Khangulov S V, Pessiki P J, Barynin V V, Ash D E, Dismukes G C
Henry H. Hoyt Laboratory, Department of Chemistry, Princeton University, New Jersey 08544.
Biochemistry. 1995 Feb 14;34(6):2015-25. doi: 10.1021/bi00006a023.
The dimanganese (II,II) catalase from Thermus thermophilus, MnCat(II,II), arginase from rat liver, Arg(II,II), and several dimanganese(II,II) compounds, LMn2XY2, which are functional catalase mimics, all possess a pair of coupled Mn(II) ions in their catalytic sites. For each of these, we have measured by EPR spectroscopy the relative energies separating the three lowest electronic states (singlet, triplet, and quintet), described a general method for extracting the individual spectra for these states by multicomponent analysis, and determined the Mn-Mn separation. The triplet-singlet and quintet-singlet energy gaps were modeled well by fitting the temperature dependence of the EPR intensities to a Boltzmann expression for a pair of Mn(II) ions coupled by isotropic Heisenberg spin exchange (-2JS1S2). This dependence indicates diamagnetic ground states with delta E10 (cm-1) = magnitude of 2J = 4 and 11.2 cm-1 for Arg-(II,II)(+borate) and MnCat(II,II)(phosphate), respectively. This large difference in magnitude of 2J reflects either a difference in the bridging ligands or, possibly, a weaker ligand field (larger ionization potential) for the Mn(II) ions in arginase. In n-butanol/CH2Cl2 the triplet-singlet energy gaps for LMn2(CH3CO2)2 (1), [LMn2(CH3CO2)3] (2), and [LMn2Cl3] (3), where HL = N,N,N',N'-tetrakis(2-methylenebenzimidazole)-1,3-diaminopropan+ ++-2-ol, are 23-24 cm-1. Comparison of the Heisenberg exchange interaction constants for more than 30 dimanganese(II,II) complexes suggests a possible bridging structure of (mu-OH)(mu-carboxylate)1-2 for MnCat(II,II), while the 3-fold weaker coupling in Arg(II,II) suggests mu-aqua in place of mu-hydroxide. EPR spectra of both the triplet and quintet electronic states were extracted and found to exhibit zero-field splittings (ZFS) and resolved 55Mn hyperfine splittings indicating spin-coupled Mn2-(II,II) species. The major ZFS interaction could be attributed to the magnetic dipole-dipole interaction between the Mn(II) ions. A linear correlation is observed between the crystallographically determined Mn-Mn distance and the ZFS of the quintet state (D2) for five dimanganese pairs for which both data sets are available. Using this correlation, the Mn-Mn distance in Arg(II,II) is predicted to be 3.36-3.57 A for the native enzyme (multiple forms) and 3.59 A for MnCat(II,II)(phosphate). Addition of the inhibitor borate to Arg(II,II) simplifies the ZFS, indicative of conversion to a single species with mean Mn-Mn separation of 3.50 A. The second metal ion in dinuclear complexes possessing a shared bridging ligand has been shown to attenuate the strength of the mu-ligand field potential, as monitored by the strength of the single ion ZFS.(ABSTRACT TRUNCATED AT 250 WORDS)
嗜热栖热菌的二价锰(II,II)过氧化氢酶(MnCat(II,II))、大鼠肝脏的精氨酸酶(Arg(II,II))以及几种作为功能性过氧化氢酶模拟物的二价锰(II,II)化合物LMn2XY2,在其催化位点均含有一对耦合的Mn(II)离子。对于其中每一种,我们通过电子顺磁共振光谱法测量了分离三个最低电子态(单重态、三重态和五重态)的相对能量,描述了一种通过多组分分析提取这些态各自光谱的通用方法,并确定了Mn-Mn间距。通过将电子顺磁共振强度的温度依赖性拟合到由各向同性海森堡自旋交换(-2JS1S2)耦合的一对Mn(II)离子的玻尔兹曼表达式,对三重态-单重态和五重态-单重态能隙进行了很好的建模。这种依赖性表明,对于精氨酸酶-(II,II)(+硼酸盐)和MnCat(II,II)(磷酸盐),其基态为抗磁性,δE10(厘米-1)= 2J的大小分别为4和11.2厘米-1。2J大小的这种巨大差异反映了桥连配体的差异,或者可能是精氨酸酶中Mn(II)离子的配体场较弱(电离势较大)。在正丁醇/二氯甲烷中,LMn2(CH3CO2)2(1)、[LMn2(CH3CO2)3](2)和[LMn2Cl3](3)(其中HL = N,N,N',N'-四(2-亚甲基苯并咪唑)-1,3-二氨基丙烷-2-醇)的三重态-单重态能隙为23 - 24厘米-1。对30多种二价锰(II,II)配合物的海森堡交换相互作用常数进行比较表明,MnCat(II,II)可能具有(μ-OH)(μ-羧酸盐)1 - 2的桥连结构,而Arg(II,II)中弱3倍的耦合表明μ-水取代了μ-氢氧化物。提取了三重态和五重态电子态的电子顺磁共振光谱,发现它们表现出零场分裂(ZFS)并分辨出55Mn超精细分裂,表明存在自旋耦合的Mn2-(II,II)物种。主要的ZFS相互作用可归因于Mn(II)离子之间的磁偶极-偶极相互作用。对于五个同时有晶体学测定的Mn-Mn距离和五重态(D2)的ZFS的二价锰对,观察到两者之间存在线性相关性。利用这种相关性,预测天然酶(多种形式)中Arg(II,II)的Mn-Mn距离为3.36 - 3.57 Å,MnCat(II,II)(磷酸盐)的为3.59 Å。向Arg(II,II)中加入抑制剂硼酸盐会简化ZFS,这表明转化为平均Mn-Mn间距为3.50 Å的单一物种。已表明,具有共享桥连配体的双核配合物中的第二个金属离子会减弱μ-配体场势的强度,这可通过单离子ZFS的强度来监测。
