Murakami T, Nojiri M, Nakayama H, Odaka M, Yohda M, Dohmae N, Takio K, Nagamune T, Endo I
RIKEN (The Institute of Physical and Chemical Research), Wako, Saitama, Japan.
Protein Sci. 2000 May;9(5):1024-30. doi: 10.1110/ps.9.5.1024.
Nitrile hydratase from Rhodococcus sp. N-771 is an alphabeta heterodimer with a nonheme ferric iron in the catalytic center. In the catalytic center, alphaCys112 and alphaCys114 are modified to a cysteine sulfinic acid (Cys-SO2H) and a cysteine sulfenic acid (Cys-SOH), respectively. To understand the function and the biogenic mechanism of these modified residues, we reconstituted the nitrile hydratase from recombinant unmodified subunits. The alphabeta complex reconstituted under argon exhibited no activity. However, it gradually gained the enzymatic activity through aerobic incubation. ESI-LC/MS analysis showed that the anaerobically reconstituted alphabeta complex did not have the modification of alphaCys112-SO2H and aerobic incubation induced the modification. The activity of the reconstituted alphabeta complex correlated with the amount of alphaCys112-SO2H. Furthermore, ESI-LC/MS analyses of the tryptic digest of the reconstituted complex, removed of ferric iron at low pH and carboxamidomethylated without reduction, suggested that alphaCys114 is modified to Cys-SOH together with the sulfinic acid modification of alphaCys112. These results suggest that alphaCys112 and alphaCys114 are spontaneously oxidized to Cys-SO2H and Cys-SOH, respectively, and alphaCys112-SO2H is responsible for the catalytic activity solely or in combination with alphaCys114-SOH.
来自红球菌属N-771的腈水合酶是一种αβ异二聚体,其催化中心含有非血红素铁。在催化中心,αCys112和αCys114分别被修饰为半胱氨酸亚磺酸(Cys-SO2H)和半胱氨酸次磺酸(Cys-SOH)。为了了解这些修饰残基的功能和生物合成机制,我们用重组的未修饰亚基重构了腈水合酶。在氩气下重构的αβ复合物没有活性。然而,通过有氧孵育它逐渐获得了酶活性。电喷雾电离液相色谱/质谱分析表明,厌氧重构的αβ复合物没有αCys112-SO2H修饰,而有氧孵育诱导了这种修饰。重构的αβ复合物的活性与αCys112-SO2H的量相关。此外,对重构复合物的胰蛋白酶消化产物进行电喷雾电离液相色谱/质谱分析,在低pH下去除铁离子并在不还原的情况下进行羧甲基化,结果表明αCys114与αCys112的亚磺酸修饰一起被修饰为Cys-SOH。这些结果表明,αCys112和αCys114分别自发氧化为Cys-SO2H和Cys-SOH,并且αCys112-SO2H单独或与αCys114-SOH共同负责催化活性。