Nonenzymatic Reactions in Natural Product Formation.

Biosynthetic mechanisms of natural products primarily depend on systems of protein catalysts. However, within the field of biosynthesis, there are cases in which the inherent chemical reactivity of metabolic intermediates and substrates evades the involvement of enzymes. These reactions are difficult to characterize based on their reactivity and occlusion within the milieu of the cellular environment.

Synthetic-Bioinformatic Natural Product Antibiotics with Diverse Modes of Action.

Bacterial natural products have inspired the development of numerous antibiotics in use today. As resistance to existing antibiotics has become more prevalent, new antibiotic lead structures and activities are desperately needed. An increasing number of natural product biosynthetic gene clusters, to which no known molecules can be assigned, are found in genome and metagenome sequencing data.

Mapping Interactions of Microbial Metabolites with Human G-Protein-Coupled Receptors.

Despite evidence linking the human microbiome to health and disease, how the microbiota affects human physiology remains largely unknown. Microbiota-encoded metabolites are expected to play an integral role in human health. Therefore, assigning function to these metabolites is critical to understanding these complex interactions and developing microbiota-inspired therapies.

Accessing Bioactive Natural Products from the Human Microbiome.

Natural products have long played a pivotal role in the development of therapeutics for a variety of diseases. Traditionally, soil and marine environments have provided a rich reservoir from which diverse chemical scaffolds could be discovered. Recently, the human microbiome has been recognized as a promising niche from which secondary metabolites with therapeutic potential have begun to be isolated.

Ammosamides Unveil Novel Biosynthetic Machinery.

In this issue of Cell Chemical Biology, Jordan and Moore (2016) present a thorough biosynthetic analysis of ammosamides, a bacterial natural product. The work highlights the previously unknown overlap between two natural products families: pyrroloquinoline alkaloids and ribosomally synthesized posttranslationally modified peptides (RiPPs).

Detailed Mechanistic Study of the Non-enzymatic Formation of the Discoipyrrole Family of Natural Products.

Discoipyrroles A-D (DPA-DPD) are recently discovered natural products produced by the marine bacterium Bacillus hunanensis that exhibit anticancer properties in vitro. Initial biosynthetic studies demonstrated that DPA is formed in the liquid fermentation medium of B. hunanensis from three secreted metabolites through an unknown but protein-independent mechanism.

Generation of highly cytotoxic natural killer cells for treatment of acute myelogenous leukemia using a feeder-free, particle-based approach.

Natural killer (NK) cell immunotherapy as a cancer treatment shows promise, but expanding NK cells consistently from a small fraction (∼ 5%) of peripheral blood mononuclear cells (PBMCs) to therapeutic amounts remains challenging. Most current ex vivo expansion methods use co-culture with feeder cells (FC), but their use poses challenges for wide clinical application. We developed a particle-based NK cell expansion technology that uses plasma membrane particles (PM-particles) derived from K562-mbIL15-41BBL FCs.

Discoipyrroles A-D: isolation, structure determination, and synthesis of potent migration inhibitors from Bacillus hunanensis.

Discoidin domain receptor 2 (DDR2) is a receptor tyrosine kinase involved in a variety of cellular response pathways, including regulation of cell growth, proliferation, and motility. Using a newly developed platform to identify the signaling pathway/molecular target of natural products, we identified a family of alkaloid natural products, discoipyrroles A-D (1-4), from Bacillus hunanensis that inhibit the DDR2 signaling pathway. The structure of 1-4, determined by detailed two-dimensional (2D) NMR methods and confirmed by X-ray crystallographic analysis has an unusual 3H-benzo[d]pyrrolo][1,3]oxazine-3,5-dione core.