| 159649-32-8

• 分子结构分类: 有机化合物 - 有机氮化合物
• CAS: 159649-32-8
• 化学式: C₃₃H₂₉N₃NiSe₂
• 分子量: 684.223
• InChiKey: JSGVDZFBGQEOLI-ANDKACCMSA-L

计算性质

• 辛醇/水分配系数(LogP)：
  None
• 重原子数：
  None
• 可旋转键数：
  None
• 环数：
  None
• sp3杂化的碳原子比例：
  None
• 拓扑面积：
  None
• 氢给体数：
  None
• 氢受体数：
  None

反应信息

• 作为反应物：
  描述：

  在 Na₂S₂O₄ 作用下， 以 N,N-二甲基甲酰胺 为溶剂， 生成
  参考文献：
  名称：

  Toward Functional Models of the Nickel Sites in [FeNi] and [FeNiSe] Hydrogenases: Syntheses, Structures, and Reactivities of Nickel(II) Complexes Containing [NiN3S2] and [NiN3Se2] Chromophores

  摘要：

  The reaction of [Ni(terpy)Cl-2] with similar to 2 equiv of 2,4,6-(Me)(3)C6H2Se- in 3:1 acetonitrile/ethanol affords [Ni(terpy)(2,4,6-(Me)3C(6)H(2)Se)(2)] (7), while [Ni(DAPA)Cl-2] (DAPA = 2,6-bis[1-(phenylimino)ethyl]pyridine) reacts with similar to 2 equiv of PhSe(-) and PhSe(-) in neat ethanol or acetonitrile to yield [Ni(DAPA)(SPh)(2)] (8) and [Ni(DAPA)-(SePh)(2)] (9), respectively. All three complexes contain the distorted trigonal bipyramidal (TBP) NiN(3)E(2) (E = S, Se) chromophore. Previous X-ray absorption spectroscopic data have indicated a distorted TBP NiN3S2 coordination for the nickel site of the hydrogenase (H(2)ase) from Thiocapsa roseopersicina. Complex 7 crystallizes in the monoclinic space group P2(1)/n with a = 13.170(6) Angstrom, b = 16.091(5) A, c = 15.111(8) Angstrom, beta = 114.42(2)degrees, V = 2916(2) Angstrom(3), and Z = 4. The structure of 7 was refined to R = 4.78% on the basis of 2730 reflections (I > 4 sigma(I). Complex 8.CH3-CN crystallizes in the monoclinic space group P2(1)/c with a = 23.012(7) Angstrom, b = 17.814(5) Angstrom, c = 15.698(4) Angstrom, beta = 108.52(2)degrees, V = 6099(5) Angstrom(3), and Z = 8. The structure of 8.CH3CN was refined to R = 6.46% on the basis of 6133 reflections (I > 4 sigma(I)). Complex 9.CH3CN also crystallizes in the monoclinic space group P(2)1/c with a = 23.209(2) Angstrom, b = 17.960(1) Angstrom, c = 15.749(1) Angstrom, beta = 108.482(6)degrees, V = 6225 Angstrom(3) and Z = 8, The structure of 9.CH3CN was refined to 3.90% on the basis of 5808 reflections (I > 4 sigma(I)). Reduction of the terpy analogue 7 with aqueous dithionite gives rise to the corresponding Ni(I) complex which binds CO (reversibly) and H-. The EPR parameters of the CO and hydride adducts resemble the Ni-CO and Ni-C signal of the H(2)ases. Much like the other terpy analogues reported previously by this group, oxidation of 7 affords unstable Ni(III) products in low yields. The two DAPA analogues (8 and 9), on the other hand, are readily oxidized and reduced by biologically relevant oxidants and reductants, and the transformation Ni(III) <-- Ni(II)) --> Ni(I) is reversible. The Ni(III) species (10 and 13) derived from 8 and 9 via oxidation with [Fe(CN)(6)](3-) are comparatively stable and do not bind CO (or H-). The single electron in both 10 and 13 resides in the d(z2) orbital. Upon reduction with aqueous dithionite, 8 and 9 produce the corresponding Ni(I) species 11 and 14 with the single electron in the d(x2-y2) orbital. These Ni(I) complexes are quite stable at low temperatures but slowly lose thiolates/selenolates at room temperature to give [Ni(DAPA)(solv)(2)](+). Both 11 and 14 bind CO reversibly. The affinity of the Ni(I) (but not the Ni(III)) model complexes toward CO strongly suggests the presence of Ni(I) in the C form of the H(2)ases since the enzymes bind CO only in the Ni-C form. Reaction of NaBH4 with 8 and 9 results in the hydride adducts 19 and 20. These hydride adducts are stable under basic conditions. The absence of any detectable proton hyperfine coupling indicates that the H- ligand is located at the basal plane of the Ni(I) center. The EPR parameters of the CO and hydride adducts are quite similar to those of the Ni-CO and Ni-C signals of the H(2)ases.Under basic conditions, both 8 and 9 react with dihydrogen at ambient temperature and pressure to afford the hydride adducts 19 and 20 in significant yields. This reaction is quite remarkable since the model complexes mimic the reductive activation step of the biological nickel site in such a reaction to ultimately produce Ni-C-like signals. Taken together, the present results strongly suggest a Ni(I)-H- formalism for the nickel site in the C form of the H(2)ases. In addition, enhancement of the intensities of the EPR signals of the hydride adducts in the presence of a base indicates heterolytic cleavage of H (coordinated or not) at the Ni(I) site of the model complexes and probably also at the enzyme active sites.

  DOI：

  10.1021/ja00110a013
• 作为产物：
  描述：

  在 (N(C₂H₅)4)3[Fe(CN)6] 作用下， 生成
  参考文献：
  名称：

  Toward Functional Models of the Nickel Sites in [FeNi] and [FeNiSe] Hydrogenases: Syntheses, Structures, and Reactivities of Nickel(II) Complexes Containing [NiN3S2] and [NiN3Se2] Chromophores

  摘要：

  The reaction of [Ni(terpy)Cl-2] with similar to 2 equiv of 2,4,6-(Me)(3)C6H2Se- in 3:1 acetonitrile/ethanol affords [Ni(terpy)(2,4,6-(Me)3C(6)H(2)Se)(2)] (7), while [Ni(DAPA)Cl-2] (DAPA = 2,6-bis[1-(phenylimino)ethyl]pyridine) reacts with similar to 2 equiv of PhSe(-) and PhSe(-) in neat ethanol or acetonitrile to yield [Ni(DAPA)(SPh)(2)] (8) and [Ni(DAPA)-(SePh)(2)] (9), respectively. All three complexes contain the distorted trigonal bipyramidal (TBP) NiN(3)E(2) (E = S, Se) chromophore. Previous X-ray absorption spectroscopic data have indicated a distorted TBP NiN3S2 coordination for the nickel site of the hydrogenase (H(2)ase) from Thiocapsa roseopersicina. Complex 7 crystallizes in the monoclinic space group P2(1)/n with a = 13.170(6) Angstrom, b = 16.091(5) A, c = 15.111(8) Angstrom, beta = 114.42(2)degrees, V = 2916(2) Angstrom(3), and Z = 4. The structure of 7 was refined to R = 4.78% on the basis of 2730 reflections (I > 4 sigma(I). Complex 8.CH3-CN crystallizes in the monoclinic space group P2(1)/c with a = 23.012(7) Angstrom, b = 17.814(5) Angstrom, c = 15.698(4) Angstrom, beta = 108.52(2)degrees, V = 6099(5) Angstrom(3), and Z = 8. The structure of 8.CH3CN was refined to R = 6.46% on the basis of 6133 reflections (I > 4 sigma(I)). Complex 9.CH3CN also crystallizes in the monoclinic space group P(2)1/c with a = 23.209(2) Angstrom, b = 17.960(1) Angstrom, c = 15.749(1) Angstrom, beta = 108.482(6)degrees, V = 6225 Angstrom(3) and Z = 8, The structure of 9.CH3CN was refined to 3.90% on the basis of 5808 reflections (I > 4 sigma(I)). Reduction of the terpy analogue 7 with aqueous dithionite gives rise to the corresponding Ni(I) complex which binds CO (reversibly) and H-. The EPR parameters of the CO and hydride adducts resemble the Ni-CO and Ni-C signal of the H(2)ases. Much like the other terpy analogues reported previously by this group, oxidation of 7 affords unstable Ni(III) products in low yields. The two DAPA analogues (8 and 9), on the other hand, are readily oxidized and reduced by biologically relevant oxidants and reductants, and the transformation Ni(III) <-- Ni(II)) --> Ni(I) is reversible. The Ni(III) species (10 and 13) derived from 8 and 9 via oxidation with [Fe(CN)(6)](3-) are comparatively stable and do not bind CO (or H-). The single electron in both 10 and 13 resides in the d(z2) orbital. Upon reduction with aqueous dithionite, 8 and 9 produce the corresponding Ni(I) species 11 and 14 with the single electron in the d(x2-y2) orbital. These Ni(I) complexes are quite stable at low temperatures but slowly lose thiolates/selenolates at room temperature to give [Ni(DAPA)(solv)(2)](+). Both 11 and 14 bind CO reversibly. The affinity of the Ni(I) (but not the Ni(III)) model complexes toward CO strongly suggests the presence of Ni(I) in the C form of the H(2)ases since the enzymes bind CO only in the Ni-C form. Reaction of NaBH4 with 8 and 9 results in the hydride adducts 19 and 20. These hydride adducts are stable under basic conditions. The absence of any detectable proton hyperfine coupling indicates that the H- ligand is located at the basal plane of the Ni(I) center. The EPR parameters of the CO and hydride adducts are quite similar to those of the Ni-CO and Ni-C signals of the H(2)ases.Under basic conditions, both 8 and 9 react with dihydrogen at ambient temperature and pressure to afford the hydride adducts 19 and 20 in significant yields. This reaction is quite remarkable since the model complexes mimic the reductive activation step of the biological nickel site in such a reaction to ultimately produce Ni-C-like signals. Taken together, the present results strongly suggest a Ni(I)-H- formalism for the nickel site in the C form of the H(2)ases. In addition, enhancement of the intensities of the EPR signals of the hydride adducts in the presence of a base indicates heterolytic cleavage of H (coordinated or not) at the Ni(I) site of the model complexes and probably also at the enzyme active sites.

  DOI：

  10.1021/ja00110a013