Neidhart D J, Howell P L, Petsko G A, Powers V M, Li R S, Kenyon G L, Gerlt J A
Department of Chemistry, Massachusetts Institute of Technology, Cambridge 02139.
Biochemistry. 1991 Sep 24;30(38):9264-73. doi: 10.1021/bi00102a019.
The crystal structure of mandelate racemase (MR) has been solved at 3.0-A resolution by multiple isomorphous replacement and subsequently refined against X-ray diffraction data to 2.5-A resolution by use of both molecular dynamics refinement (XPLOR) and restrained least-squares refinement (PROLSQ). The current crystallographic R-factor for this structure is 18.3%. MR is composed of two major structural domains and a third, smaller, C-terminal domain. The N-terminal domain has an alpha + beta topology consisting of a three-stranded antiparallel beta-sheet followed by an antiparallel four alpha-helix bundle. The central domain is a singly wound parallel alpha/beta-barrel composed of eight central strands of beta-sheet and seven alpha-helices. The C-terminal domain consists of an irregular L-shaped loop with several short sections of antiparallel beta-sheet and two short alpha-helices. This C-terminal domain partially covers the junction between the major domains and occupies a region of the central domain that is filled by an eight alpha-helix in all other known parallel alpha/beta-barrels except for the barrel domain in muconate lactonizing enzyme (MLE) [Goldman, A., Ollis, D. L., & Steitz, T. A. (1987) J. Mol. Biol. 194, 143] whose overall polypeptide fold and amino acid sequence are strikingly similar to those of MR [Neidhart, D. J., Kenyon, G. L., Gerlt, J. A., & Petsko, G. A. (1990) Nature 347, 692]. In addition, the crystal structure reveals that, like MLE, MR is tightly packed as an octamer of identical subunits. The active site of MR is located between the two major domains, at the C-terminal ends of the beta-strands in the alpha/beta-barrel domain. The catalytically essential divalent metal ion is ligated by three side-chain carboxyl groups contributed by residues of the central beta-sheet. A model of a productive substrate complex of MR has been constructed on the basis of difference Fourier analysis at 3.5-A resolution of a complex between MR and (R,S)-p-iodomandelate, permitting identification of residues that may participate in substrate binding and catalysis. The ionizable groups of both Lys 166 and His 297 are positioned to interact with the chiral center of substrate, suggesting that both of these residues may function as acid/base catalysts.(ABSTRACT TRUNCATED AT 400 WORDS)
扁桃酸消旋酶(MR)的晶体结构已通过多同晶置换法在3.0埃分辨率下解析出来,随后利用分子动力学精修(XPLOR)和约束最小二乘精修(PROLSQ),根据X射线衍射数据将其精修至2.5埃分辨率。该结构当前的晶体学R因子为18.3%。MR由两个主要结构域和第三个较小的C端结构域组成。N端结构域具有α + β拓扑结构,由一个三链反平行β折叠片层和一个反平行四螺旋束组成。中央结构域是一个单绕平行α/β桶状结构,由八条β折叠片层的中央链和七条α螺旋组成。C端结构域由一个不规则的L形环组成,带有几段反平行β折叠片层和两条短α螺旋。这个C端结构域部分覆盖了主要结构域之间的连接点,并占据了中央结构域的一个区域,除了粘康酸内酯化酶(MLE)的桶状结构域外,在所有其他已知的平行α/β桶状结构中该区域由八条α螺旋填充[戈德曼,A.,奥利,D. L.,& 施泰茨,T. A.(1987年)《分子生物学杂志》194卷,143页],其整体多肽折叠和氨基酸序列与MR的极为相似[奈德哈特,D. J.,凯尼恩,G. L.,格尔特,J. A.,& 佩茨科,G. A.(1990年)《自然》347卷,692页]。此外,晶体结构表明,与MLE一样,MR紧密堆积成由相同亚基组成的八聚体。MR的活性位点位于两个主要结构域之间,在α/β桶状结构域中β链的C端。催化必需的二价金属离子由中央β折叠片层残基贡献的三个侧链羧基配位。基于MR与(R,S)-对碘扁桃酸复合物在3.5埃分辨率下的差值傅里叶分析,构建了MR的一个有效底物复合物模型,从而能够鉴定可能参与底物结合和催化的残基。赖氨酸166和组氨酸297的可电离基团的位置能够与底物的手性中心相互作用,这表明这两个残基都可能作为酸碱催化剂发挥作用。(摘要截断于400字)
