Cardiac Allograft Vasculopathy Clinical Trial
Official title:
Pure-Heart-1: A P2X7R Single Nucleotide Mutation Promotes Chronic Allograft Vasculopathy
Heart transplantation (HT) is a lifesaving procedure for patients with end-stage heart failure and provides a better survival and quality of life if compared to medical treatment. HT is subject to alloimmune response, which, if left uncontrolled, is capable of jeopardizing long-term cardiac function. Advances in immunosuppression have enhanced the survival of HT patients. Nearly 2500 HT per year have been performed in the US during the last 10 years and despite significant improvements, long-term survival rates remain poor. More than 20% of patients do not survive more than 3 years, and those who survive are afflicted by long-term complications of alloimmunity and chronic immunosuppression. Life expectancy of patients who lose cardiac allografts is dramatically poor due to the absence of any therapeutic tool apart from re-transplantation, which is plagued by poor outcomes. The identification of novel therapeutic targets is thus mandatory. ATP/P2X7R signaling in T cells is highly relevant for cardiac allograft survival. ATP is a small molecule present at high concentrations inside cells; it is released as extracellular ATP (eATP) following cell damage or death where it acts as a danger signal. ATP is sensed by the P2X receptors (seven receptors named P2X1-7), mainly expressed by T lymphocytes. We have recently demonstrated that the ATP/P2X7R axis has a key role in cardiac allograft survival in humans and mice. Cardiac allograft vasculopathy (CAV) is a major limiting factor for HT survival; indeed CAV occurs in 50% of HT recipients by 5 years after transplantation and invariably results in allograft failure. CAV is clearly of immunological origin, as syngeneic murine grafts do not develop it. Once CAV occurs, the most definitive treatment is re-transplantation, but survival remains poor. We hypothesize that a single nucleotide polymorphysm (SNP) loss-of-function P2X7R mutation (p.Glu496Ala / c.1513A>C, rs3751143) generates a compensatory upregulation of the other purinergic receptors (P2XsR), thus creating a state of hypersensitivity to eATP. This eATP hypersensitivity results in an abnormal generation of Th1/Th17 cells, that leads to CAV and early cardiac allograft loss. Our study will answer a fundamental question: What is the effect of the P2X7R loss-of-function mutation on the immune system? Our goal is to generate the first targeted-therapy for a selected group of cardiac transplant recipients.
Heart transplantation is a lifesaving procedure however, more then 20% of patients do not survive beyond 3 years, being the cardiac allograft afflicted by cardiac allograft vasculopathy (CAV), which results in allograft loss. The purine adenosine 5'-triphosphate (ATP), released during cell damage/inflammation, is sensed by the ionotropic purinergic P2X7 receptor (P2X7R), which is expressed primarily, though not exclusively, on lymphocytes, thus regulating T cell activation. Loss-of-function single nucleotide mutations (SNPs) have been detected for P2X7R gene; particularly the Glu496 to Ala 1513A>C (rs3751143) P2X7R loss-of-function mutation is relatively common (1-3% of individuals are mutated omozygous and 25% are heterozygous). Our central hypothesis is that a loss-of-function P2X7R mutation identifies a group of cardiac transplanted patients at high risk for CAV and cardiac allograft loss because of a compensatory overexpression of P2X1R/P2X4R, which induces a disregulation of T-bet/ROR-g, ultimately leading to the abnormal generation of Th1/Th17 cells. Our primary goal is to define the effect of the P2X7R loss-of-function mutation on clinical end points in the CTOT-05 cohort of cardiac transplant recipients (200 patients) and to explore the effects of the mutation on the immune system. Our preliminary data demonstrated that P2X7R increases during cardiac transplant rejection in vivo in mice and in humans and it is activated by ATP released by cardiac cells, thus triggering activation of Th1/Th17 cells. However, while short-term disruption of the P2X7R pathway prolongs cardiac allograft survival, the genetic deletion of P2X7R accelerates CAV and shortens cardiac allograft survival. This was evident in P2X7R KO-B6 mice and in a group of cardiac transplant recipients bearing the P2X7R loss-of-function mutation. Based on our published results and our novel observations, we have developed the following working hypothesis: P2X7R loss-of-function mutation generates a compensatory overexpression of the other ionotropic purinergic receptors (P2X1/P2X4) with chronic delivery of ATP immunity, hyperactivation T-bet/ROR-g, abnormal generation of Th1/Th17 cells and ultimately leading to accelerated CAV and to cardiac allograft loss. To test this hypothesis, we will follow two main paths: i) we will evaluate in the CTOT-05 cohort of cardiac transplant recipients the effect of the Glu496 to Ala 1513A>C (rs3751143) P2X7R loss-of-function mutation on clinical end points (development of coronary artery vasculopathy, death, re-transplantation or re-listed for transplantation, any rejection) in the first year post transplant; ii) we will explore in vivo and ex vivo in the CTOT-05 cohort of cardiac transplant recipients the effects of P2X7R loss-of-function mutation on the immune system. ;
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