RESUMEN
Chiroptical broad-range spectral analysis extending from UV to mid-IR was employed to study a family of Co(II) N-(1-(aryl)ethyl)salicylaldiminato Schiff base complexes with pseudotetrahedral geometry associated with chirality-at-metal of the Δ/Λ type. While common chiral organic compounds have well-separated absorption and circular dichroism spectra (CD) in the UV/vis and IR regions, chiral Co(II) complexes feature an almost unique continuum of absorption and CD bands, which cover in sequence the UV, visible, near-IR (NIR), and IR regions of the electromagnetic spectrum. They can be collected in a single (chiro)optical superspectrum ranging from the UV (230 nm, 5.4 eV) to the mid-IR (1000 cm-1, 0.12 eV), which offers a fingerprint of the structure and stereochemistry of the metal complexes. Each region of the superspectrum contributes to one piece of information: the NIR-CD region, in combination with TDDFT calculations, allows a reliable assignment of the metal-centered chirality; the UV-CD region facilitates the analysis of the Δ/Λ diastereomeric equilibrium in solution; and the IR-VCD region contains a combination of low-lying metal-centered electronic states (LLES) and ligand-centered vibrations and displays characteristically enhanced and monosignate VCD bands. Circular dichroism in the NIR and IR regions is crucial to reveal the presence of d-d transitions of the Co(II) core which, due to the electric-dipole forbidden character, would be otherwise overlooked in the corresponding absorption spectra.
RESUMEN
Studying enzymatic reductions of substrates with more than a single keto group is challenging, as the carbonyl reduction can create a vast array of regio- and stereoisomers. If used as reference compounds, regio- and stereopure hydroxy ketides could facilitate the characterization of reductases with unclear regio- and stereoselectivity. We have combined nonenzymatic and enzymatic reduction and oxidation steps to obtain all four regio- and stereoisomers of tert-butyl hydroxyoxohexanoates in high optical purity (enantiomeric ratio (er) of 99 : 1 for the δ-hydroxy-ß-keto isomers; er of >97 : 3 for the ß-hydroxy-δ-keto isomers). Furthermore, we have prepared seven of the eight possible regioisomers and diastereomers of γ-methylated hydroxyoxohexanoates. These 11 compounds allowed unraveling the complex stereoselectivity of ß,δ-diketo ester reductions catalyzed by carbonyl reductase S1 from Candida magnoliae (CMCR-S1). Our analysis shows that the regio- and stereoselectivity of CMCR-S1-catalyzed reductions is highly sensitive toward modifications at the C-terminus of CMCR-S1: in addition to the expected δ-hydroxy product, the variant with a C-terminal His-tag also led to formation of ß-hydroxy by-products with high optical purity.
