Search result: Catalogue data in Spring Semester 2019

Biology Bachelor Information
3. Year, 6. Semester
Concept Courses
NumberTitleTypeECTSHoursLecturers
529-0732-00LProteins and LipidsW6 credits3GD. Hilvert
AbstractAn overview of the relationship between protein sequence, conformation and function.
ObjectiveOverview of the relationship between protein sequence, conformation and function.
ContentProteins, structures and properties, (bio)synthesis of polypeptides, protein folding and design, protein engineering, chemical modification of proteins, proteomics.
LiteratureGeneral Literature:
- T.E. Creighton: Proteins: Structures and Molecular Properties, 2nd Edition, H.W. Freeman and Company, New York, 1993.
- C. Branden, J. Tooze , Introduction to Protein Structure, Garland Publishing, New York, 1991.
- J. M. Berg, J. L. Tymoczko, L. Stryer: Biochemistry, 5th edition, H.W. Freeman and Company, New York, 2002.
- G.A. Petsko, D. Ringe: Protein Structure and Function, New Science Press Ltd., London, 2004.

Original Literature:
Citations from the original literature relevant to the individual lectures will be assigned weekly.
551-0324-00LSystems Biology Information W6 credits4VR. Aebersold, B. Christen, M. Claassen, U. Sauer
AbstractIntroduction to experimental and computational methods of systems biology. By using baker’s yeast as a thread through the series, we focus on global methods for analysis of and interference with biological functions. Illustrative applications to other organisms will highlight medical and biotechnological aspects.
Objective- obtain an overview of global analytical methods
- obtain an overview of computational methods in systems biology
- understand the concepts of systems biology
ContentOverview of global analytical methods (e.g. DNA arrays, proteomics, metabolomics, fluxes etc), global interference methods (siRNA, mutant libraries, synthetic lethality etc.) and imaging methods. Introduction to mass spectrometry and proteomics. Concepts of metabolism in microbes and higher cells. Systems biology of developmental processes. Concepts of mathematical modeling and applications of computational systems biology.
Lecture notesno script
LiteratureThe course is not taught by a particular book, but some books are suggested for further reading:

- Systems biology in Practice by Klipp, Herwig, Kowald, Wierling und Lehrach. Wiley-VCH 2005
551-0320-00LCellular Biochemistry (Part II)W3 credits2VY. Barral, R. Kroschewski, A. E. Smith
AbstractThis course will focus on molecular mechanisms and concepts underlying cellular biochemistry, providing advanced insights into the structural and functional details of individual cell components, and the complex regulation of their interactions. Particular emphasis will be on the spatial and temporal integration of different molecules and signaling pathways into global cellular processes.
ObjectiveThe full-year course (551-0319-00 & 551-0320-00) focuses on the molecular mechanisms and concepts underlying the biochemistry of cellular physiology, investigating how these processes are integrated to carry out highly coordinated cellular functions. The molecular characterization of complex cellular functions requires a combination of approaches such as biochemistry, but also cell biology and genetics. This course is therefore the occasion to discuss these techniques and their integration in modern cellular biochemistry.
The students will be able to describe the structural and functional details of individual cell components, and the spatial and temporal regulation of their interactions. In particular, they will learn to explain how different molecules and signaling pathways can be integrated during complex and highly dynamic cellular processes such as intracellular transport, cytoskeletal rearrangements, cell motility, and cell division. In addition, they will be able to illustrate the relevance of particular signaling pathways for cellular pathologies such as cancer or during cellular infection.
ContentSpatial and temporal integration of different molecules and signaling pathways into global cellular processes, such as cell division, cell infection and cell motility. Emphasis is also put on the understanding of pathologies associated with defective cell physiology, such as cancer or during cellular infection.
LiteratureRecommended supplementary literature (review articles and selected primary literature) will be provided during the course.
Prerequisites / NoticeTo attend this course the students must have a solid basic knowledge in chemistry, biochemistry, cell biology and general biology. Biology students have in general already attended the first part of the "Cellular Biochemistry" concept course (551-0319-00). The course will be taught in English.
In addition, the course will be based on a blended-learning scenario, where frontal lectures will be complemented with carefully chosen web-based teaching elements that students access through the ETH Moodle platform.
551-0314-00LMicrobiology (Part II)W3 credits2VW.‑D. Hardt, L. Eberl, H.‑M. Fischer, J. Piel, J. Vorholt-Zambelli
AbstractAdvanced lecture class providing a broad overview on bacterial cell structure, genetics, metabolism, symbiosis and pathogenesis.
ObjectiveThis concept class will be based on common concepts and introduce to the enormous diversity among bacteria and archaea. It will cover the current research on bacterial cell structure, genetics, metabolism, symbiosis and pathogenesis.
ContentAdvanced class covering the state of the research in bacterial cell structure, genetics, metabolism, symbiosis and pathogenesis.
Lecture notesUpdated handouts will be provided during the class.
LiteratureCurrent literature references will be provided during the lectures.
Prerequisites / NoticeEnglish
551-0326-00LCell Biology Information W6 credits4VS. Werner, M. Bordoli, R. Henneberger, W. Kovacs, M. Schäfer, U. Suter, A. Wutz
AbstractThis Course introduces principle concepts, techniques, and experimental strategies used in modern Cell Biology. Major topics include: neuron-glia interactions in health and disease; mitochondrial dynamics; stem cell biology; growth factor action in development, tissue repair and disease; cell metabolism, in particular sensing and signaling mechanisms, cell organelles, and lipid metabolism.
Objective-To prepare the students for successful and efficient lab work by learning how to ask the right questions and to use the appropriate techniques in a research project.
-To convey knowledge about neuron-glia interactions in health and disease.
- To provide information on different types of stem cells and their function in health and disease
-To provide information on growth factor signaling in development, repair and disease and on the use of growth factors or their receptors as drug targets for major human diseases
-To convey knowledge on the mechanisms underlying repair of injured tissues
-To provide the students with an overview of mitochondrial dynamics.
-Providing an understanding of RNA processing reactions and their regulations.
-To provide a comprehensive understanding of metabolic sensing mechanisms occurring in different cell types and organelles in response to glucose, hormones, oxygen, nutrients as well as lipids, and to discuss downstream signaling pathways and cellular responses.
-To provide models explaining how disturbances in complex metabolic control networks and bioenergetics can lead to disease and to highlight latest experimental approaches to uncover the intricacies of metabolic control at the cellular and organismal level.
-Providing the background and context that foster cross-disciplinary scientific thinking.
551-0318-00LImmunology IIW3 credits2VA. Oxenius, M. Kopf, S. R. Leibundgut, E. Slack, further lecturers
AbstractIntroduction into the cellular and molecular basis of the immune system and immune responses against diverse pathogens, tumors, transplants, and self (autoimmunity)
ObjectiveThe lectures will provide a detailed understanding:
- how innate and adaptive immune responses interact at the cellular and molecular level.
- how the immune system recognizes and fights against pathogenic microorganisms including viruses, bacteria, and parasites.
- why lymphocytes tolerate self molecules.
- about function and dysfunction the intestinal immune system.
- immunopathology and inflammatory diseases.
ContentThe aim of lecture is to understand:
> How pathogens are recognized by the innate immune system
> Immune defense against various pathogens
> Immunology of the skin, lung and intestines
> Tumor immunology
> Migration and homing of immune cells
> tolerance and autoimmunity
> T cell memory
Lecture notesPresentations of the lecturers are available at the Moodle link
LiteratureRecommended: Kuby Immunology (Freeman)
376-0209-00LMolecular Disease MechanismsW6 credits4VC. Wolfrum, H. Gahlon, M. Kopf
AbstractIn this course the mechanisms of disease development will be studied. Main topics will be:

1. Influence of environmental factors with an emphasis on inflammation and the immune response.
2. Mechanisms underlying disease progression in metabolic disorders, integrating genetic and environmental factors.
3. Mechanisms underlying disease progression in cancer, integrating genetic and environment
ObjectiveTo understand the mechanisms governing disease development with a special emphasis on genetic and environmental associated components
Lecture notesAll information can be found at:

Link

The enrollment key will be provided by email
551-0307-01LMolecular and Structural Biology II: From Gene to Protein
D-BIOL students are obliged to take part I and part II as a two-semester course.
W3 credits2VN. Ban, F. Allain, S. Jonas, M. Pilhofer
AbstractThis course will cover advanced topics in molecular biology and biochemistry with emphasis on the structure and function of cellular assemblies involved in expression and maintenance of genetic information. We will cover the architecture and the function of molecules involved in DNA replication, transcription, translation, nucleic acid packaging in viruses, RNA processing, and CRISPER/CAS system.
ObjectiveStudents will gain a deep understanding of large cellular assemblies and the structure-function relationships governing their function in fundamental cellular processes ranging from DNA replication, transcription and translation. The lectures throughout the course will be complemented by exercises and discussions of original research examples to provide students with a deeper understanding of the subjects and to encourage active student participation.
ContentAdvanced class covering the state of the research in structural molecular biology of basic cellular processes with emphasis on the function of large cellular assemblies.
Lecture notesUpdated handouts will be provided during the class.
LiteratureThe lecture will be based on the latest literature. Additional suggested
literature:
Branden, C., and J. Tooze, Introduction to Protein Structure, 2nd ed.
(1995). Garland, New York.
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