Kloor D, Kurz J, Fuchs S, Faust B, Osswald H
Department of Pharmacology, University of Tübingen, Germany.
Kidney Blood Press Res. 1996;19(2):100-8. doi: 10.1159/000174051.
In the present study S-adenosylhomocysteine (SAH) hydrolase from the bovine kidney has been purified to apparent homogeneity by standard chromatographic procedures. The purified enzyme was free from adenosine deaminase activity and showed a one-banded pattern in SDS-PAGE with a monomer molecular mass of 47,500. The molecular mass of the native enzyme estimated by gel filtration was about 190,000. The pI was 5.5. For hydrolysis of SAH we found a Km of 5.0 +/- 1.2 microM and a V of 0.25 mumol/min/mg. In the direction of synthesis the Km for adenosine was 5.6 microM and V 0.53 mumol/min/mg. The enzyme activity was inhibited in the presence of adenosine with a Ki = 3 microM. In a second set of experiments we determined the binding characteristics of [3H]-adenosine to purified enzyme. The enzyme bound [3H]-adenosine with three apparent affinities: Kd1 = 6.8 +/- 0.7 nM and Bmax1 = 0.24 +/- 0.04 nmol/mg protein; Kd2 = 387 +/- 41 nM and Bmax2 = 1.4 nmol/mg protein, and Kd3 = 7.05 +/- 0.9 microM and Bmax3 = 9 nmol/mg protein. Binding of 25 nM [3H]-adenosine obeyed a monophasic reaction with a k+1 value of 0.025 min/nM. Dissociation of [3H]-adenosine-SAH hydrolase complex was markedly temperature dependent. After a 240-min incubation at 0 degrees C only 5-10% and at 20 degrees C 75% were displaceable. A fraction of 25% bound [3H]-adenosine was not displaceable by unlabeled adenosine. Our data show that the renal SAH hydrolase exhibits similar enzyme kinetics as the well-characterized SAH hydrolase from liver. The amount of SAH hydrolase present in renal tissues (1.4 nmol/g wet weight) could account almost entirely for the binding of renal tissue adenosine. Finally, we report for the first time a high affinity binding site of SAH hydrolase for adenosine, which remains unexplained at present.
在本研究中,通过标准色谱程序已将牛肾中的S-腺苷同型半胱氨酸(SAH)水解酶纯化至表观均一。纯化后的酶无腺苷脱氨酶活性,在SDS-PAGE中呈现单一条带模式,单体分子量为47,500。通过凝胶过滤估算的天然酶分子量约为190,000。其pI为5.5。对于SAH的水解,我们发现Km为5.0±1.2μM,V为0.25μmol/分钟/毫克。在合成方向上,腺苷的Km为5.6μM,V为0.53μmol/分钟/毫克。在腺苷存在下酶活性受到抑制,Ki = 3μM。在第二组实验中,我们测定了[3H]-腺苷与纯化酶的结合特性。该酶以三种明显的亲和力结合[3H]-腺苷:Kd1 = 6.8±0.7 nM,Bmax1 = 0.24±0.04 nmol/毫克蛋白质;Kd2 = 387±41 nM,Bmax2 = 1.4 nmol/毫克蛋白质,以及Kd3 = 7.05±0.9μM,Bmax3 = 9 nmol/毫克蛋白质。25 nM [3H]-腺苷的结合遵循单相反应,k+1值为0.025分钟/nM。[3H]-腺苷-SAH水解酶复合物的解离明显依赖于温度。在0℃孵育240分钟后,仅有5 - 10%可被置换,在20℃时为75%。25%结合的[3H]-腺苷中有一部分不能被未标记的腺苷置换。我们的数据表明,肾SAH水解酶表现出与已充分表征的肝SAH水解酶相似的酶动力学。肾组织中存在的SAH水解酶量(1.4 nmol/克湿重)几乎可以完全解释肾组织中腺苷的结合情况。最后,我们首次报道了SAH水解酶对腺苷的高亲和力结合位点,目前其原因尚不清楚。
