BMB504: Fundamental Molecular Biology

The course builds upon FF503 Chemistry, Biology and Molecular Biology – the Empiric Experimental Science or BB537 Biology from Molecule to Ecosystem.

• Toxicology, Natural Products Chemistry and Pharmacognosy (BSc. in Pharmacy)
• Bioorganic chemistry topics(BSc./MSc. in Chemistry)
• Molecular aspects of evolution, projects involving molecular methods(BSc./MSc in Biology).

• the insight into structure and function of biomolecules at the molecular level (Degree in Biology)
• knowledge required to teach biology at high school level (Degree in Biology)
• the knowledge in fundamental biochemistry and molecular biology (Degree in Chemistry)
• knowledge about and understanding of biochemistry and disease mechanisms at the molecular level (Degree in Pharmacy).

• Use the general terms in molecular biology
  
• Outline the flow of genetic information from gene to protein
• Explain the relation between the structure and function of nucleic acids
• Describe the basic molecular events behind DNA replication, RNA transcription and protein translation
• Know the basic composition and names of enzymes involved in DNA replication, RNA transcription and translation.
• Understand the various levels of regulation of gene expression and the role of chromatin structure in those processes.
• Know the principles of common techniques in molecular biology and protein analysis.
• Relate the chemical composition of proteins to their structure.
• Give examples of molecular mechanisms underlying diseases.
• Define “homology” at the molecular level

1. The concept of central dogma of molecular biology and the information flow from DNA to RNA and to proteins.
2. Structure and function of nucleic acids (DNA and RNA)
3. Principles of DNA replication and regulation of this process
4. DNA damage and repair and their role in evolution and disease pathology
5. Basic analytical techniques for DNA sequencing, PCR and gene cloning
6. The genetic code
7. Mechanism of RNA transcription
8. Regulation of gene expression in prokaryotic and eukaryotic organisms
9. RNA processing and its role in gene expression regulation
10. The role of bioinformatics in understanding evolution.
11. Basic techniques for alignment of DNA, RNA and protein sequences.
12. Protein composition and structure.
13. Protein synthesis and translocation within the cell. The role of ribosomes, tRNAs and tRNA synthases in this process.
14. Basic analytical techniques in protein analysis: electrophoresis, chromatography and centrifugation.

Jeremy M Berg, John L Tymoczko & Lubert Stryer: Biochemistry, 9. ed.
See Blackboard for syllabus lists and additional literature references.

• Intro phase: 22 hours. Lectures based on course handbook Jeremy M Berg, John L Tymoczko & Lubert Stryer: Biochemistry, 9th edition.
• Skills training phase: 20 hours tutorials:. 10 different scientific problems will be presented and discussed with students during course seminar hours

• Online training in solving multiple choice questions. (Six electronic tests are held during the course. The tests are designed to familiarise students with the examination form. Participation in the tests are non-obligatory.)
• Self-study of course textbook Jeremy M Berg, John L Tymoczko & Lubert Stryer: Biochemistry, 9th edition during exam preparation.Preparing for tutorials