Escherichia coli-Derived γ-Lactams and Structurally Related Metabolites Are Produced at the Intersection of Colibactin and Fatty Acid Biosynthesis.

Colibactin is a genotoxic hybrid polyketide-nonribosomal peptide that drives colorectal cancer initiation. While clinical data suggest colibactin genotoxicity in vivo is largely caused by the major DNA-cross-linking metabolite, the colibactin locus produces a diverse collection of metabolites with mostly unknown biological activities. Here, we describe 10 new colibactin pathway metabolites (1-10) that are dependent on its α-aminomalonyl-carrier protein. The most abundant metabolites, 1 and 2, were isolated and structurally characterized mainly by nuclear magnetic resonance spectroscopy to be γ-lactam derivatives, and the remaining related structures were inferred via shared biosynthetic logic. Our proposed formation of 1-10, which is supported by stereochemical analysis, invokes cross-talk between colibactin and fatty acid biosynthesis, illuminating further the complexity of this diversity-oriented pathway.

Molecules from the Microbiome.

The human microbiome encodes a second genome that dwarfs the genetic capacity of the host. Microbiota-derived small molecules can directly target human cells and their receptors or indirectly modulate host responses through functional interactions with other microbes in their ecological niche. Their biochemical complexity has profound implications for nutrition, immune system development, disease progression, and drug metabolism, as well as the variation in these processes that exists between individuals. While the species composition of the human microbiome has been deeply explored, detailed mechanistic studies linking specific microbial molecules to host phenotypes are still nascent. In this review, we discuss challenges in decoding these interaction networks, which require interdisciplinary approaches that combine chemical biology, microbiology, immunology, genetics, analytical chemistry, bioinformatics, and synthetic biology. We highlight important classes of microbiota-derived small molecules and notable examples. An understanding of these molecular mechanisms is central to realizing the potential of precision microbiome editing in health, disease, and therapeutic responses.

Characterization of Autoinducer-3 Structure and Biosynthesis in E. coli.

Escherichia coli is a common inhabitant of the human microbiota and a beacon model organism in biology. However, an understanding of its signaling systems that regulate population-level phenotypes known as quorum sensing remain incomplete. Here, we define the structure and biosynthesis of autoinducer-3 (AI-3), a metabolite of previously unknown structure involved in the pathogenesis of enterohemorrhagic E. coli (EHEC). We demonstrate that novel AI-3 analogs are derived from threonine dehydrogenase (Tdh) products and "abortive" tRNA synthetase reactions, and they are distributed across a variety of Gram-negative and Gram-positive bacterial pathogens. In addition to regulating virulence genes in EHEC, we show that the metabolites exert diverse immunological effects on primary human tissues. The discovery of AI-3 metabolites and their biochemical origins now provides a molecular foundation for investigating the diverse biological roles of these elusive yet widely distributed bacterial signaling molecules.

Structure elucidation of colibactin and its DNA cross-links.

Colibactin is a complex secondary metabolite produced by some genotoxic gut Escherichia coli strains. The presence of colibactin-producing bacteria correlates with the frequency and severity of colorectal cancer in humans. However, because colibactin has not been isolated or structurally characterized, studying the physiological effects of colibactin-producing bacteria in the human gut has been difficult. We used a combination of genetics, isotope labeling, tandem mass spectrometry, and chemical synthesis to deduce the structure of colibactin. Our structural assignment accounts for all known biosynthetic and cell biology data and suggests roles for the final unaccounted enzymes in the colibactin gene cluster.

Model Colibactins Exhibit Human Cell Genotoxicity in the Absence of Host Bacteria.

Colibactins are genotoxic secondary metabolites produced in select Enterobacteriaceae, which induce downstream DNA double-strand breaks (DSBs) in human cell lines and are thought to promote the formation of colorectal tumors. Although key structural and functional features of colibactins have been elucidated, the full molecular mechanisms regulating these phenotypes remain unknown. Here, we demonstrate that free model colibactins induce DSBs in human cell cultures and do not require delivery by host bacteria. Through domain-targeted editing, we demonstrate that a subset of native colibactins generated from observed module skipping in the nonribosomal peptide synthetase-polyketide synthase (NRPS-PKS) biosynthetic assembly line share DNA alkylation phenotypes with the model colibactins in vitro. However, module skipping eliminates the strong DNA interstrand cross-links formed by the wild-type pathway in cell culture. This product diversification during the modular NRPS-PKS biosynthesis produces a family of metabolites with varying observed mechanisms of action (DNA alkylation versus cross-linking) in cell culture. The presence of membranes separating human cells from model colibactins attenuated genotoxicity, suggesting that membrane diffusion limits colibactin activity and could account for the reported bacterium-human cell-to-cell contact phenotype. Additionally, extracellular supplementation of the colibactin resistance protein ClbS was able to intercept colibactins in an Escherichia coli-human cell transient infection model. Our studies demonstrate that free model colibactins recapitulate cellular phenotypes associated with module-skipped products in the native colibactin pathway and define specific protein domains that are required for efficient DNA interstrand cross-linking in the native pathway.

ClbS Is a Cyclopropane Hydrolase That Confers Colibactin Resistance.

Certain commensal Escherichia coli contain the clb biosynthetic gene cluster that codes for small molecule prodrugs known as precolibactins. Precolibactins are converted to colibactins by N-deacylation; the latter are postulated to be genotoxic and to contribute to colorectal cancer formation. Though advances toward elucidating (pre)colibactin biosynthesis have been made, the functions and mechanisms of several clb gene products remain poorly understood. Here we report the 2.1 Å X-ray structure and molecular function of ClbS, a gene product that confers resistance to colibactin toxicity in host bacteria and which has been shown to be important for bacterial viability. The structure harbors a potential colibactin binding site and shares similarity to known hydrolases. In vitro studies using a synthetic colibactin analog and ClbS or an active site residue mutant reveal cyclopropane hydrolase activity that converts the electrophilic cyclopropane of the colibactins into an innocuous hydrolysis product. As the cyclopropane has been shown to be essential for genotoxic effects in vitro, this ClbS-catalyzed ring-opening provides a means for the bacteria to circumvent self-induced genotoxicity. Our study provides a molecular-level view of the first reported cyclopropane hydrolase and support for a specific mechanistic role of this enzyme in colibactin resistance.

Domain-Targeted Metabolomics Delineates the Heterocycle Assembly Steps of Colibactin Biosynthesis.

Modular polyketide synthases (PKSs) and nonribosomal peptide synthetases (NRPSs) comprise giant multidomain enzymes responsible for the "assembly line" biosynthesis of many genetically encoded small molecules. Site-directed mutagenesis, protein biochemical, and structural studies have focused on elucidating the catalytic mechanisms of individual multidomain proteins and protein domains within these megasynthases. However, probing their functions at the cellular level typically has invoked the complete deletion (or overexpression) of multidomain-encoding genes or combinations of genes and comparing those mutants with a control pathway. Here we describe a "domain-targeted" metabolomic strategy that combines genome editing with pathway analysis to probe the functions of individual PKS and NRPS catalytic domains at the cellular metabolic level. We apply the approach to the bacterial colibactin pathway, a genotoxic NRPS-PKS hybrid pathway found in certain Escherichia coli. The pathway produces precolibactins, which are converted to colibactins by a dedicated peptidase, ClbP. Domain-targeted metabolomics enabled the characterization of "multidomain signatures", or functional readouts of NRPS-PKS domain contributions to the pathway-dependent metabolome. These multidomain signatures provided experimental support for individual domain contributions to colibactin biosynthesis and delineated the assembly line timing events of colibactin heterocycle formation. The analysis also led to the structural characterization of two reactive precolibactin metabolites. We demonstrate the fate of these reactive intermediates in the presence and absence of ClbP, which dictates the formation of distinct product groups resulting from alternative cyclization cascades. In the presence of the peptidase, the reactive intermediates are converted to a known genotoxic scaffold, providing metabolic support of our mechanistic model for colibactin-induced genotoxicity. Domain-targeted metabolomics could be more widely used to characterize NRPS-PKS pathways with unprecedented genetic and metabolic precision.

Integration-dependent bacteriophage immunity provides insights into the evolution of genetic switches.

Genetic switches are critical components of developmental circuits. Because temperate bacteriophages are vastly abundant and greatly diverse, they are rich resources for understanding the mechanisms and evolution of switches and the molecular control of genetic circuitry. Here, we describe a new class of small, compact, and simple switches that use site-specific recombination as the key decision point. The phage attachment site attP is located within the phage repressor gene such that chromosomal integration results in removal of a C-terminal tag that destabilizes the virally encoded form of the repressor. Integration thus not only confers prophage stability but also is a requirement for lysogenic establishment. The variety of these self-contained integration-dependent immunity systems in different genomic contexts suggests that these represent ancestral states in switch evolution from which more-complex switches have evolved. They also provide a powerful toolkit for building synthetic biological circuits.