Journal Articles

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    Structural characterisation of nucleotide sugar short-chain dehydrogenases/reductases from the thermophilic pseudomurein-containing methanogen Methanothermobacter thermautotrophicus ΔH
    (John Wiley and Sons Ltd on behalf of Federation of European Biochemical Societies, 2025-09-03) Carbone V; Schofield LR; Edwards PJB; Sutherland-Smith AJ; Ronimus RS
    Epimerases and dehydratases are widely studied members of the extendedshort-chain dehydrogenase/reductase (SDR) enzyme superfamily and areimportant in nucleotide sugar conversion and diversification, for example,the interconversion of uridine diphosphate (UDP)-linked glucose andgalactose. Methanothermobacter thermautotrophicus contains a cluster ofgenes, the annotations of which indicate involvement in glycan biosynthesissuch as that of cell walls or capsular polysaccharides. In particular, genesencoding UDP-glucose 4-epimerase related protein (Mth375), UDP-glucose4-epimerase homologue (Mth380) and dTDP-glucose 4,6-dehydrataserelated protein (Mth373) may be involved in the biosynthesis of an unusualaminosugar in pseudomurein. In this paper, we present the structures ofMth375, an archaeal sugar epimerase/dehydratase protein (WbmF) deter-mined to a resolution of 2.0 A. The structure contains an N-terminalRossmann-fold domain with bound nicotinamide adenine dinucleotidehydride (NADH) and a C-terminal catalytic domain with bound UDP. Wealso present the structure for Mth373 co-crystallised with uridine-50-diphosphate-xylopyranose to a resolution of 1.96 A as a NAD+-dependentoxidative decarboxylase (UDP-xylose synthase; EC4.1.1.35). Molecularmodelling has also allowed for the identification of Mth380 as aUDP-N-acetylglucosamine 4-epimerase (WbpP; EC5.1.3.7), Mth631 as aUDP-glucose 4-epimerase (GalE; EC5.1.3.2) and Mth1789 as a classicaldTDP-D-glucose 4,6-dehydratase (EC4.2.1.46). The UDP–sugar specificityof each archaeal nucleotide sugar short-chain dehydrogenase/reductase.
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    Mapping immunogenic epitopes of an adhesin-like protein from Methanobrevibacter ruminantium M1 and comparison of empirical data with in silico prediction methods.
    (Springer Nature Limited, 2022-06-21) Khanum S; Carbone V; Gupta SK; Yeung J; Shu D; Wilson T; Parlane NA; Altermann E; Estein SM; Janssen PH; Wedlock DN; Heiser A
    In silico prediction of epitopes is a potentially time-saving alternative to experimental epitope identification but is often subject to misidentification of epitopes and may not be useful for proteins from archaeal microorganisms. In this study, we mapped B- and T-cell epitopes of a model antigen from the methanogen Methanobrevibacter ruminantium M1, the Big_1 domain (AdLP-D1, amino acids 19-198) of an adhesin-like protein. A series of 17 overlapping 20-mer peptides was selected to cover the Big_1 domain. Peptide-specific antibodies were produced in mice and measured by ELISA, while an in vitro splenocyte re-stimulation assay determined specific T-cell responses. Overall, five peptides of the 17 peptides were shown to be major immunogenic epitopes of AdLP-D1. These immunogenic regions were examined for their localization in a homology-based model of AdLP-D1. Validated epitopes were found in the outside region of the protein, with loop like secondary structures reflecting their flexibility. The empirical data were compared with epitope predictions made by programmes based on a range of algorithms. In general, the epitopes identified by in silico predictions were not comparable to those determined empirically.
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    A novel mutation in IAA16 is associated with dicamba resistance in Chenopodium album
    (John Wiley and Sons Ltd on behalf of Society of Chemical Industry, 2024-07) Ghanizadeh H; He L; Griffiths AG; Harrington KC; Carbone V; Wu H; Tian K; Bo H; Xinhui D
    BACKGROUND: Resistance to dicamba in Chenopodium album was first documented over a decade ago, however, the molecular basis of dicamba resistance in this species has not been elucidated. In this research, the resistance mechanism in a dicamba-resistant C. album phenotype was investigated using a transcriptomics (RNA-sequence) approach. RESULTS: The dose-response assay showed that the resistant (R) phenotype was nearly 25-fold more resistant to dicamba than a susceptible (S) phenotype of C. album. Also, dicamba treatment significantly induced transcription of the known auxin-responsive genes, Gretchen Hagen 3 (GH3), small auxin-up RNAs (SAURs), and 1-aminocyclopropane-1-carboxylate synthase (ACS) genes in the susceptible phenotype. Comparing the transcripts of auxin TIR/AFB receptors and auxin/indole-3-acetic acid (AUX/IAA) proteins identified from C. album transcriptomic analysis revealed that the R phenotype contained a novel mutation at the first codon of the GWPPV degron motif of IAA16, resulting in an amino acid substitution of glycine (G) with aspartic acid (D). Sequencing the IAA16 gene in other R and S individuals further confirmed that all the R individuals contained the mutation. CONCLUSION: In this research, we describe the dicamba resistance mechanism in the only case of dicamba-resistant C. album reported to date. Prior work has shown that the dicamba resistance allele confers significant growth defects to the R phenotype investigated here, suggesting that dicamba-resistant C. album carrying this novel mutation in the IAA16 gene may not persist at high frequencies upon removal of dicamba application.
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    Structural characterisation of methanogen pseudomurein cell wall peptide ligases homologous to bacterial MurE/F murein peptide ligases.
    (2022-09) Subedi BP; Schofield LR; Carbone V; Wolf M; Martin WF; Ronimus RS; Sutherland-Smith AJ
    Archaea have diverse cell wall types, yet none are identical to bacterial peptidoglycan (murein). Methanogens Methanobacteria and Methanopyrus possess cell walls of pseudomurein, a structural analogue of murein. Pseudomurein differs from murein in containing the unique archaeal sugar N-acetyltalosaminuronic acid instead of N-acetylmuramic acid, β-1,3 glycosidic bonds in place of β-1,4 bonds and only l-amino acids in the peptide cross-links. We have determined crystal structures of methanogen pseudomurein peptide ligases (termed pMurE) from Methanothermus fervidus (Mfer762) and Methanothermobacter thermautotrophicus (Mth734) that are structurally most closely related to bacterial MurE peptide ligases. The homology of the archaeal pMurE and bacterial MurE enzymes is clear both in the overall structure and at the level of each of the three domains. In addition, we identified two UDP-binding sites in Mfer762 pMurE, one at the exterior surface of the interface of the N-terminal and middle domains, and a second site at an inner surface continuous with the highly conserved interface of the three domains. Residues involved in ATP binding in MurE are conserved in pMurE, suggesting that a similar ATP-binding pocket is present at the interface of the middle and the C-terminal domains of pMurE. The presence of pMurE ligases in members of the Methanobacteriales and Methanopyrales, that are structurally related to bacterial MurE ligases, supports the idea that the biosynthetic origins of archaeal pseudomurein and bacterial peptidoglycan cell walls are evolutionarily related.