Bio-medical Ontologies Maintenance and Change Management

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338 M.T. Hoque, M. Chetty, and A. Sattar (such as GA) for PSP, has been reviewed in the context of a twin removal within population, intelligent encoding for problem presentation, so on, which become indispensable for providing further effectiveness. Domain knowledge based heuristics are shown very useful. Moreover, in the modelling point of view, simplified model can be made further effective by preferring a lattice orientation, beads and contact potential that can map real folded protein closely possible. Acknowledgments. Support from Australian Research Council (grant no DP0557303) is thankfully acknowledged. References 1. Unger, R., Moult, J.: On the Applicability of Genetic Algorithms to Protein Folding. In: The Twenty-Sixth Hawaii International Conference on System Sciences, pp. 715– 725 (1993) 2. Unger, R., Moult, J.: Genetic Algorithms for Protein Folding Simulations. Journal of Molecular Biology 231, 75–81 (1993) 3. Hoque, M.T., Chetty, M., Dooley, L.S.: A New Guided Genetic Algorithm for 2D Hydrophobic-Hydrophilic Model to Predict Protein Folding. In: IEEE Congress on Evolutionary Computation (CEC), Edinburgh, UK (2005) 4. Bonneau, R., Baker, D.: Ab Initio Protein Structure Prediction: Progress and Prospects. Annu. Rev. Biophys. Biomol. Struct. 30, 173–189 (2001) 5. Chivian, D., Robertson, T., Bonneau, R., Baker, D.: Ab Initio Methods. In: Bourne, P.E., Weissig, H. (eds.) Structural Bioinformatics. Wiley-Liss, Inc, Chichester (2003) 6. Samudrala, R., Xia, Y., Levitt, M.: A Combined Approach for ab initio Construction of Low Resolution Protein Tertiary Structures from Sequence Pacific Symposium on Biocomputing (PSB), vol. 4, pp. 505–516 (1999) 7. Corne, D.W., Fogel, G.B.: An Introduction to Bioinformatics for Computer Scientists. In: Fogel, G.B., Corne, D.W. (eds.) Evolutionary Computation in Bioinformatics, pp. 3–18 (2004) 8. Berg, J.M., Tymoczko, J.L., Stryer, L., Clarke, N.D. (eds.): Biochemistry. W. H. Freeman and Company, New York (2002) 9. Takahashi, O., Kita, H., Kobayashi, S.: Protein Folding by A Hierarchical Genetic Algorithm. In: 4th Int. Symp. AROB (1999) 10. Kuwajima, K., Arai, M. (eds.): Old and New Views of Protein Folding. Elesevier, Amsterdam (1999) 11. Pietzsch, J.: Protein folding technology (July 2007), http://www.nature.com/horizon/proteinfolding/background/ technology.html 12. Hoque, M.T., Chetty, M., Dooley, L.S.: Significance of Hybrid Evolutionary Computation for Ab Inito Protein Folding Prediction. In: Grosan, C., Abraham, A., Ishibuchi, H. (eds.) Hybrid Evolutionary Algorithms, Springer, Berlin (2006) 13. Lamont, G.B., Merkie, L.D.: Toward effective polypeptide chain prediction with parallel fast messy genetic algorithms. In: Fogel, G., Corne, D. (eds.) Evolutionary Computation in Bioinformatics, pp. 137–161 (2004) 14. Guex, N., Peitsch, M.C.: Principles of Protein Structure: Comparative Protein Modelling and Visualisation (April 2007), http://swissmodel.expasy.org/course/course-index.htm
Genetic Algorithm in Ab Initio Protein Structure Prediction 339 15. Jones, D.T., Miller, R.T., Thornton, J.M.: Successful protein fold recognition by optimal sequence threading validated by rigorous blind testing. Proteins: Structure, Function, and Genetics 23, 387–397 (1995) 16. Sánchez, R., Šali, A.: Large-scale protein structure modeling of the Saccharomyces cerevisiae genome. In: PNAS 95, pp. 13597–13602 (1998) 17. Jones, D.T.: GenTHREADER: An efficient and reliable protein fold recognition method for genomic sequences. Journal of Molecular Biology 287, 797–815 (1999) 18. Wikipedia: De novo protein structure prediction (July 2007), http://en.wikipedia.org/wiki/ De_novo_protein_structure_prediction 19. Xia, Y., Huang, E.S., Levitt, M., Samudrala, R.: Ab Initio Construction of Protein Tertiary Structures using a Hierarchical Approach. J. Mol. Biol. 300, 171–185 (2000) 20. Anfinsen, C.B.: Studies on the Principles that Govern the Folding of Protein Chains (1972), http://nobelprize.org/nobel_prizes/chemistry/laureates/ 21. Levinthal, C.: Are there pathways for protein folding? Journal of Chemical Physics 64, 44–45 (1968) 22. Backofen, R., Will, S.: A Constraint-Based Approach to Fast and Exact Structure Prediction in Three-Dimensional Protein Models. Constraints Journal 11 (2006) 23. Schueler-Furman, O., Wang, C., Bradley, P., Misura, K., Baker, D.: Progress in Modeling of Protein Structures and Interactions. Science 310, 638–642 (2005) 24. Hirst, J.D., Vieth, M., Skolnick, J., Brook, C.L.: Predicting leucine zipper structures from sequence. Protein Engineering 9, 657–662 (1996) 25. Roterman, I.K., Lambert, M.H., Gibson, K.D., Scheraga, H.: A comparison of the CHARMM, AMBER and ECEPP potentials for peptides. II. Phi-psi maps for N-acetyl alanine N’-methyl amide: comparisons, contrasts and simple experimental tests. J. Biomol. Struct. Dynamics 7, 421–453 (1989) 26. Cornell, W.D., Cieplak, P., Bayly, C.I., Gould, I.R., Merz Jr., K.M., Ferguson, D.M., Spellmeyer, D.C., Fox, T., Caldwell, J.W., Kollman, P.A.: A second generation force field for the simulation of proteins and nucleic acids. J. Am. Chem. Soc. 117, 5179– 5197 (1995) 27. Nemethy, G., Gibson, K.D., Palmer, K.A., Yoon, C.N., Paterlini, G., Zagari, A., Rumsey, S., Scheraga, H.A.: Improved geometrical parameters and non-bonded interactions for use in the ECEPP/3 algorithm, with application to proline-containing peptides. Journal of physical chemistry 96, 6472–6484 (1992) 28. Heureux, P.L., et al.: Knowledge-Based Prediction of Protein Tertiary Structure. Computational Methods for Protein Folding: Advances in Chemical Physics 120 (2002) 29. Ercolessi, F.: A molecular dynamics primer. In: ICTP, Spring College in Computational Physics (1997) 30. Schlick, T.: Molecular Modeling and Simulation. Springer, Heidelberg (2002) 31. Stote, R.: Theory of Molecular Dynamics Simulations (March 2006), http://www.ch.embnet.org/MDtutorial/ 32. Dill, K.A.: Theory for the Folding and Stability of Globular Proteins. Biochemistry 24, 1501–1509 (1985) 33. Dill, K.A., Bromberg, S., Yue, K., Fiebig, K.M., Yee, D.P., Thomas, P.D., Chan, H.S.: Principles of protein folding – A perspective from simple exact models. Protein Science 4, 561–602 (1995)
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Amandeep S. Sidhu and Tharam S. Dil
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Amandeep S. Sidhu and Tharam S. Dil
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Preface The molecular biology commu
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Preface VII biomedical systems, and
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X Contents Mining Clinical, Immunol
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2 A.S. Sidhu, M. Bellgard, and T.S.
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Towards Bioinformatics Resourceomes
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2 The New Waves Towards Bioinformat
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2.4 Semantic Web Towards Bioinforma
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A Summary of Genomic Databases: Ove
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Appendix A Summary of Genomic Datab
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Protein Data Integration Problem Am
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Protein Data Integration Problem 57
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Fig. 3. Class Hierarchy of Protein
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Bio-medical Ontologies Maintenance
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Extraction of Constraints from Biol
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Classifying Patterns in Bioinformat
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Mining Clinical, Immunological, and
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Substructure Analysis of Metabolic
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entry compound relation subtype com
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Running Time 4500 4000 3500 3000 25
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6 Conclusion Substructure Analysis
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266 J.Y. Chen, S. Taduri, and F. Ll
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Completing the Total Wellbeing Puzz
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Completing the Total Wellbeing Puzz
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