CardioSource WorldNews | Page 31

GATAATCTACACGAGCAGAATCATCAAAGCAAGATTACGCUREATCTACGACGCATCGACTACAGCAT CGCTACAGCTACGACTAGATAATCTAAGCAGAATCATCAAAGCAAGATTAGACGCATTACGAGCATC GCATCGACTACAGCATCGCTACAGCTACGACTAGATAATCTACACGAGCAGAATCATCAAAGCAAGATTA would restore SERCA2a enzyme production in the cardiomyocytes, which would then power the SR, improving contraction and relaxation of remaining cardiomyocytes. In preclinical models of HF, increasing the expression of SERCA2a in cardiomyocytes by gene transfer restored normal calcium cycling and resulted in improved cardiac function and myocardial energetics. The early phase II CUPID trial confirmed SERCA2a as an important target in HF and showed that its pairing with an AAV1 and administration as a one-time antegrade epicardial infusion was both safe in humans with advanced HF and very likely clinically beneficial at the highest dose tested (FIGURE 2).10 Just the fact that a gene therapy for HF made it successfully through a phase II trial was considered “by no means a minor achievement.”11 At this point, stock prices were looking pretty healthy for Celladon… Unfortunately, the phase IIb CUPID 2 trial didn’t go so well. The trial enrolled 250 patients in 56 clinical sites and randomized them to Mydicar or placebo in equal numbers. All patients were prescreened for the presence of AAV neutralizing antibodies. The novel treatment failed to meet any of its primary or secondary endpoints. Mydicar did not reduce HF hospitalizations, all-cause death, or the need for a mechanical circulatory device or heart transplantation (FIGURE 3). Celladon stock collapsed on the news. When Celladon went public in early 2014, its stock traded at $8/share. The month before the CUPID 2 trial results were released (in April 2015), the stock hit a high of about $28, falling to $13.68 the day before the results were revealed, and then tanking at $2 when the bad news was confirmed. In Nov. 2015, Celladon Corporation and Eiger BioPharmaceuticals, Inc., a privately-held firm, announced that they have entered into a definitive merger agreement. Renova Therapeutics Renova Therapeutics is another hot gene therapy start-up based in San Diego, CA, but of a very different flavor than Celladon and, obviously, hopeful of a different future. The company is supported by a group of high-net-worth individuals and has not taken any venture capital money—as of yet. This nonpublic route is by design, according to Renova CEO, Jack W. Reich, PhD. “When you’ve got individual investors, it’s quite different than venture capital investors who are purely finanJack W. Reich, PhD cial investors,” explained Dr. Reich in an interview with CSWN. “We’re not sort of forced to go public or something like that because we have investors that want to get liquid. Our investors and our management are on the same side of the table.” They have partnered with the National Institutes of Health (NIH) to run both an extensive preclinical ACC.org/CSWN program on their target gene therapy product and to conduct clinical trials through a public-private partnership between the NIH and Renova Therapeutics. Renova’s scientific founder is Kirk H. Hammond, MD, from the University of California San Diego. Dr. Hammond was the first to discover that adenylyl cyclase type 6 (AC6) was downregulated in patients with HF of any etiology and that regulating AC6 could have a positive effect on said patients. AC6 is a protein found in cardiomyocytes that catalyzed conversion of adenosine triphosphate to cyclic AMP (cAMP) and, thus, is a central regulator of calcium cycling. As it happens, AC6 also improves the affinity of SERCA2a for calcium by activating a cAMP-dependent protein kinase of phospholamban, placing it upstream from SERCA2a and possibly explaining its greater efficacy (at least at this point in the development cycle). “[SERCA2a] does not have the effect of normalizing heart function,” said Dr. Reich about SERCA2a. “They thought that it would improve calcium handling, but the results speak for themselves.” He also questioned whether AAV1 was the optimal vector for this therapy, noting that Renova’s adenovirus vector when delivered by catheter directly into the coronary arteries “causes the heart to take up the gene therapy like a sponge.” “You get extraordinarily high yield gene transfer and, as a result, you get extraordinary production of the protein the gene produces and then the effects that we have now demonstrated in the clinic.” RT-100 is designed to upregulate AC6 content and restore heart function. In extensive preclinical study, a single dose improved myocardial function and reversed HF-induced remodeling of the heart. These early results supported the phase II trial conducted at seven U.S. centers and presented by Dr. Hammond during a Clinical Trial Update session at the 2015 European Society of Cardiology meeting in London. In the study, 56 patients with HF with reduced ejection fraction (HFrEF) were randomly assigned to one of six dose groups of RT-100. During the 1-year trial, there were no differences in HF hospitalization or death between groups. AC6 gene transfer was not associated with myocarditis or liver inflammation, or an increase in implantable cardioverter-defibrillator events. In terms of efficacy, RT-100 given at the two highest doses increased EF significantly at 4 weeks, but because of an insignificant but substantial increase in the placebo group at 4 weeks, the between-group difference was not significant at 12 weeks. When the investigators looked at EF change > 5 units, eight of 21 individual 2v