A Convolutional Neural Network-Based Approach for the Rapid Annotation of Molecularly Diverse Natural Products

Overview

Journal J Am Chem Soc

Publisher American Chemical Society

Specialty Chemistry

Date 2020 Feb 12

PMID 32045230

Citations 52

Authors

Raphael Reher

Hyun Woo Kim

Chen Zhang

Huanru Henry Mao

Mingxun Wang

Louis-Felix Nothias

Andres Mauricio Caraballo-Rodriguez

Evgenia Glukhov

Bahar Teke

Tiago Leao

Kelsey L Alexander

Brendan M Duggan

Ezra L Van Everbroeck

Pieter C Dorrestein

Garrison W Cottrell

William H Gerwick

Affiliations

Soon will be listed here.

Abstract

This report describes the first application of the novel NMR-based machine learning tool "Small Molecule Accurate Recognition Technology" (SMART 2.0) for mixture analysis and subsequent accelerated discovery and characterization of new natural products. The concept was applied to the extract of a filamentous marine cyanobacterium known to be a prolific producer of cytotoxic natural products. This environmental extract was roughly fractionated, and then prioritized and guided by cancer cell cytotoxicity, NMR-based SMART 2.0, and MS-based molecular networking. This led to the isolation and rapid identification of a new chimeric swinholide-like macrolide, symplocolide A, as well as the annotation of swinholide A, samholides A-I, and several new derivatives. The planar structure of symplocolide A was confirmed to be a structural hybrid between swinholide A and luminaolide B by 1D/2D NMR and LC-MS analysis. A second example applies SMART 2.0 to the characterization of structurally novel cyclic peptides, and compares this approach to the recently appearing "atomic sort" method. This study exemplifies the revolutionary potential of combined traditional and deep learning-assisted analytical approaches to overcome longstanding challenges in natural products drug discovery.

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