Our field of research is primate brain development and evolution. We are trying to understand the factors underlying neocortical expansion in primates. To address this question in a practical and ethically justifiable way, we use brain organoids as our research model.
Differences in brain development between modern humans, us, and neanderthals have recently emerged. These differences are due to a small number of amino acid changes in proteins with key roles in brain development. Cerebral organoids have been a crucial model system in these studies.
The study of primate development from an evolutionary point of view conducting gain and loss of function studies is important. However, apes including humans naturally cannot be used for such experiments, so genetic modification of organoids plays a vital role in this field. While working as a postdoc in my lab, Michael Heide demonstrated that the human specific gene ARHGAP11B was a key player in increasing brain size during human evolution.
As a group leader at the German Primate Center now, Michael contributed crucial insight by comparing human versus chimpanzee cerebral organoids. Our protocol offers a targeted approach for genetic modifications by specific micro injecting ventricle-like structures instead of commercial electroporation cuvettes. This approach uses a cost efficient setup including square wave electroporator and Petri dish electrode chamber instead of expensive nuclear effector solutions.
While studying function and brain development in primates by genetic modification is technically possible, it is methodologically demanding, expensive, and not allowed for great apes. The electroporation of primate cerebral organoids provides a fast and cost efficient approach to introduce genetic modifications in a model close to primate brain development. In the future, we would like to focus on the characterization of differentially expressed genes in the cortex of different primate species.
We will study these genes by the electroporation of primate cerebral organoids and analyze their potential effects on cortical progenitor cells.
