Analysis of Protean Genomics to Increase Genome Annotation Accuracy

Zhao, Lina; He, Baoling; Li, Weiwei; Wei, Candong

doi:10.1007/978-1-4471-4850-0_29

Lina Zhao²,
Baoling He²,
Weiwei Li² &
…
Candong Wei³

Part of the book series: Lecture Notes in Electrical Engineering ((LNEE,volume 217))

Abstract

Advances in sequencing strategies facilitate complete genomic sequence of a variety of organisms. However, conventional computational predictions for genome annotation remain imperfect. Here, we applied a protean genomics approach to complement genome annotation by combining bioinformatics analysis and proteomic data. By using Shebelle Flexner 2a as a model, a total of 1041 proteins were unambiguously assigned, including 240 hypothetical proteins. Through comprehensive analysis against in-house N-terminal extension database, three annotated open reading frames (Offs) were respectively extended upstream. Above all, eight new ORFs were discovered by searching our MS/MS data against all six possible reading frames of S. Flexner 2a str. 301 genome, which were not predicted by any other annotation approaches. Our findings indicate that protean genomic analysis is quite qualified for comprehensive and accurate genome-wide annotation. This strategy could be taken as a routine work.

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References

Nielsen P, Krogh A (2005) Large-scale prokaryotic gene prediction and comparison to genome annotation. Biotin Fermatas 1(24):4322–4329
Google Scholar
Venter E, Smith RD, Pane SH (2011) Protean genomic analysis of bacteria and archaic: a 46 organism case study. Plops One 2(11):587–591
Google Scholar
Paullina A, Harrington ED, Bork P (2008) Large gene overlaps in prokaryotic genomes: result of functional constraints or miss predictions? BMC Genomics 3(9):335–338
Google Scholar
Reuse S, Chairlady R, Pander A (2011) Protean genomics. Proteomics 4(11):620–630
Google Scholar
Joseph A, Guyana M, Jean A (2012) High-throughput protean genomics of ruggeri poverty: seeding a better genomic annotation for the whole marine rose obiter clad. BMC Genomics 5(13):73–77
Google Scholar
Scrawl MM, Sigel TK, Salomon DR (2010) Functional port ergonomics-embracing complexity. Semen Immune 6(23):235–251
Google Scholar
Armin gaud J (2010) Prot ergonomics and systems biology: quest for the ultimate missing parts expert rev. Proteomics 7(5):72–77
Google Scholar
Payne SH, Huang ST, Pieper R (2010) A port ergonomic update to Yesinia: enhancing genome annotation. BMC Genomics 8(11):460–465
Google Scholar
Van Boggle RA, Schiller EE, Thomas JD, Leichardt FC (1999) Diagnosis of cellular states of microbial organisms using proteomics. Electro Pharoses 9(11):2149–2159
Google Scholar
Anson C, Purina SO, Adkins JN, Lipton MS, Smith RD (2008) Prot ergonomics: needs and roles to be filled by proteomics in genome annotation. Brief Font Genomics Proteomics 10(7):50–62
Article Google Scholar
Al-Hisami K, Raja Kumar K, Bulloch D, Robins-Browne R (2001) Genetic organization of the she pathogen city island in Shebelle Flexner 2a. Microbe Pathos 11(3):1–8
Google Scholar
Sewers RG (2005) Transcript analysis of Escherichia coli K-12 insertion element IS5. FEMS Microbiol Lett 12(24):397–401
Article Google Scholar
Alex E, Blanc-Petard AB (2009) Hydrophobic peptides: novel regulators within bacterial membrane. Mol Microbiol 13(72):5–11
Google Scholar
Kumar A (2009) An overview of nested genes in eukaryotic genomes. Eukaryot Cell 14(8):1321–1329
Article Google Scholar
Jab worksite DM, Beam-Miller M, Lure G, Barents-Reynolds R (2007) Potential regulatory relationship between the nested gene DDC8 and its host gene tissue inhibitor of metalloproteinase-2. Physiol Genomics 15(28):168–178
Google Scholar

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Authors and Affiliations

College of Life Sciences, Hubei United University, Tangshan, China
Lina Zhao, Baoling He & Weiwei Li
Institute of Pathogen Biology, Chinese Academy of Medical Sciences and Peking Union Medical College, Beijing, China
Candong Wei

Authors

Lina Zhao
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Baoling He
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Weiwei Li
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Candong Wei
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Corresponding author

Correspondence to Lina Zhao .

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Beiquan Road, Apt. 1-1-2 309, Chongqing, 400700, China, People's Republic
Zhicai Zhong

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Zhao, L., He, B., Li, W., Wei, C. (2013). Analysis of Protean Genomics to Increase Genome Annotation Accuracy. In: Zhong, Z. (eds) Proceedings of the International Conference on Information Engineering and Applications (IEA) 2012. Lecture Notes in Electrical Engineering, vol 217. Springer, London. https://doi.org/10.1007/978-1-4471-4850-0_29

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DOI: https://doi.org/10.1007/978-1-4471-4850-0_29
Published: 05 April 2013
Publisher Name: Springer, London
Print ISBN: 978-1-4471-4849-4
Online ISBN: 978-1-4471-4850-0
eBook Packages: EngineeringEngineering (R0)

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