The McbB component of microcin B17 synthetase is a zinc metalloprotein

The Microbial Toxin Microcin B17: Prospects for the Development of New Antibacterial Agents

Microcin B17 (MccB17) is an antibacterial peptide produced by strains of Escherichia coli harboring the plasmid-borne mccB17 operon. MccB17 possesses many notable features. It is able to stabilize the transient DNA gyrase–DNA cleavage complex, a very efficient mode of action shared with the highly successful fluoroquinolone drugs. MccB17 stabilizes this complex by a distinct mechanism making it potentially valuable in the fight against bacterial antibiotic resistance. MccB17 was the first compound discovered from the thiazole/oxazole-modified microcins family and the linear azole-containing peptides; these ribosomal peptides are post-translationally modified to convert serine and cysteine residues into oxazole and thiazole rings. These chemical moieties are found in many other bioactive compounds like the vitamin thiamine, the anti-cancer drug bleomycin, the antibacterial sulfathiazole and the antiviral nitazoxanide. Therefore, the biosynthetic machinery that produces these azole rings is noteworthy as a general method to create bioactive compounds. Our knowledge of MccB17 now extends to many aspects of antibacterial–bacteria interactions: production, transport, interaction with its target, and resistance mechanisms; this knowledge has wide potential applicability. After a long time with limited progress on MccB17, recent publications have addressed critical aspects of MccB17 biosynthesis as well as an explosion in the discovery of new related compounds in the thiazole/oxazole-modified microcins/linear azole-containing peptides family. It is therefore timely to summarize the evidence gathered over more than 40 years about this still enigmatic molecule and place it in the wider context of antibacterials.

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Microcin B17 (MccB17) is a microbial toxin with a unique mode of action.

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MccB17 stabilizes the gyrase–DNA cleavage complex; it is a potential substitute for fluoroquinolones.

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The structures of microcin synthase and TldD/E have given key insight into its biosynthesis.

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A variety of modified McB17s have been generated and characterized.

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MccB17 has been implicated in IBD.

YcaO-Dependent Posttranslational Amide Activation: Biosynthesis, Structure, and Function

With advances in sequencing technology, uncharacterized proteins and domains of unknown function (DUFs) are rapidly accumulating in sequence databases and offer an opportunity to discover new protein chemistry and reaction mechanisms. The focus of this review, the formerly enigmatic YcaO superfamily (DUF181), has been found to catalyze a unique phosphorylation of a ribosomal peptide backbone amide upon attack by different nucleophiles. Established nucleophiles are the side chains of Cys, Ser, and Thr which gives rise to azoline/azole biosynthesis in ribosomally synthesized and posttranslationally modified peptide (RiPP) natural products. However, much remains unknown about the potential for YcaO proteins to collaborate with other nucleophiles. Recent work suggests potential in forming thioamides, macroamidines, and possibly additional post-translational modifications. This review covers all knowledge through mid-2016 regarding the biosynthetic gene clusters (BGCs), natural products, functions, mechanisms, and applications of YcaO proteins and outlines likely future research directions for this protein superfamily.

Cyclisation mechanisms in the biosynthesis of ribosomally synthesised and post-translationally modified peptides

Ribosomally synthesised and post-translationally modified peptides (RiPPs) are a large class of natural products that are remarkably chemically diverse given an intrinsic requirement to be assembled from proteinogenic amino acids. The vast chemical space occupied by RiPPs means that they possess a wide variety of biological activities, and the class includes antibiotics, co-factors, signalling molecules, anticancer and anti-HIV compounds, and toxins. A considerable amount of RiPP chemical diversity is generated from cyclisation reactions, and the current mechanistic understanding of these reactions will be discussed here. These cyclisations involve a diverse array of chemical reactions, including 1,4-nucleophilic additions, [4 + 2] cycloadditions, ATP-dependent heterocyclisation to form thiazolines or oxazolines, and radical-mediated reactions between unactivated carbons. Future prospects for RiPP pathway discovery and characterisation will also be highlighted.

YcaO domains use ATP to activate amide backbones during peptide cyclodehydrations

Thiazole/oxazole-modified microcins (TOMMs) encompass a recently defined class of ribosomally synthesized natural products with a diverse set of biological activities. Although TOMM biosynthesis has been investigated for over a decade, the mechanism of heterocycle formation by the synthetase enzymes remains poorly understood. Using substrate analogs and isotopic labeling, we demonstrate that ATP is used to directly phosphorylate the peptide amide backbone during TOMM heterocycle formation. Moreover, we present what is to our knowledge the first experimental evidence that the D-protein component of the heterocycle-forming synthetase (YcaO/domain of unknown function 181 family member), formerly annotated as a docking protein involved in complex formation and regulation, is able to perform the ATP-dependent cyclodehydration reaction in the absence of the other TOMM biosynthetic proteins. Together, these data reveal the role of ATP in the biosynthesis of azole and azoline heterocycles in ribosomal natural products and prompt a reclassification of the enzymes involved in their installation.

Biochemical characterization of human SET and MYND domain-containing protein 2 methyltransferase

SET and MYND domain-containing protein 2 (SMYD2) is a protein lysine methyltransferase that catalyzes the transfer of methyl groups from S-adenosylmethionine (AdoMet) to acceptor lysine residues on histones and other proteins. To understand the kinetic mechanism and the function of individual domains, human SMYD2 was overexpressed, purified, and characterized. Substrate specificity and product analysis studies established SMYD2 as a monomethyltransferase that prefers nonmethylated p53 peptide substrate. Steady-state kinetic and product inhibition studies showed that SMYD2 operates via a rapid equilibrium random Bi Bi mechanism at a rate of 0.048 ± 0.001 s(-1), with K(M)s for AdoMet and the p53 peptide of 0.031 ± 0.01 μM and 0.68 ± 0.22 μM, respectively. Metal analyses revealed that SMYD2 contains three tightly bound zinc ions that are important for maintaining the structural integrity and catalytic activity of SMYD2. Catalytic activity was also shown to be dependent on the GxG motif in the S-sequence of the split SET domain, as a G18A/G20A double mutant and a sequence deletion within the conserved motif impaired AdoMet binding and significantly decreased enzymatic activity. The functional importance of other SMYD2 domains including the MYND domain, the cysteine-rich post-SET domain, and the C-terminal domain (CTD), were also investigated. Taken together, these results demonstrated the functional importance of distinct domains in the SMYD family of proteins and further advanced our understanding of the catalytic mechanism of this family.

Marine molecular machines: heterocyclization in cyanobactin biosynthesis

Natural products that contain amino-acid-derived (Cys, Ser, Thr) heterocycles are ubiquitous in nature, yet key aspects of their biosynthesis remain undefined. Cyanobactins are heterocyclic ribosomal peptide natural products from cyanobacteria, including symbiotic bacteria living with marine ascidians. In contrast to other ribosomal peptide heterocyclases that have been studied, the cyanobactin heterocyclase is a single protein that does not require an oxidase enzyme. Using this simplifying condition, we provide new evidence to support the hypothesis that these enzymes are molecular machines that use ATP in a product binding or orientation cycle. Further, we show that both protease inhibitors and ATP analogues inhibit heterocyclization and define the order of biochemical steps in the cyanobactin biosynthetic pathway. The cyanobactin pathway enzymes, PatD and TruD, are thiazoline and oxazoline synthetases.

Clostridiolysin S, a post-translationally modified biotoxin from Clostridium botulinum

Through elaboration of its botulinum toxins, Clostridium botulinum produces clinical syndromes of infant botulism, wound botulism, and other invasive infections. Using comparative genomic analysis, an orphan nine-gene cluster was identified in C. botulinum and the related foodborne pathogen Clostridium sporogenes that resembled the biosynthetic machinery for streptolysin S, a key virulence factor from group A Streptococcus responsible for its hallmark beta-hemolytic phenotype. Genetic complementation, in vitro reconstitution, mass spectral analysis, and plasmid intergrational mutagenesis demonstrate that the streptolysin S-like gene cluster from Clostridium sp. is responsible for the biogenesis of a novel post-translationally modified hemolytic toxin, clostridiolysin S.

Methanotrophs and copper

Methanotrophs, cells that consume methane (CH(4)) as their sole source of carbon and energy, play key roles in the global carbon cycle, including controlling anthropogenic and natural emissions of CH(4), the second-most important greenhouse gas after carbon dioxide. These cells have also been widely used for bioremediation of chlorinated solvents, and help sustain diverse microbial communities as well as higher organisms through the conversion of CH(4) to complex organic compounds (e.g. in deep ocean and subterranean environments with substantial CH(4) fluxes). It has been well-known for over 30 years that copper (Cu) plays a key role in the physiology and activity of methanotrophs, but it is only recently that we have begun to understand how these cells collect Cu, the role Cu plays in CH(4) oxidation by the particulate CH(4) monooxygenase, the effect of Cu on the proteome, and how Cu affects the ability of methanotrophs to oxidize different substrates. Here we summarize the current state of knowledge of the phylogeny, environmental distribution, and potential applications of methanotrophs for regional and global issues, as well as the role of Cu in regulating gene expression and proteome in these cells, its effects on enzymatic and whole-cell activity, and the novel Cu uptake system used by methanotrophs.

Ribosomal peptide natural products: bridging the ribosomal and nonribosomal worlds

Ribosomally synthesized bacterial natural products rival the nonribosomal peptides in their structural and functional diversity. The last decade has seen substantial progress in the identification and characterization of biosynthetic pathways leading to ribosomal peptide natural products with new and unusual structural motifs. In some of these cases, the motifs are similar to those found in nonribosomal peptides, and many are constructed by convergent or even paralogous enzymes. Here, we summarize the major structural and biosynthetic categories of ribosomally synthesized bacterial natural products and, where applicable, compare them to their homologs from nonribosomal biosynthesis.

How nature morphs peptide scaffolds into antibiotics

The conventional notion that peptides are poor candidates for orally available drugs because of protease-sensitive peptide bonds, intrinsic hydrophilicity, and ionic charges contrasts with the diversity of antibiotic natural products with peptide-based frameworks that are synthesized and utilized by Nature. Several of these antibiotics, including penicillin and vancomycin, are employed to treat bacterial infections in humans and have been best-selling therapeutics for decades. Others might provide new platforms for the design of novel therapeutics to combat emerging antibiotic-resistant bacterial pathogens.

Trading molecules and tracking targets in symbiotic interactions

It is probable that nearly every natural product structure results from interactions between organisms. Symbiosis, a subset of inter-organism interactions involving closely associated partners, has recently provided new and interesting experimental systems for the study of these interactions. This review discusses new observations about natural product function and structural evolution that emerge from the study of symbiotic systems. In particular, these advances directly address long-standing 'how' and 'why' questions about natural products, providing fundamental insights about the evolution, origin and purpose of natural products that are inaccessible by other methods.

Low-molecular-weight post-translationally modified microcins

Microcins are a class of ribosomally synthesized antibacterial peptides produced by Enterobacteriaceae and active against closely related bacterial species. While some microcins are active as unmodified peptides, others are heavily modified by dedicated maturation enzymes. Low-molecular-weight microcins from the post-translationally modified group target essential molecular machines inside the cells. In this review, available structural and functional data about three such microcins--microcin J25, microcin B17 and microcin C7-C51--are discussed. While all three low-molecular-weight post-translationally modified microcins are produced by Escherichia coli, inferences based on sequence and structural similarities with peptides encoded or produced by phylogenetically diverse bacteria are made whenever possible to put these compounds into a larger perspective.

Escherichia coli HypA is a zinc metalloprotein with a weak affinity for nickel

The hyp operon encodes accessory proteins that are required for the maturation of the [NiFe] hydrogenase enzymes and, in some organisms, for the production of urease enzymes as well. HypA or a homologous protein is required for nickel insertion into the hydrogenase precursor proteins. In this study, recombinant HypA from Escherichia coli was purified and characterized in vitro. Metal analysis was used to demonstrate that HypA simultaneously binds stoichiometric Zn(2+) and stoichiometric Ni(2+). Competition experiments with a metallochromic indicator reveal that HypA binds zinc with nanomolar affinity. Spectroscopic analysis of cobalt-containing HypA provides evidence for a tetrathiolate coordination sphere, suggesting that the zinc site has a structural role. In addition, HypA can exist as several oligomeric complexes and the zinc content modulates the quaternary structure of the protein. Fluorescence titration experiments demonstrate that HypA binds nickel with micromolar affinity and that the presence of zinc does not dramatically affect the nickel-binding activity. Finally, complex formation between HypA and HypB, another accessory protein required for nickel insertion, was observed. These experiments suggest that HypA is an architectural component of the hydrogenase metallocenter assembly pathway and that it may also have a direct role in the delivery of nickel to the hydrogenase large subunit.

Structural characterization of the zinc site in protein farnesyltransferase

X-ray absorption spectroscopy has been used to determine the structure of the Zn site in protein farnesyltransferase. Extended X-ray absorption fine structure (EXAFS) data are consistent with a Zn site that is ligated to three low-Z (oxygen or nitrogen) ligands and one cysteine sulfur, as predicted from the crystal structures that are available for farnesyltransferase. However, in contrast with the crystallographic results the EXAFS data do not show evidence for significant distortions in the Zn-ligand distances. The average Zn-(N/O) and Zn-S distances are 2.04 and 2.31 A, respectively. Addition of a farnesyl diphosphate analogue causes no detectable change in the structure of the Zn site. However, addition of peptide substrate causes a change in ligation from ZnS(N/O)(3) to ZnS(2)(N/O)(2), consistent with ligation of the C-terminal cysteine to the Zn. There is no significant change in Zn-ligand distances when a substrate binds, demonstrating that the Zn remains four-coordinate. Addition of both peptide and farnesyl diphosphate to give the product complex causes the Zn to return to ZnS(N/O)(3) ligation, indicating that the product thioether is not tightly coordinated to the Zn. These spectroscopic experiments provide insight into the catalytic mechanism of FTase.

Expression and purification of recombinant tristetraprolin that can bind to tumor necrosis factor-alpha mRNA and serve as a substrate for mitogen-activated protein kinases

Tristetraprolin (TTP) is an mRNA-binding protein, but studies of this interaction have been difficult due to problems with the purification of recombinant TTP. In the present study, we expressed human and mouse TTP as glutathione S-transferase and maltose-binding protein (MBP) fusion proteins in Escherichia coli, and purified them by affinity resins and Mono Q chromatography. TTP cleaved from the fusion protein was identified by immunoblotting, MALDI-MS, and protein sequencing, and was further purified to homogeneity by continuous-elution SDS-gel electrophoresis. Purified recombinant TTP bound to the AU-rich element of tumor necrosis factor-alpha (TNFalpha) mRNA and this binding was dependent on Zn(2+). Results from sizing columns suggested that the active species might be in the form of an oligomer of MBP-TTP. Recombinant TTP was phosphorylated by three members of the mitogen-activated protein (MAP) kinase family, p42, p38, and JNK, with half-maximal phosphorylation occurring at approximately 0.5, 0.25, and 0.25 microM protein, respectively. Phosphorylation by these kinases did not appear to affect the ability of TTP to bind to TNFalpha mRNA under the assay conditions. This study describes a procedure for purifying nonfusion protein TTP to homogeneity, demonstrates that TTP's RNA-binding activity is zinc dependent, and that TTP can be phosphorylated by JNK as well as by the other members of the greater MAP kinase family.

Cloning and characterization of the bleomycin biosynthetic gene cluster from Streptomyces verticillus ATCC15003

Bleomycin (BLM) biosynthesis has been studied as a model for hybrid peptide-polyketide natural product biosynthesis. Cloning, sequencing, and biochemical characterization of the blm biosynthetic gene cluster from Streptomyces verticillus ATCC15003 revealed that (1) the BLM hybrid peptide-polyketide aglycon is assembled by the BLM megasynthetase that consists of both nonribosomal peptide synthetase (NRPS) and polyketide synthase (PKS) modules; (2) BlmIX/BlmVIII/BlmVII constitute a natural hybrid NRPS/PKS/NRPS system, serving as a model for both hybrid NRPS/PKS and PKS/NRPS systems; (3) the catalytic sites appear to be conserved in both hybrid NRPS/PKS and nonhybrid NRPS or PKS systems, with the exception of the KS domains in the hybrid NRPS/PKS systems that are unique; (4) specific interpolypeptide linkers may play a critical role in intermodular communication to facilitate the transfer of the growing intermediates between the interacting NRPS and/or PKS modules; (5) post-translational modification of the BLM megasynthetase has been accomplished by a single PPTase with broad carrier protein specificity; and (6) BlmIV/BlmIII-templated assembly of the BLM bithiazole moiety requires intriguing protein juxtaposition and modular recognition. These results lay the foundation to investigate the molecular basis for intermodular communication between NRPS and PKS in hybrid peptide-polyketide natural product biosynthesis and set the stage for engineering novel BLM analogues by genetic manipulation of genes governing BLM biosynthesis.

Glycopeptide antibiotic biosynthesis: enzymatic assembly of the dedicated amino acid monomer (S)-3,5-dihydroxyphenylglycine

Four proteins, DpgA-D, required for the biosynthesis by actinomycetes of the nonproteinogenic amino acid monomer (S)-3,5-dihydroxyphenylglycine (Dpg), that is a crosslinking site in the maturation of vancomycin and teicoplanin antibiotic scaffolds, were expressed in Escherichia coli, purified in soluble form, and assayed for enzymatic activity. DpgA is a type III polyketide synthase, converting four molecules of malonyl-CoA to 3,5-dihydroxyphenylacetyl-CoA (DPA-CoA) and three free coenzyme A (CoASH) products. Almost no turnover was observed for DpgA until DpgB was added, producing a net k(cat) of 1-2 min(-1) at a 3:1 ratio of DpgB:DpgA. Addition of DpgD gave a further 2-fold rate increase. DpgC had the unusual catalytic capacity to convert DPA-CoA to 3,5-dihydroxyphenylglyoxylate, which is a transamination away from Dpg. DpgC performed a net CH(2) to C=O four-electron oxidation on the Calpha of DPA-CoA and hydrolyzed the thioester linkage with a k(cat) of 10 min(-1). Phenylacetyl-CoA was also processed, to phenylglyoxylate, but with about 500-fold lower k(cat)/K(M). DpgC showed no activity in anaerobic incubations, suggesting an oxygenase function, but had no detectable bound organic cofactors or metals. A weak enoyl-CoA hydratase activity was detected for both DpgB and DpgD.