Cobalt III amino acid

All these methods have found applications in theoretical considerations of numerous problems more or less directly related to solvent extraction. The MM calculated structures and strain energies of cobalt(III) amino acid complexes have been related to the experimental distribution of isomers, their thermodynamic stability, and some kinetic data connected with transition state energies [15]. The influence of steric strain upon chelate stability, the preference of metal ions for ligands forming five- and six-membered chelate rings, the conformational isomerism of macrocyclic ligands, and the size-match selectivity were analyzed [16] as well as the relation between ligand structures, coordination stereochemistry, and the thermodynamic properties of TM complexes [17]. 

O-Donor Ligands. A number of new cobalt(iii) complexes containing a single bi-dentate o-dihydroxy aromatic ligand and amine counter ligands have been prepared by methods similar to those used for cobalt(in) amino-acid complexes. The reduction of polynuclear o-terephthalatocobalt(in) complexes by Cr and has been studied. Kinetic data from the reduction of trisoxalatocobaltate(m) by... 

The compounds studied are the substituted triethylenetetra-aminecobalt(III) amino acid complexes depicted in Figure 1. Formally the A Bj chromophore will be the triethylenetetraamine-cobalt(III) glycinato moiety (compounds 1 and 7, identified in Figure 1) (with an associated configurational effect) and the optically active (Bj) chromophores will be represented by the various R2 substituents at the a-carbon of the chelated glycine... 

As shown in Scheme 1, NHase catalyzes the conversion of nitriles to amides 4), The active site contains either a non-corrin cobalt(III) or non-heme iron(III). Amino acid sequence comparisons have shown that the primary coordination sphere is conserved regardless of the identity of the metal center and consists of a -C-S-L-C-S-C- motif (5). EPR studies on Fe-NHase revealed the iron center maintains a low-spin Fe(III) state throughout the catalytic cycle, and that the iron center has a variable coordination site for substrate interaction (6). These findings are consistent with the hypothesis that the enzyme functions solely as a hydrolytic (i.e., redox-inactive) catalyst. Incubation of the enzyme with nitric oxide in the dark inactivates the enzyme. Exposure to light was found to reinstate activity with concomitant loss of NO, thus revealing a novel photo-regulatory mechanism (7-70). 

Fanali, S., Ossicini, L., Foret, F., and Bocek, R, Resolution of optical isomers by capillary zone electrophoresis study of enantiomeric and distereoisomeric cobalt (III) complexes with ethylenediamine and amino acid ligands, /. Microcol. Sep., 1, 190, 1989. 

The variety and extent of research devoted to ligands carrying both O- and N-donors is simply immense. The type of cobalt(III) systems extant include amino acids, amino alcohols, amino ethers, amino phosphates, amino phenolates, as well as amide and imine analogs of these. These are met as simple chelates or more elaborate polydentates. Here, we highlight a strictly limited selection of examples to illustrate the type of systems reported no attempt at exhaustive review has been made. 

Kinetic parameters k, often also and AS, occasionally AV ) for formation and dissociation of several pentacyanoferrate(II) complexes [Fe(CN)5L]" have been established. Ligands L include several S- and A-donor heterocycles,4-methyl- and 4-amino-pyridines, a series of alkylamines, 3- and 4-hydroxy- and 3- and 4-methoxy-pyridines, several amino acids, nicotinamide, " 4-pyridine aldoxime, 3-Me and 3-Ph sydnones, several bis-pyridine ligands,neutral, protonated, and methylated 4,4 -bipyridyl, 1,2-bis(4-pyridyl)ethane and traTO-l,2-bis0-pyridyl)ethene, pyrazine- 4,4 -bipyridyl- and bis(4-pyridyl)ethyne-pentaammine-cobalt(III), edta-ruthenium(III), and pentaammineruthenium-(II)and-(III) complexes of... 

Schollkopf, U. Enantioselective Synthesis of Nonproteinogenic Amino Acids. 109, 65-84 (1983). Shibata, M. Modern Syntheses of Cobalt(III) Complexes. 110, 1-120 (1983). ... 

Eujii Y, Matsutani K, Kikuchi K. Formation of a specific coordination cavity for a chiral amino-acid by template synthesis of a polymer Schiff-base cobalt(III) complex. Chem Commun 1985 415-417. 

Complexes of other amino acids or their derivatives with cobalt(II) that have been investigated include dipeptides (120) these complexes have long been known to absorb dioxygen. For example, the mononuclear cobalt(II) complex of N, N,N", N "-diglycylethylenediaminete-traacetic acid (121) absorbs one mole of dioxygen per two moles of complex. This system has been proposed as a simple, convenient model system for the study of dioxygen complexes of cobalt(II) peptides in solution because of its relatively slow conversion to the irreversibly formed cobalt(III) dioxygen complex. 

Corey and Bailar s analysis (5) also predicts that the stability difference between the d and l forms of a-fm-[L-( + )-alanine]cobalt(III) would not be great. The five-membered amino acid rings are near planar (17), and the difference between axial and equatorial substituents is much less distinct. This accounts for Lifschitz s partial isolation of both d- and L-a forms (18), whereas the rra-( —)-propylenediamine system gave predominantly one isomer. However, it has been pointed out recently (9) that for [Cu(gly-cine)2] H20 (17) the Cu and N atoms are on opposite sides of the... 

For tridentate amino acids with three non-equivalent donor atoms such as L-aspartic acid or L-cysteine, the isomers possible are illustrated below (252-254). There have been a number of reports of the preparation of L-aspartic acid complexes.1180,1181,1182. In the earlier work the isomers were not identified, however in the later study, the complexes were tentatively identified by comparison of their spectroscopic properties with those of the corresponding cobalt(III) complexes.1183 The order of elution of the complexes on HPLC was also similar to that observed for the corresponding cobalt(III) complexes. Mixed complexes containing l- or D-aspartate and L-histidine were also prepared.1182 A crystal structure of one salt obtained from this kind of system, bis(L-histidinato-0,Ar,Ar )chromium(III) nitrate, has been determined.1184... 

Sutton, P. A., and D. A. Buckingham, Cobalt(III)-promoted hydrolysis of amino acid esters and peptides and the synthesis of small peptides , Acc. Chem. Res., 20, 357-364 (1987). 

The resolution of racemic amino acid mixtures via coordination to a metal ion has been a popular field of study. [Cu(L-aa)2] complexes can be used to resolve DL-Asp, dl-G1u and DL-His.58,59 (—)-[Co(EDTA)] has been used to resolve DL-His having first resolved the racemic [Co(EDTA)] ion using the L-histidinium cation.60 Schiff base complexes of both Co111 and Ni11 have also been used to resolve amino acids.61,62 A more esoteric finding is that the bacterium Enterobacter cloacae prefers to metabolize the A-( —) isomer of/ac-[Co(GlyO)3] rather than the A-(+) form,63 an observation reminiscent of that made by Bailar using tris(ethylenediamine)cobalt(III) salts. 

Coordinated a-amino amides can be formed by the nucleophilic addition of amines to coordinated a-amino esters (see Chapter 7.4). This reaction forms the basis of attempts to use suitable metal coordination to promote peptide synthesis. Again, studies have been carried out using coordination of several metals and an interesting early example is amide formation on an amino acid imine complex of magnesium (equation 75).355 However, cobalt(III) complexes, because of their high kinetic stability, have received most serious investigation. These studies have been closely associated with those previously described for the hydrolysis of esters, amides and peptides. Whereas hydrolysis is observed when reactions are carried out in water, reactions in dimethyl-formamide or dimethyl sulfoxide result in peptide bond formation. These comparative results are illustrated in Scheme 91.356-358 The key intermediate (126) has also been reacted with dipeptide... 

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