Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.4.21.64 (proteinase K)
 4,071 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Monoclonal antibodies were raised against amphiphilic detergent-soluble (DS) acetylcholinesterase (AChE) from human brain caudate nucleus. Three mAb, 132-4 (IgG1), 132-5 (IgG1) and 132-6 (IgG3), specific for brain DS-AChE were selected and subcloned. These mAb reacted with native as well as heat-denatured and SDS-denatured DS-AChE, indicating that the epitopes to which mAb bound are continuous determinants. The mAb cross-reacted with DS-AChE from bovine and mouse brain and with brain DS-AChE from river trout (Salmo trutta forma fario) and lake trout (Salmo trutta forma lacustris). No cross-reaction was detected with the following antigens: salt-soluble (SS) AChE from bovine brain, glycophospholipid-anchored AChE from human and bovine erythrocytes, DS-butyrylcholinesterase and SS-butyrylcholinesterase (BtChE) from the brains of human and bovine, DS-BtChE from chicken and BtChE from human serum. Deglycosylation of brain DS-AChE with N-glycosidase F did not abolish the binding of mAb to DS-AChE. After reduction of brain DS-AChE by dithiothreitol, the mAb no longer reacted with the antigen, indicating that a disulfide bridge is important for the epitope. Monomerization of brain DS-AChE by trypsin and limited proteinase K treatment also abolished the binding of mAb to DS-AChE. Sucrose-density-gradient centrifugation showed that mAb reacted only with native tetrameric forms, but not with dimeric and monomeric forms. Western blot, after SDS/PAGE under non-reducing conditions, showed that mAb reacted with those subunits carrying the hydrophobic anchor (i.e. tetramers, trimers and heavy dimers) but not with those devoid of it (light dimers or monomers). Since mAb 132-4, 132-5 and 132-6 recognized DS-AChE from fish up to mammalian brain in the evolutionary tree, it is concluded that the epitope to which these mAb bind, is conserved in nature.
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PMID:Monoclonal antibodies against brain acetylcholinesterases which recognize the subunits bearing the hydrophobic anchor. 768 3

All microbial biofilms are initiated through direct physical contact between a bacterium and a solid surface, a step that is controlled by inter- and intramolecular forces. Atomic force microscopy and confocal laser scanning microscopy were used simultaneously to observe the formation of a bond between a fluorescent chimeric protein on the surface of a living Escherichia coli bacterium and a solid substrate in situ. The chimera was composed of a portion of outer membrane protein A (OmpA) fused to the cyan-fluorescent protein AmCyan. Sucrose gradient centrifugation and fluorescent confocal slices through bacteria demonstrated that the chimeric protein was targeted and anchored to the external cell surface. The wormlike chain theory predicted that this protein should exhibit a nonlinear force-extension "signature" consistent with the sequential unraveling of the AmCyan and OmpA domains. Experimentally measured force-extension curves revealed a unique pair of "sawtooth" features that were present when a bond formed between a silicon nitride surface (atomic force microscopy tip) and E. coli cells expressing the OmpA-AmCyan protein. The observed sawtooth pair closely matched the wormlike chain model prediction for the mechanical unfolding of the AmCyan and OmpA substructures in series. These sawteeth disappeared from the measured force-extension curves when cells were treated with proteinase K. Furthermore, these unique sawteeth were absent for a mutant stain of E. coli incapable of expressing the AmCyan protein on its outer surface. Together, these data show that specific proteins exhibit unique force signatures characteristic of the bond that is formed between a living bacterium and another surface.
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PMID:Simultaneous force and fluorescence measurements of a protein that forms a bond between a living bacterium and a solid surface. 1574 61

The collagenous region of adiponectin is glycosylated in vitro with glucosylgalactosyl moieties on four conserved lysines. We investigated the glycosylation of human adiponectin in vivo. Sugar vicinyl hydroxides on adiponectin were oxidized with 10 or 1 mM metaperiodate, and the result analyzed by two-dimensional electrophoresis and immunoblotting. Only 10 mM metaperiodate caused significant changes in electrophoretic mobility and an altered susceptibility to proteinase K digestion. Such treatment also increased the susceptibility of hexamers and high molecular weight (HMW) isoforms to dissociation by SDS. By contrast, untreated low molecular weight (LMW) isoforms were readily dissociated by low concentrations of SDS. Reduced HMW isoforms were able to partially reassemble following the removal of dithiothreitol, and this process was unaffected by metaperiodate. The presence of sialic acid was detected by Maackia amurensis Lectin II blotting, and by oxidation with 1 mM metaperiodate, followed by detection with Emerald Green 300 fluorescent dye. Quantitation of sugars on affinity-purified adiponectin from nine human plasmas showed that dimers of HMW isoforms contained a 1.3-fold greater amount of total sugar than LMW isoforms. However, both contained similar amounts of sialic acid. We conclude that glucosylgalactosyl residues contribute to the conformation of HMW human plasma adiponectin. In addition, the HMW isoform contains greater amounts of glucosylgalactosyl residues than the LMW isoform, and these sugars are important in determining its stability in vivo.
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PMID:Glycosylation of human adiponectin affects its conformation and stability. 1760 84

Cells of Lactobacillus plantarum ML11-11, an isolate from Fukuyama pot vinegar, and the yeast Saccharomyces cerevisiae formed significant mixed-species biofilms with concurrent inter-species co-aggregation. The co-aggregation did not occur with heated or proteinase K-treated ML11-11 cells, or in the presence of D-mannose, suggesting that surface proteins of ML11-11 and mannose-containing surface substance(s) of yeast were the predominant contributing factors. Sugar fatty acid ester inhibited mixed-species biofilm formation, but did not inhibit co-aggregation, suggesting that the cell-cell adhesion and cell-polystylene adhesion are controlled by different mechanisms. Microscopic observation and microflora analysis revealed that inter-species co-aggregation plays an important role in the formation of the mixed-species biofilm.
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PMID:The importance of inter-species cell-cell co-aggregation between Lactobacillus plantarum ML11-11 and Saccharomyces cerevisiae BY4741 in mixed-species biofilm formation. 2182 55