No description available.

Laboratory course with advanced experiments in the plant sciences, biochemistry, and structural biology.

This 1st year Laboratory course introduces the student to the entire range of classical and modern molecular biosciences. During this course (Praktikum GL BioI) the students will do three praktikum days in:- Biochemistry- Cell Biology I- Microbiology- Plant Anantomy & Ecology(total of 12 experiments)Each experiment takes one full day.

The course provides an introduction to the basics of cell biology and genetics, the mechanisms of evolution, the evolutionary history of biological diversity, principal plant and animal form and function, and ecology.

This introductory Laboratory course introduces the student to the entire range of classical and modern molecular biosciences. In the second year (Praktikum GL Bio II) the students will perform three praktikum days in:- Bioinformatics- Plant Physiology- Genetics and- Cell Biology II.(total of 12 experiments)Each experiment takes one full day.

Plant Biology: Water balance, assimilation and transport in plants; developmental biology and stress physiology.Neurobiology: Development and function of the nervous system, visual processing, human amnesia, theories of human and animal memory.Immunology: Introduction into the fundamental mechanisms of our immunological defence system.

In the module "Integrative Plant Sciences", which consists of the online course and seminar "Plant Response to Stress" (PRESS) and the colloquium "Challenges in Plant Sciences" , the focus lies on interdisciplinarity, ranging from molecular biology and biochemistry to ecosystem research, and an integrated understanding of plants in their environments.

The 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.

Photomorphogenesis during seedling development will be described. The role of different photoreceptors and the underlying molecular mechanisms of their activity during light control will be discussed. Experimental approaches such as mutant screens that have been used successfully to understand this light control will be introduced.

This practical course will use three Arabidopsis lines, wild type and the flu and flu/executer1 mutants to analyze experimentally the control of tetrapyrrole synthesis and the lethal consequences of deregulation of this pathway.