Pfaltz, Andreas;
Livingston, Douglas A.;
Jaun, Bernhard;
Diekert, Gabriele;
Thauer, Rudolf K.;
Eschenmoser, Albert
Zur Kenntnis des Faktors F430 aus methanogenen Bakterien: Über die Natur der Isolierungsartefakte von F430, ein Beitrag zur Chemie von F430 und zur konformationellen Stereochemie der Ligandperipherie von hydroporphinoiden Nickel(II)‐Komplexen
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Media type:
E-Article
Title:
Zur Kenntnis des Faktors F430 aus methanogenen Bakterien: Über die Natur der Isolierungsartefakte von F430, ein Beitrag zur Chemie von F430 und zur konformationellen Stereochemie der Ligandperipherie von hydroporphinoiden Nickel(II)‐Komplexen
Contributor:
Pfaltz, Andreas;
Livingston, Douglas A.;
Jaun, Bernhard;
Diekert, Gabriele;
Thauer, Rudolf K.;
Eschenmoser, Albert
Published:
Wiley, 1985
Published in:
Helvetica Chimica Acta, 68 (1985) 5, Seite 1338-1358
Description:
Factor F430 from Methanogenic Bacteria: On the Nature of the Isolation Artefacts of F430, a Contribution to the Chemistry of F430 and the Conformational Stereochemistry of the Ligand Periphery of Hydroporphinoid Nickel(II) ComplexesFactor F430 (1), a coenzyme from methanogenic bacteria, when heated in aqueous solution isomerizes to 12,13‐di‐epi‐F430 (5) via 13‐epi‐F430 (3). The equilibrium mixture of the three F430 isomers in aqueous phosphate buffer solution (pH 7, 100°) contains 88 % of 5, 8 % of 3, and 4 % of 1 (Scheme 1). The structural assignment for the F430 isomers rests on FAB‐MS‐, UV/VIS‐, 1H‐ and 13C‐NMR spectra of their pentamethyl esters. Chemical proof for the double epimerization at the two chiral centers of F430's ring C was provided by ozonolytic degradation of the di‐epimer to give a ring‐C‐derived succinimide derivative that was shown to be the enantiomer of the one previously obtained by ozonolysis of F430M (see Scheme 2). The two F430 ring‐C epimers 3 and 5 are the isolation artefacts described in the earlier F430 literature. F430 is susceptible to autoxidation in air and the product, that absorbs at 560 nm, was shown to be the 12,13‐didehydro derivative 8 of F430 by spectroscopic characterization of its pentamethyl ester 9. The dehydrogenation product 8 can be diastereoselectively reduced with Zn in AcOH to give natural F430 as the main product rather than the thermodynamically more stable F430‐di‐epimer (Scheme 3). In the double epimerization of F430, the two ring‐C side chains change from a trans‐quasi‐diaxial arrangement to the (locally) enantiomorphic position in which the same side chains are again in a trans‐quasi‐diaxial arrangement. This equilibrium paradox as well as the kinetic diastereoselectivity of the reduction of 12,13‐didehydro‐F430 (8) are rationalized to be consequences of the general phenomenon documented earlier (see the preceding paper) according to which hydroporphinoid Ni(II) complexes all show a characteristic conformational ruffling of their ligand system due to the tendency of the (small) Ni(II) ion to contract the size of the ligand's central coordination hole (see Fig. 5 and 6).