Yang Seung-Ju, Huh Jae-Wan, Hong Hea-Nam, Kim Tae Ue, Cho Sung-Woo
Department of Biochemistry and Molecular Biology, University of Ulsan College of Medicine, 388-1 Poongnap-2dong, Songpa-gu, Seoul 138-736, South Korea.
FEBS Lett. 2004 Mar 26;562(1-3):59-64. doi: 10.1016/S0014-5793(04)00183-8.
Molecular biological studies confirmed that two glutamate dehydrogenase isozymes (hGDH1 and hGDH2) of distinct genetic origin are expressed in human tissues. hGDH1 is heat-stable and expressed widely, whereas hGDH2 is heat-labile and specific for neural and testicular tissues. A selective deficiency of hGDH2 has been reported in patients with spinocerebellar ataxia. We have identified an amino acid residue involved in the different thermal stability of human GDH isozymes. At 45 degrees C (pH 7.0), heat inactivation proceeded faster for hGDH2 (half life=45 min) than for hGDH1 (half-life=310 min) in the absence of allosteric regulators. Both hGDH1 and hGDH2, however, showed much slower heat inactivation processes in the presence of 1 mM ADP or 3 mM L-Leu. Virtually most of the enzyme activity remained up to 100 min at 45 degrees C after treatment with ADP and L-Leu in combination. In contrast to ADP and L-Leu, the thermal stabilities of the hGDH isozymes were not affected by addition of substrates or coenzymes. In human GDH isozymes, the 443 site is Arg in hGDH1 and Ser in hGDH2. Replacement of Ser by Arg at the 443 site by cassette mutagenesis abolished the heat lability of hGDH2 with a similar half-life of hGDH1. The mutagenesis at several other sites (L415M, A456G, and H470R) having differences in amino acid sequence between the two GDH isozymes did not show any change in the thermal stability. These results suggest that the Ser443 residue plays an important role in the different thermal stability of human GDH isozymes.
分子生物学研究证实,人类组织中表达了两种遗传起源不同的谷氨酸脱氢酶同工酶(hGDH1和hGDH2)。hGDH1热稳定且广泛表达,而hGDH2热不稳定且对神经和睾丸组织具有特异性。据报道,脊髓小脑共济失调患者存在hGDH2的选择性缺陷。我们已经确定了一个参与人类GDH同工酶不同热稳定性的氨基酸残基。在45℃(pH 7.0)下,在没有变构调节剂的情况下,hGDH2(半衰期=45分钟)的热失活比hGDH1(半衰期=310分钟)更快。然而,在存在1 mM ADP或3 mM L-亮氨酸的情况下,hGDH1和hGDH2的热失活过程都要慢得多。在用ADP和L-亮氨酸联合处理后,实际上在45℃下100分钟内大部分酶活性仍保留。与ADP和L-亮氨酸相反,底物或辅酶的添加不影响hGDH同工酶的热稳定性。在人类GDH同工酶中,443位点在hGDH1中是精氨酸,在hGDH2中是丝氨酸。通过盒式诱变将443位点的丝氨酸替换为精氨酸消除了hGDH2的热不稳定性,其半衰期与hGDH1相似。在两种GDH同工酶之间氨基酸序列存在差异的其他几个位点(L415M、A456G和H470R)进行诱变,热稳定性没有任何变化。这些结果表明,Ser443残基在人类GDH同工酶的不同热稳定性中起重要作用。
