Description of content
Regulation of gene expression is pivotal for the understanding of developmental programs, cellular homeostasis and many disease states including cancer, immune diseases and metabolic disorders. The gene transcription process is critically linked to regulation of chromatin. Epigenetic mechanisms such as histone modifications can transmit active/inactive states of a gene through cellular divisions. The study of transcription and chromatin regulation has received a great impetus through the availability of whole genome sequences, which sparked novel applications of high-throughput sequencing technologies. Integration of biochemistry, molecular biology, genomics, proteomics and cell biology approaches can now provide unprecedented insight into transcription and chromatin regulation in health and disease.
This course will teach the crucial concepts of regulation of gene expression, with a focus on the process of transcription at the molecular level, but also including concepts derived from cellular, developmental and disease states. Epigenetics, chromatin and genome organization will be taught, as well as state-of-the-art strategies and techniques in the field of gene regulation and genome research, all with a reference to human disease.
The covered topics are: nuclear organization, genome/gene organization, the pol II transcription machinery, chromatin regulation, epigenetics, regulation through small and long non-coding RNAs. Many techniques will be explained, including classical assays used to investigate transcription, as well as high-throughput genomic approaches and systems biology analyses. When you are only superficially interested in mechanisms of gene expression/epigenetics, this course is not suitable for you.
The course consists of a combination of lectures, exercises, literature and discussions and closes with a written exam. A large part is taught by leading (inter)national scientists (9-11 different instructors in total). The course is ideal to become acquainted with top labs working in gene expression control. The course is intense and challenging and requires full attention throughout the full duration. Although many basic molecular principles will be reintroduced, the course is only suited for students with a basic molecular understanding of gene expression and chromatin through bachelor programs such as Biomolecular Sciences taught from textbooks like Molecular Biology of the Cell (“Alberts”) or Genes (“Lewin”). In previous years this course was rated very highly (8.2-8.7).
Registration
You can register for this course via
Osiris Student. More information about the registration procedure can be found
here on the Studyguide.
The maximum number of participants is 40.
Literature/study material used
Research papers, handed out during the course
Mandatory for students in Master’s programme
N.A.
Optional for students in other GSLS Master’s programme:
Yes
Prerequisite knowledge:
Students must have a basic molecular understanding of gene expression and chromatin through bachelor programs such as Biomolecular Sciences taught from textbooks like Molecular Biology of the Cell (“Alberts”) or Genes (“Lewin”).