|Language of Instruction:||Czech|
|Guarantor:||Martínek Tomáš, Ing., Ph.D. (DCSY)|
|Lecturer:||Burgetová Ivana, Ing., Ph.D. (DIFS)|
Martínek Tomáš, Ing., Ph.D. (DCSY)
|Instructor:||Hon Jiří, Ing. (DIFS)|
Musil Miloš, Ing. (DIFS)
Puterová Janka, Ing. (DIFS)
|Faculty:||Faculty of Information Technology BUT|
|Department:||Department of Computer Systems FIT BUT|
|Tue||lecture||lectures||G202 ||11:00||12:50||1MIT 2MIT ||MBI xx |
| || ||To understand the principles of molecular biology. To perceive the basic used algorithms and to well informed about relevant biological databases. To be able to design new effective methods for biological data analysis.|
| || ||This course introduces students to basic principles of molecular biology, present algorithms pro biological data analysis, describes their time complexity and shows direction how to design the new methods very effectively. Particularly, the following algorithms will be discussed: methods for sequence alignment, evolutionary models, construction of phylogenetic trees, algorithms for gene identification using machine learning and approaches for prediction of 2D and 3D protein structure. Lectures will be supplement with practical examples using available biological databases.|
|Subject specific learning outcomes and competencies:|
| || ||Students will be able to take advantages of large biological database and design new efficient algorithms for their analysis.|
|Generic learning outcomes and competencies:|
| || ||Understanding the relations between computers (computing) and selected molecular processes.|
|Syllabus of lectures:|
- Introduction to bioinformatics
- Basis of molecular biology
- Tools of molecular biology
- Biological databases
- Sequence alignment, dynamic programing, BLAST, FASTA
- Evolutionary models
- Construction of phylogenetic trees
- DNA assembling
- Genomics and gene searching
- Proteins and their prediction
- Computation of RNA secondary structure
- Proteomics, regulatory networks
- Polymorphism of genes
|Syllabus of computer exercises:|
- Biological databases
- Analysis of genome sequences
- Sequence alignment
- Phylogenetic trees
- Gene prediction
- Protein structure analysis
|Syllabus - others, projects and individual work of students:|
| ||A project will be assigned to each student. Implementation, presentation and documentation of the project will be evaluated.|
- Dan K. Krane, Michael L. Raymer: Fundamental Concepts of Bioinformatics, ISBN: 0-8053-4633-3, Benjamin Cummings 2003.
- Neil C. Jones, Pavel A. Pevzner: An Introduction to Bioinformatics Algorithms, ISBN: 0262101068, MIT Press, 2004.
- Andreas D. Baxevanis, B. F. Francis Ouellette: Bioinformatics: A Practical Guide to the Analysis of Genes and Proteins, ISBN: 0-471-47878-4, Wiley-Interscience, 2005.
- Jacques Cohen: Bioinformatics - An introduction for Computer Scientists, ACM Computing Surveys, 2004, Vol. 36, No. 2, p. 122-158.
- Jean-Michel Claverie, Cedric Notredame: Bioinformatics for Dummies, ISBN: 0-7645-1696-5, Wiley Publishing, Inc., 2003.
- Yi-Ping Phoebe Chen: Bioinformatics Technologies, ISBN: 3540208739, Springer, 2005.
- Alberts, Bray, Johnson, Lewis, Raff, Roberts, Walter: Základy buněčné biologie, ISBN: 80-902906-0-4, Espero Publishing, 1998.
| || ||Presence in any form of instruction is not compulsory. An absence (and
hence loss of points) can be compensated in the following ways: |
- presence in another laboratory group dealing with the same task.
- showing a summary of results to the tutor at the next lab.
a short report (summarizing the results of the missed lab and answering
the questions from the assignment) to the tutor, in 14 days after the
| || ||Mid-term exam, project, computer lab assignments.|
| || ||None.|