My hosting team identified and characterized the role of 3 Usher proteins in the auditory cortex. They demonstrated that many GABAergic interneurons require for their normal development two cadherin-related (cdhr) proteins, cdhr15 and cdhr23, that form the hair bundle tip links gating the mechanoelectrical transduction channels. Mutant mice lacking either protein showed a major decrease in the number of some inhibitory neurons the auditory cortex, and displayed audiogenic reflex seizures. In addition, in the absence of adhesion G protein-coupled receptor V1 (adgrv1), we observed a similar decrease of inhibitory neurons in the auditory cortex. These results were published in PNAS in July 2017 (Libé-Philippot et al., PNAS. 2017 114(30):7765-7774.).
To continue on this work, during my Marie Curie action I designed and produced new genetic tools that express cre recombinase under the control of the Cdhr23 and Cdhr15 promoters i) to characterize the neuronal populations expressing Cdhr15 or Cdhr23 by fluorescent tracing in the auditory cortex and in the brain, and ii) to manipulate the activity of Cdhr15/Cdhr23-expressing cells. Results from Cdhr23-Cre knock-in mice suggest that several populations of cells throughout the brain express Cdhr23. In addition, we observed many projecting neurons in the auditory cortex that originate from Cdhr23-expressing neurons.
In parallel, I implemented the RNAscope technique in the lab, allowing the detection of mRNA expression for target genes in the brain. Using this technique, I obtained additional results on the role of Cdhr15 showing that Cdhr15 was expressed in some inhibitory neurons and also in a subtype of glial cells involved in the stabilization of cortical interneurons through their myelination.
In parallel, I identified an additional Usher protein in the auditory cortex. This protein is a mechanoelectrical transduction complex protein for which cre knock-in mice was already available. Through RNAscope and high-throughput single-cell transcriptomics, we could confirm that cells expressing this protein in the temporal cortex are excitatory neurons. The analysis of these brains were performed using a new software, NeuroInfo, allowing the mapping of neuroanatomical structures in histological sections. Using this software, I characterized the localization of cells that were expressing this MET complex protein during their development and could show that they are mainly located in different layers of the cortex, with a higher density of cells in layer 4.
The data from the two main objectives of my project are currently being used to write two manuscripts that are in preparation for a future submission process. These data have also been presented in a national and in an international meeting. Some of the data have been used in a presentation to general public.