Studying Arrhythmogenic Right Ventricular Dysplasia with patient-specific iPS cells

Studying Arrhythmogenic Right Ventricular Dysplasia with patient-specific iPS cells

Funding Type: 
Basic Biology IV
Grant Number: 
RB4-06276
Award Value: 
$1,582,606
Disease Focus: 
Heart Disease
Pediatrics
Stem Cell Use: 
iPS Cell
Cell Line Generation: 
iPS Cell
Status: 
Active
Public Abstract: 
Most heart conditions leading to sudden death or impaired pumping heart functions in the young people (<35 years old) are the results of genetic mutations inherited from parents. It is very difficult to find curative therapy for these inherited heart diseases due to late diagnosis and lack of understanding in how genetic mutations cause these diseases. Using versatile stem cells derived from patients’ skin cells with genetic mutations in cell-cell junctional proteins, we have made a significant breakthrough and successfully modeled one of these inherited heart diseases within a few months in cell cultures. These disease-specific stem cells can give rise to heart cells, which allow us to discover novel abnormalities in heart energy consumption that causes dysfunction and death of these diseased heart cells. Currently, there is no disease-slowing therapy to these inherited heart diseases except implanting a shocking device to prevent sudden death. We propose here to generate more patient-specific stem cell lines in a dish from skin cells of patients with similar clinical presentations but with different mutations. With these new patient-specific stem cell lines, we will be able to understand more about the malfunctioned networks and elucidate common disease-causing mechanisms as well as to develop better and safer therapies for treating these diseases. We will also test our new therapeutic agents in a mouse model for their efficacy and safety before applying to human patients.
Statement of Benefit to California: 
Heart conditions leading to sudden death or impaired pumping functions in the young people (<35 years old) frequently are the results of genetic mutations inherited from parents. Currently, there is no disease-slowing therapy to these diseases. It is difficult to find curative therapy for these diseases due to late diagnosis. Many cell culture and animal models of human inherited heart diseases have been established but with significant limitation in their application to invent novel therapy for human patients. Recent progress in cellular reprogramming of skin cells to patient-specific induced pluripotent stem cells (iPSCs) enables modeling human genetic disorders in cell cultures. We have successfully modeled one of the inherited heart diseases within a few months in cell cultures using iPSCs derived from patients’ skin cells with genetic mutations in cell-cell junctional proteins. Heart cells derived from these disease-specific iPSCs enable us to discover novel disease-causing abnormalities and develop new therapeutic strategies. We plan to generate more iPSCs with the same disease to find common pathogenic pathways, identify new therapeutic strategies and conduct preclinical testing in a mouse model of this disease. Successful accomplishment of proposed research will make California the epicenter of heart disease modeling in vitro, which very likely will lead to human clinical trials and benefit its young citizens who have inherited heart diseases.
Progress Report: 

Year 1

Most heart conditions leading to sudden death or impaired cardiac pumping functions in the young people (<35 years old) are the results of genetic mutations inherited from parents. It is very difficult to find curative therapy for these inherited heart diseases due to late diagnosis and lack of understanding in how genetic mutations cause these diseases. One of these inherited heart diseases is named arrhythmogenic right ventricular dysplasia/cardiomyopathy (ARVD/C). The signature features of sick ARVD/C hearts are progressive heart muscle loss and their replacement by fat and scare tissues, which can lead to lethal irregular heart rhythms and/or heart failure. We have made a significant breakthrough and successfully modeled the sick ARVD/C heart muscles within two months in cell cultures using versatile stem cells derived from ARVD/C patients’ skin cells with genetic mutations in one of the desmosomal (a specific type of cell-cell junctions in hearts) proteins, named plakophilin-2. These disease-specific stem cells can give rise to heart cells, which allow us to discover specific abnormalities in heart energy consumption of ARVD/C heart muscles that causes dysfunction and death of these diseased heart cells. In the Year 1 of this grant support, we have made and characterized additional stem cells lines from ARVD/C patients with different desmosomal mutations. We are in the process to determine if heart muscles derived from these new ARVD/C patient-specific stem cells have common disease-causing mechanisms as we had published. We found two proposed therapeutic agents are ineffective in suppressing ARVD/C disease in culture but we have identified one potential drug that suppressed the loss of ARVD/C heart cells in culture. We also started to establish a known ARVD/C mouse model for future preclinical drug testing.

© 2013 California Institute for Regenerative Medicine