About 20,000 people in the U.S. live with hemophilia A. It’s a rare X-linked genetic disorder that affects predominantly males and causes their blood to clot poorly when healing wounds. For some, routine daily activities can turn into painful medical emergencies to stop internal bleeding, all because of changes in a single gene that disables an essential clotting protein.

Now, results of an early-stage clinical trial, published recently in the New England Journal of Medicine, demonstrate that gene therapy is within reach to produce the essential clotting factor in people with hemophilia A. The results show that, in most of the 18 adult participants, a refined gene therapy strategy produced lasting expression of factor VIII (FVIII), the missing clotting factor in hemophilia A [1]. In fact, gene therapy helped most participants reduce—or, in some cases, completely eliminate—bleeding events.

Currently, the most-common treatment option for males with hemophilia A is intravenous infusion of FVIII concentrate. Though infused FVIII becomes immediately available in the bloodstream, these treatments aren’t a cure and must be repeated, often weekly or every other day, to prevent or control bleeding.

Gene therapy, however, represents a possible cure for hemophilia A. Earlier clinical trials reported some success using benign adeno-associated viruses (AAVs) as the vector to deliver the therapeutic FVIII gene to cells in the liver, where the clotting protein is made. But after a year, those trial participants had a marked decline in FVIII expression. Follow-up studies then found that the decline continued over time, thought to be at least in part because of an immune response to the AAV vector.

In the new study, an NIH-funded team led by Lindsey George and Katherine High of the Children’s Hospital of Philadelphia and the University of Pennsylvania, tested their refined delivery system. High is also currently with Asklepios BioPharmaceutical, Inc., Chapel Hill, NC. (Back in the 1970s, she and I were medical students in the same class at the University of North Carolina.) The study was also supported by Spark Therapeutics, Philadelphia.

Trial participants received a single infusion of the novel recombinant AAV-based gene therapy called SPK-8011. It is specifically designed to produce FVIII expression in the liver. In this phase 1/2 clinical trial, which evaluates the safety and initial efficacy of a treatment, participants received one of four different doses of SPK-8011. Most also received steroids to prevent or treat the presumed counterproductive immune response to the therapy.

The researchers followed participants for a year after the experimental treatment, and all enrolled in a follow-up trial for continued observation. During this time, researchers detected no major safety concerns, though several patients had increases in blood levels of a liver enzyme.

The great news is all participants produced the missing FVIII after gene therapy. Twelve of the 16 participants were followed for more than two years and had no apparent decrease in clotting factor activity. This is especially noteworthy because it offers the first demonstration of multiyear stable and durable FVIII expression in individuals with hemophilia A following gene transfer.

Even more encouraging, the men in the trial had more than a 92 percent reduction in bleeding episodes on average. Before treatment, most of the men had 8.5 bleeding episodes per year. After treatment, those events dropped to an average of less than one per year. However, two study participants lost FVIII expression within a year of treatment, presumably due to an immune response to the therapeutic AAV. This finding shows that, while steroids help, they don’t always prevent loss of a therapeutic gene’s expression.

Overall, the findings suggest that AAV-based gene therapy can lead to the durable production of FVIII over several years and significantly reduce bleeding events. The researchers are now exploring possibly more effective ways to control the immune response to AAV in expansion of this phase 1/2 investigation before pursuing a larger phase 3 trial. They’re continuing to monitor participants closely to establish safety and efficacy in the months and years to come.

On a related note, the recently announced Bespoke Gene Therapy Consortium (BGTC), a partnership between NIH and industry, will expand the refined gene therapy approach demonstrated here to more rare and ultrarare diseases. That should make these latest findings extremely encouraging news for the millions of people born with other rare genetic conditions caused by known alterations to a single gene.

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