Novozhilova Irina V, Coppens Philip, Lee Jonghyuk, Richter-Addo George B, Bagley Kimberly A
Department of Chemistry, University at Buffalo, The State University of New York, Buffalo, NY 14260, USA.
J Am Chem Soc. 2006 Feb 15;128(6):2093-104. doi: 10.1021/ja0567891.
A critical component of the biological activity of NO and nitrite involves their coordination to the iron center in heme proteins. Irradiation (330 < lambda < 500 nm) of the nitrosyl-nitro compound (TPP)Fe(NO)(NO(2)) (TPP = tetraphenylporphyrinato dianion) at 11 K results in changes in the IR spectrum associated with both nitro-to-nitrito and nitrosyl-to-isonitrosyl linkage isomerism. Only the nitro-to-nitrito linkage isomer is obtained at 200 K, indicating that the isonitrosyl linkage isomer is less stable than the nitrito linkage isomer. DFT calculations reveal two ground-state conformations of (porphine)Fe(NO)(NO(2)) that differ in the relative axial ligand orientations (i.e., GS parallel and GS perpendicular). In both conformations, the FeNO group is bent (156.4 degrees for GS parallel, 159.8 degrees for GS perpendicular) for this formally {FeNO}(6) compound. Three conformations of the nitrosyl-nitrito isomer (porphine)Fe(NO)(ONO) (MSa parallel, MSa perpendicular, and MSa(L)) and two conformations of the isonitrosyl-nitro isomer (porphine)Fe(ON)(NO(2)) (MSb parallel and MSb perpendicular) are identified, as are three conformations of the double-linkage isomer (porphine)Fe(ON)(ONO) (MSc parallel, MSc perpendicular, MSc(L)). Only 2 of the 10 optimized geometries contain near-linear FeNO (MSa(L)) and FeON (MSc(L)) bonds. The energies of the ground-state and isomeric structures increase in the order GS < MSa < MSb < MSc. Vibrational frequencies for all of the linkage isomers have been calculated, and the theoretical gas-phase absorption spectrum of (porphine)Fe(NO)(NO(2)) has been analyzed to obtain information on the electronic transitions responsible for the linkage isomerization. Comparison of the experimental and theoretical IR spectra does not provide evidence for the existence of a double linkage isomer of (TPP)Fe(NO)(NO(2)).
一氧化氮(NO)和亚硝酸盐生物活性的一个关键组成部分涉及它们与血红素蛋白中铁中心的配位。在11K下,对亚硝酰 - 硝基化合物(TPP)Fe(NO)(NO₂)(TPP = 四苯基卟啉二价阴离子)进行辐照(330<λ<500nm),会导致红外光谱发生变化,这与硝基到亚硝酸根以及亚硝酰到异亚硝酰的键连异构现象有关。在200K时仅得到硝基到亚硝酸根的键连异构体,这表明异亚硝酰键连异构体比亚硝酸根键连异构体稳定性更低。密度泛函理论(DFT)计算揭示了(卟啉)Fe(NO)(NO₂)的两种基态构象,它们在相对轴向配体取向上有所不同(即GS平行和GS垂直)。对于这个形式上的{FeNO}⁶化合物,在两种构象中,FeNO基团都是弯曲的(GS平行为156.4度,GS垂直为159.8度)。确定了亚硝酰 - 亚硝酸根异构体(卟啉)Fe(NO)(ONO)的三种构象(MSa平行、MSa垂直和MSa(L))以及异亚硝酰 - 硝基异构体(卟啉)Fe(ON)(NO₂)的两种构象(MSb平行和MSb垂直),还有双连键异构体(卟啉)Fe(ON)(ONO)的三种构象(MSc平行、MSc垂直、MSc(L))。在10种优化几何结构中只有2种包含近线性的FeNO(MSa(L))和FeON(MSc(L))键。基态和异构结构的能量按GS<MSa<MSb<MSc的顺序增加。已经计算了所有键连异构体的振动频率,并对(卟啉)Fe(NO)(NO₂)的理论气相吸收光谱进行了分析,以获取有关导致键连异构化的电子跃迁的信息。实验红外光谱与理论红外光谱的比较并未提供(TPP)Fe(NO)(NO₂)双连键异构体存在的证据。
