Structural and Kinetic Analysis of Schwanniomyces occidentalis Invertase Reveals a New Oligomerization Pattern and the Role of Its Supplementary Domain in Substrate Binding

Álvaro-Benito, Miguel; Polo, Aitana; González, Beatriz; Fernández-Lobato, María; Sanz‐Aparicio, Julia

doi:10.1074/jbc.m109.095430

Cited by 77 publications

(105 citation statements)

References 40 publications

(41 reference statements)

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“…This construct was used as a template to obtain all the mutants generated in this work. Site-directed mutagenesis was carried out using specific primers, including substitutions responsible for mutations N58S, D80A, N107S, E303A, E334S/E334N/E334V/E334Q, Q341N, N342S, H343A/H343T, N471S, and Y659STOP, and following the method described previously (21). DNA sequencing was used to verify that only the desired mutations were present in all the obtained constructs.…”

Section: Methodsmentioning

confidence: 99%

“…In the last decade, GH32 enzymes from bacteria (13,14), fungi (15)(16)(17), and plants (18 -20) have been the subject of many structural studies that showed that all are monomeric enzymes. Surprisingly, studies on Schwanniomyces occidentalis fructofuranosidase (SoFfase) (21) and Saccharomyces cerevisiae invertase (ScINV) (22) showed that these enzymes from yeast are unique in that they form dimers mediated by their ␤-sandwich domain, which in the case of ScINV associate into higher oligomers. The structural studies have delineated the main structural determinants of activity, the loops and turns connecting the different elements of the ␤-propeller domain, in the surroundings of the active site, defining the specificity unique to each enzyme (21,23).…”

mentioning

confidence: 99%

“…Surprisingly, studies on Schwanniomyces occidentalis fructofuranosidase (SoFfase) (21) and Saccharomyces cerevisiae invertase (ScINV) (22) showed that these enzymes from yeast are unique in that they form dimers mediated by their ␤-sandwich domain, which in the case of ScINV associate into higher oligomers. The structural studies have delineated the main structural determinants of activity, the loops and turns connecting the different elements of the ␤-propeller domain, in the surroundings of the active site, defining the specificity unique to each enzyme (21,23). However, and remarkably, oligomerization of the yeast enzymes regulates their functionality.…”

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confidence: 99%

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Structural Analysis of β-Fructofuranosidase from Xanthophyllomyces dendrorhous Reveals Unique Features and the Crucial Role of N-Glycosylation in Oligomerization and Activity

Ramirez-Escudero

Gimeno-Pérez

González

et al. 2016

Journal of Biological Chemistry

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Xanthophyllomyces dendrorhous ␤-fructofuranosidase (XdINV) is a highly glycosylated dimeric enzyme that hydrolyzes sucrose and releases fructose from various fructooligosaccharides (FOS) and fructans. It also catalyzes the synthesis of FOS, prebiotics that stimulate the growth of beneficial bacteria in human gut. In contrast to most fructosylating enzymes, XdINV produces neo-FOS, which makes it an interesting biotechnology target. We present here its three-dimensional structure, which shows the expected bimodular arrangement and also a long extension of its C terminus that together with an N-linked glycan mediate the formation of an unusual dimer. The two active sites of the dimer are connected by a long crevice, which might indicate its potential ability to accommodate branched fructans. This arrangement could be representative of a group of GH32 yeast enzymes having the traits observed in XdINV. The inactive D80A mutant was used to obtain complexes with relevant substrates and products, with their crystals structures showing at least four binding subsites at each active site. Moreover, two different positions are observed from subsite ؉2 depending on the substrate, and thus, a flexible loop (Glu-334 -His-343) is essential in binding sucrose and ␤(2-1)-linked oligosaccharides. Conversely, ␤(2-6) and neo-type substrates are accommodated mainly by stacking to Trp-105, explaining the production of neokestose and the efficient fructosylating activity of XdINV on ␣-glucosides. The role of relevant residues has been investigated by mutagenesis and kinetics measurements, and a model for the transfructosylating reaction has been proposed. The plasticity of its active site makes XdINV a valuable and flexible biocatalyst to produce novel bioconjugates.

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Section: Methodsmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Structural Analysis of β-Fructofuranosidase from Xanthophyllomyces dendrorhous Reveals Unique Features and the Crucial Role of N-Glycosylation in Oligomerization and Activity

Ramirez-Escudero

Gimeno-Pérez

González

et al. 2016

Journal of Biological Chemistry

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“…Higher 1-kestose levels for the parent highlighted the difference in activities, as this is the initial FOS species produced from sucrose. It in turn serves as the substrate for the formation of nystose and GF 4 . The fructose data for both enzymes were similar, which indicated that the hydrolytic activity was unchanged in the variant.…”

Section: Resultsmentioning

confidence: 99%

“…Also known as invertases (EC 3.2.1.26), they hydrolyze sucrose to produce invert sugar, an equimolar mixture of dextrorotatory D-glucose and levorotatory D-fructose (2). Crystal structures reveal that these enzymes display the bimodular arrangement of an N-terminal catalytic domain containing a fivebladed ␤-propeller fold linked to a C-terminal ␤-sandwich domain (3)(4)(5)(6). Multiple sequence alignments (MSAs) identified a highly conserved aspartate close to the N terminus that serves as the catalytic nucleophile and a glutamate residue that acts as a general acid/base catalyst (7).…”

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Semirational Directed Evolution of Loop Regions in Aspergillus japonicus β-Fructofuranosidase for Improved Fructooligosaccharide Production

Trollope

Görgens

Volschenk

2015

Appl Environ Microbiol

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bThe Aspergillus japonicus ␤-fructofuranosidase catalyzes the industrially important biotransformation of sucrose to fructooligosaccharides. Operating at high substrate loading and temperatures between 50 and 60°C, the enzyme activity is negatively influenced by glucose product inhibition and thermal instability. To address these limitations, the solvent-exposed loop regions of the ␤-fructofuranosidase were engineered using a combined crystal structure-and evolutionary-guided approach. This semirational approach yielded a functionally enriched first-round library of 36 single-amino-acid-substitution variants with 58% retaining activity, and of these, 71% displayed improved activities compared to the parent. The substitutions yielding the five most improved variants subsequently were exhaustively combined and evaluated. A four-substitution combination variant was identified as the most improved and reduced the time to completion of an efficient industrial-like reaction by 22%. Characterization of the top five combination variants by isothermal denaturation assays indicated that these variants displayed improved thermostability, with the most thermostable variant displaying a 5.7°C increased melting temperature. The variants displayed uniquely altered, concentration-dependent substrate and product binding as determined by differential scanning fluorimetry. The altered catalytic activity was evidenced by increased specific activities of all five variants, with the most improved variant doubling that of the parent. Variant homology modeling and computational analyses were used to rationalize the effects of amino acid changes lacking direct interaction with substrates. Data indicated that targeting substitutions to loop regions resulted in improved enzyme thermostability, specific activity, and relief from product inhibition.

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Synthesis of 6‐Kestose using an Efficient β‐Fructofuranosidase Engineered by Directed Evolution

et al. 2013

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The β-fructofuranosidase (Ffase) from Schwanniomyces occidentalis (Ffase-Leu196 variant) was subjected to four cycles of directed evolution to enhance the transglycosylation activity for the synthesis of β-(26) linked fructooligosaccharides (FOS). With a 5.5-fold improvement in fructose transferase activity over the parental type and greater selectivity for the synthesis of 6kestose (up to 73 % of the total FOS), the mutants doubled FOS synthesis to 168 g/L. Whilst the F523V and H510P mutations were located at the C-terminus of the protein, mutations Q78L and I203L were associated with the acidic catalytic triad where they modified its interactions with the surrounding residues, in turn varying the hydrolase and transferase rates.

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Structural and Kinetic Analysis of Schwanniomyces occidentalis Invertase Reveals a New Oligomerization Pattern and the Role of Its Supplementary Domain in Substrate Binding

Cited by 77 publications

References 40 publications

Structural Analysis of β-Fructofuranosidase from Xanthophyllomyces dendrorhous Reveals Unique Features and the Crucial Role of N-Glycosylation in Oligomerization and Activity

Structural Analysis of β-Fructofuranosidase from Xanthophyllomyces dendrorhous Reveals Unique Features and the Crucial Role of N-Glycosylation in Oligomerization and Activity

Semirational Directed Evolution of Loop Regions in Aspergillus japonicus β-Fructofuranosidase for Improved Fructooligosaccharide Production

Synthesis of 6‐Kestose using an Efficient β‐Fructofuranosidase Engineered by Directed Evolution

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