Specific capture of the hydrolysate on magnetic beads for sensitive detecting plant vacuolar processing enzyme activity

Conventional plant protease detection always suffers from high background interference caused by the complex coloring metabolites in plant cells. In this study, a bio-modified magnetic beads-based strategy was developed for sensitive and quantitative detection of plant vacuolar processing enzyme (VP...

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Published in:Biosensors & bioelectronics 2016-05, Vol.79, p.881-886
Main Authors: Zhou, Jun, Cheng, Meng, Zeng, Lizhang, Liu, Weipeng, Zhang, Tao, Xing, Da
Format: Article
Language:English
Subjects:
Arabidopsis - chemistry
Arabidopsis - enzymology
Beads
Cadmium
Coloring
Condensation reaction
Condensing
Confocal microscopy
Cysteine Endopeptidases - analysis
Cysteine Endopeptidases - metabolism
Enzyme Assays - methods
Flow cytometry
Hydrolysis
Interference
Magnetic beads
Magnetics - methods
Magnets - chemistry
Peptides - chemistry
Peptides - isolation & purification
Peptides - metabolism
Plants (organisms)
Protease
Protease activity
Strategy
Vacuolar processing enzyme
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description Conventional plant protease detection always suffers from high background interference caused by the complex coloring metabolites in plant cells. In this study, a bio-modified magnetic beads-based strategy was developed for sensitive and quantitative detection of plant vacuolar processing enzyme (VPE) activity. Cleavage of the peptide substrate (ESENCRK-FITC) after asparagine residue by VPE resulted in the 2-cyano-6-amino-benzothiazole (CABT)-functionalized magnetic beads capture of the severed substrate CRK-FITC via a condensation reaction between CABT and cysteine (Cys). The catalytic activity was subsequently obtained by the confocal microscopy imaging and flow cytometry quantitative analysis. The sensor system integrated advantages of (i) the high efficient enrichment and separation capabilities of magnetic beads and (ii) the catalyst-free properties of the CABT-Cys condensation reaction. It exhibited a linear relationship between the fluorescence signal and the concentration of severed substrate in the range of 10–600pM. The practical results showed that, compared with normal growth conditions, VPE activity was increased by 2.7-fold (307.2±25.3μMmin−1g−1) upon cadmium toxicity stress. This platform effectively overcame the coloring metabolites-caused background interference, showing fine applicability for the detection of VPE activity in real samples. The strategy offers great sensitivity and may be further extended to other protease activity detection. •A magnetic beads-based strategy was developed for plant protease activity detection.•The hydrolysate was specially captured and enriched by CABT-coated magnetic beads.•The sensing system exhibited low background interference and high sensitivity.
doi_str_mv 10.1016/j.bios.2016.01.007
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subjects Arabidopsis - chemistry
Arabidopsis - enzymology
Beads
Cadmium
Coloring
Condensation reaction
Condensing
Confocal microscopy
Cysteine Endopeptidases - analysis
Cysteine Endopeptidases - metabolism
Enzyme Assays - methods
Flow cytometry
Hydrolysis
Interference
Magnetic beads
Magnetics - methods
Magnets - chemistry
Peptides - chemistry
Peptides - isolation & purification
Peptides - metabolism
Plants (organisms)
Protease
Protease activity
Strategy
Vacuolar processing enzyme
title Specific capture of the hydrolysate on magnetic beads for sensitive detecting plant vacuolar processing enzyme activity
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