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Molecular Simulation Volume 32, 2006 - Issue 3-4: SPECIAL ISSUE: FRONTIERS OF MOLECULAR SIMULATION
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Original Articles

Biological network analyses: computational genomics and systems approaches

S.P. Walton Michigan State University, Cellular and Biomolecular Laboratory, Department of Chemical Engineering and Materials Science, 3249 Engineering Building, East Lansing, MI, 48824-1226, USACorrespondence[email protected]
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,
Z. Li Michigan State University, Cellular and Biomolecular Laboratory, Department of Chemical Engineering and Materials Science, 3249 Engineering Building, East Lansing, MI, 48824-1226, USAView further author information
&
C. Chan Michigan State University, Cellular and Biomolecular Laboratory, Department of Chemical Engineering and Materials Science, 3249 Engineering Building, East Lansing, MI, 48824-1226, USAView further author information
Pages 203-209 | Received 01 Dec 2005, Accepted 01 Feb 2006, Published online: 31 Jan 2007

References

  • Affymetrix—GeneChip; Human Genome U133 Plus 2.0 Array, Available online at: http://www.affymetrix.com/support/technical/datasheets/human_datasheet.pdf (accessed 15 November 2005).
  • Liang , S. , Fuhrman , S. and Somogyi , R. 1998 . Reveal, a general reverse engineering algorithm for inference of genetic network architectures . Pac. Symp. Biocomput. , : 18
  • Chen , T. , He , H.L. and Church , G.M. 1999 . Modeling gene expression with differential equations . Pac. Symp. Biocomput. , : 29
  • AIChE Annual Meeting Program—Session: #494—Computational and Functional Genomics (21010). Available online at: http://aiche.confex.com/aiche/2005/techprogram/S1342.htm (accessed 13 December 2005).
  • AIChE Annual Meeting Program—Session: #208—Computational Genomics (21012). Available online at: http://aiche.confex.com/aiche/2005/techprogram/S1344.htm (accessed 13 December 2005).
  • Kidgell , C. and Winzeler , E.A. 2005 . Elucidating genetic diversity with oligonucleotide arrays . Chromosome Res. , 13 : 225
  • Androulakis , I.P. 2005 . Selecting maximally informative genes . Comput. Chem. Eng. , 29 : 535
  • Gorg , A. , Weiss , W. and Dunn , M.J. 2004 . Current two-dimensional electrophoresis technology for proteomics . Proteomics , 4 : 3665
  • Shen , Y. , Zhang , R. , Moore , R.J. , Kim , J. , Metz , T.O. , Hixson , K.K. , Zhao , R. , Livesay , E.A. , Udseth , H.R. and Smith , R.D. 2005 . Automated 20 kpsi RPLC-MS and MS/MS with chromatographic peak capacities of 1000–1500 and capabilities in proteomics and metabolomics . Anal. Chem. , 77 : 3090
  • Breci , L. , Hattrup , E. , Keeler , M. , Letarte , J. , Johnson , R. and Haynes , P.A. 2005 . Comprehensive proteomics in yeast using chromatographic fractionation, gas phase fractionation, protein gel electrophoresis, and isoelectric focusing . Proteomics , 5 : 2018
  • Aebersold , R. and Mann , M. 2003 . Mass spectrometry-based proteomics . Nature , 422 : 198
  • Graham , D.R. , Elliott , S.T. and Van Eyk , J.E. 2005 . Broad-based proteomic strategies: a practical guide to proteomics and functional screening . J. Physiol. , 563 : 1
  • Lueking , A. , Cahill , D.J. and Mullner , S. 2005 . Protein biochips: a new and versatile platform technology for molecular medicine . Drug Discov. Today , 10 : 789
  • Pilobello , K.T. , Krishnamoorthy , L. , Slawek , D. and Mahal , L.K. 2005 . Development of a lectin microarray for the rapid analysis of protein glycopatterns . Chembiochem ,
  • MacBeath , G. and Schreiber , S.L. 2000 . Printing proteins as microarrays for high-throughput function determination . Science , 289 : 1760
  • Mukherjee , S. , Berger , M.F. , Jona , G. , Wang , X.S. , Muzzey , D. , Snyder , M. , Young , R.A. and Bulyk , M.L. 2004 . Rapid analysis of the DNA-binding specificities of transcription factors with DNA microarrays . Nat. Genet. , 36 : 1331
  • Egener , T. , Roulet , E. , Zehnder , M. , Bucher , P. and Mermod , N. 2005 . Proof of concept for microarray-based detection of DNA-binding oncogenes in cell extracts . Nucleic Acids Res. , 33 : e79
  • Kim , J. , Bhinge , A.A. , Morgan , X.C. and Iyer , V.R. 2005 . Mapping DNA–protein interactions in large genomes by sequence tag analysis of genomic enrichment . Nat. Methods , 2 : 47
  • Stoevesandt , O. , Elbs , M. , Kohler , K. , Lellouch , A.C. , Fischer , R. , Andre , T. and Brock , R. 2005 . Peptide microarrays for the detection of molecular interactions in cellular signal transduction . Proteomics , 5 : 2010
  • Kim Guisbert , K. , Duncan , K. , Li , H. and Guthrie , C. 2005 . Functional specificity of shuttling hnRNPs revealed by genome-wide analysis of their RNA binding profiles . RNA , 11 : 383
  • Choi , Y.S. , Pack , S.P. and Yoo , Y.J. 2005 . Development of a protein microarray using sequence-specific DNA binding domain on DNA chip surface . Biochem. Biophys. Res. Commun. , 329 : 1315
  • MacBeath , G. , Koehler , A.N. and Schreiber , S.L. 1999 . Printing small molecules as microarrays and detecting protein–ligand interactions en masse . J. Am. Chem. Soc. , 121 : 7967
  • Kuruvilla , F.G. , Shamji , A.F. , Sternson , S.M. , Hergenrother , P.J. and Schreiber , S.L. 2002 . Dissecting glucose signalling with diversity-oriented synthesis and small-molecule microarrays . Nature , 416 : 653
  • Naffin , J.L. , Han , Y. , Olivos , H.J. , Reddy , M.M. , Sun , T. and Kodadek , T. 2003 . Immobilized peptides as high-affinity capture agents for self-associating proteins . Chem. Biol. , 10 : 251
  • Feezor , R.J. , Baker , H.V. , Xiao , W. , Lee , W.A. , Huber , T.S. , Mindrinos , M. , Kim , R.A. , Ruiz-Taylor , L. , Moldawer , L.L. , Davis , R.W. and Seeger , J.M. 2004 . Genomic and proteomic determinants of outcome in patients undergoing thoracoabdominal aortic aneurysm repair . J. Immunol. , 172 : 7103
  • Sreekumar , A. , Nyati , M.K. , Varambally , S. , Barrette , T.R. , Ghosh , D. , Lawrence , T.S. and Chinnaiyan , A.M. 2001 . Profiling of cancer cells using protein microarrays: discovery of novel radiation-regulated proteins . Cancer Res. , 61 : 7585
  • O'Sullivan , C.K. 2002 . Aptasensors—the future of biosensing? . Anal. Bioanal. Chem. , 372 : 44
  • Collett , J.R. , Cho , E.J. , Lee , J.F. , Levy , M. , Hood , A.J. , Wan , C. and Ellington , A.D. 2005 . Functional RNA microarrays for high-throughput screening of antiprotein aptamers . Anal. Biochem. , 338 : 113
  • Smith , D. , Collins , B.D. , Heil , J. and Koch , T.H. 2003 . Sensitivity and specificity of photoaptamer probes . Mol. Cell. Proteomics , 2 : 11
  • McCauley , T.G. , Hamaguchi , N. and Stanton , M. 2003 . Aptamer-based biosensor arrays for detection and quantification of biological macromolecules . Anal. Biochem. , 319 : 244
  • Kirby , R. , Cho , E.J. , Gehrke , B. , Bayer , T. , Park , Y.S. , Neikirk , D.P. , McDevitt , J.T. and Ellington , A.D. 2004 . Aptamer-based sensor arrays for the detection and quantitation of proteins . Anal. Chem. , 76 : 4066
  • Liu , Y. , Lin , C. , Li , H. and Yan , H. 2005 . Aptamer-directed self-assembly of protein arrays on a DNA nanostructure . Angew. Chem. Int. Ed. Engl. , 44 : 4333
  • Koch , T.H. , Smith , D. , Tabacman , E. and Zichi , D.A. 2004 . Kinetic analysis of site-specific photoaptamer-protein cross-linking . J. Mol. Biol. , 336 : 1159
  • Lee , M. and Walt , D.R. 2000 . A fiber-optic microarray biosensor using aptamers as receptors . Anal. Biochem. , 282 : 142
  • Fields , S. and Song , O. 1989 . A novel genetic system to detect protein–protein interactions . Nature , 340 : 245
  • Park , S.J. , Lee , S.Y. , Cho , J. , Kim , T.Y. , Lee , J.W. , Park , J.H. and Han , M.J. 2005 . Global physiological understanding and metabolic engineering of microorganisms based on omics studies . Appl. Microbiol. Biotechnol. , 68 : 567
  • Fiehn , O. 2002 . Metabolomics—the link between genotypes and phenotypes . Plant Mol. Biol. , 48 : 155
  • KEGG: Kyoto Encyclopedia of Genes and Genomes. Available online at: http://www.genome.ad.jp/kegg/ (accessed 23 Nov 2005).
  • Ingenuity Systems. Available online at: http://www.ingenuity.com/ (accessed 23 Nov 2005).
  • Vadigepalli , R. , Chakravarthula , P. , Zak , D.E. , Schwaber , J.S. and Gonye , G.E. 2003 . PAINT: a promoter analysis and interaction network generation tool for gene regulatory network identification . Omics , 7 : 235
  • Liao , J.C. , Boscolo , R. , Yang , Y.L. , Tran , L.M. , Sabatti , C. and Roychowdhury , V.P. 2003 . Network component analysis: reconstruction of regulatory signals in biological systems . Proc. Natl. Acad. Sci. USA , 100 : 15522
  • Tran , L.M. , Brynildsen , M.P. , Kao , K.C. , Suen , J.K. and Liao , J.C. 2005 . gNCA: a framework for determining transcription factor activity based on transcriptome: identifiability and numerical implementation . Metab. Eng. , 7 : 128
  • Bailey , J.E. 1998 . Mathematical modeling and analysis in biochemical engineering: past accomplishments and future opportunities . Biotechnol. Prog. , 14 : 8
  • Nielsen , J. 1998 . Metabolic engineering: techniques for analysis of targets for genetic manipulations . Biotechnol. Bioeng. , 58 : 125
  • Stephanopoulos , G. 1998 . Metabolic engineering . Biotechnol. Bioeng. , 58 : 119
  • Li , Z. and Chan , C. 2004 . Integrating gene expression and metabolic profiles . J. Biol. Chem. , 279 : 27124
  • Li , Z. and Chan , C. 2004 . Inferring pathways and networks with a Bayesian framework . FASEB J. , 18 : 746
  • Z. Li, S. Srivastava, X. Yang, C. Chan. Inferring pathways that confer a cellular phenotype by integrating gene expression and metabolic profiles. Paper presented at the AIChE Annual Meeting, Cincinnati, OH (2005).
  • Yu , J. , Smith , V. , Wang , P. , Hartemink , A. and Jarvis , E. Using bayesian network inference algorithms to recover molecular genetic regulatory networks . Paper presented at the International Conference on Systems Biology
  • J.M. Lee, J. Papin. Dynamical analysis of an integrated signaling network at a genome-scale. Paper presented at the Annual AIChE Meeting, Cincinnati, OH (2005).
  • Klipp , E. , Nordlander , B. , Kruger , R. , Gennemark , P. and Hohmann , S. 2005 . Integrative model of the response of yeast to osmotic shock . Nat. Biotechnol. , 23 : 975

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