Search for a dextransucrase minimal motif involved in dextran binding

Suwannarangsee, Surisa; Moulis, Claire; Potocki-Véronèse, Gabrielle; Monsan, Pierre; Remaud‐Siméon, Magali; Chulalaksananukul, Warawut

doi:10.1016/j.febslet.2007.08.062

Cited by 14 publications

(11 citation statements)

References 15 publications

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“…Isothermal titration calorimetry, as well as affinity gel electrophoreses, confirmed that DSR-MΔ2 affinity for dextran chains is mainly mediated by domain V, as no binding to dextran could be detected for DSR-MΔV (Figure S7 in the Supporting Information). However, in comparison to the nanomolar affinity estimated for dextran binding of GTF-I and DSR-S domain V fragments, 30,33 DSR-MΔ2 K d values were estimated at 10 mM for I6 and 300 μM for 68.4 kg mol −1 dextran, respectively, which are extremely high but are in agreement with the nonprocessive character of the enzyme.…”

Section: ■ Discussioncontrasting

confidence: 99%

“…reuteri 180 or the alternansucrase ASR from L. mesenteroides NRRL B-1355 synthesize two glucan populations, the first of very high molar mass (around 10 7 g mol –1 ) and the other comprising oligosaccharides or polymers of medium size (10 3 –10 4 g mol –1 ). − Several studies suggest that domain V, located at the N- and C-terminal extremity of the enzymes, plays a role in the polymer size through its capacity to bind glucans. ,, Indeed, domain V fragments are able to fold independently and strongly bind α-glucans with dissociation constants in the nanomolar range. ,− Called accordingly the glucan binding domain (GBD), this domain V contains repeated motifs derived from a common YG motif . The available crystal structures of GH70 enzymes unfortunately mostly concern truncated constructs, in which only a small part of the native domain V is visible. ,, Only very recently, several complexes of the ΔN123-GBD-CD2 branching sucrase with glucose, isomaltose (I2), and isomaltotriose (I3) provided the first structural evidence of sugar binding pockets with a common topology and directly interacting with carbohydrates in domain V .…”

Section: Introductionmentioning

confidence: 99%

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Investigations on the Determinants Responsible for Low Molar Mass Dextran Formation by DSR-M Dextransucrase

et al. 2017

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Certain enzymes of the GH70 family dextransucrases synthesize very high molar mass dextran polymers, whereas others produce a mixed population of very high and low molar mass products directly from sucrose substrate. Identifying the determinants dictating polymer elongation would allow the tight control of dextran size. To explore this central question, we focus on the recently discovered DSR-M enzyme from Leuconostoc citreum NRRL B-1299, which is the sole enzyme that naturally, exclusively, and very efficiently produces only low molar mass dextrans from sucrose. Extensive biochemical and structural characterization of a truncated form of DSR-M (DSR-MΔ2, displaying the same biochemical behavior as the parental enzyme) and X-ray structural analysis of complexes with sucrose and isomaltotetraose molecules together with accurate monitoring of the resulting polymer formation reveal that DSR-MΔ2 adopts a nonprocessive mechanism attributed to (i) a high propensity to recognize sucrose as a preferred acceptor at the initial stage of catalysis, (ii) an ability to elongate oligodextrans irrespective of their size, and (iii) the presence of a domain V showing a weak ability to bind to the growing dextran chains. In this study, we present the 3D structure with the largest defined domain V reported to date in the GH70 family and map sugar binding pockets on the basis of the structure of the complex obtained with isomaltotetraose. Altogether, these findings give insights into the interplay between the domain V and the catalytic site during polymerization. They open promising strategies for GH70 enzyme engineering aiming at modulating glucan size.

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Section: ■ Discussioncontrasting

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Investigations on the Determinants Responsible for Low Molar Mass Dextran Formation by DSR-M Dextransucrase

et al. 2017

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“…Repeated sequences are found in this domain and their role has been investigated since the 90s [ 92 , 94 , 166 , 169 , 170 ]. Their partial or total truncations influence the glucan binding ability and also modify the size of the synthesized polymer [ 77 , 94 , 119 , 123 , 160 , 171 , 172 , 173 , 174 , 175 , 176 , 177 , 178 ]. In particular, the glucan binding domain was proposed to be a major actor of the processive synthesis of high molar mass dextrans by providing anchoring platform with high affinity for the growing chain [ 119 ].…”

Section: Structure–function Relationshipsmentioning

confidence: 99%

Bacterial α-Glucan and Branching Sucrases from GH70 Family: Discovery, Structure–Function Relationship Studies and Engineering

et al. 2021

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Glucansucrases and branching sucrases are classified in the family 70 of glycoside hydrolases. They are produced by lactic acid bacteria occupying very diverse ecological niches (soil, buccal cavity, sourdough, intestine, dairy products, etc.). Usually secreted by their producer organisms, they are involved in the synthesis of α-glucans from sucrose substrate. They contribute to cell protection while promoting adhesion and colonization of different biotopes. Dextran, an α-1,6 linked linear α-glucan, was the first microbial polysaccharide commercialized for medical applications. Advances in the discovery and characterization of these enzymes have remarkably enriched the available diversity with new catalysts. Research into their molecular mechanisms has highlighted important features governing their peculiarities thus opening up many opportunities for engineering these catalysts to provide new routes for the transformation of sucrose into value-added molecules. This article reviews these different aspects with the ambition to show how they constitute the basis for promising future developments.

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“…Since the binding affinity of DBD to dextran is in the nmolar range 6 while the binding strength of agarose-binding domain to agarose is in the µmolar range 4,22 , the retention ability of the bound monomeric or tetrameric DBD to the Sephadex surface is much better than that of the monomeric or tetrameric agarose-binding domain to agarose. This makes DBD an attractive immobilization tool for affinity matrix preparation.…”

Section: Resultsmentioning

confidence: 99%

“…To extend the fusion protein based bio-coupling approach for affinity matrix preparation, the feasibility to use a dextran-binding domain (DBD) as a matrix immobilization tool was explored. DBD used in this study is a well characterized domain 6 from a monomeric Leuconostoc mesenteroides dextransucrase 7 . It has two key features.…”

Section: Introductionmentioning

confidence: 99%

A bio-coupling approach using a dextran-binding domain to immobilize an engineered streptavidin to Sephadex for easy preparation of affinity matrix

Wang

Chin

et al. 2019

Sci Rep

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An engineered streptavidin, SAVSBPM18 with reversible biotin binding capability, has been successfully applied to purify biotinylated and streptavidin-binding peptide (SBP) tagged proteins. To simplify the preparation for the SAVSBPM18 affinity matrix without chemical conjugation, two bio-coupling approaches were developed based on a 14-kDa dextran-binding domain (DBD) from a Leuconostoc mesenteroides dextransucrase. The first approach offers simplicity for bio-coupling by creating a direct fusion, SAVSBPM18-Linker-DBD. Purification of the fusion from crude extract and its immobilization to Sephadex can be consolidated in one-step. The second approach aims at flexibility. A SnoopCatcher (SC) was fused to DBD to create SC-Linker-DBD. This fusion can covalently capture any recombinant proteins tagged with a SnoopTag (ST) including SAVSBPM18-Linker-ST via the formation of an isopeptide bond at the interface through the SnoopCatcher-SnoopTag interaction. Although monomeric DBD binds to dextran with nanomolar affinity, DBD tetramerized via streptavidin (SAVSBPM18-Linker-ST·SC-Linker-DBD) showed an even tighter binding to Sephadex. The majority of the fluorescently labelled DBD tetramers were retained on the Sephadex surface even after four months. Affinity columns generated using either approach effectively purified both SBP-tagged and biotinylated proteins. These columns are reusable and functional even after a year of frequent use.

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Search for a dextransucrase minimal motif involved in dextran binding

Cited by 14 publications

References 15 publications

Investigations on the Determinants Responsible for Low Molar Mass Dextran Formation by DSR-M Dextransucrase

Investigations on the Determinants Responsible for Low Molar Mass Dextran Formation by DSR-M Dextransucrase

Bacterial α-Glucan and Branching Sucrases from GH70 Family: Discovery, Structure–Function Relationship Studies and Engineering

A bio-coupling approach using a dextran-binding domain to immobilize an engineered streptavidin to Sephadex for easy preparation of affinity matrix

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