Kirsten Bomblies: Catalogue data in Autumn Semester 2022

Award: The Golden Owl
Name Prof. Dr. Kirsten Bomblies
FieldPlant Evolutionary Genetics
Address
Professur Pflanzenevolutionsgen.
ETH Zürich, LFW E 56.1
Universitätstrasse 2
8092 Zürich
SWITZERLAND
Telephone+41 44 632 71 89
E-mailkirstenbomblies@ethz.ch
DepartmentBiology
RelationshipFull Professor

NumberTitleECTSHoursLecturers
551-0003-AALGeneral Biology I+II
Enrolment ONLY for MSc students with a decree declaring this course unit as an additional admission requirement.

Any other students (e.g. incoming exchange students, doctoral students) CANNOT enrol for this course unit.
7 credits13RU. Sauer, K. Bomblies, O. Y. Martin, A. Widmer
AbstractGeneral Biology I: Organismic biology to teach the basic principles of classical and molecular genetics, evolutionary biology and phylogeny.

General Biology II: Molecular biology approach to teach the basic principles of biochemistry, cell biology, cgenetics, evolutionary biology and form and function of vacular plants.
ObjectiveGeneral Biology I: The understanding of basic principles of biology (inheritance, evolution and phylogeny) and an overview of the diversity of life.

General Biology II: The understanding basic concepts of biology: the hierarchy of the structural levels of biological organisation, with particular emphasis on the cell and its molecular functions, the fundamentals of metabolism and molecular genetics, as well as form and function of vascular plants.
ContentGeneral Biology I:
General Biology I focuses on the organismal biology aspects of genetics, evolution and diversity of life in the Campbell chapters 12-34.

Week 1-7 by Alex Widmer, Chapters 12-25
12 Cell biology Mitosis
13 Genetics Sexual life cycles and meiosis
14 Genetics Mendelian genetics
15 Genetics Linkage and chromosomes
20 Genetics Evolution of genomes
21 Evolution How evolution works
22 Evolution Phylogentic reconstructions
23 Evolution Microevolution
24 Evolution Species and speciation
25 Evolution Macroevolution

Week 8-14 by Oliver Martin, Chapters 26-34
26 Diversity of Life Introdution to viruses
27 Diversity of Life Prokaryotes
28 Diversity of Life Origin & evolution of eukaryotes
29 Diversity of Life Nonvascular&seedless vascular plants
30 Diversity of Life Seed plants
31 Diversity of Life Introduction to fungi
32 Diversity of Life Overview of animal diversity
33 Diversity of Life Introduction to invertebrates
34 Diversity of Life Origin & evolution of vertebrates


General Biology II: The structure and function of biomacromolecules; basics of metabolism; tour of the cell; membrane structure and function; basic energetics of cellular processes; respiration, photosynthesis; cell cycle, from gene to protein; structure and growth of vascular plants, resource acquisition and transport, soil and plant nutrition.

Specifically the following Campbell chapters will be covered:
3 Biochemistry Chemistry of water
4 Biochemistry Carbon: the basis of molecular diversity
5 Biochemistry Biological macromolecules and lipids
7 Cell biology Cell structure and function
8 Cell biology Cell membranes
10 Cell biology Respiration: introduction to metabolism
10 Cell biology Cell respiration
11 Cell biology Photosynthetic processes
16 Genetics Nucleic acids and inheritance
17 Genetics Expression of genes
18 Genetics Control of gene expression
19 Genetics DNA Technology
35 Plant structure&function Plant Structure and Growth
36 Plant structure&function Transport in vascular plants
37 Plant structure&function Plant nutrition
38 Plant structure&function Reproduction of flowering plants
39 Plant structure&function Plants signal and behavior
Lecture notesNo script
LiteratureCampbell et al. (2017) Biology - A Global Approach. 11th Edition (Global Edition)
Prerequisites / NoticeBasic general and organic chemistry


This is a virtual self-study lecture for non-German speakers of the "Allgemeine Biology I (551-0001-00L) and "Allgemeine Biology II (551-0002-00L) lectures. The exam will be written jointly with the participants of this lecture.
551-0120-00LPlant Biology Colloquium (Autumn Semester)
This compulsory course is required only once. It may be taken in autumn as course 551-0120-00 "Plant Biology Colloquium (Autumn Semester)" or in spring as course 551-0120-01 "Plant Biology Colloquium (Spring Semester)".
2 credits1KS. C. Zeeman, K. Bomblies, C. Sánchez-Rodríguez, O. Voinnet
AbstractCurrent topics in Molecular Plant Biology presented by internal and external speakers from accademia.
ObjectiveGetting insight into actual areas and challenges of Molecular Plant Biology.
Contenthttp://www.impb.ethz.ch/news-and-events/colloquium-impb.html
551-0311-00LMolecular Life of Plants6 credits4VS. C. Zeeman, K. Bomblies, O. Voinnet
AbstractThe advanced course introduces students to plants through a concept-based discussion of developmental processes that integrates physiology and biochemistry with genetics, molecular biology, and cell biology. The course follows the life of the plant, starting with the seed, progressing through germination to the seedling and mature plant, and ending with reproduction and senescence.
ObjectiveThe new course "Molecular Life of Plants" reflects the rapid advcances that are occurring in the field of experimental plant biology as well as the changing interests of students being trained in this discipline. Contemporary plant biology courses emphasize a traditional approach to experimental plant biology by discussing discrete topics that are removed from the context of the plant life cycle. The course will take an integrative approach that focuses on developmental concepts. Whereas traditional plant physiology courses were based on research carried out on intact plants or plant organs and were often based on phenomenological observations, current research in plant biology emphasizes work at the cellular, subcellular and molecular levels.

The goal of "Molecular Life of Plants" is to train students in integrative approaches to understand the function of plants in a developmental context. While the course focuses on plants, the training integrative approaches will also be useful for other organisms.
ContentThe course "Molecular Life of Plants" will cover the following topics:

Plant genome organization and evolution
Plant functional genomics and systems biology
Plant genome engineering and editing
Seed development and embryogenesis
Root apical meristem: structure, function and hormone regulation
Shoot apical meristem: structure, function and hormone regulation
Mobilization of seed reserves
Heterotrophic to autotrophic growth
Chloroplast biogenesis and light perception
Photosynthetic and central carbon metabolism
Integration of carbon and nitrogen metabolism
Principles of RNA silencing
MicroRNAs: discovery and modes of action
RNA silencing and pathogen defense
RNA silencing movement, amplification and trans-generational silencing
Plants and the environment
Plant-pathogen interactions: pathogen attack, first layers of plant defense and plant responses
Senescence
551-1517-00LProtein Change in Adaptive Evolution Restricted registration - show details
Number of participants limited to 5.
The enrolment is done by the D-BIOL study administration.
6 credits7PC. S. Hughes, K. Bomblies, A. P. Nayak
AbstractProteins that seem to have evolved to help stabilize meiosis to temperature and/or polyploidy in plants.
ObjectiveTo learn techniques in protein structure prediction, functional prediction and evolutionary analyses (bioinformatic), as well as protein purification from e. coli, insect cell, and/or cell-free systems, and analysis of e.g. interactions with DNA, thermostability, etc…
ContentGuided research projects to study the biochemical consequences of adaptive evolution in a variety of proteins. Mostly the focus is on proteins that seem to have evolved to help stabilize meiosis to temperature and/or polyploidy in plants.
Lecture notesWill be provided, as appropriate, during the course.
LiteratureWill be provided during course.