INTRODUCTION: Research on the human microbiome has revealed extensive correlations between bacterial populations and host physiology and disease states. However, moving past correlations to understanding causal relationships between the bacteria in our bodies and our health remains a challenge. A well-studied human-bacteria relationship is that of certain gut Escherichia coli strains whose presence correlates with colorectal cancer in humans. These E. coli damage host DNA and cause tumor formation in animal models, and this genotoxic phenotype is thought to derive from a secondary metabolite—known as colibactin—that is synthesized by the bacteria. Because colibactin’s biosynthetic pathway is only partially resolved, the complete structure of colibactin has remained unknown for more than a decade. Similarly, because colibactin is unstable and is produced in vanishingly small quantities, it has yet to be isolated and characterized by means of standard spectroscopic methods. RATIONALE: Determining colibactin’s chemical structure and related biological activity will allow researchers to determine whether the metabolite is the causal agent underlying many colorectal cancers. To that end, we used an interdisciplinary approach to overcome the challenges that have impeded determination of colibactin’s structure. Inspired by an earlier study that showed that colibactin-producing bacteria cross-link DNA, we used DNA as a probe to isolate colibactin from bacterial cultures. Using a combination of isotope labeling and tandem mass spectrometry analysis, we deduced the structure of the colibactin residue when bound to two nucleobases. This information allowed us to then identify and characterize colibactin in bacterial extracts and to identify plausible biosynthetic precolibactin precursors. Last, we developed a method to recreate colibactin in the laboratory and thereby confirm these structure-function relationships. RESULTS: Colibactin is formed through the union of two complex biosynthetic intermediates. This coupling generates a nearly symmetrical structure that contains two electrophilic cyclopropane warheads. We found that each of these residues undergoes ring-opening through nucleotide addition, a determination that is consistent with earlier studies of truncated colibactin derivatives and the observation that colibactin-producing bacteria cross-link DNA. Using genome editing techniques, we were able to show that the production of colibactin’s precursor, precolibactin 1489, requires every biosynthetic gene in the colibactin gene cluster, implicating it as being derived from the long-elusive and now completed biosynthetic pathway. Because natural colibactin remains non-isolable, the chemical synthetic route to colibactin we developed will allow researchers to probe for causal relationships between the metabolite and inflammation-associated colorectal cancer. CONCLUSION: These studies reveal the structure of colibactin, which accounts for the entire gene cluster encoding its biosynthesis, a goal that has remained b...
Precolibactins and colibactins represent a family of natural products that are encoded by the clb gene cluster and are produced by certain commensal, extraintestinal, and probiotic E. coli. clb+ E. coli induce megalocytosis and DNA double-strand breaks in eukaryotic cells, but paradoxically, this gene cluster is found in the probiotic Nissle 1917. Evidence suggests precolibactins are converted to genotoxic colibactins by colibactin peptidase (ClbP)-mediated cleavage of an N-acyl- D-Asn side chain, and all isolation efforts have employed ΔclbP strains to facilitate accumulation of precolibactins. It was hypothesized that colibactins form unsaturated imines that alkylate DNA by cyclopropane ring opening (2 → 3). However, as no colibactins have been isolated, this hypothesis has not been tested experimentally. Additionally, precolibactins A–C (7–9) contain a pyridone that cannot generate the unsaturated imines that form the basis of this hypothesis. To resolve this, we prepared 13 synthetic colibactin derivatives and evaluated their DNA binding and alkylation activity. We show that unsaturated imines, but not the corresponding pyridone derivatives, potently alkylate DNA. The imine, unsaturated lactam, and cyclopropane are essential for efficient DNA alkylation. A cationic residue enhances activity. These studies suggest that precolibactins containing a pyridone are not responsible for the genotoxicity of the clb cluster. Instead, we propose that these are off-pathway fermentation products produced by a facile double cyclodehydration route that manifests in the absence of viable ClbP. The results presented herein provide a foundation to begin to connect metabolite structure with the disparate phenotypes associated with clb+ E. coli.
The development of non-genotoxic therapies that activate wild-type p53 in tumors is of great interest since the discovery of p53 as a tumor suppressor. Here we report the identification of over 100 small-molecules activating p53 in cells. We elucidate the mechanism of action of a chiral tetrahydroindazole (HZ00), and through target deconvolution, we deduce that its active enantiomer (R)-HZ00, inhibits dihydroorotate dehydrogenase (DHODH). The chiral specificity of HZ05, a more potent analog, is revealed by the crystal structure of the (R)-HZ05/DHODH complex. Twelve other DHODH inhibitor chemotypes are detailed among the p53 activators, which identifies DHODH as a frequent target for structurally diverse compounds. We observe that HZ compounds accumulate cancer cells in S-phase, increase p53 synthesis, and synergize with an inhibitor of p53 degradation to reduce tumor growth in vivo. We, therefore, propose a strategy to promote cancer cell killing by p53 instead of its reversible cell cycle arresting effect.
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.
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.
Convergent and Modular Synthesis of Candidate Precolibactins. Structural Revision of Precolibactin A
The colibactins are hybrid polyketide–nonribosomal peptide natural products produced by certain strains of commensal and extraintestinal pathogenic Escherichia coli. The metabolites are encoded by the clb gene cluster as prodrugs termed precolibactins. clb+ E. coli induce DNA double-strand breaks in mammalian cells in vitro and in vivo and are found in 55–67% of colorectal cancer patients, suggesting that mature colibactins could initiate tumorigenesis. However, elucidation of their structures has been an arduous task as the metabolites are obtained in vanishingly small quantities (μg/L) from bacterial cultures and are believed to be unstable. Herein we describe a flexible and convergent synthetic route to prepare advanced precolibactins and derivatives. The synthesis proceeds by late-stage union of two complex precursors (e.g., 28 + 17 → 29a, 90%) followed by a base-induced double dehydrative cascade reaction to form two rings of the targets (e.g., 29a → 30a, 79%). The sequence has provided quantities of advanced candidate precolibactins that exceed those obtained by fermentation, and is envisioned to be readily scaled. These studies have guided a structural revision of the predicted metabolite precolibactin A (from 5a or 5b to 7) and have confirmed the structures of the isolated metabolites precolibactins B (3) and C (6). Synthetic precolibactin C (6) was converted to N-myristoyl-D-asparagine and its corresponding colibactin by colibactin peptidase ClbP. The synthetic strategy outlined herein will facilitate mechanism of action and structure–function studies of these fascinating metabolites, and is envisioned to accommodate the synthesis of additional (pre)colibactins as they are isolated.
The clb gene cluster encodes the biosynthesis of metabolites known as precolibactins and colibactins. The clb pathway is found in gut commensal E. coli, and clb metabolites are thought to initiate colorectal cancer via DNA cross-linking. Here we report confirmation of the structural assignment of the complex clb product precolibactin 886 via a biomimetic synthetic pathway. We show that a α-ketoimine linear precursor undergoes spontaneous cyclization to precolibactin 886 upon HPLC purification. Studies of this α-ketoimine and the related α-dicarbonyl revealed that these compounds are unexpectedly susceptible to nucleophilic cleavage under mildly basic conditions. This cleavage pathway forms other known clb metabolites or biosynthetic intermediates and explains the difficulties in isolating fully mature biosynthetic products. This cleavage also accounts for a recently identified colibactin-adenine adduct. The colibactin peptidase ClbP deacylates synthetic precolibactin 886 to form a non-genotoxic pyridone, suggesting precolibactin 886 lies off-path of the major biosynthetic route.
Abstract. A series of 73 bisphosphonium salts and 10 monophosphonium salt derivatives were synthesized and tested in vitro against several wild type and resistant lines of Trypanosoma brucei (T. b. rhodesiense STIB900, T. b. brucei strain 427, TbAT1-KO, and TbB48). More than half of the compounds tested showed a submicromolar EC 50 against these parasites. The compounds did not display any crossresistance to existing diamidine therapies, such as pentamidine. In most cases, the compounds displayed a good selectivity index versus human cell lines. None of the known T. b. brucei drug transporters were required for trypanocidal activity, although some of the bisphosphonium compounds inhibited the Low Affinity PentamidineTransporter. It was found that phosphonium drugs act slowly to clear a trypanosome population, but that only a short exposure time is needed for irreversible damage to the cells. A Comparative Molecular Field Analysis Model (CoMFA) was generated to gain insights into the SAR of this class of compounds, identifying key features for trypanocidal activity.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
