Mattevi A, Schierbeek A J, Hol W G
Department of Chemistry, University of Groningen, The Netherlands.
J Mol Biol. 1991 Aug 20;220(4):975-94. doi: 10.1016/0022-2836(91)90367-f.
The structure of lipoamide dehydrogenase from Azotobacter vinelandii has been refined by the molecular dynamics technique to an R-factor of 19.8% at 2.2 A resolution. In the final model, the root-mean-square deviation from ideality is 0.02 A for bond lengths and 3.2 degrees for bond angles. The asymmetric unit comprises two subunits, each consisting of 466 amino acid residues and the prosthetic group FAD, plus 512 solvent molecules. The last ten amino acid residues of both chains are not visible in the electron density distribution and they are probably disordered. The operation required to superimpose the two chains forming the dimer is a rotation of exactly 180 degrees with no translation component. The final model shows the two independently refined subunits to be very similar, except for six loops located at the surface of the molecule. The structure of each subunit of the enzyme consists of four domains with the catalytic centre located at the subunit interface. The reactive disulphide bridge, 48-53, is oxidized with S gamma of Cys53 located 3.5 A away from carbon C-4a of the isoalloxazine ring. The side-chain of His450' points its N epsilon 2 towards S gamma of Cys48 and is hydrogen bonded to the carboxylate of Glu455'. The FAD is bound in an extended conformation and the isoalloxazine ring is not completely planar with an angle between the pteridine and the benzene ring of 7.3 degrees in the first subunit and of 12.1 degrees in the second one. The overall folding of lipoamide dehydrogenase is very similar to that of glutathione reductase. However, a comparison of the two enzymes, which have only 26% sequence identity, reveals significant conformational differences. These concern the tertiary as well as the quaternary structure of the two molecules. In each subunit of lipoamide dehydrogenase the NAD-binding domain and the interface domain appear to be differently oriented with respect to the FAD-binding domain by 7.1 degrees and 7.8 degrees, respectively. The interface domain contains, in addition, major changes in tertiary structure. Furthermore, the two subunits forming the dimer appear to be shifted with respect to each other by more than 4 A, when the lipoamide dehydrogenase dimer is compared with that of glutathione reductase. In spite of all these changes at the tertiary and quaternary level the active sites of the enzymes, which occur at the dimer interface, appear to be remarkably similar.(ABSTRACT TRUNCATED AT 400 WORDS)
利用分子动力学技术对棕色固氮菌的硫辛酰胺脱氢酶结构进行了优化,在2.2 Å分辨率下,R因子为19.8%。在最终模型中,键长与理想值的均方根偏差为0.02 Å,键角为3.2度。不对称单元包含两个亚基,每个亚基由466个氨基酸残基和辅基FAD组成,外加512个溶剂分子。两条链的最后十个氨基酸残基在电子密度分布中不可见,可能是无序的。形成二聚体的两条链进行叠加所需的操作是精确旋转180度,无平移分量。最终模型显示,除了位于分子表面的六个环外,两个独立优化的亚基非常相似。该酶每个亚基的结构由四个结构域组成,催化中心位于亚基界面处。反应性二硫键(48 - 53)被氧化,半胱氨酸53的Sγ距离异咯嗪环的碳C - 4a为3.5 Å。组氨酸450'的侧链将其Nε2指向半胱氨酸48的Sγ,并与谷氨酸455'的羧酸盐形成氢键。FAD以伸展构象结合,异咯嗪环不完全平面,第一个亚基中蝶啶和苯环之间夹角为7.3度,第二个亚基中为12.1度。硫辛酰胺脱氢酶的整体折叠与谷胱甘肽还原酶非常相似。然而,对这两种序列同一性仅为26%的酶进行比较,发现存在显著的构象差异。这些差异涉及两个分子的三级结构和四级结构。在硫辛酰胺脱氢酶的每个亚基中,NAD结合结构域和界面结构域相对于FAD结合结构域的取向分别不同,相差7.1度和7.8度。此外,界面结构域的三级结构有重大变化。此外,与谷胱甘肽还原酶的二聚体相比,形成硫辛酰胺脱氢酶二聚体的两个亚基彼此相对移动超过4 Å。尽管在三级和四级水平上有所有这些变化,但位于二聚体界面处的酶活性位点似乎非常相似。(摘要截断于400字)
