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Genetic approaches to skin regeneration in zebrafish

斑马鱼皮肤再生的遗传方法

基本信息

批准号：
10559624
负责人：
David Andrew Brown
金额：
$ 16.56万
依托单位：
DUKE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2020
资助国家：
美国
起止时间：
2020-03-01 至 2025-02-28
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10559624
关键词：
Award Basal Cell Behavior Biological Assay Biomedical Engineering Cell Cycle Progression Cells Chromatin Complex Data Defect Development Development Plans Developmental Biology Doctor of Medicine Doctor of Philosophy Educational Status Elements Epidermis Epithelium Equilibrium Event Evolution Exhibits Faculty Future Gene Expression Gene Transfer Techniques Genes Genetic Genetic Enhancer Element Genetic Transcription Genomics Goals Heart Human Image Imaging technology Individual Innovative Therapy K-Series Research Career Programs Laboratories Learning Link Mammals Maps Mediating Mentorship Modeling Molecular Morphology Natural regeneration Nucleic Acid Regulatory Sequences Optics Organism Pathway interactions Pattern Phylogenetic Analysis Plastic Surgeon Positioning Attribute Process Proliferating Regulation Regulatory Element Research Research Personnel Resolution Role Scientist Shapes Signal Transduction Site Skin Skin injury Spinal Cord Structure Surgeon Techniques Testing Tissue Engineering Tissue Model Tissues Training Transcriptional Regulation Transgenic Organisms Universities Work Wound models Zebrafish appendage career career development chronic wound design epidermal stem cell epithelial wound epithelium regeneration experimental study genetic approach genetic manipulation genetic technology improved in vivo in vivo imaging insight keratinocyte member migration neonatal mice novel novel strategies prevent programs quantitative imaging regenerative regenerative approach regenerative biology regenerative therapy skin regeneration skin wound tissue regeneration tissue repair tool transcriptome sequencing wound wound bed wound healing

项目摘要

PROJECT SUMMARY/ABSTRACT The proposed career development award is designed to support the transition of David A. Brown, M.D., Ph.D., to an independent investigator in the field of wound healing. Dr. Brown is a plastic and reconstructive surgeon at Duke University with a Ph.D. in tissue engineering. His long-term career goal is to utilize principles of bioengineering and regeneration biology to develop novel regenerative therapies for chronic wounds. Advanced training in regeneration biology is proposed, comprised of laboratory work under the mentorship of Kenneth Poss, Ph.D., a leader in the field of zebrafish models for tissue regeneration, as well as structured activities, coursework, and mentorship from faculty in related fields. The project will focus on re- epithelialization, which is mediated by migration of basal epidermal keratinocytes and stands as a central process in wound healing required to prevent progression to chronic wounds. Zebrafish harbor an innate ability to re-epithelialize wounds and regenerate skin more rapidly and completely than mammals, although the underlying mechanisms of this ability remain unclear. Based on prior work that demonstrates the existence of tissue regeneration enhancer elements (TREEs) involved in zebrafish heart and appendage regeneration, the central hypothesis of this project is that re-epithelialization is governed by regeneration-linked regulatory elements that orchestrate coordinated basal keratinocyte behaviors and gene expression. This proposal represents a novel approach to wound healing research and will provide the candidate with high-level training in live imaging, transgenesis, and genomics that will supplement his background in tissue engineering. In Aim 1, live clonal analysis and transgenic zebrafish lines will be used to map dynamic basal keratinocytes behaviors in re-epithelialization. Experiments will track cell fate decisions and morphologic changes during re- epithelialization and identify subpopulations of basal cells and their relative contributions to the neoepidermis. A quantitative imaging practical course will be pursued along with mentorship from experts in wound healing and live imaging. In Aim 2, the candidate will determine the role of the 103runx1 TREE in basal keratinocyte fate decisions, then use transcriptome sequencing, chromatin profiling, and transgenic assays to identify other key cis-acting regulatory sequences involved in skin regeneration. University courses in transcriptional regulation and computational genomics will be completed as well. Altogether, these experiments are expected to link critical cell fate decisions of basal keratinocytes to activation of specific regulatory elements. Future studies will test the hypothesis that genetic manipulation of these elements can enhance re-epithelialization by promoting basal keratinocyte migration and proliferation, thus leading to improved wound healing. This project will position the candidate to submit an R01 application in the final years of the award period, which will be focused on the next translational step in a mammalian model.

项目摘要/摘要拟议的职业发展奖旨在支持大卫·A·布朗，医学博士，博士，一位伤口愈合领域的独立调查者。布朗医生是一名整形和再造外科医生在杜克大学获得组织工程博士学位。他的长期职业目标是利用生物工程和再生生物学，为慢性伤口开发新的再生疗法。建议进行再生生物学方面的高级培训，包括在 Kenneth Poss博士，斑马鱼组织再生模型领域的领导者，以及结构化相关领域教职员工的活动、课程和指导。该项目将专注于重新- 上皮化是由基底表皮角质形成细胞的迁移所介导的，是一个中心伤口愈合过程中需要防止进展为慢性伤口。斑马鱼具有与生俱来的能力比哺乳动物更快、更彻底地将伤口上皮化和皮肤再生，尽管这种能力的潜在机制仍不清楚。基于之前的工作，证明了组织再生促进因子(树)参与斑马鱼心脏和附件的再生，这个项目的中心假设是，再上皮化是由再生相关的调节机制控制的。协调基本角质形成细胞行为和基因表达的元件。这项建议代表了伤口愈合研究的一种新方法，并将为应聘者提供高级培训在活体成像、转基因和基因组学方面，这将补充他在组织工程方面的背景。在AIM 1、活克隆分析和转基因斑马鱼品系将被用来定位动态的基底角质形成细胞。再上皮化过程中的行为。实验将跟踪细胞命运的决定和重新启动过程中的形态变化上皮化并鉴定基底细胞亚群及其对新生表皮的相对贡献。将在伤口愈合专家的指导下进行定量成像实践课程。和实况影像。在目标2中，候选人将确定103runx1树在基底角质形成细胞中的作用命运决定，然后使用转录组测序、染色质图谱和转基因分析来鉴定其他参与皮肤再生的关键顺式作用调控序列。转录方面的大学课程监管和计算基因组学也将完成。总之，这些实验是可以预料到的。将基底角质形成细胞的关键细胞命运决定与特定调控元件的激活联系起来。未来研究将验证这样的假设，即这些元素的遗传操作可以通过以下方式促进再上皮化促进基底层角质形成细胞迁移和增殖，从而促进伤口愈合。这个项目将安排候选人在获奖期的最后几年提交R01申请，这将是专注于哺乳动物模型的下一步翻译。