Epigenetic regulation of human cardiac differentiation
Grant Award Details
Grant Type:
Grant Number:
RB4-05901
Investigator(s):
Disease Focus:
Human Stem Cell Use:
Award Value:
$1,568,148
Status:
Closed
Progress Reports
Reporting Period:
Year 1
Reporting Period:
Year 2
Reporting Period:
Year 3
Grant Application Details
Application Title:
Epigenetic regulation of human cardiac differentiation
Public Abstract:
Each cell type in our body has its own identity. This identity allows a heart cell to contract repetitively, and a brain cell to conduct nerve impulses. Each cell type gains its identity by turning on or off thousands of genes that together give the cell its identity. Understanding how these sets of genes are regulated together as a cell gains its identity is important to be able to generate new cells in disease. For example, after a heart attack, heart muscle dies, leaving scar tissue and a poorly functioning heart. It would be very useful to be able to make new heart muscle by introducing the right set of instructions into other cells in the heart, and turn them into new heart muscle cells. One way that many genes are turned on or off together is by a cellular mechanism called epigenetic regulation. This global regulation coordinates thousands of genes. We plan to understand the epigenetic regulatory mechanisms that give a human heart muscle cell its identity. Understanding their epigenetic blueprint of cardiac muscle cells will help develop strategies for cardiac regeneration, and for a deeper understanding of how cells in our body acquire their individual identities and function.
Statement of Benefit to California:
This research will benefit the state of California and its citizens by helping develop new approaches to cardiac regeneration that will be more efficient than current approaches, and amenable to drug-based approaches. In addition, the knowledge acquired in these studies will be important not only for heart disease, but for any other disease where reprogramming to regenerate new cells is desirable. The mechanisms revealed by this research will also lead to new understanding of the basis for congenital heart defects, which affect several thousand Californian children every year, and for which we understand very little.