Kelly Brenda S, Antholine William E, Griffith Owen W
Department of Biochemistry and Biophysics Institute, Medical College of Wisconsin, Milwaukee, Wiscosin 53226, USA.
J Biol Chem. 2002 Jan 4;277(1):50-8. doi: 10.1074/jbc.M107961200. Epub 2001 Oct 23.
Gamma-glutamylcysteine synthetase (gamma-GCS, glutamate-cysteine ligase), which catalyzes the first and rate-limiting step in glutathione biosynthesis, is present in many prokaryotes and in virtually all eukaryotes. Although all eukaryotic gamma-GCS isoforms examined to date are rapidly inhibited by buthionine sulfoximine (BSO), most reports indicate that bacterial gamma-GCS is resistant to BSO. We have confirmed the latter finding with Escherichia coli gamma-GCS under standard assay conditions, showing both decreased initial binding affinity for BSO and a reduced rate of BSO-mediated inactivation compared with mammalian isoforms. We also find that substitution of Mn2+ for Mg2+ in assay mixtures increases both the initial binding affinity of BSO and the rate at which BSO causes mechanism-based inactivation. Similarly, the specificity of E. coli gamma-GCS for its amino acid substrates is broadened in the presence of Mn2+, and the rate of reaction for some very poor substrates is improved. These results suggest that divalent metal ions have a role in amino acid binding to E. coli gamma-GCS. Electron paramagnetic resonance (EPR) studies carried out with Mn2+ show that E. coli gamma-GCS binds two divalent metal ions; Kd values for Mn2+ are 1.1 microm and 82 microm, respectively. Binding of l-glutamate or l-BSO to the two Mn2+/gamma-GCS species produces additional upfield and downfield X-band EPR hyperfine lines at 45 G intervals, a result indicating that the two Mn2+ are spin-coupled and thus apparently separated by 5 A or less in the active site. Additional EPR studies in which Cu2+ replaced Mg2+ or Mn2+ suggest that Cu2+ is bound by one N and three O ligands in the gamma-GCS active site. The results are discussed in the context of the catalytic mechanism of gamma-GCS and its relationship to the more fully characterized glutamine synthetase reaction.
γ-谷氨酰半胱氨酸合成酶(γ-GCS,谷氨酸-半胱氨酸连接酶)催化谷胱甘肽生物合成的第一步且是限速步骤,存在于许多原核生物以及几乎所有的真核生物中。尽管迄今为止检测的所有真核γ-GCS同工型都能被丁硫氨酸亚砜胺(BSO)迅速抑制,但大多数报告表明细菌γ-GCS对BSO具有抗性。我们已在标准测定条件下用大肠杆菌γ-GCS证实了后一发现,结果显示与哺乳动物同工型相比,其对BSO的初始结合亲和力降低,且BSO介导的失活速率也降低。我们还发现,在测定混合物中用Mn2+替代Mg2+会增加BSO的初始结合亲和力以及BSO导致基于机制的失活速率。同样,在存在Mn2+的情况下,大肠杆菌γ-GCS对其氨基酸底物的特异性会变宽,并且一些极难作用底物的反应速率会提高。这些结果表明二价金属离子在氨基酸与大肠杆菌γ-GCS的结合中起作用。用Mn2+进行的电子顺磁共振(EPR)研究表明,大肠杆菌γ-GCS结合两个二价金属离子;Mn2+的解离常数(Kd)值分别为1.1微摩尔和82微摩尔。l-谷氨酸或l-BSO与这两种Mn2+/γ-GCS物种结合会在45高斯间隔处产生额外的上磁场和下磁场X波段EPR超精细线,这一结果表明这两个Mn2+是自旋耦合的,因此在活性位点中它们之间的距离显然在5埃或更小。用Cu2+替代Mg2+或Mn2+的其他EPR研究表明,Cu2+在γ-GCS活性位点中由一个氮和三个氧配体结合。将结合这些结果在γ-GCS的催化机制及其与特征更充分的谷氨酰胺合成酶反应的关系的背景下进行了讨论。
