3 min readResearchers Optimize Gene Editing for SCD and Beta Thalassemia
Boston, MA — Researchers at Dana-Farber/Boston Children’s Cancer and Blood Disorders Center and the University of Massachusetts Medical School have developed a strategy to treat two of the most common inherited blood diseases — sickle cell disease and beta thalassemia — applying CRISPR-Cas9 gene editing to patients’ own blood stem cells. Described this week in Nature Medicine and in a January report in the journal Blood, their approach overcomes prior technical challenges, editing blood stem cells more efficiently than in the past.
The two studies show that the gene-edited cells generate genetically corrected red blood cells producing functional hemoglobin.
“We think our work defines a strategy that could lead to the cure of common hemoglobin disorders,” says Dr. Daniel Bauer, an attending physician with Dana-Farber/Boston Children’s and a senior author on both papers. “Combining gene editing with an autologous stem-cell transplant could be a therapy for sickle-cell disease, beta-thalassemia and other blood disorders.”
Together, sickle cell disease and beta-thalassemia affect 332,000 conceptions or births worldwide each year, according to the World Health Organization. Both diseases involve mutations in the gene for beta globin protein. In beta-thalassemia, the mutations prevent red blood cells from producing enough of the oxygen-carrying hemoglobin molecule, leading to anemia. In sickle cell disease, the mutation causes hemoglobin to change shape, distorting red blood cells into stiff “sickle” shapes that block up blood vessels.
The Nature Medicine study used CRISPR-Cas9 technology, in particular a Cas9 protein modified by a team led by Scot Wolfe, PhD at UMass Medical School, to optimize gene editing. In previous attempts to edit the genomes of human blood stem and progenitor cells, the efficiency, specificity and long-term stability of the edits once the cells engraft in the bone marrow have varied. The new technique improves the targeting and durability of the edits.
“Efficient editing of the blood stem cell population — ideally at rates approaching 100 percent — is critical to achieve a durable therapeutic effect for patients,” says Wolfe, a professor in the Department of Molecular, Cell and Cancer Biology at UMass Medical School. “Progress toward this goal has been advancing through the contributions of multiple laboratories in the scientific community. My research team, in collaboration with the Bauer laboratory, focused on improving the efficiency of delivery and nuclear entry of the CRISPR-Cas9 technology to achieve nearly complete therapeutic editing of the entire blood stem cell population.”
Bauer’s team used the strategy to make a highly targeted edit. Previous work at Boston Children’s had showed that inactivating a gene called BCL11A allows red blood cells to keep producing a foetal form of haemoglobin even after birth. Foetal haemoglobin doesn’t sickle and can stand in for defective “adult” haemoglobin. More recently, Bauer found a safer target: a genetic enhancer of BCL11A that is active only in red blood cells.
“With our new very efficient protocol, we can edit the BCL11A enhancer in nearly all blood stem cells we collect, overcoming some of the technical challenges of editing these cells,” says Bauer. “In our experiments, more than 95 percent of copies of the enhancer sequence were changed in a way we expect would be therapeutic.”
The strategy enabled mice carrying blood stem cells from patients with sickle cell disease to produce red blood cells with enough foetal haemoglobin to prevent cell sickling. The team showed that the gene-edited cells, infused back into the bloodstream, engrafted in the bone marrow and produced genetically corrected red blood cells. Later, when blood stem cells were isolated from these mice and transplanted into other mice, the cells engrafted again, still carrying the therapeutic gene changes.
Applied to blood stem cells from patients with beta-thalassemia, the same strategy restored the normal balance of the globin chains that make up haemoglobin.
The other study, published in Blood, used a similar gene editing protocol to target forms of beta-thalassemia that involve splicing mutations — errors in bits of DNA near the beta-globin gene that change how the gene is read out to assemble beta-globin protein. In this study, nine patients with beta thalassemia donated their cells, which were manipulated in a dish. For some patients, the UMass team produced a different enzyme, Cas12a, to more effectively target their mutations. The CRISPR system efficiently made edits and restored normal splicing of the beta-globin protein in blood cells from each of the patients.
The investigators are taking steps to take their BCL11A enhancer editing strategy to the clinic. They are developing a clinical-grade, scaled up protocol for cell product manufacturing, and performing safety studies necessary for regulatory approval from the FDA. They plan to seek funding from the National Heart, Lung and Blood Institute’s Cure Sickle Cell initiative to launch a clinical trial in patients.
Dana-Farber/Boston Children’s has already begun a clinical trial of gene therapy for sickle cell disease. That approach increases foetal haemoglobin production by exposing patients’ blood stem cells to a lentivirus carrying instructions to knock down the BCL11A gene in red-blood-cell precursors.
Bauer believes it’s important to keep pursuing both approaches. “These conditions are very common inherited diseases and occur especially often in parts of the world where resources are quite limited,” he says. “So we need a broad set of therapeutic options to make treatment available to as many patients as possible.”
Article adapted from a Boston Children’s Hospital news release.