Parallelization of the spectral deconvolution stage of the proteomic discovery process
Pages 673 - 676
Abstract
Mass spectrometry is one of the primary analytical tools for the quantification and identification of proteins in human body. Scientists analyze the data generated from mass spectrometry instruments to detect protein patterns. The operations performed on mass spectrometric output to detect such patterns include spectrum visualization, deconvolution, alignment, normalization, statistical significance tests, and pattern recognition. Bindley Bioscience center in Purdue University's Discovery Park hosts a Omics Discovery Pipeline (ODP). The ODP is available as a web-based analysis platform that performs the aforementioned operations.
The time taken to generate output in the spectrum deconvolution stage is a major concern. Much of this concern results from the fact that this stage has to deal with a sizable number of large input files that are present in potentially many different input formats. Due to slow operation speed of this stage, overall performance of the process for protein quantification and identification is hampered. Our research work concentrates on discovering and implementing ways to increase the performance of the spectral deconvolution stage of the process for protein quantification used in the ODP by leveraging multi-core and multi-node architectures. By leveraging OpenMP and MPI, we were able to obtain an order of magnitude speedup of the spectrum deconvolution stage of the ODP.
References
[1]
Purdue Steele User Guide at https://www.xsede.org/purdue-steele, 2012.
[2]
R. D. Bjornson, N. J. Carriero, C. Colangelo, M. Shifman, K.-H. Cheung, P. L. Miller, and K. Williams. X!!Tandem, an Improved Method for Running X!Tandem in Parallel on Collections of Commodity Computers. Journal of Proteome Research, 7(1):293--299, 2008.
[3]
E. H.-H. Chi, E. Shoop, J. Carlis, E. Retzel, and J. Riedl. Efficiency of Shared-Memory Multiprocessors for a Genetic Sequence Similarity Search Algorithm, 1997.
[4]
D. T. Duncan, R. Craig, and A. J. Link. Parallel Tandem:âĂL' A Program for Parallel Processing of Tandem Mass Spectra Using PVM or MPI and X!Tandem. Journal of Proteome Research, 4(5):1842--1847, Aug. 2005.
[5]
J. Lichtenberg, K. Kurz, X. Liang, R. Al-ouran, L. Neiman, L. J. Nau, J. D. Welch, E. Jacox, T. Bitterman, K. Ecker, L. Elnitski, F. Drews, S. S. Lee, and L. R. Welch. WordSeeker: concurrent bioinformatics software for discovering genome-wide patterns and word-based genomic signatures. BMC bioinformatics, 11 Suppl 1(Suppl 12):S6, Jan. 2010.
[6]
H. N. B. Moseley, A. N. Lane, A. C. Belshoff, R. M. Higashi, and T. W. M. Fan. A novel deconvolution method for modeling UDP-N-acetyl-D-glucosamine biosynthetic pathways based on (13)C mass isotopologue profiles under non-steady-state conditions. BMC biology, 9(1):37, Jan. 2011.
[7]
B. Pratt, J. J. Howbert, N. I. Tasman, and E. J. Nilsson. MR-Tandem: Parallel X!Tandem using Hadoop MapReduce on Amazon Web Services. Bioinformatics, Nov. 2011.
[8]
R. G. Sadygov, J. Eng, E. Durr, A. Saraf, H. McDonald, M. J. MacCoss, and J. R. Yates. Code Developments to Improve the Efficiency of Automated MS/MS Spectra Interpretation. Journal of Proteome Research, 1(3):211--215, Mar. 2002.
[9]
S. E. Stein. An Integrated Method for Spectrum Extraction and Compound Identification from Gas Chromatography/Mass Spectrometry Data. J. Am. Soc. Mass Spectrom., 10:770--781, 1999.
[10]
O. Thorsen, B. E. Smith, C. P. Sosa, K. Jiang, H. Lin, A. E. Peters, and W.-c. Feng. Parallel genomic sequence-search on a massively parallel system. In U. Banerjee, J. Moreira, M. Dubois, and P. Stenström, editors, Conf. Computing Frontiers, pages 59--68. ACM, 2007.
[11]
X. Zhang, W. Hines, J. Adamec, J. M. Asara, S. Naylor, and F. E. Regnier. An automated method for the analysis of stable isotope labeling data in proteomics. Journal of the American Society for Mass Spectrometry, 16(7):1181--91, July 2005.
[12]
H. Zheng, P. C. Ojha, S. McClean, N. D. Black, J. G. Hughes, and C. Shaw. Heuristic charge assignment for deconvolution of electrospray ionization mass spectra. Rapid communications in mass spectrometry: RCM, 17(5):429--36, Jan. 2003.
Index Terms
- Parallelization of the spectral deconvolution stage of the proteomic discovery process
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Published In
October 2012
725 pages
ISBN:9781450316705
DOI:10.1145/2382936
- General Chair:
- Sanjay Ranka,
- Program Chairs:
- Tamer Kahveci,
- Mona Singh
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Published: 07 October 2012
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BCB' 12: ACM International Conference on Bioinformatics, Computational Biology and Biomedicine
October 7 - 10, 2012
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BCB '12 Paper Acceptance Rate 33 of 159 submissions, 21%;
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