EC:3.2.1.21 - FACTA Search

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Query: EC:3.2.1.21 (beta-glucosidase)
3,280 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In certain maize genotypes, called "null," beta-glucosidase does not enter gels and therefore cannot be detected on zymograms after electrophoresis. Such genotypes were originally thought to be homozygous for a null allele at the glu1 gene and thus devoid of enzyme. We have shown that a beta-glucosidase-aggregating factor (BGAF) is responsible for the "null" phenotype. BGAF is a chimeric protein consisting of two distinct domains: the disease response or "dirigent" domain and the jacalin-related lectin (JRL) domain. First, it was not known whether the lectin domain in BGAF is functional. Second, it was not known which of the two BGAF domains is involved in beta-glucosidase binding and aggregation. To this end, we purified BGAF to homogeneity from a maize null inbred line called H95. The purified protein gave a single band on SDS-PAGE, and the native protein was a homodimer of 32-kDa monomers. Native and recombinant BGAF (produced in Escherichia coli) agglutinated rabbit erythrocytes, and various carbohydrates and glycoproteins inhibited their hemagglutination activity. Sugars did not have any effect on the binding of BGAF to the beta-glucosidase isozyme 1 (Glu1), and the BGAF-Glu1 complex could still bind lactosyl-agarose, indicating that the sugar-binding site of BGAF is distinct from the beta-glucosidase-binding site. Neither the dirigent nor the JRL domains alone (produced separately in E. coli) produced aggregates of Glu1 based on results from pull-down assays. However, gel shift and competitive binding assays indicated that the JRL domain binds beta-glucosidase without causing it to aggregate. These results with those from deletion mutagenesis and replacement of the JRL domain of a BGAF homolog from sorghum, which does not bind Glu1, with that from maize allowed us to conclude that the JRL domain of BGAF is responsible for its lectin and beta-glucosidase binding and aggregating activities.
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PMID:Maize beta-glucosidase-aggregating factor is a polyspecific jacalin-related chimeric lectin, and its lectin domain is responsible for beta-glucosidase aggregation. 1721 May 77

Lectins from the surface of Azospirillum brasilense Sp7 and Azospirillumn brasilense Sp7.2.3 (a mutant with impaired lectin activity) were shown to induce a stabilizing effect on the activity of almond beta-glucosidase under conditions of thermoinactivation and proteolytic enzyme treatment. Differences were revealed in the influence of lectins with various antigenic properties. Our results indicate that the effects of lectins on the catalytic activity of the enzyme are mainly associated with conformational changes in lectin molecules during mutagenesis, but not with carbohydrate specificity (general property). These data should be taken into account in evaluating the role of lectins in the formation of nitrogen-fixing associations.
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PMID:[Stabilizing effect of Azospirillum lectins on beta-glucosidase activity]. 1817 6

PYK10/BGLU23 is a beta-glucosidase that is a major protein of ER bodies, which are endoplasmic reticulum (ER)-derived organelles that may be involved in defense systems. PYK10 has active and inactive forms. Active PYK10 molecules form large complexes with diameters ranging from 0.65 microm to > 70 microm. We identified three beta-glucosidases (PYK10, BGLU21 and BGLU22), five jacalin-related lectins (JALs) and a GDSL lipase-like protein (GLL) in the purified PYK10 complex. Expression levels of JALs and GLLs were lower in the nai1-1 mutant, which has no ER bodies, than in Col-0. The subcellular localization of PYK10 is predicted to be different from the localizations of JALs and GLLs. This suggests that PYK10 interacts with its partners (JALs and GLLs) when the subcellular structure is destroyed by pathogens. The PYK10 complex was found to be larger in the pbp1-1 and jal22-1 mutants than in Col-0, while it was smaller in the jal23-1, jal31-1 and jal31-2 mutants than in Col-0. These results show that two types of JALs having opposite roles regulate the size of the PYK10 complex antagonistically. We define the two types of lectins as a 'polymerizer-type lectin' and an 'inhibitor-type lectin'. Interestingly, the closest homologs of polymerizer-type lectins (JAL31 and JAL23) were inhibitor-type lectins (PBP1/JAL30 and JAL22). The pairs of polymerizer-type and inhibitor-type lectins reported here are good examples of genes that have evolved new functions after gene duplication (neofunctionalization).
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PMID:Antagonistic jacalin-related lectins regulate the size of ER body-type beta-glucosidase complexes in Arabidopsis thaliana. 1846 40

Commercial mushroom tyrosinase contains other proteins, enzymes, carbohydrates, and phenolic material besides tyrosinase. Carbohydrate and phenolic material comprise a large percentage of the powder resuspensions derived from Agaricus bisporus. Enzyme assays identified the presence of tyrosinase, laccase, beta-glucosidase, beta-galactosidase, beta-xylosidase, cellulase, chitinase, xylanase, and mannanase in the commercial tyrosinase. Protein sequencing indicated the presence of tyrosinase, a lectin, and a putative mannanase as well as 10 unidentified protein/peptides in the commercial tyrosinase preparations. Characteristics of tyrosinase isoforms were similar in two different commercial tyrosinase sources. Inhibition studies indicated that I 50 values for some tyrosinase inhibitors were different when the crude powder was compared to a partially purified tyrosinase. The presence of these contaminants has the potential to affect studies using commercial tyrosinase.
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PMID:Enzyme, protein, carbohydrate, and phenolic contaminants in commercial tyrosinase preparations: potential problems affecting tyrosinase activity and inhibition studies. 1850 Aug 13

Recently, we identified the maize beta-glucosidase aggregating factor (BGAF) as a jacalin-related lectin (JRL) and showed that its lectin domain is responsible for beta-glucosidase aggregation. By searching for BGAF homologs in sorghum, we identified and obtained an EST clone and determined its complete sequence. The predicted protein had the same modular structure as maize BGAF, shared 67% sequence identity with it, and revealed the presence of two potential carbohydrate-binding sites (GG...ATYLQ, site I and GG...GVVLD, site II). Maize BGAF1 is the only lectin from a class of modular JRLs containing an N-terminal dirigent and a C-terminal JRL domain, whose sugar specificity and beta-glucosidase aggregating activity have been studied in detail. We purified to homogeneity a BGAF homolog designated as SL (Sorghum lectin) from sorghum and expressed its recombinant version in Escherichia coli. The native protein had a molecular mass of 32 kD and was monomeric. Both native and recombinant SL-agglutinated rabbit erythrocytes, and inhibition assays indicated that SL is a GalNAc-specific lectin. Exchanging the GG...GVVLD motif in SL with that of maize BGAF1 (GG...GIAVT) had no effect on GalNAc-binding, whereas binding to Man was abolished. Substitution of Thr(293) and Gln(296) in site I to corresponding residues (Val(294) and Asp(297)) of maize BGAF1 resulted in the loss of GalNAc-binding, indicating that site I is responsible for generating GalNAc specificity in SL. Gel-shift and pull-down assays after incubating SL with maize and sorghum beta-glucosidases showed no evidence of interaction nor were any SL-protein complexes detected in sorghum tissue extracts, suggesting that the sorghum homolog does not participate in protein-protein interactions.
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PMID:Homolog of the maize beta-glucosidase aggregating factor from sorghum is a jacalin-related GalNAc-specific lectin but lacks protein aggregating activity. 1905 85

In certain maize genotypes (nulls), beta-glucosidase specifically interacts with a chimeric lectin called beta-glucosidase aggregating factor (BGAF), resulting in high molecular weight complexes. Previously, we showed that three regions (S1-T29, E50-N127, and F466-A512) on the maize beta-glucosidase isozyme Glu1 are involved in interaction and aggregation with BGAF. Recently, we found that the peptide span I72-T82 within E50-N127 is essential and sufficient for BGAF binding, whereas the S1-T29 and F466-A512 regions are required for formation of large complexes. To define the contribution of individual amino acids in the above three regions to BGAF binding, we constructed mutant beta-glucosidases based on sequence differences between maize beta-glucosidase and sorghum beta-glucosidase (dhurrinase 2, Dhr2), which does not bind BGAF. Binding was evaluated by gel-shift assay and affinity by frontal affinity chromatography (FAC). In the gel-shift assay, Glu1 mutants K81E and T82Y failed to bind BGAF, and their FAC profiles were essentially similar to that of Dhr2, indicating that these two amino acids within the I72-T82 region are important for BGAF binding. Substitution of N481 with E (as in Dhr2) lowered affinity for BGAF, whereas none of the mutations in the S1-T29 region showed any effect on BGAF binding. To further confirm the importance of K81 and T82 for BGAF binding, we produced a number of Dhr2 mutants, and the results showed that all four amino acids (I72, N75, K81, and T82) that differ between Glu1 and Dhr2 in the peptide span I72-T82 are required to impart BGAF-binding ability to Dhr2.
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PMID:Lysine-81 and threonine-82 on maize beta-glucosidase isozyme Glu1 are the key amino acids involved in beta-glucosidase aggregating factor binding. 1922 73

Beta-glucosidases (Glu1 and Glu2) in maize specifically interact with a lectin called beta-glucosidase aggregating factor (BGAF). We have shown that the N-terminal (Glu(50)-Val(145)) and the C-terminal (Phe(466)-Ala(512)) regions of maize Glu1 are involved in binding to BGAF. Sequence comparison between sorghum beta-glucosidases (dhurrinases, which do not bind to BGAF) and maize beta-glucosidases, and the 3D-structure of Glu1 suggested that the BGAF-binding site on Glu1 is much smaller than predicted previously. To define more precisely the BGAF-binding site, we constructed additional chimeric beta-glucosidases. The results showed that a region spanning 11 amino acids (Ile(72)-Thr(82)) on Glu1 is essential and sufficient for BGAF binding, whereas the extreme N-terminal region Ser(1)-Thr(29), together with C-terminal region Phe(466)-Ala(512), affects the size of Glu1-BGAF complexes. The dissociation constants (K(d)) of chimeric beta-glucosidase-BGAF interactions also demonstrated that the extreme N-terminal and C-terminal regions are important but not essential for binding. To confirm the importance of Ile(72)-Thr(82) on Glu1 for BGAF binding, we constructed a chimeric sorghum beta-glucosidase, Dhr2 (C-11, Dhr2 whose Val(72)-Glu(82) region was replaced with the Ile(72)-Thr(82) region of Glu1). C-11 binds to BGAF, indicating that the Ile(72)-Thr(82) region is indeed a major interaction site on Glu1 involved in BGAF binding.
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PMID:Determination of beta-glucosidase aggregating factor (BGAF) binding and polymerization regions on the maize beta-glucosidase isozyme Glu1. 1971 49

Maize beta-glucosidase aggregating factor (BGAF) and its homolog Sorghum Lectin (SL) are modular proteins consisting of an N-terminal dirigent domain and a C-terminal jacalin-related lectin (JRL) domain. BGAF is a polyspecific lectin with a monosaccharide preference for galactose, whereas SL displays preference for GalNAc. Here, we report that deletion of the N-terminal dirigent domain in the above lectins dramatically changes their sugar-specificities. Deletions in the N-terminal region of the dirigent domain of BGAF abolished binding to galactose/lactose, but binding to mannose was unaffected. Glucose, which was a poor inhibitor of hemagglutinating activity of BGAF, displayed higher inhibitory effect on the hemagglutinating activity of deletion mutants. Deletion of the dirigent domain in SL abolished binding to GalNAc, but binding to mannose was not affected. Surprisingly, fructose, an extremely poor inhibitor (minimum inhibitory concentration (MIC) = 125 mM) of SL hemagglutinating activity, was found to be a very potent inhibitor (MIC = 1 mM) of hemagglutinating activity of its JRL domain. These results indicate that the dirigent domain in this class of modular lectins, at least in the case of maize BGAF and SL, influences sugar specificity.
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PMID:Deletion of the N-terminal dirigent domain in maize beta-glucosidase aggregating factor and its homolog sorghum lectin dramatically alters the sugar-specificities of their lectin domains. 2046 65

Gray leaf spot (GLS) disease in maize, caused by the fungus Cercospora zeina, is a threat to maize production globally. Understanding the molecular basis for quantitative resistance to GLS is therefore important for food security. We developed a de novo assembly pipeline to identify candidate maize resistance genes. Near-isogenic maize lines with and without a QTL for GLS resistance on chromosome 10 from inbred CML444 were produced in the inbred B73 background. The B73-QTL line showed a 20% reduction in GLS disease symptoms compared to B73 in the field (p = 0.01). B73-QTL leaf samples from this field experiment conducted under GLS disease pressure were RNA sequenced. The reads that did not map to the B73 or C. zeina genomes were expected to contain novel defense genes and were de novo assembled. A total of 141 protein-coding sequences with B73-like or plant annotations were identified from the B73-QTL plants exposed to C. zeina. To determine whether candidate gene expression was induced by C. zeina, the RNAseq reads from C. zeina-challenged and control leaves were mapped to a master assembly of all of the B73-QTL reads, and differential gene expression analysis was conducted. Combining results from both bioinformatics approaches led to the identification of a likely candidate gene, which was a novel allele of a lectin receptor-like kinase named L-RLK-CML that (i) was induced by C. zeina, (ii) was positioned in the QTL region, and (iii) had functional domains for pathogen perception and defense signal transduction. The 817AA L-RLK-CML protein had 53 amino acid differences from its 818AA counterpart in B73. A second "B73-like" allele of L-RLK was expressed at a low level in B73-QTL. Gene copy-specific RT-qPCR confirmed that the l-rlk-cml transcript was the major product induced four-fold by C. zeina. Several other expressed defense-related candidates were identified, including a wall-associated kinase, two glutathione s-transferases, a chitinase, a glucan beta-glucosidase, a plasmodesmata callose-binding protein, several other receptor-like kinases, and components of calcium signaling, vesicular trafficking, and ethylene biosynthesis. This work presents a bioinformatics protocol for gene discovery from de novo assembled transcriptomes and identifies candidate quantitative resistance genes.
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PMID:De novo Assembly of Transcriptomes From a B73 Maize Line Introgressed With a QTL for Resistance to Gray Leaf Spot Disease Reveals a Candidate Allele of a Lectin Receptor-Like Kinase. 3223 73

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