Bioorganic asymmetric reduction of carbonyl compounds is one of the most important fundamental and practical reactions for producing chiral alcohols. The stereoselective bioreduction of prochiral ketones of benzofuran derivatives in the presence of yeast‐like fungus Aureobasidium pullulans contained in the antifungal Boni Protect agent was studied. Biotransformations were carried out under moderate conditions in an aqueous and two‐phase system and without multiplication of the bioreagent. Despite similar chemical structure, each of the used ketone has been reduced with varying efficiency and selectivity. One of the reasons for these results is the presence of a whole set of oxidoreductases in A. pullulans cells that are sensitive to the smallest changes in the structure of prochiral substrate. The unsymmetrical methyl ketones were biotransformed with the highest selectivity. Aureobasidium pullulans microorganism is less effective in the reduction of unsymmetrical halomethyl ketones. The presence of a heteroatom in the alkyl group significantly decreases the selectivity of the process. Finally, as a result of the preferred hydride ion transfer from the dihydropyridine ring of the cofactor to the carbonyl double bond on the re side, secondary alcohols of the S and R configuration were obtained with moderate to high enantioselectivity (55‐99%).
The cascade process of a dynamic chirality transmission from the permanent chirality center to the stereodynamic triphenylmethyl group has been studied for series of optically active trityl derivatives. The structural analysis, carried out with the use of complementary methods, enabled us to determine the mechanism of chirality transfer. The process of chirality transmission involves a set of weak but complementary electrostatic interactions. The induction of helicity in a trityl propeller is revealed by rising non-zero cotton effects in the area of trityl UV-absorption. The presence of an additional stereogenic center in close proximity to the trityl-containing stereogenic center significantly affects the sign and, to a lesser extent, magnitude of the respective cotton effects. Despite the bulkiness of the trityl, in the crystalline phase, the molecules under study strictly fill the space. In the crystal, molecules form aggregates stabilized by OH•••O hydrogen bonds. However, the presence of two trityl groups precludes formation of OH•••O hydrogen bonding. Additionally, the trityl group seems to be responsible for the formation of the solid solutions by e.g., racemates of trans- and cis-2-tritylcyclohexanol. Therefore, the trityl group acts as a supramolecular protective group, which in turn can be used in the crystal engineering.
A series of new benzofuryl α-azole ketones was synthesized and reduced by asymmetric transfer hydrogenation (ATH). Novel benzofuryl β-amino alcohols bearing an imidazolyl and triazolyl substituents were obtained with excellent enantioselectivity (96–99%). The absolute configuration (R) of the products was confirmed by means of electronic circular dichroism (ECD) spectroscopy supported by theoretical calculations. Selected benzofuryl α-azole ketones were also successfully asymmetrically bioreduced by fungi of Saccharomyces cerevisiae and Aureobasidium pullulans species. Racemic and chiral β-amino alcohols, as well as benzofuryl α-amino and α-bromo ketones were evaluated for their antibacterial and antifungal activities. From among the synthesized β-amino alcohols, the highest antimicrobial activity was found for (R)-1-(3,5-dimethylbenzofuran-2-yl)-2-(1H-imidazol-1-yl)ethan-1-ol against S. aureus ATCC 25923 (MIC = 64, MBC = 96 μg mL−1) and (R)-1-(3,5-dimethylbenzofuran-2-yl)-2-(1H-1,2,4-triazol-1-yl)ethan-1-ol against yeasts of M. furfur DSM 6170 (MIC = MBC = 64 μg mL−1). In turn, from among the tested ketones, 1-(benzofuran-2-yl)-2-bromoethanones (1–4) were found to be the most active against M. furfur DSM 6170 (MIC = MBC = 1.5 μg mL−1) (MIC—minimal inhibitory concentration, MBC—minimal biocidal concentration).
A series of artificial triarylmethanols
has been synthesized and
studied toward the possibility of exhibiting an induced optical activity.
The observed chiroptical response of these compounds resulted from
the chiral conformation of a triarylmethyl core. The chirality induction
from a permanent chirality element to the liable triarylmethyl core
proceeds as a cooperative and cascade process. The OH···O(R)
and/or (H)O···H
ortho
C hydrogen
bond formation along with the C–H···π
interactions seem to be the most important factors that control efficiency
of the chirality induction. The position of chiral and methoxy electron-donating
groups within a trityl skeleton affects the amplitude of observed
Cotton effects and stability of the trityl carbocations. In the neutral
environment, the most intense Cotton effects are observed for
ortho
-substituted derivatives, which undergo a rapid decomposition
associated with the complete decay of ECD signals upon acidification.
From all of the in situ generated stable carbocations, only two exhibit
intense Cotton effects in the low energy region at around 450 nm.
The formation of carbocations is reversible; after alkalization, the
ions return to the original neutral forms. Unlike most triarylmethyl
derivatives known so far, in the crystal, the triarylmethanol,
para
-substituted with the chiral moiety, shows a propensity
for a solid-state sorting phenomenon.
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