Horizons in Molecular Biology 2017: Genetics and epigenetics of adaptation to the environment

Horizons in Molecular Biology 2017

  • Datum: 13.09.2017
  • Uhrzeit: 10:15 - 11:00
  • Vortragende(r): Detlef Weigel
  • Max Planck Institute for Developmental Biology, Germany
  • Ort: Max-Planck-Institut für biophysikalische Chemie (MPIBPC)
  • Raum: Manfred Eigen Hall
  • Gastgeber: Horizons in Molecular Biology
  • Kontakt: participants.horizons@mpibpc.mpg.de
Plenary lecture of the 14th annual Horizons in Molecular Biology International PhD Symposium
My group is addressing fundamental questions in evolutionary biology, using both genome-first and phenotype-first approaches: (i) Where do new genetic variants come from? (ii) Why are some variants maintained for a much longer time than others? (iii) And why are some combinations of variants incompatible with each other?

The background for these questions is our population genomic work in Arabidopsis and the related genus Capsella. In collaboration with our Bergelson, Ecker, Mott, Nordborg, K. Schmid and others, including Monsanto, we have been describing whole-genome variation in wild isolates of A. thaliana (http://1001genomes.org). This has, for example, led to the discovery of a Neanderthal-like group that has apparently survived since the Last Glacial Maximum. A similarly remarkable finding that emerged from the Capsella work with Neuffer, Slotte and Wright is the ubiquity of long-term balancing selection, specifically at immunity loci. On the other end of the spectrum, we are analyzing new DNA mutations and epigenetic variants that have arisen under laboratory conditions or in a natural mutation accumulation experiment. The latter studies, with Bergelson and Burbano, take advantage of an A. thaliana lineage that was apparently introduced to North America in historic times and accounts for about half the population there.

The ultimate goal of our top-down studies is to understand how genetic and epigenetic variation interacts with reassortment of variants after crosses and with natural selection to shape geographic patterns of diversity. One example is our work with Dangl on the evolution of immune receptors, which have evolved to be highly diverse because of pathogen pressure – which in turn can lead to paranoid plants that mount an immune response even though they are not even attacked by pathogens. A final example is our prediction of which A. thaliana populations will and which populations will not be able to adapt to climate change.

Additional information about our work can be found on our website, http://weigelworld.org.

Free registration at www.horizons.uni-goettingen.de
Zur Redakteursansicht