A targeted proteomics approach to the rapid identification of bacterial cell mixtures by matrix-assisted laser desorption/ionization mass spectrometry.

A proteomic approach to the rapid identification of bacteria is presented, which relies on the solubilization of a limited number of proteins from intact cells combined with on-probe tryptic digestion. Within 20 min, complete cleavage products of a limited set of bacterial proteins with molecular masses of about 4-125 kDa were obtained by on-probe digestion with immobilized trypsin. Bacterial peptides suitable for unimolecular decomposition analysis were generated within 5 min, and the sequence information obtained allowed identification of abundant proteins, and accordingly, their bacterial sources via searches in the NCBI database. Analysis of fragmentation products was also shown to allow for identification of bacterial peptides identical in mass but differing slightly in amino acid sequence by manual data analysis. In this work, Bacillus subtilis 168, B. globigii, B. sphaericus 14577, B. cereus T, and B. anthracis Sterne were examined, and various cold shock proteins were identified in all species. In addition, DNA-binding, 60 kDa-heat shock, surface-related and other stress-protective proteins were identified in the bacterial cell digests, and species-specific tryptic peptides could be generated from each of the Bacillus species studied. Bacterial peptides could be analyzed with greater sensitivity and mass accuracy than the parent proteins. The applicability of this targeted proteomics approach to the rapid identification of Bacillus species was further established by analyzing binary cell mixtures.