1. Rapid and efficient protein digestion using trypsin-coated magnetic nanoparticles under pressure cycles
- Author
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Marvin G. Warner, Karl K. Weitz, Jungbae Kim, Richard D. Smith, Byoungsoo Lee, Daniel Lopez-Ferrer, Yong Il Park, Taeghwan Hyeon, Sang Won Lee, Byoung Chan Kim, and Hyon Bin Na
- Subjects
Male ,Proteomics ,Autolysis (biology) ,Proteome ,Protein digestion ,Nanoparticle ,Peptide ,Biochemistry ,Article ,Magnetics ,Mice ,Pressure ,medicine ,Animals ,Trypsin ,Molecular Biology ,chemistry.chemical_classification ,Chromatography ,Atmospheric pressure ,Chemistry ,technology, industry, and agriculture ,Brain ,Proteins ,Enzymes, Immobilized ,Mice, Inbred C57BL ,Enzyme ,Nanoparticles ,Magnetic nanoparticles ,medicine.drug - Abstract
Trypsin-coated magnetic nanoparticles (EC-TR/NPs), prepared via a simple multilayer random crosslinking of the trypsin molecules onto magnetic nanoparticles, were highly stable and could be easily captured using a magnet after the digestion was complete. EC-TR/NPs showed a negligible loss of trypsin activity after multiple uses and continuous shaking, whereas the conventional immobilization of covalently attached trypsin on NPs resulted in a rapid inactivation under the same conditions due to the denaturation and autolysis of trypsin. A single model protein, a five-protein mixture, and a whole mouse brain proteome were digested at atmospheric pressure and 37°C for 12 h or in combination with pressure cycling technology at room temperature for 1 min. In all cases, EC-TR/NPs performed equally to or better than free trypsin in terms of both the identified peptide/protein number and the digestion reproducibility. In addition, the concomitant use of EC-TR/NPs and pressure cycling technology resulted in very rapid (∼1 min) and efficient digestions with more reproducible digestion results.
- Published
- 2010
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