Integrated Algorithms for High-Throughput Examination of Covalently Labeled Biomolecules by Structural Mass Spectrometry

• Published in: Analytical chemistry (Washington) Vol. 81; no. 19; pp. 8141 - 8149
• Main Authors: Kaur, Parminder, Kiselar, Janna G., Chance, Mark R.
• Format: Journal Article
• Language: English
• Published: Washington, DC American Chemical Society 01.10.2009
• Subjects: ALGORITHMS; Amino Acid Sequence; Analytical chemistry; BASIC BIOLOGICAL SCIENCES; Chemistry; Crystallography; DETECTION; Exact sciences and technology; GENERAL AND MISCELLANEOUS//MATHEMATICS, COMPUTING, AND INFORMATION SCIENCE; Humans; Hydroxyl Radical - chemistry; INSULIN; Insulin - chemistry; Mass spectrometry; Mass Spectrometry - methods; MASS SPECTROSCOPY; Molecules; national synchrotron light source; Oxidation-Reduction; PEPTIDES; PROTEIN STRUCTURE; PROTEINS; Proteomics; SIMULATION; Spectrometric and optical methods; VERIFICATION; High resolution; Peptides; Automatic analysis; Algorithm; Modeling; Mass spectrometry; Protein; Quantitative analysis; Automatic processing
• ISSN: 0003-2700; 1520-6882; 1520-6882
• DOI: 10.1021/ac9013644

Mass spectrometry based structural proteomics approaches for probing protein structures are increasingly gaining in popularity. The potential for such studies is limited because of the lack of analytical techniques for the automated interpretation of resulting data. In this article, a suite of algorithms called ProtMapMS is developed, integrated, and implemented specifically for the comprehensive automatic analysis of mass spectrometry data obtained for protein structure studies using covalent labeling. The functions include data format conversion, mass spectrum interpretation, detection, and verification of all peptide species, confirmation of the modified peptide products, and quantification of the extent of peptide modification. The results thus obtained provide valuable data for use in combination with computational approaches for protein structure modeling. The structures of both monomeric and hexameric forms of insulin were investigated by oxidative protein footprinting followed by high-resolution mass spectrometry. The resultant data was analyzed both manually and using ProtMapMS without any manual intervention. The results obtained using the two methods were found to be in close agreement and overall were consistent with predictions from the crystallographic structure.