Torsten Bruhn scite author profile

This article outlines theory and practice of the comparison of calculated and experimental electronic circular dichroism (ECD) curves to determine the absolute configuration of chiral molecules. The focus is on the evaluation of excited-state calculations giving hints at the identification of the correct bandwidth and the application of the so-called "UV shift" as a correction factor. A similarity factor is introduced, which helps to quantify the degree of matching of curves. In addition, a few common errors are described that can be made during the measurements of ECD and UV spectra-and advice is given of how to avoid these mistakes. All equations mentioned in the article are implemented in our SpecDis software, which has been developed to rapidly compare calculated ECD and UV curves with experimental ones, and to produce graphics in publication quality.

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Good Computational Practice in the Assignment of Absolute Configurations by TDDFT Calculations of ECD Spectra

Pescitelli

2016

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Quantum-mechanical calculations of chiroptical properties have rapidly become the most popular method for assigning absolute configurations (AC) of organic compounds, including natural products. Black-box time-dependent Density Functional Theory (TDDFT) calculations of electronic circular dichroism (ECD) spectra are nowadays readily accessible to nonexperts. However, an uncritical attitude may easily deliver a wrong answer. We present to the Chirality Forum a discussion on what can be called good computational practice in running TDDFT ECD calculations, highlighting the most crucial points with several examples from the recent literature. Chirality 28:466-474, 2016. © 2016 Wiley Periodicals, Inc.

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The Assignment of Absolute Stereostructures through Quantum Chemical Circular Dichroism Calculations

et al. 2009

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The determination of the absolute configuration of a chiral compound of synthetic or natural origin is a problem that every organic chemist willl certainly have to face some day. An efficient and reliable method for the assignment of absolute stereostructures, independent of empirical CD rules, is the combination of experimental circular dichroism (CD) investigations with quantum chemical CD calculations. The availability of a broad variety of quantum chemical methods and the continuing appearance of new approaches permits -but also requires -the most appropriate method to be selected in each particular case, with respect to accuracy, time con-

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Cleavage of Four Carbon−Carbon Bonds during Biosynthesis of the Griseorhodin A Spiroketal Pharmacophore

et al. 2009

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The rubromycins, such as gamma-rubromycin, heliquinomycin, and griseorhodin A, are a family of extensively modified aromatic polyketides that inhibit HIV reverse transcriptase and human telomerase. Telomerase inhibition crucially depends on the presence of a spiroketal moiety that is unique among aromatic polyketides. Biosynthetic incorporation of this pharmacophore into the rubromycins results in a dramatic distortion of the overall polyketide structure, but how this process is achieved by the cell has been obscure. To identify the enzymes involved in spiroketal construction, we generated 14 gene-deletion variants of the griseorhodin A biosynthetic gene cluster isolated from the tunicate-associated bacterium Streptomyces sp. JP95. Heterologous expression and metabolic analysis allowed for an assignment of most genes to various stages of griseorhodin tailoring and pharmacophore generation. The isolation of the novel advanced intermediate lenticulone, which exhibits cytotoxic, antibacterial, and elastase-inhibiting activity, provided direct evidence that the spiroketal is formed by cleavage of four carbon-carbon bonds in a pentangular polyketide precursor. This remarkable transformation is followed by an epoxidation catalyzed by an unusual cytochrome P450/NADPH:ubiquinone oxidoreductase pair that utilizes a saturated substrate. In addition, the absolute configuration of griseorhodin A was determined by quantum-chemical circular dichroism (CD) calculations in combination with experimental CD measurements.

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Torsten Bruhn

SpecDis: Quantifying the Comparison of Calculated and Experimental Electronic Circular Dichroism Spectra

Good Computational Practice in the Assignment of Absolute Configurations by TDDFT Calculations of ECD Spectra

The Assignment of Absolute Stereostructures through Quantum Chemical Circular Dichroism Calculations

Cleavage of Four Carbon−Carbon Bonds during Biosynthesis of the Griseorhodin A Spiroketal Pharmacophore

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