Highly stable trypsin-aggregate coatings on polymer nanofibers for repeated protein digestion

A stable and robust trypsin-based biocatalytic system was developed and demonstrated for proteomic applications. The system utilizes polymer nanofibers coated with trypsin aggregates for immobilized protease digestions. After covalently attaching an initial layer of trypsin to the polymer nanofibers...

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Bibliographic Details
Published in:Proteomics (Weinheim) 2009-04, Vol.9 (7), p.1893-1900
Main Authors: Kim, Byoung Chan, Lopez-Ferrer, Daniel, Lee, Sang-Mok, Ahn, Hye-Kyung, Nair, Sujith, Kim, Seong H, Kim, Beom Soo, Petritis, Konstantinos, Camp, David G, Grate, Jay W, Smith, Richard D, Koo, Yoon-Mo, Gu, Man Bock, Kim, Jungbae
Format: Article
Language:English
Subjects:
Analytical, structural and metabolic biochemistry
Biocatalysis
Biological and medical sciences
Bioreactors
Chromatography, Liquid
Enzyme aggregate coatings
Enzyme Stability
Enzymes, Immobilized - metabolism
Equipment Reuse
Fundamental and applied biological sciences. Psychology
Microscopy, Electron, Scanning
Miscellaneous
Nanofibers
Nanostructures - ultrastructure
Peptide Fragments
Polymers - metabolism
Protein digestion
Proteins
Proteins - metabolism
Proteomics - instrumentation
Recyclable biocatalysts
Reproducibility of Results
Tandem Mass Spectrometry
Trypsin
Trypsin - metabolism
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Summary:A stable and robust trypsin-based biocatalytic system was developed and demonstrated for proteomic applications. The system utilizes polymer nanofibers coated with trypsin aggregates for immobilized protease digestions. After covalently attaching an initial layer of trypsin to the polymer nanofibers, highly concentrated trypsin molecules are crosslinked to the layered trypsin by way of a glutaraldehyde treatment. This process produced a 300-fold increase in trypsin activity compared with a conventional method for covalent trypsin immobilization, and proved to be robust in that it still maintained a high level of activity after a year of repeated recycling. This highly stable form of immobilized trypsin was resistant to autolysis, enabling repeated digestions of BSA over 40 days and successful peptide identification by LC-MS/MS. This active and stable form of immobilized trypsin was successfully employed in the digestion of yeast proteome extract with high reproducibility and within shorter time than conventional protein digestion using solution phase trypsin. Finally, the immobilized trypsin was resistant to proteolysis when exposed to other enzymes (i.e., chymotrypsin), which makes it suitable for use in "real-world" proteomic applications. Overall, the biocatalytic nanofibers with trypsin aggregate coatings proved to be an effective approach for repeated and automated protein digestion in proteomic analyses.
ISSN:1615-9853
1615-9861
DOI:10.1002/pmic.200800591