Abstract

We have demonstrated that human cardiac stem cells (hCSC) derived from end-stage heart failure (ESHF) hearts are markedly superior in improving post-infarct LV function in comparison to age-match control hCSC. The goal of this application is to characterize the molecular mechanisms underlying this improved performance of ESHF-derived hCSC and to optimize their harvest, molecular characterization and application in a clinically-relevant model of post-MI cardiac failure. Improvement of LV function in ESHF patients, particularly children with end- stage heart failure, via stem cell therapy is of enormous importance since heart transplantation is the only other viable option and in limited supply. Despite their encouraging clinical Phase I results, cardiosphere derived cells (CDCs), comprised of heterogeneous cell types, including c- kit+ cells, are still not well characterized1. Our preliminary data shows that ESHF-derived hCDCs isolated from the left atrium improve ischemic left ventricular function better than ESHF-derived hCDCs from the right atrium, but whether different functional activity is present in all other heart chamber-derived hCDCs is still unknown. Furthermore, since we document significantly higher numbers of c-kit+ cells within ESHF-derived CDCs, the frequency of the c-kit+ cells within CDCs may be critical to recovery of function. Finally, ESHF-derived CDCs secrete higher levels of angiogenic cytokines that correlates with increased angiogenesis in the infarcted myocardium and higher levels of HIF-1a, but the mechanism for the increased cytokine secretion is unclear. Our hypothesis is that the effect of ESHF-derived hCDCs in improving myocardial function is dependent on the anatomic site of hCDC origin and molecular mechanisms by c-kit+ and HIF- 1a. These studies will clarify the biology and function of hCDCs by determining: 1) chamber specific differences amongst hCDCs with the potential need to modify for a more powerful myocardial functional activity, 2) the effect of the frequency of c-kit+ cells on LV recovery, and lastly, 3) the role of HIF-1a as a master cytokine regulator of the myocardial function of ESHF- derived hCDCs. ESHF patients, particularly children, are potentially the most to benefit from hCDC based therapies. This application is the first study designed to determine critical characteristics of ESHF-derived hCDCs and to uncover new mechanisms of their functional activity in a manner that may eventually influence future therapeutic interventions.

Public Health Relevance

Heart failure is a common and lethal disease worldwide, affecting nearly 6 million people in the United States. The notion of replacing lost cardiomyocytes through cell-based therapies to attenuate or even reverse deleterious structural consequences of heart failure via remodeling is appealing and holds enormous therapeutic promise. To improve clinical stem cells protocols in the future, we need to better understand the biology of resident cardiac stem cell biology and see how location within the heart, composition of stem cells and physiological states may affect their functional activity.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL118491-03
Application #
9042032
Study Section
Bioengineering, Technology and Surgical Sciences Study Section (BTSS)
Program Officer
Lee, Albert
Project Start
2014-04-20
Project End
2019-03-31
Budget Start
2016-04-01
Budget End
2017-03-31
Support Year
3
Fiscal Year
2016
Total Cost
Indirect Cost

  Institution

Name
University of Maryland Baltimore
Department
Surgery
Type
Schools of Medicine
DUNS #
188435911
City
Baltimore
State
MD
Country
United States
Zip Code
21201

  Publications

Sharma, Sudhish; Mishra, Rachana; Bigham, Grace E et al. (2017) A Deep Proteome Analysis Identifies the Complete Secretome as the Functional Unit of Human Cardiac Progenitor Cells. Circ Res 120:816-834
Bittle, Gregory J; Wehman, Brody; Karathanasis, Sotirios K et al. (2017) Clinical Progress in Cell Therapy for Single Ventricle Congenital Heart Disease. Circ Res 120:1060-1062
Wehman, Brody; Kaushal, Sunjay (2015) The emergence of stem cell therapy for patients with congenital heart disease. Circ Res 116:566-9
Wehman, Brody; Kaushal, Sunjay (2015) Invited Commentary. Ann Thorac Surg 100:1029
Wehman, Brody; Sharma, Sudhish; Mishra, Rachana et al. (2015) Pediatric End-Stage Failing Hearts Demonstrate Increased Cardiac Stem Cells. Ann Thorac Surg 100:615-22
Kaushal, Sunjay; Wehman, Brody (2015) Stem cells on a new stage: Treatment of hypoplastic left heart syndrome. J Thorac Cardiovasc Surg 150:1209-11
Wehman, Brody; Siddiqui, Osama T; Mishra, Rachana et al. (2015) Stem cell therapy for CHD: towards translation. Cardiol Young 25 Suppl 2:58-66
Sharma, Sudhish; Mishra, Rachana; Simpson, David et al. (2015) Cardiosphere-derived cells from pediatric end-stage heart failure patients have enhanced functional activity due to the heat shock response regulating the secretome. Stem Cells 33:1213-29
Simpson, David L; Wehman, Brody; Galat, Yekaterina et al. (2014) Engineering patient-specific valves using stem cells generated from skin biopsy specimens. Ann Thorac Surg 98:947-54
Kaushal, Sunjay; Wehman, Brody (2013) Invited commentary. Ann Thorac Surg 96:1404-1405