Unequivocal Determination of Caulamidines A and B: Application and Validation of New Tools in the Structure Elucidation Tool Box

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2018 Apr 6

PMID 29619201

Citations 22

Authors

Dennis J Milanowski

Naoya Oku

Laura K Cartner

Heidi R Bokesch

R Thomas Williamson

Josep Sauri

Yizhou Liu

Kirill A Blinov

Yuanqing Ding

Xing-Cong Li

Daneel Ferreira

Larry A Walker

Shabana Khan

Michael T Davies-Coleman

James A Kelley

James B McMahon

Gary E Martin

Kirk R Gustafson

Affiliations

Soon will be listed here.

Abstract

Ambiguities and errors in the structural assignment of organic molecules hinder both drug discovery and total synthesis efforts. Newly described NMR experimental approaches can provide valuable structural details and a complementary means of structure verification. The caulamidines are trihalogenated alkaloids from a marine bryozoan with an unprecedented structural scaffold. Their unique carbon and nitrogen framework was deduced by conventional NMR methods supplemented by new experiments that define 2-bond heteronuclear connectivities, reveal very long-range connectivity data, or visualize the Cl isotopic effect on chlorinated carbons. Computer-assisted structural elucidation (CASE) analysis of the spectroscopic data for caulamidine A provided only one viable structural alternative. Anisotropic NMR parameters, specifically residual dipolar coupling and residual chemical shift anisotropy data, were measured for caulamidine A and compared to DFT-calculated values for the proposed structure, the CASE-derived alternative structure, and two energetically feasible stereoisomers. Anisotropy-based NMR experiments provide a global, orthogonal means to verify complex structures free from investigator bias. The anisotropic NMR data were fully consistent with the assigned structure and configuration of caulamidine A. Caulamidine B has the same heterocyclic scaffold as A but a different composition and pattern of halogen substitution. Caulamidines A and B inhibited both wild-type and drug-resistant strains of the malaria parasite at low micromolar concentrations, yet were nontoxic to human cells.

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