Integration of solid-phase extraction membranes for sample multiplexing: application to rapid protein identification from gel-isolated protein extracts.

The present report describes the design and application of a dual sprayer system for high-throughput proteome analysis. This system comprises parallel solid-phase extraction cartridges used for preconcentration and desalting of proteolytic digests prior to nanoelectrospray mass spectrometry analyses. Tryptic peptides from in-gel digest of protein bands/spots are first adsorbed on styrene divinyl benzene membrane and subsequently eluted with a short plug of organic buffer prior to infusion to the mass spectrometer at a flow rate of typically 500 nL/min. Tryptic peptide eluting from the membrane are analyzed by the mass spectrometer by moving in turn each sprayer in front of the sampling orifice. Sequential injection, preconcentration and analyses of tryptic digests are typically achieved with a throughput of up to 3.5 min/sample and a detection limit of approximately 8-80 fmol per injection. Replicate injections of peptide mixtures indicated that reproducibility of peak areas ranged from relative standard deviations (RSD) of 1.1% to 4.5%. The application of this device is demonstrated for digests of gel-isolated proteins obtained from sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) separation of rat liver plasma membrane and from two-dimensional gel electrophoresis of total cell lysate extracts from human prostatic cancer cell.

Integrated system for high-throughput protein identification using a microfabricated device coupled to capillary electrophoresis/nanoelectrospray mass spectrometry.

An integrated microsystem providing rapid analyses of trace-level tryptic digests for proteomics application is presented. This modular microsystem includes an autosampler and a microfabricated device comprising a sample introduction port and an array of separation channels together with a low dead-volume facilitating the interface to nanoelectrospray mass spectrometry. Sequential injection and separation of peptide standards and tryptic digests was achieved with a throughput of up to 30 samples per hour with less than 3% sample carryover. Replicate injections of peptide mixtures indicated that reproducibility of migration time was typically better than 2.3% relative standard deviation (RSD) whereas RSD values of 3.7-11.8% were observed on peak height. Mass spectral detection of submicromolar protein digests (< 7 femtomoles/injection) was achieved using a quadrupole/time of flight instrument in less than 2 min/per sample with peak widths of 1.8-7.0 s. The analytical potential of this integrated device for the identification of gel isolated proteins from Neisseria meningitidis immunotype L3 has been demonstrated using both peptide mass-fingerprint database searching and on-line tandem mass spectrometry.

The so-called tRNAGlu1 of Escherichia coli is a stable denatured conformer of the major isoacceptor tRNAGlu2.

A single peak of tRNAGlu is obtained upon chromatography of unfractionated tRNA from Escherichia coli on DEAE-Sephadex A-50 if this tRNA was previously renatured, whereas two peaks of tRNAGlu are resolved if the sample chromatographed is a mixture of native (renatured) and denatured tRNA. Higher resolution analysis of native E. coli tRNA by RPC-5 chromatography showed that most of the tRNAGlu is present in one peak, eluted shortly after a minor peak containing about or less than 5% of the total amount of tRNAGlu; these two peaks were also observed with commercially available tRNAGlu purified from E. coli. When denatured, the tRNAGlu present in each of these two peaks was eluted from the RPC-5 column at a much lower salt concentration. The properties of the denatured conformers obtained from native tRNAGlu present in the major and minor peaks, and the variation, with growth conditions of E. coli, in the relative amount of tRNAGlu in the minor peak suggest that the tRNAGlu present in the minor peak is an undermodified form of the tRNAGlu present in the major peak. This tRNAGluUUC (or tRNAGluSUC when modified in the anticodon) would then be the only tRNA species acceptor of glutamate in E. coli.