cancer Institute, National Institutes of Health, Bethesda, MD 20892.
Proc Natl Acad Sci U S A. 1992 Oct 15;89(20):9700-4. doi: 10.1073/pnas.89.20.9700.
The cAMP receptor protein (CRP) of Escherichia coli is a dimer of a two-domain subunit. It requires binding of cAMP for a conformational change in order to function as a site-specific DNA-binding protein that regulates gene activity. The hinge region connecting the cAMP-binding domain to the DNA-binding domain is involved in the cAMP-induced allosteric change. We studied the structural changes in CRP that are required for gene regulation by making a large number of single and double amino acid substitutions at four different positions in or near the hinge. To achieve cAMP-independent transcription by CRP, amino acid residues 138 (located within the hinge region) and 141 (located in the D alpha-helix adjacent to the hinge) must be polar. This need for polar residues at positions 138 and 141 suggests an interaction that causes the C and D alpha-helices to come together. As a consequence, the F alpha-helix is released from the D alpha-helix and can interact with DNA. At position 144 in the D alpha-helix and within interacting distances of the F alpha-helix, replacement of alanine by an amino acid with a larger side chain, regardless of its nature, allows cAMP independence. This result indicates that pushing against the F alpha-helix may be a way of making the helix available for DNA binding. We believe that the cAMP-induced allosteric change involves similar hinge reorientation to adjust the C and D alpha-helices, allowing outward movement of the F alpha-helix.
大肠杆菌的环磷酸腺苷(cAMP)受体蛋白(CRP)是一种由两个结构域亚基组成的二聚体。它需要结合cAMP才能发生构象变化,从而作为一种调节基因活性的位点特异性DNA结合蛋白发挥作用。连接cAMP结合结构域和DNA结合结构域的铰链区参与了cAMP诱导的变构变化。我们通过在铰链区或其附近的四个不同位置进行大量单氨基酸和双氨基酸替换,研究了CRP中基因调控所需的结构变化。为了使CRP实现不依赖cAMP的转录,138位氨基酸残基(位于铰链区内)和141位氨基酸残基(位于与铰链相邻的Dα螺旋中)必须是极性的。138位和141位需要极性残基,这表明存在一种相互作用,使得Cα螺旋和Dα螺旋聚集在一起。结果,Fα螺旋从Dα螺旋中释放出来,并能与DNA相互作用。在Dα螺旋的144位且处于与Fα螺旋相互作用距离内,用侧链较大的氨基酸取代丙氨酸,无论其性质如何,都能实现不依赖cAMP。这一结果表明,对Fα螺旋施加压力可能是使该螺旋可用于与DNA结合的一种方式。我们认为,cAMP诱导的变构变化涉及类似的铰链重新定向,以调整Cα螺旋和Dα螺旋,使Fα螺旋向外移动。