Ten measures of experimental electron-density-map quality are examined and the skewness of electron density is found to be the best indicator of actual map quality. A Bayesian approach to estimating map quality is developed and used in the PHENIX AutoSol wizard to make decisions during automated structure solution.

Decision-making in structure solution using Bayesian estimates of map quality: the PHENIX autosol wizard

Mycobacterium abscessus is an emerging pathogen that is often refractory to antibiotic control. Treatment is further complicated by considerable variation among clinical isolates in both their genetic constitution and their clinical manifestations. Here, we show that the prophage and plasmid mobilome is a likely contributor to this variation. Prophages and plasmids are common, abundant, and highly diverse, and code for large repertoires of genes influencing virulence, antibiotic susceptibility, and defense against viral infection. At least 85% of the strains we describe carry one or more prophages, representing at least 17 distinct and diverse sequence “clusters,” integrated at 18 different attB locations. The prophages code for 19 distinct configurations of polymorphic toxin and toxin-immunity systems, each with WXG-100 motifs for export through type VII secretion systems. These are located adjacent to attachment junctions, are lysogenically expressed, and are implicated in promoting growth in infected host cells. Although the plethora of prophages and plasmids confounds the understanding of M. abscessus pathogenicity, they also provide an abundance of tools for M. abscessus engineering. IMPORTANCEMycobacterium abscessus is an important emerging pathogen that is challenging to treat with current antibiotic regimens. There is substantial genomic variation in M. abscessus clinical isolates, but little is known about how this influences pathogenicity and in vivo growth. Much of the genomic variation is likely due to the large and varied mobilome, especially a large and diverse array of prophages and plasmids. The prophages are unrelated to previously characterized phages of mycobacteria and code for a diverse array of genes implicated in both viral defense and in vivo growth. Prophage-encoded polymorphic toxin proteins secreted via the type VII secretion system are common and highly varied and likely contribute to strain-specific pathogenesis.

https://mbio.asm.org/content/mbio/12/2/e03441-20.full.pdf

The Prophage and Plasmid Mobilome as a Likely Driver of Mycobacterium abscessus Diversity

Sordarin ( 1 ) is a fungal diterpene glycoside that displays potent antifungal bioactivity through inhibition of elongation factor 2. The structures of sordarin and related compounds are featured by a highly rearranged tetracyclic diterpene core. In this work we identified a concise pathway in the biosynthesis of sordarin. A diterpene cyclase (SdnA) generates the 5/8/5 cycloaraneosene framework, which was decorated by a set of P450s that catalyze a series of oxidations, including hydroxylation, desaturation, and C-C bond oxidative cleavage, to give a carboxylate intermediate with a terminal alkene and a cyclopentadiene moiety. A novel Diels-Alderase SdnG catalyzes an intramolecular Diels-Alder (IMDA) reaction on this intermediate to forge the sordarin core structure. The subsequent methyl hydroxylation and glycosylation completed the biosynthesis of sordarin. Our work disclosed a new strategy to the rearranged diterpene skeleton used by nature.

Biosynthesis of Sordarin Revealing a Diels-Alderase for the Formation of the Norbornene Skeleton.

Lipoic acid is an essential biomolecule found in all domains of life and is involved in central carbon metabolism and dissimilatory sulfur oxidation. The machineries for lipoate assembly in mitochondria and chloroplasts of higher eukaryotes, as well as in the apicoplasts of some protozoa, are all of prokaryotic origin. Here, we provide experimental evidence for a novel lipoate assembly pathway in bacteria based on a sLpl(AB) lipoate:protein ligase, which attaches octanoate or lipoate to apo-proteins, and 2 radical SAM proteins, LipS1 and LipS2, which work together as lipoyl synthase and insert 2 sulfur atoms. Extensive homology searches combined with genomic context analyses allowed us to precisely distinguish between the new and established pathways and map them on the tree of life. This not only revealed a much wider distribution of lipoate biogenesis systems than expected, in particular, the novel sLpl(AB)–LipS1/S2 pathway, and indicated a highly modular nature of the enzymes involved, with unforeseen combinations, but also provided a new framework for the evolution of lipoate assembly. Our results show that dedicated machineries for both de novo lipoate biogenesis and scavenging from the environment were implemented early in evolution and that their distribution in the 2 prokaryotic domains was shaped by a complex network of horizontal gene transfers, acquisition of additional genes, fusions, and losses. Our large-scale phylogenetic analyses identify the bipartite archaeal LplAB ligase as the ancestor of the bacterial sLpl(AB) proteins, which were obtained by horizontal gene transfer. LipS1/S2 have a more complex evolutionary history with multiple of such events but probably also originated in the domain archaea.

/pdf/identification-of-a-novel-lipoic-acid-biosynthesis-pathway-213pf26n.pdf

Identification of a novel lipoic acid biosynthesis pathway reveals the complex evolution of lipoate assembly in prokaryotes

Efficient biosynthesis of microbial bioactive natural products (NPs) is beneficial for the survival of producers, while self-protection is necessary to avoid self-harm resulting from over-accumulation of NPs. The underlying mechanisms for the effective but tolerable production of bioactive NPs is not well understood. Here in the biosynthesis of two fungal polyketide mycotoxins aurovertin E (1) and asteltoxin (4), we show that the cyclases in the gene clusters promote the release of the polyketide backbone, and reveal that a signal peptide is crucial for their subcellular localization and full activity. Meanwhile, the fungus adopts enzymatic acetylation as the major detoxification pathway of 1. If intermediates are over-produced, the non-enzymatic shunt pathways work as salvage pathways to avoid excessive accumulation of the toxic metabolites for self-protection. These findings provided new insights into the interplay of efficient backbone release and multiple detoxification strategies for the production of fungal bioactive NPs.

Coordination of Polyketide Release and Multiple Detoxification Pathways for Tolerable Production of Fungal Mycotoxins.

Lipoic acid is an eight-carbon sulfur-containing biomolecule that functions primarily as a cofactor in several multienzyme complexes. It is biosynthesized as an attachment to a specific lysyl residue on one of the subunits of these multienzyme complexes. In Escherichia coli and many other organisms, this biosynthetic pathway involves two dedicated proteins: octanoyltransferase (LipB) and lipoyl synthase (LipA). LipB transfers an n-octanoyl chain from the octanoyl-acyl carrier protein to the target lysyl residue, and then, LipA attaches two sulfur atoms (one at C6 and one at C8) to give the final lipoyl cofactor. All classical lipoyl synthases (LSs) are radical S-adenosylmethionine (SAM) enzymes, which use an [Fe4S4] cluster to reductively cleave SAM to generate a 5′-deoxyadenosyl 5′-radical. Classical LSs also contain a second [Fe4S4] cluster that serves as the source of both appended sulfur atoms. Recently, a novel pathway for generating the lipoyl cofactor was reported. This pathway replaces the canonical LS with two proteins, LipS1 and LipS2, which act together to catalyze formation of the lipoyl cofactor. In this work, we further characterize LipS1 and LipS2 biochemically and spectroscopically. Although LipS1 and LipS2 were previously annotated as biotin synthases, we show that both proteins, unlike E. coli biotin synthase, contain two [Fe4S4] clusters. We identify the cluster ligands to both iron–sulfur clusters in both proteins and show that LipS2 acts only on an octanoyl-containing substrate, while LipS1 acts only on an 8-mercaptooctanoyl-containing substrate. Therefore, similarly to E. coli biotin synthase and in contrast to E. coli LipA, sulfur attachment takes place initially at the terminal carbon (C8) and then at the C6 methylene carbon.

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9585515

Characterization of LipS1 and LipS2 from Thermococcus kodakarensis: Proteins Annotated as Biotin Synthases, which Together Catalyze Formation of the Lipoyl Cofactor

MppQ is an enzyme of unknown function from Streptomyces hygroscopicus that is involved in the biosynthesis of the nonproteinogenic amino acid L-enduracididine (L-End). Since L-End is a component of several peptides showing high activity against methicillin-resistant Staphylococcus aureus (MRSA), a complete understanding of its biosynthetic pathway is of utmost importance for developing chemoenzymatic routes for syntheses of novel antibiotics. In this work, we report high-resolution X-ray crystal structures of MppQ complexed with pyridoxal-5’-phosphate (PLP) and pyridoxamine-5’-phosphate (PMP). The structure of MppQ shares a fold with known Type I PLP-dependent aminotransferases, consisting of an N-terminal extension, large domain, and a small domain. We also report the first functional characterization of MppQ, which we incubated with enzymatically produced 2-ketoenduracidine and observed conversion to L-End via mass spectroscopy. Additionally, we have observed that MppQ has a relatively high affinity for 2-ketoarginine, a shunt product in the L-End biosynthetic pathway, indicating a possible role of MppQ in increasing efficiency of L-End biosynthesis by converting 2-ketoarginine back to the starting material, L-arginine.

/pdf/structural-and-preliminary-biochemical-characterization-of-udsrly6a.pdf

Structural and Preliminary Biochemical Characterization of MppQ, a PLP-Dependent Aminotransferase from Streptomyces hygroscopicus

The E. coli glyoxylate reductase/hydroxypyruvate reductase A (EcGhrA) was investigated as a coupling enzyme to monitor the transamination of 2-ketoarginine and glycine by the L-enduracididine biosynthetic enzyme MppQ. Surprisingly, 2-ketoarginine proved to be an efficient substrate for EcGhrA. Since the promiscuity of EcGhrA prevented its use as a coupling enzyme to monitor the aminotransferase activity of MppQ, we set about engineering a more specific variant. X-ray crystal structures of EcGhrA were determined in the unliganded state, as well as with glyoxylate and 2-ketoarginine bound. The electron density maps of EcGhrA with 2-ketoarginine bound showed weak electron density for the side chain of this substrate, complicating the choice of active site residues to target for site-directed mutagenesis. The structure of the complex did, however, suggest that the side chain of W45 could interact with the guanidinium group of 2-ketoarginine. We therefore generated the EcGhrAW45F variant and tested it for activity with 2-ketoarginine, glyoxylate, oxaloacetate, α-ketoglutarate, α-oxofuranacetic acid, phenyl pyruvate, 3-mercaptopyruvate and 2-ketobutyric acid. The W45F variant exhibited a ∼10-fold decrease in the specificity constant (kcat/KM) for 2-ketoarginine, while the reaction with glyoxylate was not significantly impaired. The reactions of the W45F variant with the alternative substrates oxaloacetate and α-ketoglutarate were also impaired. Thus, the W45F variant is a less promiscuous enzyme than the wild-type. This engineered EcGhrAW45F variant could be generally useful as a coupling system for enzymes that produce glyoxylate, such as 4-hydroxy-2-oxoglutarate aldolase or isocitrate lyase.

Engineering a more specific E. coli glyoxylate/hydroxypyruvate reductase for coupled steady state kinetics assays

Proteins belonging to the NTF2-like superfamily are present in the biosynthetic pathways of numerous polyketide natural products, such as anthracyclins and benzoisochromanequinones. Some have been found to be bona fide polyketide cyclases, but many of them have roles that are currently unknown. Here, the X-ray crystal structures of three NTF2-like proteins of unknown function are reported: those of ActVI-ORFA from Streptomyces coelicolor A3(2) and its homologs Caci_6494, a protein from an uncharacterized biosynthetic cluster in Catenulispora acidiphila, and Aln2 from Streptomyces sp. CM020, a protein in the biosynthetic pathway of alnumycin. The presence of a solvent-accessible cavity and the conservation of the His/Asp dyad that is characteristic of many polyketide cyclases suggest a potential enzymatic role for these enzymes in polyketide biosynthesis.

Structural characterization of three noncanonical NTF2-like superfamily proteins: implications for polyketide biosynthesis.

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Characterization of LipS1 and LipS2 from Thermococcus kodakarensis: Proteins Annotated as Biotin Synthases, which Together Catalyze Formation of the Lipoyl Cofactor

Structural and Preliminary Biochemical Characterization of MppQ, a PLP-Dependent Aminotransferase from Streptomyces hygroscopicus

Engineering a more specific E. coli glyoxylate/hydroxypyruvate reductase for coupled steady state kinetics assays

Structural characterization of three noncanonical NTF2-like superfamily proteins: implications for polyketide biosynthesis.