PdF:VZpB52 Genetics - Course Information
VZpB52 Genetics
Faculty of EducationAutumn 2021
- Extent and Intensity
- 1/1/0. 4 credit(s). Type of Completion: zk (examination).
- Teacher(s)
- PhDr. Mgr. Lenka Adámková, Ph.D. (lecturer)
Mgr. et Mgr. Lenka Falk, Ph.D. (lecturer)
doc. MUDr. Petr Kachlík, Ph.D. (lecturer) - Guaranteed by
- doc. MUDr. Petr Kachlík, Ph.D.
Department of Physical Education and Health Education – Faculty of Education
Contact Person: Andrea Špačková
Supplier department: Department of Physical Education and Health Education – Faculty of Education - Timetable of Seminar Groups
- VZpB52/01: Tue 21. 9. to Tue 14. 12. Tue 9:00–10:50 učebna 41, L. Falk
- Prerequisites (in Czech)
- VzpB21 Human biology and basic health education 2
- Course Enrolment Limitations
- The course is only offered to the students of the study fields the course is directly associated with.
- fields of study / plans the course is directly associated with
- Lower Secondary School Teacher Training in Health Education (programme PdF, B-SPE)
- Health Education (programme PdF, B-SPE)
- Health Education (programme PdF, B-VZ3S) (2)
- Course objectives
- On the basis of the knowledge acquired the students will understand the importance of inherited qualities of an individual, describe the human genome, the principle of mutations, causes and consequences of their occurrence, basic genetic diseases, and the causes of lifestyle diseases in a broader context.
- Learning outcomes
- Upon completion of the course the students will: Be able to clearly explain the basic genetic concepts, Mendel’s laws and principles of heredity, Understand and be able to explain examples of monohybridism and dihybridism, propose suitable teaching examples for elementary schools, Understand the molecular principle of heredity, function of nucleic acids, and gene expression, Be able to see the human genome in the context of the creation, development and health of a human being.
- Syllabus
- 1. Basic genetic concepts and principles: heredity, variability, gene, allele and their relations, genotype, phenotype; 2. Basic genetic principles: Mendel’s phenotype laws. Monohybridism, dihybridism; 3. Chromosomal principle of heredity. Structure and significance of chromosomes. Human karyotype; 4. Cell cycle, mitosis, meiosis. Gametogenesis. Cell cycle regulation; 5. Molecular principle of heredity. Structure and function of nucleic acids. Genome; 6. DNA replication. Gene expression – transcription, translation. Genetic code. Protein synthesis. Human genome; 7. Monogenic inheritance in humans. Mutation. Genetic disorders in humans – gene-based. Autosomal dominant, autosomal recessive disorders; 8. Deviations from Mendelian segregation ratios. Gene linkage. Gene interaction. Gonosomal inheritance. Extranuclear inheritance; 9. Genetic disorders in humans – genome mutations. Aneuploidy in humans; 10. Genetic disorders in humans – chromosomal aberrations. Mutagens; 11. Inheritance of quantitative traits. Polygenous inheritance in humans. Multifactorial and complex traits in humans. Cancer – genetic disease; 12. Genetic prevention. Prenatal diagnosis. Assisted reproduction, pre-implantation diagnosis. Content of seminars: 1. Basic genetic principles, dominance and recessiveness; 2. Mendel’s crossing peas experiments; 3. Principle of segregation – training on specific examples of non-pathological traits in humans; 4. Monohybridism – training on specific examples of pathological traits in humans; 5. Inheritance of blood groups in humans, AB0 system, Rh-factor, molecular and biochemical principles, Bombay phenotype; 6. Blood groups – examples; 7. Principle of combination – training on specific examples of vegetable and animal organisms; 8. Dihybridism – training on specific examples of hereditary traits in humans; 9. Principles of segregation and combination in the context of cell division, mitosis, meiosis, chromatin replication and division; 10. Molecular principles – replication, transcription, translation – examples; 11. - 12. Bioethics in genetics – discussion on current issues (GMO, assisted reproduction, genetic research, etc.)
- Literature
- required literature
- KŘEČEK, Jiří. Jedinec: Gen – prostředí – vývoj. 1. vyd. Praha: Academia, 2007. 232 s. ISBN 978-80-200-1490-0.
- NUSSBAUM, Robert L., Roderick R. MCINNES, Huntington F. WILLARD, James THOMPSON a Margaret Wilson THOMPSON. Klinická genetika: Thompson &Thompson : 6. vyd.Translated by Petr Goetz. Vyd. 1. Praha: Triton, 2004. 426, lix. ISBN 8072544756.
- FRYDRYCH, Karol. Zdeněk Hatina jako učitel hry na varhany (Zdeněk Hatina as an organ teacher). Zpravodaj Musica sacra. Brno, 2016, vol. 24, No 2, p. 8-10. ISSN 2336-5374. info
- ŠMARDA, Jan. Genetika : pro gymnázia. 1. vyd. Praha: Fortuna, 2003, 143 s. ISBN 8071688517. info
- SNUSTAD, D. Peter and Michael J. SIMMONS. Principles of genetics [Snustad, Simmons, 2000]. 2nd ed. New York: John Wiley & Sons, 2000, xviii, 876. ISBN 0-471-29800-X. info
- Teaching methods
- Theoretical preparation – lectures with selected scientific videos. The topic of each lecture including recommended literature will be announced one week in advance. Each lecture will be rounded off by a summary in the form of a discussion on new concepts and contexts presented and explained to students during the lectures.
- Assessment methods
- The final part of the course is an oral exam, which consists of two parts: a) practical – solving and defending of a specific model genetic task – to be drawn by each student from a total of 95 tasks; b) theoretical – each student shall answer and explain two theoretical questions on general genetics – to be drawn from a total of 40 double-questions.
- Language of instruction
- Czech
- Further Comments
- Study Materials
The course is taught annually.
- Enrolment Statistics (Autumn 2021, recent)
- Permalink: https://is.muni.cz/course/ped/autumn2021/VZpB52