An enzyme family reunion — similarities, differences and eccentricities in actions on α-glucans

Seo, Eun-Seong; Christiansen, C; Hachem, Maher Abou; Nielsen, Morten; Fukuda, Kenji; Bozonnet, Sophie; Blennow, Andreas; Aghajari, Nushin; Haser, R.; Svensson, Birte

doi:10.2478/s11756-008-0164-2

Cited by 8 publications

(4 citation statements)

References 77 publications

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“…Moreover, another preliminary work indicated that the starch binding to SBS2 in AMY2 is weaker than in AMY1. This finding was also confirmed by its crystal structure [ 32 ].…”

Section: Surface-binding Site In α -Amylasesupporting

confidence: 65%

The Importance of Surface-Binding Site towards Starch-Adsorptivity Level in α-Amylase: A Review on Structural Point of View

et al. 2017

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Starch is a polymeric carbohydrate composed of glucose. As a source of energy, starch can be degraded by various amylolytic enzymes, including α-amylase. In a large-scale industry, starch processing cost is still expensive due to the requirement of high temperature during the gelatinization step. Therefore, α-amylase with raw starch digesting ability could decrease the energy cost by avoiding the high gelatinization temperature. It is known that the carbohydrate-binding module (CBM) and the surface-binding site (SBS) of α-amylase could facilitate the substrate binding to the enzyme's active site to enhance the starch digestion. These sites are a noncatalytic module, which could interact with a lengthy substrate such as insoluble starch. The major interaction between these sites and the substrate is the CH/pi-stacking interaction with the glucose ring. Several mutation studies on the Halothermothrix orenii, SusG Bacteroides thetaiotamicron, Barley, Aspergillus niger, and Saccharomycopsis fibuligera α-amylases have revealed that the stacking interaction through the aromatic residues at the SBS is essential to the starch adsorption. In this review, the SBS in various α-amylases is also presented. Therefore, based on the structural point of view, SBS is suggested as an essential site in α-amylase to increase its catalytic activity, especially towards the insoluble starch.

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“…Moreover, another preliminary work indicated that the starch binding to SBS2 in AMY2 is weaker than in AMY1. This finding was also confirmed by its crystal structure [ 32 ].…”

Section: Surface-binding Site In α -Amylasesupporting

confidence: 65%

The Importance of Surface-Binding Site towards Starch-Adsorptivity Level in α-Amylase: A Review on Structural Point of View

et al. 2017

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“…Despite an extremely large number of available sequences (more than 4,500 CAZy entries) and almost 30 different enzyme specificities, the α-amylase family members possess several typical common features. These are (Svensson 1994;Kuriki & Imanaka 1999;MacGregor et al 2001;Janecek 1997Janecek , 2002avan der Maarel et al 2002;MacGregor 2005;Kuriki et al 2006;Seo et al 2008): (i) acting on α-glucosidic linkages, i.e. their hydrolysis or formation by transglycosylation; (ii) possessing from 4 up to 7 conserved sequence regions; (iii) adopting the parallel (β/α) 8 -barrel domain (i.e.…”

Section: Introductionmentioning

confidence: 99%

Domain evolution in the GH13 pullulanase subfamily with focus on the carbohydrate-binding module family 48

Martín

Janeček

2008

Biologia

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Glycoside hydrolase (GH) family 13 comprises about 30 different specificities. Four of them have been proposed to form the GH13 pullulanase subfamily: pullulanase, isoamylase, maltooligosyl trehalohydrolase and branching enzyme forming the seven CAZy GH13 subfamilies: GH13 8-GH13 14. Recently, a new family of carbohydrate-binding modules (CBMs), the family CBM48 has been established containing the putative starch-binding domains from the pullulanase subfamily, the β-subunit of AMP-activated protein kinase and some other GH13 enzymes with pullulanase and/or α-amylase-pullulanase specificity. Since all of these enzymes are multidomain proteins and the structure for at least one representative of each enzyme specificity has already been determined, the main goal of the present study was to elucidate domain evolution within this GH13 pullulanase subfamily (84 real enzymes) focusing on the CBM48 module. With regard to CBM48 positioning in the amino acid sequence, the N-terminal end of a protein appears to be a predominant position. This is especially true for isoamylases and maltooligosyl trehalohydrolases. Secondary structure-based alignment of CBM modules from CBM48, CBM20 and CBM21 revealed that several residues known as consensus for CBM20 and CBM21 could also be identified in CBM48, but only branching enzymes possess the aromatic residues that correspond with the two tryptophans forming the evolutionary conserved starch-binding site 1 in CBM20. The evolutionary trees constructed for the individual domains, complete alignment, and the conserved sequence regions of the α-amylase family were found to be comparable to each other (except for the C-domain tree) with two basic parts: (i) branching enzymes and maltooligosyl trehalohydrolases; and (ii) pullulanases and isoamylases. Taxonomy was respected only within clusters with pure specificity, i.e. the evolution of CBM48 reflects the evolution of specificities rather than evolution of species. This is a feature different from the one observed for the starch-binding domain of the family CBM20 where the starch-binding domain evolution reflects the evolution of species.

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“…Within GHs, the most abundant family across all nine microbiomes were GH13 (517 ORFs), of which 171 and 125 ORFs were found in T 9 -37 (in red) and T 9 -50 (in green), respectively (Figure 10 and Table 4). This family, together with GH4, GH31, GH57, GH63, GH97, and GH126, can be linked to starch degradation by encompassing starch-and pullulanmodifying enzymes, including α-amylases, pullulanases, α-1,6-glucosidases, neopullulanases, and cyclodextrinases [38]. From a biotechnological point of view, amylases are among the most important enzymes for the food industry and recently have found applications also in biofilm inhibition [39].…”

Section: Meta-functional Analysis Of Cazymesmentioning

confidence: 99%

Lignocellulolytic Potential of Microbial Consortia Isolated from a Local Biogas Plant: The Case of Thermostable Xylanases Secreted by Mesophilic Bacteria

Bombardi,

Salini,

Aulitto

et al. 2024

IJMS

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Lignocellulose biomasses (LCB), including spent mushroom substrate (SMS), pose environmental challenges if not properly managed. At the same time, these renewable resources hold immense potential for biofuel and chemicals production. With the mushroom market growth expected to amplify SMS quantities, repurposing or disposal strategies are critical. This study explores the use of SMS for cultivating microbial communities to produce carbohydrate-active enzymes (CAZymes). Addressing a research gap in using anaerobic digesters for enriching microbiomes feeding on SMS, this study investigates microbial diversity and secreted CAZymes under varied temperatures (37 °C, 50 °C, and 70 °C) and substrates (SMS as well as pure carboxymethylcellulose, and xylan). Enriched microbiomes demonstrated temperature-dependent preferences for cellulose, hemicellulose, and lignin degradation, supported by thermal and elemental analyses. Enzyme assays confirmed lignocellulolytic enzyme secretion correlating with substrate degradation trends. Notably, thermogravimetric analysis (TGA), coupled with differential scanning calorimetry (TGA-DSC), emerged as a rapid approach for saccharification potential determination of LCB. Microbiomes isolated at mesophilic temperature secreted thermophilic hemicellulases exhibiting robust stability and superior enzymatic activity compared to commercial enzymes, aligning with biorefinery conditions. PCR-DGGE and metagenomic analyses showcased dynamic shifts in microbiome composition and functional potential based on environmental conditions, impacting CAZyme abundance and diversity. The meta-functional analysis emphasised the role of CAZymes in biomass transformation, indicating microbial strategies for lignocellulose degradation. Temperature and substrate specificity influenced the degradative potential, highlighting the complexity of environmental–microbial interactions. This study demonstrates a temperature-driven microbial selection for lignocellulose degradation, unveiling thermophilic xylanases with industrial promise. Insights gained contribute to optimizing enzyme production and formulating efficient biomass conversion strategies. Understanding microbial consortia responses to temperature and substrate variations elucidates bioconversion dynamics, emphasizing tailored strategies for harnessing their biotechnological potential.

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An enzyme family reunion — similarities, differences and eccentricities in actions on α-glucans

Cited by 8 publications

References 77 publications

The Importance of Surface-Binding Site towards Starch-Adsorptivity Level in α-Amylase: A Review on Structural Point of View

The Importance of Surface-Binding Site towards Starch-Adsorptivity Level in α-Amylase: A Review on Structural Point of View

Domain evolution in the GH13 pullulanase subfamily with focus on the carbohydrate-binding module family 48

Lignocellulolytic Potential of Microbial Consortia Isolated from a Local Biogas Plant: The Case of Thermostable Xylanases Secreted by Mesophilic Bacteria

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