Daugherty Roxanne G, Wasowicz Tomasz, Gibney Brian R, DeRose Victoria J
Department of Chemistry, Texas A&M University, College Station, Texas 77842-3012, and Department of Chemistry, Columbia University, New York, New York 10027.
Inorg Chem. 2002 May 20;41(10):2623-32. doi: 10.1021/ic010555a.
The Cu(II)- and Co(II)-binding properties of two peptides, designed on the basis of the active site sequence and structure of the blue copper protein plastocyanin, are explored. Peptide BCP-A, Ac-Trp-(Gly)(3)-Ser-Tyr-Cys-Ser-Pro-His-Gln-Gly-Ala-Gly-Met-(Gly )(3)-His-(Gly)(2)-Lys-CONH(2), conserves the Cu-binding loop of plastocyanin containing three of the four copper ligands and has a flexible (Gly)(3) linker to the second His ligand. Peptide BCP-B, Ac-Trp-(Gly)(3)-Cys-Gly-His-Gly-Val-Pro-Ser-His-Gly-Met-Gly-CONH(2), contains all four blue copper ligands, with two on either side of a beta-turn. Both peptides form 1:1 complexes with Cu(II) through His and Cys ligands. BCP-A, the ligand loop, binds to Cu(II) in a tetrahedrally distorted square plane with axial solvent ligation, while BCP-B-Cu(II) has no tetrahedral distortion in aqueous solution. In methanolic solution, distortion of the square plane is evident for both BCP-Cu(II) complexes. Tetrahedral Co(II) complexes are observed for both peptides in aqueous solution but with 4:2 peptide:Co(II) stoichiometries as estimated by ultracentrifugation. Cu(II) reduction potentials for the aqueous peptide-Cu(II) complexes were measured to be +75 +/- 30 mV vs NHE for BCP-A-Cu(II) and -10 +/- 20 mV vs NHE for BCP-B-Cu(II). The results indicate that the plastocyanin ligand loop can act as a metal-binding site with His and Cys ligands in the absence of the remainder of the folded protein but, by itself, cannot stabilize a type 1 copper site, emphasizing the role of the protein matrix in protecting the Cu binding site from solvent exposure and the Cys from oxidation.
研究了基于蓝铜蛋白质体蓝素的活性位点序列和结构设计的两种肽与铜(II)和钴(II)的结合特性。肽BCP-A,Ac-Trp-(Gly)₃-Ser-Tyr-Cys-Ser-Pro-His-Gln-Gly-Ala-Gly-Met-(Gly)₃-His-(Gly)₂-Lys-CONH₂,保留了质体蓝素的铜结合环,其中包含四个铜配体中的三个,并通过一个柔性的(Gly)₃连接子连接到第二个组氨酸配体。肽BCP-B,Ac-Trp-(Gly)₃-Cys-Gly-His-Gly-Val-Pro-Ser-His-Gly-Met-Gly-CONH₂,包含所有四个蓝铜配体,在β-转角的两侧各有两个。两种肽都通过组氨酸和半胱氨酸配体与铜(II)形成1:1复合物。配体环BCP-A在具有轴向溶剂配位的四面体扭曲正方形平面中与铜(II)结合,而BCP-B-铜(II)在水溶液中没有四面体扭曲。在甲醇溶液中,两种BCP-铜(II)复合物的正方形平面都明显扭曲。通过超速离心估计,在水溶液中两种肽都观察到四面体钴(II)复合物,但肽与钴(II)的化学计量比为4:2。测量得到,对于水溶液中的肽-铜(II)复合物,BCP-A-铜(II)相对于标准氢电极(NHE)的铜(II)还原电位为+75±30 mV,BCP-B-铜(II)相对于NHE的铜(II)还原电位为-10±20 mV。结果表明,在没有折叠蛋白其余部分的情况下,质体蓝素配体环可以作为与组氨酸和半胱氨酸配体结合的金属结合位点,但仅凭其自身不能稳定1型铜位点,这强调了蛋白质基质在保护铜结合位点免受溶剂暴露和保护半胱氨酸免受氧化方面的作用。
