Plant vascular system-feeding Psyllidae (Hemiptera) and Nematoda genomes encode family 12 glycosyl hydrolases

2019 ◽  
Vol 151 (3) ◽  
pp. 291-297
Author(s):  
Richard W. Jones
Keyword(s):  
Plant Cell Wall ◽  
Vascular Tissue ◽  
Vascular System ◽  
Glycosyl Hydrolase ◽  
Expression System ◽  
Root Tip ◽  
Glycosyl Hydrolases ◽  
Endoglucanase Activity ◽  
Intron Structure ◽  
Hydrolase Family

AbstractInsect-encoded cellulolytic plant cell wall hydrolases have thus far been found mostly from glycosyl hydrolase family 5, 9, 10, and 45. We now report the first evidence for genomic encoding of family 12 glycosyl hydrolases in vascular feeding Psyllidae (Hemiptera) and Nematoda. The genes were identified in three psyllids (Acanthocasuarina muellerianae Taylor, Pachypsylla venusta (Osten-Sacken), and Diaphorina citri Kuwayama) and a root tip feeding dagger nematode (Xiphinema index Thorne and Allen; Dorylaimida: Longidoridae). While the final gene products were highly similar, the genomic intron structure varied, having a 2 kB intron in P. venusta, a 283 base-pair intron in D. citri, and no intron in X. index. Endoglucanase activity was demonstrated using the D. citri genes in an Agrobacterium Conn (Rhizobiaceae) infiltration-based plant expression system. The presence of family 12 endoglucanases in this set of insects suggests a specific role in facilitating feeding on vascular tissue.

scholarly journals A constitutive expression system for glycosyl hydrolase family 7 cellobiohydrolases in Hypocrea jecorina

2015 ◽  
Vol 8 (1) ◽  
Author(s):  
Jeffrey G Linger ◽  
Larry E Taylor ◽  
John O Baker ◽  
Todd Vander Wall ◽  
Sarah E Hobdey ◽  
...  
Keyword(s):  
Glycosyl Hydrolase ◽  
Expression System ◽  
Constitutive Expression ◽  
Hypocrea Jecorina ◽  
Glycosyl Hydrolase Family ◽  
Hydrolase Family

scholarly journals Growth of Azospirillum irakense KBC1 on the Aryl β-Glucoside Salicin Requires either salA or salB

1999 ◽  
Vol 181 (10) ◽  
pp. 3003-3009 ◽  
Author(s):  
Denis Faure ◽  
Jos Desair ◽  
Veerle Keijers ◽  
My Ali Bekri ◽  
Paul Proost ◽  
...  
Keyword(s):  
Microbial Growth ◽  
Glycosyl Hydrolase ◽  
Cosmid Library ◽  
Glycosyl Hydrolases ◽  
Amino Acid Similarity ◽  
Functional Homology ◽  
Low Degree ◽  
Genetic Implication ◽  
Glycosyl Hydrolase Family 3 ◽  
Hydrolase Family

ABSTRACT The rhizosphere nitrogen-fixing bacteriumAzospirillum irakense KBC1 is able to grow on pectin and β-glucosides such as cellobiose, arbutin, and salicin. Two adjacent genes, salA and salB, conferring β-glucosidase activity to Escherichia coli, have been identified in a cosmid library of A. irakense DNA. The SalA and SalB enzymes preferentially hydrolyzed aryl β-glucosides. A Δ(salA-salB) A. irakense mutant was not able to grow on salicin but could still utilize arbutin, cellobiose, and glucose for growth. This mutant could be complemented by either salA or salB, suggesting functional redundancy of these genes in salicin utilization. In contrast to this functional homology, the SalA and SalB proteins, members of family 3 of the glycosyl hydrolases, show a low degree of amino acid similarity. Unlike SalA, the SalB protein exhibits an atypical truncated C-terminal region. We propose that SalA and SalB are representatives of the AB and AB′ subfamilies, respectively, in glycosyl hydrolase family 3. This is the first genetic implication of this β-glucosidase family in the utilization of β-glucosides for microbial growth.

scholarly journals Characterization of a highly xylose tolerant β-xylosidase isolated from high temperature horse manure compost

2021 ◽  
Vol 21 (1) ◽  
Author(s):  
Kanyisa Ndata ◽  
Walter Nevondo ◽  
Bongi Cekuse ◽  
Leonardo Joaquim van Zyl ◽  
Marla Trindade
Keyword(s):  
Glycosyl Hydrolase ◽  
Metagenomic Library ◽  
Bioinformatic Analysis ◽  
Glycoside Hydrolase Family ◽  
Kinetic Properties ◽  
Glycosyl Hydrolases ◽  
Remarkable Feature ◽  
Manure Compost ◽  
Horse Manure ◽  
Hydrolase Family

Abstract Background There is a continued need for improved enzymes for industry. β-xylosidases are enzymes employed in a variety of industries and although many wild-type and engineered variants have been described, enzymes that are highly tolerant of the products produced by catalysis are not readily available and the fundamental mechanisms of tolerance are not well understood. Results Screening of a metagenomic library constructed of mDNA isolated from horse manure compost for β-xylosidase activity identified 26 positive hits. The fosmid clones were sequenced and bioinformatic analysis performed to identity putative β-xylosidases. Based on the novelty of its amino acid sequence and potential thermostability one enzyme (XylP81) was selected for expression and further characterization. XylP81 belongs to the family 39 β-xylosidases, a comparatively rarely found and characterized GH family. The enzyme displayed biochemical characteristics (KM—5.3 mM; Vmax—122 U/mg; kcat—107; Topt—50 °C; pHopt—6) comparable to previously characterized glycoside hydrolase family 39 (GH39) β-xylosidases and despite nucleotide identity to thermophilic species, the enzyme displayed only moderate thermostability with a half-life of 32 min at 60 °C. Apart from acting on substrates predicted for β-xylosidase (xylobiose and 4-nitrophenyl-β-D-xylopyranoside) the enzyme also displayed measurable α-L-arabainofuranosidase, β-galactosidase and β-glucosidase activity. A remarkable feature of this enzyme is its ability to tolerate high concentrations of xylose with a Ki of 1.33 M, a feature that is highly desirable for commercial applications. Conclusions Here we describe a novel β-xylosidase from a poorly studied glycosyl hydrolase family (GH39) which despite having overall kinetic properties similar to other bacterial GH39 β-xylosidases, displays unusually high product tolerance. This trait is shared with only one other member of the GH39 family, the recently described β-xylosidases from Dictyoglomus thermophilum. This feature should allow its use as starting material for engineering of an enzyme that may prove useful to industry and should assist in the fundamental understanding of the mechanism by which glycosyl hydrolases evolve product tolerance.

scholarly journals A Noncellulosomal Mannanase26E Contains a CBM59 inClostridium cellulovorans

2014 ◽  
Vol 2014 ◽  
pp. 1-7 ◽  
Author(s):  
Kosuke Yamamoto ◽  
Yutaka Tamaru
Keyword(s):  
Plant Cell Wall ◽  
Glycosyl Hydrolase ◽  
Expression Patterns ◽  
Glycoside Hydrolases ◽  
Crystalline Cellulose ◽  
Carbohydrate Binding ◽  
Sds Page ◽  
Mannanase Activity ◽  
Coomassie Brilliant ◽  
Hydrolase Family

A multicomponent enzyme-complex prevents efficient degradation of the plant cell wall for biorefinery. In this study, the method of identifying glycoside hydrolases (GHs) to degrade hemicelluloses was demonstrated. The competence ofC. cellulovorans, which changes to be suitable for degradation of each carbon source, was used for the method.C. cellulovoranswas cultivated into locust bean gum (LBG) that is composed of galactomannan. The proteins produced byC. cellulovoranswere separated into either fractions binding to crystalline cellulose or not. Proteins obtained from each fraction were further separated by SDS-PAGE and were stained with Coomassie Brilliant Blue and were detected for mannanase activity. The proteins having the enzymatic activity for LBG were cut out and were identified by mass spectrometry. As a result, four protein bands were classified into glycosyl hydrolase family 26 (GH26) mannanases. One of the identified mannanases, Man26E, contains a carbohydrate-binding module (CBM) family 59, which binds to xylan, mannan, and Avicel. Although mannose and galactose are the same as a hexose, the expression patterns of the proteins fromC. cellulovoranswere quite different. More interestingly, zymogram for mannanase activity showed that Man26E was detected in only LBG medium.

scholarly journals New Chitosan-Degrading Strains That Produce Chitosanases Similar to ChoA of Mitsuaria chitosanitabida

2005 ◽  
Vol 71 (9) ◽  
pp. 5138-5144 ◽  
Author(s):  
ChoongSoo Yun ◽  
Daiki Amakata ◽  
Yasuhiro Matsuo ◽  
Hideyuki Matsuda ◽  
Makoto Kawamukai
Keyword(s):  
Southern Hybridization ◽  
Glycosyl Hydrolase ◽  
Pcr Amplification ◽  
Rrna Gene ◽  
16S Rrna Gene Sequences ◽  
Glycosyl Hydrolase Family ◽  
Broad Variety ◽  
Hydrolase Family ◽  
The 16S Rrna Gene ◽  
Sequence Similarities

ABSTRACT The betaproteobacterium Mitsuaria chitosanitabida (formerly Matsuebacter chitosanotabidus) 3001 produces a chitosanase (ChoA) that is classified in glycosyl hydrolase family 80. While many chitosanase genes have been isolated from various bacteria to date, they show limited homology to the M. chitosanitabida 3001 chitosanase gene (choA). To investigate the phylogenetic distribution of chitosanases analogous to ChoA in nature, we identified 67 chitosan-degrading strains by screening and investigated their physiological and biological characteristics. We then searched for similarities to ChoA by Western blotting and Southern hybridization and selected 11 strains whose chitosanases showed the most similarity to ChoA. PCR amplification and sequencing of the chitosanase genes from these strains revealed high deduced amino acid sequence similarities to ChoA ranging from 77% to 99%. Analysis of the 16S rRNA gene sequences of the 11 selected strains indicated that they are widely distributed in the β and γ subclasses of Proteobacteria and the Flavobacterium group. These observations suggest that the ChoA-like chitosanases that belong to family 80 occur widely in a broad variety of bacteria.

Variants of glycosyl hydrolase family 2 β-glucuronidases have increased activity on recalcitrant substrates

2021 ◽  
Vol 145 ◽  
pp. 109742
Author(s):  
Caleb R. Schlachter ◽  
Amanda C. McGee ◽  
Pongkwan N. Sitasuwan ◽  
Gary C. Horvath ◽  
Nanda G. Karri ◽  
...  
Keyword(s):  
Glycosyl Hydrolase ◽  
Glycosyl Hydrolase Family ◽  
Increased Activity ◽  
Hydrolase Family

scholarly journals Arabinanase A from Pseudomonas fluorescens subsp. cellulosa exhibits both an endo- and an exo- mode of action

1997 ◽  
Vol 323 (2) ◽  
pp. 547-555 ◽  
Author(s):  
Vincent A. McKIE ◽  
Gary W. BLACK ◽  
Sarah J. MILLWARD-SADLER ◽  
Geoffrey P. HAZLEWOOD ◽  
Judith I. LAURIE ◽  
...  
Keyword(s):  
Pseudomonas Fluorescens ◽  
Mode Of Action ◽  
Plant Cell Wall ◽  
Catalytic Domain ◽  
Genomic Library ◽  
Glycosyl Hydrolase ◽  
Single Copy ◽  
Terminal Sequence ◽  
Reading Frame ◽  
Significant Release

Pseudomonas fluorescens subsp. cellulosa expressed arabinanase activity when grown on media supplemented with arabinan or arabinose. Arabinanase activity was not induced by the inclusion of other plant structural polysaccharides, and was repressed by the addition of glucose. The majority of the Pseudomonas arabinanase activity was extracellular. Screening of a genomic library of P. fluorescens subsp. cellulosa DNA constructed in Lambda ZAPII, for recombinants that hydrolysed Red-dyed arabinan, identified five arabinan-degrading plaques. Each of the phage contained the same Pseudomonas arabinanase gene, designated arbA, which was present as a single copy in the Pseudomonas genome. The nucleotide sequence of arbA revealed an open reading frame of 1041 bp encoding a protein, designated arabinanase A (ArbA), of Mr 39438. The N-terminal sequence of ArbA exhibited features typical of a prokaryotic signal peptide. Analysis of the primary structure of ArbA indicated that, unlike most Pseudomonas plant cell wall hydrolases, it did not contain linker sequences or have a modular structure, but consisted of a single catalytic domain. Sequence comparison between the Pseudomonas arabinanase and proteins in the SWISS-PROT database showed that ArbA exhibits greatest sequence identity with arabinanase A from Aspergillus niger, placing the enzyme in glycosyl hydrolase Family 43. The significance of the differing substrate specificities of enzymes in Family 43 is discussed. ArbA purifed from a recombinant strain of Escherichia coli had an Mr of 34000 and an N-terminal sequence identical to residues 32–51 of the deduced sequence of ArbA, and hydrolysed linear arabinan, carboxymethylarabinan and arabino-oligosaccharides. The enzyme displayed no activity against other plant structural polysaccharides, including branched sugar beet arabinan. ArbA produced almost exclusively arabinotriose from linear arabinan and appeared to hydrolyse arabino-oligosaccharides by successively releasing arabinotriose. ArbA and the Aspergillus arabinanase mediated a decrease in the viscosity of linear arabinan that was associated with a significant release of reducing sugar. We propose that ArbA is an arabinanase that exhibits both an endo- and an exo- mode of action.

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