Facultative courses
Sylabus data
| Name and level of the course |
Type of course | Hours | ECTS | Program | Lecturer | |
|---|---|---|---|---|---|---|
| 1 |
Fundamentals of genetic engineering Bachelor course |
lecture seminar laboratory class |
30 30 60 |
2 3 5 |
Properties of carriers of genetic information; genetic code and flow of genetic information; Mutations; regulatory protein-DNA interactions; regulator-RNA protein interactions; basic molecular tools (vectors, polymerases, ligases, nucleases and other DNA-modifying enzymes); restriction endonucleases and their use; nucleic acid isolation techniques; molecular cloning procedures; DNA duplication methods: PCR and Real-time PCR and alternative DNA amplification methods (definitions, varieties, modifications, uses); nucleic acid sequencing techniques; sequencing strategies and genome analysis, Human Genome Sequencing Project; genetic engineering and molecular biotechnology (concepts, history, achievements, prospects, threats); microorganisms, animals and transgenic plants.
|
prof. dr hab. Piotr Skowron dr hab. Agnieszka Żylicz-Stachula, prof UG |
| 2 |
Fundamentals of eukariotic cell biology Bachelor course |
lecture
|
30
|
2 |
Structure of the eukaryotic cell; basics of healthy eukaryotic cell biology; DNA repair mechanisms; control of cell division; oncogenes and tumor suppressor genes (definitions, examples); basic properties of the tumor cell; classification of tumors; cell lines; the role of bacteria in cancer transformation; mutagenic agents: carcinogenic compounds, UV radiation, gamma radiation; inheritance of tumors; selected diagnostic methods in oncology; personalization of medicine.
|
dr hab. Agnieszka Żylicz-Stachula, prof UG |
| 3 |
BIOPUZZLE Engineer course
|
laboratory class | 20 | 2 |
Molecular techniques and tools used in molecular biotechnology. Cellular, plasmid DNA. DNA purification, DNA duplication reaction, DNA enzymatic hydrolysis, electrophoretic separation of DNA, measurement of DNA concentration. The concept of a size standard (molecular weight). Basic IT tools in biotechnological design. Biotechnology databases. |
dr inż. Joanna Jeżewska-Frąckowiak |
| 4 |
Ethical problems in biotechnology Engineer course
|
auditorium class | 15 | 1 |
Substantive basis of genetic engineering, including: cloning, genetic modification of plants and animals, therapies, prevention of infectious diseases. Outline of the humanistic theory of bioethics in a systematic approach. Sources of ethical conflicts. The influence of the media on the formation of non-scientific opinions. Verification of the reliability of the source of information. Scientific, non-scientific sources of information.
|
dr inż. Joanna Jeżewska-Frąckowiak |
| 5 |
Biotechnology in the environmental and human health protection Master course |
lecture | 30 | 2 |
Biotechnological aspects of human health and environmental protection, advanced methods of DNA manipulation, protection of biodiversity, molecular diagnostic methods, immunological procedures, ELISA, use of monoclonal antibodies, diagnostic systems based on bioluminescence and biofluorescence, DNA diagnostic methods, including hybridization techniques, PCR, molecular diagnostics of genetic diseases, biotechnological drugs of protein nature (hormones, enzymes, monoclonal and recombinant antibodies), antibiotics, nucleic acids as pharmaceuticals, basics of molecular biotechnology of vaccines, bioremediation and utilization of biomass, phytoremediation, genetic engineering of biodegradation pathways, transgenic plants and animals, resistance to biotic and abiotic factors, plants as bioreactors and edible vaccines, bacterial stimulation of plant growth, insecticides of bacterial origin, engineering of biotoxins, baculoviruses as tools of biocontrol.
|
dr inż. Joanna Jeżewska-Frąckowiak dr hab. Agnieszka Żylicz-Stachula, prof UG |
| 6 |
Molecular genetics Master course |
lecture | 30 | 3 |
Structure and physical organization of genetic material, genetic code, genes and phenotype, Mendel's laws, bacteriophages, DNA replication, DNA repair, mutations, recombinant DNA, DNA transcription, catalytic and regulatory RNA, translation, regulation of gene expression, transcription switches: inducible and repressible operons, catabolic repression, sources of genetic variation, structure and function of eukaryotic genes, DNA sequencing, Sanger method, pyrosequenceing, NGS, genome sequencing, matrix preparation, vectors for library generation, sequence assembly, genome sequencing strategies, first sequenced genome, Human Genome Project, genome mapping, genotyping.
|
dr hab. Agnieszka Żylicz-Stachula, prof UG
dr inż. Joanna Jeżewska-Frąckowiak |
| 7 |
Microorganisms in biotechnology Master course |
lecture | 30 | 2 |
Definitions of biotechnology and biotechnological process. Elements of biotechnological process design. Phylogenetic tree, groups of microorganisms used in biotechnology and their sources. Conventional and genetically modified microorganisms. Biotechnological applications of complete microorganisms and products derived from them, native and recombinant enzymes. Isolation and purification of native and recombinant proteins. Characterization of selected biotechnological processes using microorganisms (examples of white, green and red biotechnology), use of microorganisms in waste management. Probiotics and model microorganisms. Legal bases for uses of microorganisms and genetically modified microorganisms in biotechnology.
|
dr inż. Joanna Jeżewska-Frąckowiak |
| 8 |
Medical biotechnology Master course |
lecture | 30 | 3 |
The use of stem cells in medical biotechnology; tissue engineering and regenerative medicine; methods of obtaining new biomaterials; proteomics as a tool for identifying new therapeutic targets; pharmacogenetics and pharmacogenomics; recombinant vaccines; examples of gene therapy; use of antibodies in biotechnology and immunotherapy; The future of medical biotechnology, ethical controversies.
|
dr hab. Agnieszka Żylicz-Stachula, prof UG |
| 9 |
Peptides and proteins in science and industry Master course |
lecture | 30 | 3 |
Structure of the peptide bond and the structure of peptides and proteins; division of peptides and proteins; nomenclature and stereochemistry of peptides; Methods obtaining peptides on a laboratory and industrial scale; techniques for isolating and purifying peptides and proteins; protein databases and bioactive peptides; The structure and importance of peptides and proteins in medicine, pharmacy, cosmetology and food industry (e.g. peptide drugs, cosmetic peptides, biologically and functionally active peptides, bioactive sequences derived from food proteins, etc.)
|
dr hab. Elżbieta Kamysz, prof. UG |