PřF:Bi1700 Cell Biology - Course Information

Bi1700 Cell Biology

Extent and Intensity

2/0/0. 2 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Renata Veselská, Ph.D., M.Sc. (lecturer)
prof. RNDr. Jan Šmarda, CSc. (lecturer)

Guaranteed by

prof. RNDr. Renata Veselská, Ph.D., M.Sc.
Department of Experimental Biology – Biology Section – Faculty of Science
Contact Person: prof. RNDr. Renata Veselská, Ph.D., M.Sc.
Supplier department: Department of Experimental Biology – Biology Section – Faculty of Science

Timetable

Mon 18. 9. to Fri 15. 12. Mon 11:00–12:50 B11/132

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

there are 35 fields of study the course is directly associated with, display

Course objectives

At the end of the course students should be able to understand basic processes of life on cellular level. He or she should be able to explain their principles and structural components. In addition, he or she should be able to make deductions based on acquired knowledge to explain differences between prokaryotic and eukaryotic cells.

Learning outcomes

Student copmletenig this course understands the cellular world and basic principles of its functioning. Specifically: he/she knows basic cellular chemical compounds and their organization to functional complexes; principles of maintaing and expression of genetics information; the logic of internal organization of a cell to compartments and the way of communication among them; basic mechanisms of cell cycle control and intracellular signalling; pathological behavior of cells; origin and evolution of cells.

Syllabus

• 1) CHEMISTRY OF A CELL (atoms - molecules - macromolecules; chemical elements in living systems; atomic bonds in molecules; polar and nonpolar molecules; significance of water for chemistry of a cell; main types of organic molecules; saccharides, fatty acids, aminoacids, nucleotides; formation of polymers from monomers in essential cell polymers - nucleic acids and proteins).
• 2) CELLULAR AND NONCELLULAR FORMS OF LIFE (history and technical limits of cellular analyses by microscopy; light and electron microscopy; organization of living system; noncellular forms of life; cellular forms of life - types of prokaryotic and eukaryotic cells, basic characteristic; principles of functional organization of a cell)
• 3) BIOMEMBRANES AND INTERNAL CELL ORGANIZATION (structure and function of biomembranes; transport function of biomembranes; plasmatic membrane; osmotic phenomena; biomembranes of prokaryotic cells; compartmentalization of eukaryotic cells; organelles of eukaryotic cells - composition and function; membrane fusion; principles of vesicular transport; endocytosis and exocytosis)
• 4) STORAGE AND EXPRESSION OF GENETIC INFORMATION (definitions of a gene and genetic information; main functions of genetic material; chemistry of genetic material; structure of DNA and RNA; replication of DNA;, principles of gene expression; prokaryotic and eukaryotic transcription; modification of primary transcript; RNA splicing; translation and genetic code)
• 5) CYTOSKELETON (components and basic functions; methods of visualization; microtubules; actin filaments; intermediate filaments; nuclear and cortical skeleton; cytoskeleton of prokaryotes)
• 6) INTRACELLULAR TRANSPORT (cell compartmentalization; protein folding and chaperons/chaperonins; protein sorting; protein import to membrane organelles; transport of molecules to nucleus; secretion and endocytic pathways; transport vesicles; endoplasmic reticulum and Golgi apparátu in intracellular transport)
• 7) CELL CYCLE (phases and kinetics of a cell cycle; the role of yeasts in the cell cycle research; methodical approaches to cell cycle analyses; molecular principles of cell cycling; cell cycle regulators; types of cyclins; cell cycle checkpoints; p53 and Rb proteins in cell cycle regulation)
• 8) CELL DIVISION (types of cell division; binary division in prokaryotes; changes of chromatin during eukaryotic cell division; composition of eukaryotic chromosomes; mitosis and meiosis; roles and phases of mitosis and meiosis; cytokinesis in plant and animal cells)
• 9) CELL COMMUNICATION (principles of cell signaling, types of signal molecules; the role of chemical properties of signals; types of receptors; endocrine and paracrine signaling; synapses; transfer of extracellular signals to intracellular secondary messengers; G proteins; MAPK signaling pathway; cytokine signaling; SH2 domain; effectors of signaling pathways)
• 10) CELL PATHOLOGY (physiological and pathological life conditions; cell response to stress; types of stress factors; physical stress factors - temperatures shifts, visible light, UV light, ionizing radiation; chemical stress factors - nonspecific toxins, specific inhibitors; biological stress factors - intracellular parasitism; types of cell death; catastrophic cell death - necrosis: induction, characteristics; physiological cell death - autophagy, apoptosis: induction, characteristics)
• 11) CELL EVOLUTION (hypotheses on origin of organic compounds and biopolymers; Miller test; ribozymes and RNA world; primitive proteosynthesis; encapsulation; origin of first cells; evolutionary relations among cells; origin and development of eukaryotic cell; endosymbiotic theory)

Literature

recommended literature
• SNUSTAD, D. Peter and Michael J. SIMMONS. Genetika. Translated by Jiřina Relichová. Druhé, aktualizované vydá. Brno: Masarykova univerzita. xix, 844. ISBN 9788021086135. 2017. info
• ALBERTS, Bruce. Základy buněčné biologie : úvod do molekulární biologie buňky. Translated by Arnošt Kotyk. 2. vyd. Ústí nad Labem: Espero Publishing. xxvi, 630. ISBN 8090290620. 2004. info

Teaching methods

lectures

Assessment methods

Written test is required. To pass the exam, at least 50% of answers have to be correct.

Language of instruction

Czech

Further Comments

The course can also be completed outside the examination period.
The course is taught annually.

Listed among pre-requisites of other courses

• LF:AMOLp Introduction into molecular biology and genetics - lecture
  (!VSBI0222p) && (!VLBI0222p) && (!ZLBI0222p) && (!PřF:Bi1700)  
• LF:BLKH0311c Clinical Haematology - practice
  BLMB011p || PřF:Bi1700  
• LF:BLKH0311p Clinical Haematology - lecture
  BLMB011p || PřF:Bi1700  
• LF:VLMB011 Modern imaging and analytical methods in cellular biology
  VLBI0222p || ZLBI0222p || PřF:Bi1700 || VSBI0222p  
• Bi1190 Biology of Plant Cell
  Bi1700 && Bi1060 && Bi4060  
• Bi1700c Cell Biology - practical course
  NOW(Bi1700)  
• Bi1700en Cell Biology
  (!Bi1700) && !NOWANY(Bi1700)  
• Bi2020 Scientific Work in Cell Biology
  Bi1700  
• Bi2021 Information technology in cell biology
  Bi1700  

Zobrazit další předměty

• Bi7001 Cell Architecture
  Bi1700 && Bi4020  
• Bi7001c Cell Architecture - Practicals
  Bi1700 && Bi1700c && NOW(Bi7001)  
• Bi7005 Cell Regulations
  Bi1700 && Bi4020  
• Bi7420 Modern methods for genome analysis
  Bi1700 && (Bi4010 || Bi4020) && (Bi4020c || Bi6400)  
• Bi8005 Cell Biology of Protists
  Bi1700 && Bi4020  
• Bi8120 Biomedical Applications of Cell Biology
  Bi1700 && (Bi4010 || Bi4020)  
• Bi8440 Basics of Clinical Oncology
  Bi1700 && Bi4020  
• Bi8790 Regulation of development processes
  (Bi1700 || Bi2080) && Bi3030 && (Bi4010 || Bi4020) && Bi6140  
• Bi8920 Advanced Microscopic Methods
  Bi1700 || Bi1700c  
• Bi8920c Fluorescence microscopy - practice
  Bi1700 || Bi1700c && NOW(Bi8920)  
• C6210 Biotechnology
  (Bi1700 || C7920 || CG010 || C1470 || souhlas) && !NOWANY(C6211)  
• C8004 Advanced Plant Cell Biology
  Bi1700 && Bi4020  

• Enrolment Statistics (autumn 2017, recent)
  
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