Coronavirus information for participants
The onsite course and conference programme at EMBL has been paused until the end of June 2020.
We aim to continue offering our advanced training for the scientific community however we safely can. While some events have been cancelled, many have been rescheduled for a later date and others will be delivered as virtual events.
Registration is open for onsite courses and conferences starting after 1 July and for the virtual events. All registration fees for any events which don’t take place due to the COVID-19 disruption are fully refundable.
More information for participants of events at EMBL Heidelberg can be found here.
Genomic and proteomic approaches have enabled breakthrough advances in the understanding of chromatin biology. This course attempts to integrate these omics approaches to understand the principle of chromatin operation and its biological relevance. Using a murine embryonic stem cells as a tractable model system, this course aims to analyse the composition and variation of chromatin components using antibody and small molecule tools, and the “epigenetic landscape” at key time points following the induction of cellular differentiation.
During the 5 days of the course we will teach how murine stem cells can be differentiated into neuronal progenitors, how specific antibodies and small molecule drugs can be used to enrich for chromatin loci by ChIP- and Chem-seq approaches and how Mass Spectrometry and Next Generation Sequencing read-outs can be used to identify proteins and DNA associated with transcriptionally active chromatin. Combined with the experimental part, a series of lectures given by academic and industry experts in the field will expand the topic of chromatin players and the use of small molecule probes to understand chromatin biology.
This course is aimed at PhD students and post-doctoral researchers who seek to assess chromatin reorganization and/or are working in the field of neuronal development.
Culture and neuronal differentiation of murine stem cells
Chromatin sample preparation for genomic and proteomic analysis by means of antibodies and small molecules
Meta-analysis of post sequencing data
Integration of MS proteomic data
After this course participants should be able to:
Cultivate and differentiate neuronal murine stem cells
Prepare chromatin samples for genomic and proteomic analysis
Analysis genomic and proteomic data