I03-Macromolecular Crystallography
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Diamond Proposal Number(s):
[24447]
Open Access
Abstract: The β-glucans are structurally varied, naturally occurring components of the cell walls and storage materials of a variety of plant and microbial species. In the human diet, mixed-linkage glucans [MLG - β-(1,3/4)-glucans] influence the gut microbiome and the host immune system. Although consumed daily, the molecular mechanism by which human gut Gram-positive bacteria utilize MLG largely remains unknown. In this study, we used Blautia producta ATCC 27340 as a model organism to develop understanding of MLG utilization. B. producta encodes a gene locus comprising a multi-modular cell-anchored endo-glucanase (BpGH16MLG), an ABC transporter, and a glycoside phosphorylase (BpGH94MLG) for utilizing MLG, as evidenced by the up-regulation of expression of the enzyme- and solute binding protein (SBP)-encoding genes in this cluster when the organism is grown on MLG. We determined that recombinant BpGH16MLG cleaved various types of β-glucan, generating oligosaccharides suitable for cellular uptake by B. producta. Cytoplasmic digestion of these oligosaccharides is then performed by recombinant BpGH94MLG and β-glucosidases (BpGH3-AR8MLG and BpGH3-X62MLG). Using targeted deletion, we demonstrated BpSBPMLG is essential for B. producta growth on barley β-glucan. Furthermore, we revealed that beneficial bacteria, such as Roseburia faecis JCM 17581T, Bifidobacterium pseudocatenulatum JCM 1200T, Bifidobacterium adolescentis JCM 1275T, and Bifidobacterium bifidum JCM 1254, can also utilize oligosaccharides resulting from the action of BpGH16MLG. Disentangling the β-glucan utilizing capability of B. producta provides a rational basis on which to consider the probiotic potential of this class of organism.
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May 2023
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I03-Macromolecular Crystallography
I04-1-Macromolecular Crystallography (fixed wavelength)
I04-Macromolecular Crystallography
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Alice R.
Cross
,
Sumita
Roy
,
Mirella
Vivoli Vega
,
Martin
Rejzek
,
Sergey A.
Nepogodiev
,
Matthew
Cliff
,
Debbie
Salmon
,
Michail N.
Isupov
,
Robert A.
Field
,
Joann L.
Prior
,
Nicholas J.
Harmer
Diamond Proposal Number(s):
[16378]
Open Access
Abstract: The sugars streptose and dihydrohydroxystreptose (DHHS) are unique to the bacteria Streptomyces griseus and Coxiella burnetii, respectively. Streptose forms the central moiety of the antibiotic streptomycin, whilst DHHS is found in the O-antigen of the zoonotic pathogen C. burnetii. Biosynthesis of these sugars has been proposed to follow a similar path to that of TDP-rhamnose, catalyzed by the enzymes RmlA, RmlB, RmlC, and RmlD, but the exact mechanism is unclear. Streptose and DHHS biosynthesis unusually requires a ring contraction step that could be performed by orthologues of RmlC or RmlD. Genome sequencing of S. griseus and C. burnetii has identified StrM and CBU1838 proteins as RmlC orthologues in these respective species. Here, we demonstrate that both enzymes can perform the RmlC 3’’,5’’ double epimerization activity necessary to support TDP-rhamnose biosynthesis in vivo. This is consistent with the ring contraction step being performed on a double epimerized substrate. We further demonstrate that proton exchange is faster at the 3’’-position than the 5’’-position, in contrast to a previously studied orthologue. We additionally solved the crystal structures of CBU1838 and StrM in complex with TDP, and show that they form an active site highly similar to those of the previously characterized enzymes RmlC, EvaD, and ChmJ. These results support the hypothesis that streptose and DHHS are biosynthesized using the TDP pathway and that an RmlD paralogue most likely performs ring contraction following double epimerization. This work will support the elucidation of the full pathways for biosynthesis of these unique sugars.
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Apr 2022
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I24-Microfocus Macromolecular Crystallography
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Diamond Proposal Number(s):
[13587]
Open Access
Abstract: Pectins are a major dietary nutrient source for the human gut microbiota (HGM). The prominent gut microbe Bacteroides thetaiotaomicron was recently shown to encode the founding member (BT1017) of a new family of pectin methylesterases (PMEs) essential for the metabolism of the complex pectin rhamnogalacturonan-II (RG-II). However, biochemical and structural knowledge of this family is lacking. Here, we showed that BT1017 is critical for the metabolism of an RG-II-derived oligosaccharide ΔBT1017oligoB generated by a BT1017 deletion mutant (ΔBT1017) during growth on carbohydrate extract from apple juice. Structural analyses of ΔBT1017oligoB using a combination of enzymatic, mass spectrometric and nuclear magnetic resonance approaches revealed that it is a bi-methylated nona-oligosaccharide GlcA-β1,4-(2-O-Me-Xyl-α1,3)-Fuc-α1,4-(GalA-β1,3)-Rha-α1,3-Api-β1,2-(Araf-α1,3)-(GalA-α1,4)-GalA containing components of the RG-II backbone and its side chains. We showed that the catalytic module of BT1017 adopts an alpha/beta (α/β) hydrolase fold, consisting of a central twisted 10-stranded β-sheet sandwiched by several α-helices. This constitutes a new fold for PMEs, which are predominantly right-handed β-helical proteins. Bioinformatics analyses revealed that the family is dominated by sequences from the prominent genera of the HGM, including Bacteroides and Prevotella. Our results not only highlight the critical role played by this family of enzymes in pectin metabolism but provide new insights into the molecular basis of the adaptation of B. thetaiotaomicron to the human gut.
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Oct 2020
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I03-Macromolecular Crystallography
I04-Macromolecular Crystallography
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Diamond Proposal Number(s):
[13467]
Open Access
Abstract: Glycoside phosphorylases (GPs) with specificity for β‐(1 → 3)‐gluco‐oligosaccharides are potential candidate biocatalysts for oligosaccharide synthesis. GPs with this linkage specificity are found in two families thus far—glycoside hydrolase family 94 (GH94) and the recently discovered glycoside hydrolase family 149 (GH149). Previously, we reported a crystallographic study of a GH94 laminaribiose phosphorylase with specificity for disaccharides, providing insight into the enzyme's ability to recognize its' sugar substrate/product. In contrast to GH94, characterized GH149 enzymes were shown to have more flexible chain length specificity, with preference for substrate/product with higher degree of polymerization. In order to advance understanding of the specificity of GH149 enzymes, we herein solved X‐ray crystallographic structures of GH149 enzyme Pro_7066 in the absence of substrate and in complex with laminarihexaose (G6). The overall domain organization of Pro_7066 is very similar to that of GH94 family enzymes. However, two additional domains flanking its catalytic domain were found only in the GH149 enzyme. Unexpectedly, the G6 complex structure revealed an oligosaccharide surface binding site remote from the catalytic site, which, we suggest, may be associated with substrate targeting. As such, this study reports the first structure of a GH149 phosphorylase enzyme acting on β‐(1 → 3)‐gluco‐oligosaccharides and identifies structural elements that may be involved in defining the specificity of the GH149 enzymes.
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May 2019
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I03-Macromolecular Crystallography
I04-Macromolecular Crystallography
I24-Microfocus Macromolecular Crystallography
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Diamond Proposal Number(s):
[13587]
Open Access
Abstract: The metabolism of carbohydrate polymers drives microbial diversity in the human gut microbiome. The selection pressures in this environment have spurred the evolution of a complex reservoir of microbial genes encoding carbohydrate-active enzymes (CAZymes). Previously, we have shown that the human gut bacterium Bacteroides thetaiotaomicron (Bt) can depolymerize the most structurally complex glycan, the plant pectin rhamnogalacturonan II (RGII), commonly found in the human diet. Previous investigation of the RGIIdegrading apparatus in Bt identified BT0997 as a new CAZyme family, classified as glycoside hydrolase 138 (GH138). The mechanism of substrate recognition by GH138, however, remains unclear. Here, using synthetic substrates and biochemical assays, we show that BT0997 targets the D-galacturonic acid-α-1,2-L-rhamnose linkage in chain A of RGII and that it absolutely requires the presence of a second D-galacturonic acid side chain (linked β-1,3 to L-rhamnose) for activity. NMR analysis revealed that BT0997 operates through a double-displacement, retaining mechanism. We also report the crystal structure of a BT0997 homolog, BPA0997 from Bacteroides paurosaccharolyticus, in complex with ligands at 1.6 Å resolution. The structure disclosed that the enzyme comprises four domains, including a catalytic TIM (α/β)8 barrel. Characterization of several BT0997 variants identified Glu-294 and Glu361 as the catalytic acid/base and nucleophile, respectively, and we observed a chloride ion close to the active site. The three-dimensional structure and bioinformatic analysis revealed that two arginines, Arg-332 and Arg-521, are key specificity determinants of BT0997 in targeting D-galacturonic acid residues. In summary, our study reports the first structural and mechanistic analyses of GH138 enzymes.
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Mar 2019
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I03-Macromolecular Crystallography
I04-Macromolecular Crystallography
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Diamond Proposal Number(s):
[13467]
Abstract: Glycoside phosphorylases (GPs) carry out a reversible phosphorolysis of carbohydrates into oligosaccharide acceptors and the corresponding sugar 1‐phosphates. The reversibility of the reaction enables the use of GPs as biocatalysts for carbohydrate synthesis. Glycosyl hydrolase family 94 (GH94), which only comprises GPs, is one of the most studied GP families that have been used as biocatalysts for carbohydrate synthesis, in academic research and in industrial production. Understanding the mechanism of GH94 enzymes is a crucial step towards enzyme engineering to improve and expand the applications of these enzymes in synthesis. In this work with a GH94 laminaribiose phosphorylase from Paenibacillus sp. YM1 (PsLBP), we have demonstrated an enzymatic synthesis of disaccharide 1 using natural acceptor glucose and non‐cognate donor substrate ‐mannose 1‐phosphate (Man1P). To investigate how the enzyme recognizes different sugar 1‐phosphates, we solved the X‐ray crystal structures of PsLBP in complex with Glc1P and Man1P, providing the first molecular detail of the recognition of a non‐cognate donor substrate by GPs, which revealed the importance of hydrogen bonding between the active site residues and hydroxyl groups at C2, C4 and C6 of sugar 1‐phosphates. Furthermore, we used STD NMR to support the crystallographic studies on the sugar 1‐phosphates, as well as to provide further insights into the PsLBP recognition of the acceptors and the disaccharide products.
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Jun 2018
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I03-Macromolecular Crystallography
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Diamond Proposal Number(s):
[13775]
Open Access
Abstract: The biosynthetic pathway of peptidoglycan is essential for Mycobacterium tuberculosis. We report here the acetyltransferase substrate specificity and catalytic mechanism of the bifunctional N-acetyltransferase/uridyltransferase from M. tuberculosis (GlmU). This enzyme is responsible for the final two steps of the synthesis of UDP-N-acetylglucosamine, which is an essential precursor of peptidoglycan, from glucosamine-1-phosphate, acetyl coenzyme A and uridine-5'-triphosphate. GlmU utilizes requires ternary complex formation to transfer an acetyl from acetyl coenzyme A to glucosamine-1-phosphate to form N-acetylglucosmaine-1-phosphate. Steady-state kinetic studies and equilibrium binding experiments indicate that GlmU follows a steady-state ordered kinetic mechanism, with acetyl coenzyme A binding first, which triggers a conformational change on GlmU, followed by glucosamine-1-phosphate binding. Coenzyme A is the last product to dissociate. Chemistry is partially rate-limiting as indicated by pH-rate studies and solvent kinetic isotope effects. A novel crystal structure of a mimic of the Michaelis complex, with glucose-1-phosphate and acetyl-coenzyme A, helps us to propose the residues involved in deprotonation of glucosamine-1-phosphate and the loop movement that likely generates the active site required for glucosamine-1-phosphate to bind. Together, these results pave the way for the rational discovery of improved inhibitors against M. tuberculosis GlmU, some of which might become candidates for antibiotic discovery programs.
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Apr 2018
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I04-1-Macromolecular Crystallography (fixed wavelength)
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Diamond Proposal Number(s):
[11175]
Abstract: Sorbitol-6-phosphate 2-dehydrogenases (S6PDH) catalyze the interconversion of d-sorbitol 6-phosphate to d-fructose 6-phosphate. In the plant pathogen Erwinia amylovora the S6PDH SrlD is used by the bacterium to utilize sorbitol, which is used for carbohydrate transport in the host plants belonging to the Amygdaloideae subfamily (e.g., apple, pear, and quince). We have determined the crystal structure of S6PDH SrlD at 1.84 Å resolution, which is the first structure of an EC 1.1.1.140 enzyme. Kinetic data show that SrlD is much faster at oxidizing d-sorbitol 6-phosphate than in reducing d-fructose 6-phosphate, however, equilibrium analysis revealed that only part of the d-sorbitol 6-phosphate present in the in vitro environment is converted into d-fructose 6-phosphate. The comparison of the structures of SrlD and Rhodobacter sphaeroides sorbitol dehydrogenase showed that the tetrameric quaternary structure, the catalytic residues and a conserved aspartate residue that confers specificity for NAD+ over NADP+ are preserved.
Analysis of the SrlD cofactor and substrate binding sites identified residues important for the formation of the complex with cofactor and substrate and in particular the role of Lys42 in selectivity towards the phospho-substrate. The comparison of SrlD backbone with the backbone of 302 short-chain dehydrogenases/reductases showed the conservation of the protein core and identified the variable parts. The SrlD sequence was compared with 500 S6PDH sequences selected by homology revealing that the C-terminal part is more conserved than the N-terminal, the consensus of the catalytic tetrad (Y[SN]AGXA) and a not previously described consensus for the NAD(H) binding.
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Mar 2018
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I02-Macromolecular Crystallography
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Diamond Proposal Number(s):
[7641]
Open Access
Abstract: The GH94 glycoside hydrolase cellodextrin phosphorylase (CDP, EC 2.4.1.49) produces cellodextrin oligomers from short β-1→4-glucans and α-D-glucose 1-phosphate. Compared to cellobiose phosphorylase (CBP), which produces cellobiose from glucose and α-D-glucose 1-phosphate, CDP is biochemically less well characterised. Herein, we investigate the donor and acceptor substrate specificity of recombinant CDP from Ruminiclostridium thermocellum and we isolate and characterise a glucosamine addition product to the cellobiose acceptor with the non-natural donor α-D-glucosamine 1-phosphate. In addition, we report the first X-ray crystal structure of CDP, along with comparison to the available structures from CBPs and other closely related enzymes, which contributes to understanding of the key structural features necessary to discriminate between monosaccharide (CBP) and oligosaccharide (CDP) acceptor substrates.
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Jul 2017
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I02-Macromolecular Crystallography
I04-1-Macromolecular Crystallography (fixed wavelength)
I24-Microfocus Macromolecular Crystallography
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Didier
Ndeh
,
Artur
Rogowski
,
Alan
Cartmell
,
Ana S.
Luis
,
Arnaud
Basle
,
Joseph
Gray
,
Immacolata
Venditto
,
Jonathon
Briggs
,
Xiaoyang
Zhang
,
Aurore
Labourel
,
Nicolas
Terrapon
,
Fanny
Buffetto
,
Sergey
Nepogodiev
,
Yao
Xiao
,
Robert A.
Field
,
Yanping
Zhu
,
Malcolm A.
O’neill
,
Breeanna R.
Urbanowicz
,
William S.
York
,
Gideon J.
Davies
,
D. Wade
Abbott
,
Marie-Christine
Ralet
,
Eric C.
Martens
,
Bernard
Henrissat
,
Harry J.
Gilbert
Diamond Proposal Number(s):
[1960, 7854, 9948]
Abstract: The metabolism of carbohydrate polymers drives microbial diversity in the human gut microbiota. It is unclear, however, whether bacterial consortia or single organisms are required to depolymerize highly complex glycans. Here we show that the gut bacterium Bacteroides thetaiotaomicron uses the most structurally complex glycan known: the plant pectic polysaccharide rhamnogalacturonan-II, cleaving all but 1 of its 21 distinct glycosidic linkages. The deconstruction of rhamnogalacturonan-II side chains and backbone are coordinated to overcome steric constraints, and the degradation involves previously undiscovered enzyme families and catalytic activities. The degradation system informs revision of the current structural model of rhamnogalacturonan-II and highlights how individual gut bacteria orchestrate manifold enzymes to metabolize the most challenging glycan in the human diet.
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Mar 2017
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