David Raible Ph.D.

Integrative Analysis

Integrative Analysis
Seth Ament, Ph.D. (co-chair), University of Maryland
Ronna Hertzano, M.D., Ph.D. (co-chair), National Institute on Deafness and Other Communication Disorders
Albert Edge, Ph.D., Mass Eye & Ear
Stefan Heller, Ph.D., Stanford University
David Raible, Ph.D., University of Washington
Jennifer Stone, Ph.D., University of Washington

This group will take the lead on data curation and analysis. A dedicated full-time HRP analyst is working across groups to help collect and process data, thereby facilitating a broader analysis of cell states and trajectories across species. The group will start by annotating hair cell types from all species so that anyone in the field can assess what kind of hair cell their regeneration approaches may produce, while also easing identification of common hair cell genes, which will help the Cross-Species Epigenetics group. Analysis of the hair cells produced in mouse organoids will be performed as an example. The Ament lab will leverage their expertise in bioinformatics, while the Hertzano lab will continue to oversee upkeep of gEAR, with a goal of making it even easier for HRP members to post their new data and for others in the community to analyze those data. The Edge lab will take the lead on the development of organoids as a screening platform for the future. The Heller, Hertzano, Raible, and Stone labs will validate markers by in situ hybridization across species, and all working group members will help direct the analysis.

Epigenetics of the Mouse Inner Ear

Epigenetics of the mouse inner ear
Michael Lovett, Ph.D., Imperial College London
David Raible, Ph.D., University of Washington
Neil Segil, Ph.D., University of Southern California
Jennifer Stone, Ph.D., University of Washington

Inner ear supporting cells from newborn mice harbor a latent capacity for some regenerative responses, but these disappear within the first few weeks of life. This observation provides an experimental window this proposal will exploit to address fundamental questions about the failure of hair cell regeneration in mammals. Specifically, we propose experiments to identify those changes in the genetic material, the chromatin, that are responsible for orchestrating the differentiation of new hair cells within the perinatal organ of Corti; and investigating the changes in the chromatin, the epigenome, that lead to the failure of regeneration in the adult inner ear.

Fish CRISPR/Cas9 Screen, Enhancer screen

Fish CRISPR/Cas9 screen, enhancer screen
David Raible, Ph.D. University of Washington

The functional testing of candidate genes is essential for us to be able to wade through the dozens or hundreds of candidates that have been put forward from the Lovett-Warchol RNA-seq experiments. Raible has successfully developed a zebrafish CRISPR screen approach that allows for the rapid testing of candidate genes for their role in hair cell development and regeneration. Raible will continue in his characterization of genes that affect hair cell regeneration. In addition, the project includes a second aim that proposes to test candidate enhancers in the zebrafish.

Epigenetics of Mouse Inner Ear Maturation and Transdifferentiation

Epigenetics of mouse inner ear maturation and transdifferentiation
Neil Segil, Ph.D. University of Southern California
Jennifer Stone, Ph.D. University of Washington
Michael Lovett, Ph.D. Imperial College London
David Raible, Ph.D. University of Washington

Many genes are turned off by chemical modifications (epigenetic marks) that prevent activation of the gene. One hypothesis is that mammals cannot activate a hair cell regeneration program after the first few postnatal days because the responsible genes have been epigenetically silenced. This second-year project looks at these epigenetic marks in the ear for every gene, during both early and late development. The investigators will use this analysis to find candidate promoter regions, which control gene activity. Preliminary data support the idea that supporting cells turn off expression of key hair cell genes (e.g., Atoh1), and so a plausible approach to triggering regeneration in the mammalian ear is to reverse such changes.

An Epigenetic Framework for Regulating HC Regeneration

An epigenetic framework for regulating HC regeneration
David Raible, Ph.D. University of Washington
Neil Segil, Ph.D. University of Southern California
Jennifer S. Stone, Ph.D. University of Washington

Many genes are turned off by chemical modifications (epigenetic marks) that prevent activation of the gene. One hypothesis is that mammals cannot activate a hair cell regeneration program after the first few postnatal days because the responsible genes have been epigenetically silenced. This project uses HRP data that looks at these epigenetic marks in the ear for every gene, both during early and late development. The investigators will use this analysis to find candidate promoter regions, which control gene activity. Candidate genetic sequences from the mouse experiments will then be tested in zebrafish. These experiments will allow us to better understand how key hair cell regeneration genes are controlled.

A Cross-Species Approach Toward Functional Testing for Hair Cell Regeneration

A cross-species approach toward functional testing for hair cell regeneration
Andy Groves, Ph.D. Baylor College of Medicine
David Raible, Ph.D. University of Washington
Jennifer S. Stone, Ph.D. University of Washington

This multi-modal, cross-species analysis project allows the HRP to test the role of molecules identified in our previous and ongoing experiments. Experience gained in the first year has led to first screening pathway inhibitors in chicks, then validating these initial hits by generating gene knockouts in zebrafish using CRISPR technology. Targets that pass both screens will then be assessed in the mouse. This project exemplifies the consortium’s shift toward Phase II of the HRP’s strategic research plan.

A Cross-Species Approach to Functional Testing of Hair Cell Regeneration Pathways

A cross-species approach to functional testing of hair cell regeneration pathways
David Raible, Ph.D. University of Washington
Andy Groves, Ph.D. Baylor College of Medicine
Jennifer S. Stone, Ph.D. University of Washington

This group has developed a multi-modal, cross-species analysis platform that will allow the HRP to test the role of molecules identified in our previous and ongoing experiments. Coupling gene knockout in zebrafish using the newly emerging CRISPR technology, which allows rapid testing, with pathway manipulation and gene knockouts in chicks and mice, we will be able to rapidly interrogate the many molecules the group wishes to examine. This project exemplifies the consortium’s shift towards phase II of the project.