The Role of SoxE Transcription Factors in Neural Crest Cell Specialization

Project Summary/Abstract Neurocristopathies are a class of syndromes that are predominately characterized by malformations in the craniofacial complex. These defects are caused by aberrant development of the neural crest, a stem cell population unique to vertebrates. One distinctive feature of the neural crest is their ability to give rise to both

ectomesenchymal (bone/cartilage) and non-ectomesenchymal (melanocytes and peripheral neurons/glia) derivatives. SoxE transcription factors play important roles in both the formation and the diversification of the neural crest. All three SoxE factors (Sox8, Sox9, and Sox10) function redundantly to promote neural crest

formation. Interestingly, individual SoxE factors direct the differentiation of the neural crest into distinct lineages. Sox9 promotes chondrogenesis while Sox10 supports both the melanocyte and peripheral neuron/glial fates. An outstanding question is how these highly similar SoxE factors lead to neural crest specialization. This proposal

utilizes omics-based approaches, gain and loss of function experiments, and Sox9-Sox10 chimera constructs to assess how and when SoxE-mediated neural crest specialization occurs. Furthermore, mutations in SOX9 and SOX10 are causative for Campomelic dysplasia and Waardenburg syndrome, respectively. The syndromes

present with very different craniofacial phenotypes which are reflective of SOX9/SOX10 specific defects during

neural crest specialization. Work from this study will lead to the identification of novel SoxE transcriptional targets, determine when SoxE factors begin to promote neural crest specialization, and determine how specific patient variants for Campomelic dysplasia/Waardenburg syndrome cause disease phenotypes. Overall, this work is of

high clinical significance and will provide evolutionary insights into the molecular origins of neural crest diversification. My primary goal for the mentored phase of this proposal is to identify when SoxE factors begin to promote lineage specialization within the neural crest and determine the functional domains that contribute to

SoxE family subfunctionalization. I plan to use my remaining time as a postdoctoral fellow to master new experimental techniques and develop robust computational analyses. I will capitalize on the rich academic environment of Northwestern University, especially the expertise in NSF-Simons Center for Quantitative Biology.

My long-term career goal is to establish an independent research program that uses multiple model systems to investigate the cellular and molecular origins of syndromes characterized by craniofacial phenotypes. I plan to use Sox transcription factors (and associated syndromes) as a starting point in my career, but then extend my

research interests to other gene families through collaboration with clinicians. My measurable experience with various model organisms will allow me to investigate biochemical, molecular, cellular, and morphological aspects of developmental disorders by exploiting the benefits of each model system.