Multitasking in the gut: the X-ray structure of the multidomain BbgIII from Bifidobacterium bifidum offers possible explanations for its alternative functions

2021 ◽  
Vol 77 (12) ◽  
Author(s):  
Olga V. Moroz ◽  
Elena Blagova ◽  
Andrey A. Lebedev ◽  
Filomeno Sánchez Rodríguez ◽  
Daniel J. Rigden ◽  
...  
Keyword(s):  
Active Site ◽  
Model Building ◽  
Catalytic Domain ◽  
Bifidobacterium Bifidum ◽  
Host Cells ◽  
Intact Protein ◽  
Lactose Hydrolysis ◽  
Carbohydrate Binding ◽  
X Ray ◽  
Carbohydrate Binding Modules

β-Galactosidases catalyse the hydrolysis of lactose into galactose and glucose; as an alternative reaction, some β-galactosidases also catalyse the formation of galactooligosaccharides by transglycosylation. Both reactions have industrial importance: lactose hydrolysis is used to produce lactose-free milk, while galactooligosaccharides have been shown to act as prebiotics. For some multi-domain β-galactosidases, the hydrolysis/transglycosylation ratio can be modified by the truncation of carbohydrate-binding modules. Here, an analysis of BbgIII, a multidomain β-galactosidase from Bifidobacterium bifidum, is presented. The X-ray structure has been determined of an intact protein corresponding to a gene construct of eight domains. The use of evolutionary covariance-based predictions made sequence docking in low-resolution areas of the model spectacularly easy, confirming the relevance of this rapidly developing deep-learning-based technique for model building. The structure revealed two alternative orientations of the CBM32 carbohydrate-binding module relative to the GH2 catalytic domain in the six crystallographically independent chains. In one orientation the CBM32 domain covers the entrance to the active site of the enzyme, while in the other orientation the active site is open, suggesting a possible mechanism for switching between the two activities of the enzyme, namely lactose hydrolysis and transgalactosylation. The location of the carbohydrate-binding site of the CBM32 domain on the opposite site of the module to where it comes into contact with the catalytic GH2 domain is consistent with its involvement in adherence to host cells. The role of the CBM32 domain in switching between hydrolysis and transglycosylation modes offers protein-engineering opportunities for selective β-galactosidase modification for industrial purposes in the future.

scholarly journals Enzymatic Adaptation of Bifidobacterium bifidum to Host Glycans, Viewed from Glycoside Hydrolyases and Carbohydrate-Binding Modules

2020 ◽  
Vol 8 (4) ◽  
pp. 481 ◽  
Author(s):  
Toshihiko Katoh ◽  
Miriam N. Ojima ◽  
Mikiyasu Sakanaka ◽  
Hisashi Ashida ◽  
Aina Gotoh ◽  
...  
Keyword(s):  
Carbon Sources ◽  
Bifidobacterium Bifidum ◽  
Glycoside Hydrolases ◽  
Altruistic Behavior ◽  
Carbohydrate Binding ◽  
Human Gut ◽  
Genetic Characteristics ◽  
Beneficial Effects ◽  
Carbohydrate Binding Modules ◽  
Enzymatic Machinery

Certain species of the genus Bifidobacterium represent human symbionts. Many studies have shown that the establishment of symbiosis with such bifidobacterial species confers various beneficial effects on human health. Among the more than ten (sub)species of human gut-associated Bifidobacterium that have significantly varied genetic characteristics at the species level, Bifidobacterium bifidum is unique in that it is found in the intestines of a wide age group, ranging from infants to adults. This species is likely to have adapted to efficiently degrade host-derived carbohydrate chains, such as human milk oligosaccharides (HMOs) and mucin O-glycans, which enabled the longitudinal colonization of intestines. The ability of this species to assimilate various host glycans can be attributed to the possession of an adequate set of extracellular glycoside hydrolases (GHs). Importantly, the polypeptides of those glycosidases frequently contain carbohydrate-binding modules (CBMs) with deduced affinities to the target glycans, which is also a distinct characteristic of this species among members of human gut-associated bifidobacteria. This review firstly describes the prevalence and distribution of B. bifidum in the human gut and then explains the enzymatic machinery that B. bifidum has developed for host glycan degradation by referring to the functions of GHs and CBMs. Finally, we show the data of co-culture experiments using host-derived glycans as carbon sources, which underpin the interesting altruistic behavior of this species as a cross-feeder.

scholarly journals Glucoamylase starch-binding domain of Aspergillus niger B1: molecular cloning and functional characterization

2003 ◽  
Vol 372 (3) ◽  
pp. 905-910 ◽  
Author(s):  
Tzur PALDI ◽  
Ilan LEVY ◽  
Oded SHOSEYOV
Keyword(s):  
Aspergillus Niger ◽  
Corn Starch ◽  
Catalytic Domain ◽  
Functional Characterization ◽  
Carbohydrate Binding ◽  
Amylolytic Enzymes ◽  
Binding Domains ◽  
C Terminus ◽  
Carbohydrate Binding Modules ◽  
Modified Starches

Carbohydrate-binding modules (CBMs) are protein domains located within a carbohydrate-active enzyme, with a discrete fold that can be separated from the catalytic domain. Starch-binding domains (SBDs) are CBMs that are usually found at the C-terminus in many amylolytic enzymes. The SBD from Aspergillus niger B1 (CMI CC 324262) was cloned and expressed in Escherichia coli as an independent domain and the recombinant protein was purified on starch. The A. niger B1 SBD was found to be similar to SBD from A. kawachii, A. niger var. awamori and A. shirusami (95–96% identity) and was classified as a member of the CBM family 20. Characterization of SBD binding to starch indicated that it is essentially irreversible and that its affinity to cationic or anionic starch, as well as to potato or corn starch, does not differ significantly. These observations indicate that the fundamental binding area on these starches is essentially the same. Natural and chemically modified starches are among the most useful biopolymers employed in the industry. Our study demonstrates that SBD binds effectively to both anionic and cationic starch.

scholarly journals Spatially remote motifs cooperatively affect substrate preference of a ruminal GH26-type endo-β-1,4-mannanase

2020 ◽  
Vol 295 (15) ◽  
pp. 5012-5021 ◽  
Author(s):  
Fernanda Mandelli ◽  
Mariana Abrahão Bueno de Morais ◽  
Evandro Antonio de Lima ◽  
Leane Oliveira ◽  
Gabriela Felix Persinoti ◽  
...  
Keyword(s):  
Catalytic Domain ◽  
Substrate Binding ◽  
Substrate Recognition ◽  
Systematic Investigation ◽  
Substrate Preference ◽  
Carbohydrate Binding ◽  
Carbohydrate Binding Modules ◽  
Binding Cleft ◽  
Aromatic Cluster ◽  
Shed Light

β-Mannanases from the glycoside hydrolase 26 (GH26) family are retaining hydrolases that are active on complex heteromannans and whose genes are abundant in rumen metagenomes and metatranscriptomes. These enzymes can exhibit distinct modes of substrate recognition and are often fused to carbohydrate-binding modules (CBMs), resulting in a molecular puzzle of mechanisms governing substrate preference and mode of action that has not yet been pieced together. In this study, we recovered a novel GH26 enzyme with a CBM35 module linked to its N terminus (CrMan26) from a cattle rumen metatranscriptome. CrMan26 exhibited a preference for galactomannan as substrate and the crystal structure of the full-length protein at 1.85 Å resolution revealed a unique orientation of the ancillary domain relative to the catalytic interface, strategically positioning a surface aromatic cluster of the ancillary domain as an extension of the substrate-binding cleft, contributing to galactomannan preference. Moreover, systematic investigation of nonconserved residues in the catalytic interface unveiled that residues Tyr195 (−3 subsite) and Trp234 (−5 subsite) from distal negative subsites have a key role in galactomannan preference. These results indicate a novel and complex mechanism for substrate recognition involving spatially remote motifs, distal negative subsites from the catalytic domain, and a surface-associated aromatic cluster from the ancillary domain. These findings expand our molecular understanding of the mechanisms of substrate binding and recognition in the GH26 family and shed light on how some CBMs and their respective orientation can contribute to substrate preference.

scholarly journals Cloning, purification, crystallization and preliminary X-ray studies of a carbohydrate-binding module (CBM_E1) derived from sugarcane soil metagenome

2014 ◽  
Vol 70 (9) ◽  
pp. 1232-1235 ◽  
Author(s):  
Bruna Medeia Campos ◽  
Thabata Maria Alvarez ◽  
Marcelo Vizona Liberato ◽  
Igor Polikarpov ◽  
Harry J. Gilbert ◽  
...  
Keyword(s):  
Fossil Fuels ◽  
Plant Biomass ◽  
Metagenomic Library ◽  
Glycoside Hydrolases ◽  
Diffusion Method ◽  
Carbohydrate Binding ◽  
X Ray Diffraction ◽  
X Ray ◽  
Cell Parameters ◽  
Carbohydrate Binding Modules

In recent years, owing to the growing global demand for energy, dependence on fossil fuels, limited natural resources and environmental pollution, biofuels have attracted great interest as a source of renewable energy. However, the production of biofuels from plant biomass is still considered to be an expensive technology. In this context, the study of carbohydrate-binding modules (CBMs), which are involved in guiding the catalytic domains of glycoside hydrolases for polysaccharide degradation, is attracting growing attention. Aiming at the identification of new CBMs, a sugarcane soil metagenomic library was analyzed and an uncharacterized CBM (CBM_E1) was identified. In this study, CBM_E1 was expressed, purified and crystallized. X-ray diffraction data were collected to 1.95 Å resolution. The crystals, which were obtained by the sitting-drop vapour-diffusion method, belonged to space groupI23, with unit-cell parametersa=b=c= 88.07 Å.

scholarly journals The modular architecture of Cellvibrio japonicus mannanases in glycoside hydrolase families 5 and 26 points to differences in their role in mannan degradation

2003 ◽  
Vol 371 (3) ◽  
pp. 1027-1043 ◽  
Author(s):  
Deborah HOGG ◽  
Gavin PELL ◽  
Paul DUPREE ◽  
Florence GOUBET ◽  
Susana M. MARTÍN-ORÚE ◽  
...  
Keyword(s):  
Glycoside Hydrolase ◽  
Plant Cell Wall ◽  
Catalytic Domain ◽  
Glycoside Hydrolases ◽  
Crystalline Cellulose ◽  
Carbohydrate Binding ◽  
Molecular Architecture ◽  
Catalytic Domains ◽  
Carbohydrate Binding Modules ◽  
Cellvibrio Japonicus

β-1,4-Mannanases (mannanases), which hydrolyse mannans and glucomannans, are located in glycoside hydrolase families (GHs) 5 and 26. To investigate whether there are fundamental differences in the molecular architecture and biochemical properties of GH5 and GH26 mannanases, four genes encoding these enzymes were isolated from Cellvibrio japonicus and the encoded glycoside hydrolases were characterized. The four genes, man5A, man5B, man5C and man26B, encode the mannanases Man5A, Man5B, Man5C and Man26B, respectively. Man26B consists of an N-terminal signal peptide linked via an extended serine-rich region to a GH26 catalytic domain. Man5A, Man5B and Man5C contain GH5 catalytic domains and non-catalytic carbohydrate-binding modules (CBMs) belonging to families 2a, 5 and 10; Man5C in addition contains a module defined as X4 of unknown function. The family 10 and 2a CBMs bound to crystalline cellulose and ivory nut crystalline mannan, displaying very similar properties to the corresponding family 10 and 2a CBMs from Cellvibrio cellulases and xylanases. CBM5 bound weakly to these crystalline polysaccharides. The catalytic domains of Man5A, Man5B and Man26B hydrolysed galactomannan and glucomannan, but displayed no activity against crystalline mannan or cellulosic substrates. Although Man5C was less active against glucomannan and galactomannan than the other mannanases, it did attack crystalline ivory nut mannan. All the enzymes exhibited classic endo-activity producing a mixture of oligosaccharides during the initial phase of the reaction, although their mode of action against manno-oligosaccharides and glucomannan indicated differences in the topology of the respective substrate-binding sites. This report points to a different role for GH5 and GH26 mannanases from C. japonicus. We propose that as the GH5 enzymes contain CBMs that bind crystalline polysaccharides, these enzymes are likely to target mannans that are integral to the plant cell wall, while GH26 mannanases, which lack CBMs and rapidly release mannose from polysaccharides and oligosaccharides, target the storage polysaccharide galactomannan and manno-oligosaccharides.

scholarly journals Comparative Analyses of Two Thermophilic Enzymes Exhibiting both β-1,4 Mannosidic and β-1,4 Glucosidic Cleavage Activities from Caldanaerobius polysaccharolyticus

2010 ◽  
Vol 192 (16) ◽  
pp. 4111-4121 ◽  
Author(s):  
Yejun Han ◽  
Dylan Dodd ◽  
Charles W. Hespen ◽  
Samuel Ohene-Adjei ◽  
Charles M. Schroeder ◽  
...  
Keyword(s):  
Catalytic Domain ◽  
Biochemical Properties ◽  
Degree Of Polymerization ◽  
Glycoside Hydrolase Family ◽  
Carbohydrate Binding ◽  
Biofuel Industry ◽  
Carbohydrate Binding Modules ◽  
Mannanase Activity ◽  
Hydrolysis Of ◽  
Derivatives Of

ABSTRACT The hydrolysis of polysaccharides containing mannan requires endo-1,4-β-mannanase and 1,4-β-mannosidase activities. In the current report, the biochemical properties of two endo-β-1,4-mannanases (Man5A and Man5B) from Caldanaerobius polysaccharolyticus were studied. Man5A is composed of an N-terminal signal peptide (SP), a catalytic domain, two carbohydrate-binding modules (CBMs), and three surface layer homology (SLH) repeats, whereas Man5B lacks the SP, CBMs, and SLH repeats. To gain insights into how the two glycoside hydrolase family 5 (GH5) enzymes may aid the bacterium in energy acquisition and also the potential application of the two enzymes in the biofuel industry, two derivatives of Man5A (Man5A-TM1 [TM1 stands for truncational mutant 1], which lacks the SP and SLH repeats, and Man5A-TM2, which lacks the SP, CBMs, and SLH repeats) and the wild-type Man5B were biochemically analyzed. The Man5A derivatives displayed endo-1,4-β-mannanase and endo-1,4-β-glucanase activities and hydrolyzed oligosaccharides with a degree of polymerization (DP) of 4 or higher. Man5B exhibited endo-1,4-β-mannanase activity and little endo-1,4-β-glucanase activity; however, this enzyme also exhibited 1,4-β-mannosidase and cellodextrinase activities. Man5A-TM1, compared to either Man5A-TM2 or Man5B, had higher catalytic activity with soluble and insoluble polysaccharides, indicating that the CBMs enhance catalysis of Man5A. Furthermore, Man5A-TM1 acted synergistically with Man5B in the hydrolysis of β-mannan and carboxymethyl cellulose. The versatility of the two enzymes, therefore, makes them a resource for depolymerization of mannan-containing polysaccharides in the biofuel industry. Furthermore, on the basis of the biochemical and genomic data, a molecular mechanism for utilization of mannan-containing nutrients by C. polysaccharolyticus is proposed.

The evolutionary origin and possible functional roles of FNIII domains in two Microbacterium aurum B8.A granular starch degrading enzymes, and in other carbohydrate acting enzymes

Amylase ◽  
2017 ◽  
Vol 1 (1) ◽  
pp. 1-11 ◽  
Author(s):  
Vincent Valk ◽  
Rachel M. van der Kaaij ◽  
Lubbert Dijkhuizen
Keyword(s):  
Protein Interactions ◽  
Catalytic Domain ◽  
Substrate Surface ◽  
Carbohydrate Binding ◽  
Protein Protein Interactions ◽  
Functional Roles ◽  
Cazy Database ◽  
Carbohydrate Binding Modules ◽  
Fibronectin Type Iii

AbstractFibronectin type III (FNIII) domains were first identified in the eukaryotic plasma protein fibronectin, where they act as structural spacers or enable protein-protein interactions. Recently we characterized two large and multi-domain amylases in Microbacterium aurum B8.A that both carry multiple FNIII and carbohydrate binding modules (CBMs). The role of (multiple) FNIII domains in such carbohydrate acting enzymes is currently unclear. Four hypothetical functions are considered here: a substrate surface disruption domain, a carbohydrate binding module, as a stable linker, or enabling protein-protein interactions. We performed a phylogenetic analysis of all FNIII domains identified in proteins listed in the CAZy database. These data clearly show that the FNIII domains in eukaryotic and archaeal CAZy proteins are of bacterial origin and also provides examples of interkingdom gene transfer from Bacteria to Archaea and Eucarya. FNIII domains occur in a wide variety of CAZy enzymes acting on many different substrates, suggesting that they have a non-specific role in these proteins. While CBM domains are mostly found at protein termini, FNIII domains are commonly located between other protein domains. FNIII domains in carbohydrate acting enzymes thus may function mainly as stable linkers to allow optimal positioning and/or flexibility of the catalytic domain and other domains, such as CBM.

scholarly journals Crystallization and preliminary crystallographic studies of a novel noncatalytic carbohydrate-binding module from theRuminococcus flavefacienscellulosome

2015 ◽  
Vol 71 (1) ◽  
pp. 45-48 ◽  
Author(s):  
Immacolata Venditto ◽  
Arun Goyal ◽  
Andrew Thompson ◽  
Luis M. A. Ferreira ◽  
Carlos M. G. A. Fontes ◽  
...  
Keyword(s):  
Cell Wall ◽  
Plant Cell ◽  
Plant Cell Wall ◽  
Catalytic Domain ◽  
Glycoside Hydrolase Family ◽  
Carbohydrate Binding ◽  
Cellulolytic Bacterium ◽  
Modular Architecture ◽  
Carbohydrate Binding Modules ◽  
Fundamental Biological Process

Microbial degradation of the plant cell wall is a fundamental biological process with considerable industrial importance. Hydrolysis of recalcitrant polysaccharides is orchestrated by a large repertoire of carbohydrate-active enzymes that display a modular architecture in which a catalytic domain is connectedvialinker sequences to one or more noncatalytic carbohydrate-binding modules (CBMs). CBMs direct the appended catalytic modules to their target substrates, thus potentiating catalysis. The genome of the most abundant ruminal cellulolytic bacterium,Ruminococcus flavefaciensstrain FD-1, provides an opportunity to discover novel cellulosomal proteins involved in plant cell-wall deconstruction. It encodes a modular protein comprising a glycoside hydrolase family 9 catalytic module (GH9) linked to two unclassified tandemly repeated CBMs (termed CBM-Rf6A and CBM-Rf6B) and a C-terminal dockerin. The novel CBM-Rf6A from this protein has been crystallized and data were processed for the native and a selenomethionine derivative to 1.75 and 1.5 Å resolution, respectively. The crystals belonged to orthorhombic and cubic space groups, respectively. The structure was solved by a single-wavelength anomalous dispersion experiment using theCCP4 program suite andSHELXC/D/E.

scholarly journals Crystallization, neutron data collection, initial structure refinement and analysis of a xyloglucan heptamer bound to an engineered carbohydrate-binding module from xylanase

2015 ◽  
Vol 71 (8) ◽  
pp. 1072-1077 ◽  
Author(s):  
Mats Ohlin ◽  
Laura von Schantz ◽  
Tobias E. Schrader ◽  
Andreas Ostermann ◽  
Derek T. Logan ◽  
...  
Keyword(s):  
Protein Interactions ◽  
Structure Refinement ◽  
Carbohydrate Binding ◽  
Initial Structure ◽  
Data Sets ◽  
Rhodothermus Marinus ◽  
Structural Determinants ◽  
X Ray ◽  
Carbohydrate Binding Modules ◽  
Hydrolyzing Enzymes

Carbohydrate-binding modules (CBMs) are discrete parts of carbohydrate-hydrolyzing enzymes that bind specific types of carbohydrates. Ultra high-resolution X-ray crystallographic studies of CBMs have helped to decipher the basis for specificity in carbohydrate–protein interactions. However, additional studies are needed to better understand which structural determinants confer which carbohydrate-binding properties. To address these issues, neutron crystallographic studies were initiated on one experimentally engineered CBM derived from a xylanase, X-2 L110F, a protein that is able to bind several different plant carbohydrates such as xylan, β-glucan and xyloglucan. This protein evolved from a CBM present in xylanase Xyn10A ofRhodothermus marinus. The protein was complexed with a branched xyloglucan heptasaccharide. Large single crystals of hydrogenous protein (∼1.6 mm3) were grown at room temperature and subjected to H/D exchange. Both neutron and X-ray diffraction data sets were collected to 1.6 Å resolution. Joint neutron and X-ray refinement usingphenix.refineshowed significant density for residues involved in carbohydrate binding and revealed the details of a hydrogen-bonded water network around the binding site. This is the first report of a neutron structure of a CBM and will add to the understanding of protein–carbohydrate binding interactions.

scholarly journals The structure of a glycoside hydrolase 29 family member from a rumen bacterium reveals unique, dual carbohydrate-binding domains

2016 ◽  
Vol 72 (10) ◽  
pp. 750-761 ◽  
Author(s):  
Emma L. Summers ◽  
Christina D. Moon ◽  
Renee Atua ◽  
Vickery L. Arcus
Keyword(s):  
Glycoside Hydrolase ◽  
Catalytic Domain ◽  
Binding Domain ◽  
Carbohydrate Binding ◽  
Catalytic Core ◽  
Binding Domains ◽  
Carbohydrate Binding Modules ◽  
Tim Barrel ◽  
Domain Arrangement ◽  
Hydrolysis Of

Glycoside hydrolase (GH) family 29 consists solely of α-L-fucosidases. These enzymes catalyse the hydrolysis of glycosidic bonds. Here, the structure of GH29_0940, a protein cloned from metagenomic DNA from the rumen of a cow, has been solved, which reveals a multi-domain arrangement that has only recently been identified in bacterial GH29 enzymes. The microbial species that provided the source of this enzyme is unknown. This enzyme contains a second carbohydrate-binding domain at its C-terminal end in addition to the typical N-terminal catalytic domain and carbohydrate-binding domain arrangement of GH29-family proteins. GH29_0940 is a monomer and its overall structure consists of an N-terminal TIM-barrel-like domain, a central β-sandwich domain and a C-terminal β-sandwich domain. The TIM-barrel-like catalytic domain exhibits a (β/α)8/7arrangement in the core instead of the typical (β/α)8topology, with the `missing' α-helix replaced by a long meandering loop that `closes' the barrel structure and suggests a high degree of structural flexibility in the catalytic core. This feature was also noted in all six other structures of GH29 enzymes that have been deposited in the PDB. Based on sequence and structural similarity, the residues Asp162 and Glu220 are proposed to serve as the catalytic nucleophile and the proton donor, respectively. Like other GH29 enzymes, the GH29_0940 structure shows five strictly conserved residues in the catalytic pocket. The structure shows two glycerol molecules in the active site, which have also been observed in other GH29 structures, suggesting that the enzyme catalyses the hydrolysis of small carbohydrates. The two binding domains are classed as family 32 carbohydrate-binding modules (CBM32). These domains have residues involved in ligand binding in the loop regions at the edge of the β-sandwich. The predicted substrate-binding residues differ between the modules, suggesting that different modules bind to different groups on the substrate(s). Enzymes that possess multiple copies of CBMs are thought to have a complex mechanism of ligand recognition. Defined electron density identifying a long 20-amino-acid hydrophilic loop separating the two CBMs was observed. This suggests that the additional C-terminal domain may have a dynamic range of movement enabled by the loop, allowing a unique mode of action for a GH29 enzyme that has not been identified previously.

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