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The course objectives include: introduction to fundamental bioinformatic approaches and tools allowing analyzing nucleotide and protein sequences, including critical interpretation of analysis outputs; survey of potential uses of bioinformatic analyses to address experimental tasks; and detailed insight into practical aspects of related molecular biology and proteomic methods and approaches.
Last update: Holík Purkrtová Zita (14.11.2012)
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Students will be able to: Use publicly accessible bioinformatics tools and nucleotide and protein databases. Independently design a strategy to analyze the sequence data, critically interpret the outcome of analyses and propose an experimental approach to prove the in silico predictions correct. Taking advantage from bioinformatic analyses of nucleotide and protein sequences, propose complex, feasible solution for a successful molecular biology experiment. Last update: Holík Purkrtová Zita (16.07.2013)
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R: Cvrčková F., Úvod do praktické bioinformatiky, Academia, 2006, 8020013601 A: Campbel A.M., Heyer L.J., Discovering genomics, proteomics and bioinformatics, CSHL Press, 0805347224 A: Wilkins M., et al., ed., Proteome Research: New Frontiers in Functional Genomics , Springer-Verlag, 1997, 3540627537 Last update: Kotrba Pavel (09.07.2013)
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http://www.ncbi.nlm.nig.gov http://www.ebi.ac.uk/Databases http://www.expasy.org http://www.uniprot.org http://prosite.expasy.org Last update: Kotrba Pavel (09.07.2013)
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1. Bioinformatics, cross-database search platforms for data mining. 2. Databases and software for nucleotide sequence analyses. 3. Gene function predictions, prediction of promoters and regulatory elements. 4. Design and practical aspects of PCR experiment. 5. Central dogma upturned: a strategy to isolate coding sequence. 6. Practical aspects and method selection in DNA and DNA-binding protein analyses. 7. Practical aspects and method selection in RNA and transcript level analyses. 8. Proteomic servers and databases. Tools for protein sequence alignments. 9. Protein modifications. In silico prediction and experimental proof. 10. Protein secondary structure and hydropathy profile. In silico prediction and experimental proof. 11. Protein quaternary structure and oligomerization state. In silico prediction and experimental proof. 12. Membrane proteins. Determination of protein localization in biological membrane, the surface properties of proteins and detergents. 13. Native state of protein. Intracellular localization and interactions of protein. 14. Laboratory work with proteins. Protein storage and sample preparation for analyses. Last update: Holík Purkrtová Zita (16.07.2013)
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none Last update: Kotrba Pavel (09.07.2013)
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| Teaching methods | ||||
| Activity | Credits | Hours | ||
| Konzultace s vyučujícími | 0.2 | 6 | ||
| Obhajoba individuálního projektu | 0.1 | 2 | ||
| Práce na individuálním projektu | 5.7 | 160 | ||
| Účast na seminářích | 1 | 28 | ||
| 7 / 7 | 196 / 196 | |||
| Coursework assessment | |
| Form | Significance |
| Defense of an individual project | 100 |