Structural Dynamics and Catalytic Properties of a Multimodular Xanthanase

Moroz, Olga V.; Jensen, Pernille Foged; McDonald, Sean; McGregor, N.G.S.; Blagova, E.V.; Comamala, Gerard; Seura, Dorotea R.; Anderson, Lars; Vasu, S; Rao, V.P.; Giger, Lars; Sørensen, Trine; Monrad, Rune Nygaard; Svendsen, Allan; Henrissat, Bernard; Davies, G.J.; Brumer, Harry; Rand, Kasper D.; Wilson, K.S.

doi:10.1021/acscatal.8b00666

Cited by 16 publications

(32 citation statements)

References 52 publications

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“…Surprisingly, the NMR analysis suggested that Ru GH5a cleaves XG at the reducing end of the non-branching backbone glucosyl residue ( Figure 3c, Extended Data 7 ). This contrasts with the product of other known xanthanases (such as the GH9 from Paenibacillus nanensis 35 or the β-D-glucanase in Bacillus sp. strain GL1 15 ), which hydrolyze xanthan at the reducing end of the branching glucose, demonstrating a hitherto unknown enzymatic mechanism for the degradation of XG.…”

Section: Introductionmentioning

confidence: 74%

“…strain GL1 15 ), which hydrolyze xanthan at the reducing end of the branching glucose, demonstrating a hitherto unknown enzymatic mechanism for the degradation of XG. While Ru GH5a displayed little activity on other polysaccharides ( Extended Data 6 ), it was able to hydrolyze both native and lyase-treated XG with comparable specificity, once more in contrast to most previously known xanthanases, which show ≥600-fold preference for the lyase-treated substrate 35 ( Figure 3d ). One exception is the xanthanase from Microbacterium sp.…”

Section: Introductionmentioning

confidence: 86%

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The Food Additive Xanthan Gum Drives Adaptation of the Human Gut Microbiota

Ostrowski

Rosa

Kunath

et al. 2021

Preprint

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The diets of industrialized countries reflect the increasing use of processed foods, often with the introduction of novel food additives. Xanthan gum is a complex polysaccharide with unique rheological properties that have established its use as a widespread stabilizer and thickening agent. However, little is known about its direct interaction with the gut microbiota, which plays a central role in digestion of other, chemically-distinct dietary fiber polysaccharides. Here, we show that the ability to digest xanthan gum is surprisingly common in industrialized human gut microbiomes and appears to be contingent on the activity of a single bacterium that is a member of an uncultured bacterial genus in the family Ruminococcaceae. We used a combination of enrichment culture, multi-omics, and recombinant enzyme studies to identify and characterize a complete pathway in this uncultured bacterium for the degradation of xanthan gum. Our data reveal that this keystone degrader cleaves the xanthan gum backbone with a novel glycoside hydrolase family 5 (GH5) enzyme before processing the released oligosaccharides using additional enzymes. Surprisingly, some individuals harbor a Bacteroides species that is capable of consuming oligosaccharide products generated by the keystone Ruminococcaceae or a purified form of the GH5 enzyme. This Bacteroides symbiont is equipped with its own distinct enzymatic pathway to cross-feed on xanthan gum breakdown products, which still harbor the native linkage complexity in xanthan gum, but it cannot directly degrade the high molecular weight polymer. Thus, the introduction of a common food additive into the human diet in the past 50 years has promoted the establishment of a food chain involving at least two members of different phyla of gut bacteria.

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Section: Introductionmentioning

confidence: 74%

Section: Introductionmentioning

confidence: 86%

The Food Additive Xanthan Gum Drives Adaptation of the Human Gut Microbiota

Ostrowski

Rosa

Kunath

et al. 2021

Preprint

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“…This endo-xanthanase is able to attack the backbone of XL-treated xanthan and possesses a CD belonging to glycoside hydrolase family 9 along with four additional domains constituted largely of b sheets. The latter of these corresponds to the module identified here, and has now been shown to bind xanthan, becoming the founding member of CBM family 84 (Moroz et al, 2018). Structurally related to CBM6, CBM35, and CBM36, the structure of PXL CBM84 is shown in Figure 2.…”

Section: Crystal Structure Of Pxlmentioning

confidence: 65%

“…As seen in the Results section, CBM84 is essential for full activity by PXL. Interestingly, truncation of the corresponding module did not impair the activity of the endo-xanthanase in Moroz et al (2018). Since initial sequence analysis indicated a relationship of CBM84 and X to CBM35, which are related to CBM6 and CBM36, pairwise structural similarity comparisons were carried out for both modules against all representatives of CBM6, CBM35, and CBM36.…”

Section: Discussionmentioning

confidence: 99%

“…Structurally related to CBM6, CBM35, and CBM36, the structure of PXL CBM84 is shown in Figure 2. Notably, the structure of the corresponding module in the endo-xanthanase could not be fully structurally characterized due to disorder (Moroz et al, 2018). The second module (referred to here as X) can be aligned with CBM84 with C a root-mean-square deviation (RMSD) of 2.51 A ˚over 119 out of 136 residues (Data S1) and the two modules are thus structurally related.…”

Section: Crystal Structure Of Pxlmentioning

confidence: 99%

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Structure and Dynamics of a Promiscuous Xanthan Lyase from Paenibacillus nanensis and the Design of Variants with Increased Stability and Activity

Jensen

Kadziola

Comamala

et al. 2019

Cell Chemical Biology

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Xanthan: enzymatic degradation and novel perspectives of applications

Berezina,

Rykov,

Schwarz

et al. 2024

Appl Microbiol Biotechnol

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The extracellular heteropolysaccharide xanthan, synthesized by bacteria of the genus Xanthomonas, is widely used as a thickening and stabilizing agent across the food, cosmetic, and pharmaceutical sectors. Expanding the scope of its application, current efforts target the use of xanthan to develop innovative functional materials and products, such as edible films, eco-friendly oil surfactants, and biocompatible composites for tissue engineering. Xanthan-derived oligosaccharides are useful as nutritional supplements and plant defense elicitors. Development and processing of such new functional materials and products often necessitate tuning of xanthan properties through targeted structural modification. This task can be effectively carried out with the help of xanthan-specific enzymes. However, the complex molecular structure and intricate conformational behavior of xanthan create problems with its enzymatic hydrolysis or modification. This review summarizes and analyzes data concerning xanthan-degrading enzymes originating from microorganisms and microbial consortia, with a particular focus on the dependence of enzymatic activity on the structure and conformation of xanthan. Through a comparative study of xanthan-degrading pathways found within various bacterial classes, different microbial enzyme systems for xanthan utilization have been identified. The characterization of these new enzymes opens new perspectives for modifying xanthan structure and developing innovative xanthan-based applications. Key points • The structure and conformation of xanthan affect enzymatic degradation. • Microorganisms use diverse multienzyme systems for xanthan degradation. • Xanthan-specific enzymes can be used to develop xanthan variants for novel applications.

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Structural Dynamics and Catalytic Properties of a Multimodular Xanthanase

Cited by 16 publications

References 52 publications

The Food Additive Xanthan Gum Drives Adaptation of the Human Gut Microbiota

The Food Additive Xanthan Gum Drives Adaptation of the Human Gut Microbiota

Structure and Dynamics of a Promiscuous Xanthan Lyase from Paenibacillus nanensis and the Design of Variants with Increased Stability and Activity

Xanthan: enzymatic degradation and novel perspectives of applications

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