Spencer P, Jordan P M
Department of Biochemistry, School of Biological Sciences, University of Southampton, U.K.
Biochem J. 1995 Jan 1;305 ( Pt 1)(Pt 1):151-8. doi: 10.1042/bj3050151.
Experiments are described in which the individual properties of the two 5-aminolaevulinic acid (ALA) binding sites, the A-site and the P-site, of 5-aminolaevulinic acid dehydratase (ALAD) have been investigated. The ALA binding affinity at the A-site is greatly enhanced (at least 10-fold) on the binding of the catalytic metal ion (bound at the alpha-site). The nature of the catalytic metal ion, Mg2+ or Zn2+, also gave major variations in the substrate Km, P-site affinity for ALA, the effect of potassium and phosphate ions and the pH-dependence of substrate binding. Modification of the P-site by reaction of the enzyme-substrate Schiff base with NaBH4 and analysis of the reduced adduct by electro-spray mass spectrometry indicated a maximum of 1 mol of substrate incorporated/mol of subunit, correlating with a linear loss of enzyme activity. The reduced Schiff-base adduct was used to investigate substrate binding at the A-site by using rate-of-dialysis analysis. The affinity for ALA at the A-site of Mg alpha Zn beta ALAD was found to determine the Km for the reaction and was pH-dependent, with its affinity increasing from 1 mM at pH 6 to 70 microM at pH 8.5. The affinity of ALA at the P-site of Zn alpha An beta ALAD is proposed to limit the Km at pH values above 7, since the measured Kd for ALA at the A-site in 45 microM Tris, pH 8, was well below the observed Km (600 microM) under the same conditions. The amino group of the ALA molecule bound at the P-site was identified as a critical binding component for the A-site, explaining why ALA binding to ALAD is ordered, with the P-site ALA binding first. Structural requirements for ALA binding at the A- and P-sites have been identified: the P-site requires the carbonyl and carboxylate groups, whereas the A-site requires the amino, carbonyl and carboxylate groups of the substrate.
本文描述了一些实验,其中对5-氨基乙酰丙酸脱水酶(ALAD)的两个5-氨基乙酰丙酸(ALA)结合位点,即A位点和P位点的个体特性进行了研究。在催化金属离子(结合在α位点)结合时,A位点对ALA的结合亲和力大大增强(至少10倍)。催化金属离子Mg2+或Zn2+的性质,也导致底物Km、P位点对ALA的亲和力、钾离子和磷酸根离子的影响以及底物结合的pH依赖性出现重大变化。通过酶-底物席夫碱与NaBH4反应对P位点进行修饰,并用电喷雾质谱分析还原加合物,结果表明每摩尔亚基最多掺入1摩尔底物,这与酶活性的线性丧失相关。还原的席夫碱加合物用于通过透析速率分析研究A位点的底物结合。发现MgαZnβALAD的A位点对ALA的亲和力决定了反应的Km,且依赖于pH,其亲和力从pH 6时的1 mM增加到pH 8.5时的70 μM。有人提出,ZnαAnβALAD的P位点对ALA的亲和力在pH值高于7时限制了Km,因为在45 μM Tris,pH 8条件下,A位点上ALA的实测解离常数(Kd)远低于相同条件下观察到的Km(600 μM)。结合在P位点的ALA分子的氨基被确定为A位点的关键结合成分,这解释了为什么ALA与ALAD的结合是有序的,P位点的ALA先结合。已经确定了A位点和P位点上ALA结合的结构要求:P位点需要羰基和羧基,而A位点需要底物的氨基、羰基和羧基。