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Scientists found base editing increased fetal hemoglobin production in a new treatment for sickle cell disease and beta-thalassemia.
The study was published in the journal, 'Nature Genetics.' Gene therapy that modifies haemoglobin genes may hold the key to healing sickle cell disease (SCD) and beta thalassemia. Millions of people worldwide suffer from these two frequent life-threatening anaemias. Scientists at St. Jude Children's Research Hospital and the Broad Institute of MIT and Harvard employed adenosine base editing, a next-generation genome editing method, to resume foetal haemoglobin expression in SCD patient cells. The method increased foetal haemoglobin expression to higher, more stable, and more uniform levels than existing genome editing technologies that use the CRISPR/Cas9 nuclease in human hematopoietic stem cells. The findings were reported in Nature Genetics today. SCD and beta thalassemia are blood illnesses that afflict millions of people; these disorders are caused by abnormalities in the gene that encodes an adult version of the oxygen-carrying molecule haemoglobin. Previously, restoring gene expression of an alternative haemoglobin component active in a developing foetus has shown therapeutic effect in patients with SCD and beta thalassemia. The team aimed to discover and improve genomic technologies for editing the foetal haemoglobin gene. Adenosine base editing was particularly effective at restoring foetal haemoglobin expression in post-natal red blood cells. "We showed base editors meaningfully increase fetal hemoglobin levels," said lead corresponding author Jonathan Yen, Ph.D., St. Jude Therapeutic Genome Engineering group director. "Now, my Therapeutic Genome Engineering team is already hard at work, starting to optimize base editing to move this technology to the clinic." Hemoglobin holds the key Adult hemoglobin, expressed primarily after birth, contains four protein subunits -- two beta-globin and two alpha-globin. Mutations in the beta-globin gene cause sickle cell disease and beta-thalassemia. But humans have another hemoglobin subunit gene (gamma-globin), which is expressed during fetal development instead of beta-globin. Gamma-globin combines with alpha-globin to form fetal hemoglobin. Normally around birth, gamma-globin expression is turned off, and beta-globin is turned on, switching from fetal to adult hemoglobin. Genome editing technologies can introduce mutations that turn the gamma-globin gene back on, thereby increasing fetal hemoglobin production, which can effectively substitute for defective adult hemoglobin production. "We used a based editor to create a new TAL1 transcription factor binding site that causes particularly strong induction of fetal hemoglobin," Yen said. "Creating a new transcription factor binding site requires a precise base pair change -- something that can't be done using CRISPR-Cas9 without generating unwanted byproducts and other potential consequences from double-stranded breaks." "The gamma-globin [fetal hemoglobin] gene is a good target for base editing because there are very precise mutations that can reactivate its expression to induce expression after birth, which may provide a powerful 'one-size-fits-all' treatment for all mutations that cause SCD and beta-thalassemia," said co-corresponding author Mitchell Weiss, M.D., Ph.D., St. Jude Department of Hematology chair. Thus, scientists want to restore fetal hemoglobin expression because it is a more universal treatment for major hemoglobin disorders than correcting the SCD mutation or hundreds of mutations that cause beta thalassemia. Increasing fetal hemoglobin expression has the potential to therapeutically benefit most patients with SCD or beta thalassemia, regardless of their causative mutations. Researchers have previously shown proof-of-principle with multiple genome editing approaches, but this study is the first to systematically compare these different strategies' efficacy. "We looked closely at the individual DNA sequence outcomes of nucleases and base editors used to make therapeutic edits of fetal hemoglobin genes. Since nucleases often generate complex, uncontrolled mixtures of many different DNA sequence outcomes, we characterized how each nuclease-edited sequence affects fetal hemoglobin expression. Then we did the same for base editing outcomes, which were much more homogeneous," said co-corresponding author David Liu, Ph.D., Richard Merkin, Professor at Broad Institute of MIT and Harvard, whose lab invented base editing in 2016. The study discovered that using base editing at the most potent site in the gamma-globin promoter achieved 2- to 4-fold greater HbF levels than Cas9 editing. They further demonstrated that these base edits could be retained in engrafting blood stem cells from healthy donors and SCD patients by putting them into immunocompromised mice. Addressing safety concerns "Ultimately, we showed that not all genetic approaches are equal," Yen said. "Base editors may be able to create more potent and precise edits than other technologies. But we must do more safety testing and optimization." When compared for safety, base editing caused fewer genotoxic events, such as p53 activation and large deletions. Base editing was much more consistent in its edits and products -- a highly desirable safety property for a clinical therapy. In contrast to conventional Cas9, which generates uncontrolled mixtures of insertion and deletion mutations termed "indels," base editing generates precise nucleotide changes with few undesired byproducts. "In our comparison, we found unanticipated problems with conventional Cas9 nucleases," Weiss said. "We were somewhat surprised that not every Cas9 insertion or deletion raised fetal hemoglobin to the same extent, indicating the potential for heterogeneous biological outcomes with that technology." The group found that individual red blood cells derived from hematopoietic stem cells treated with the same Cas9 produce a more variable amount of fetal hemoglobin compared to cells treated with base editing. Thus, base editing produced more potent, reliable, and consistent outcomes, which are desirable therapeutic properties. Though base editing performed well, researchers have yet to determine its safety in patients. Notably, base editing may have some risks not presented by Cas9; for example, some early base editors can cause undesired changes in genomic DNA or RNA at off-target sites. The group showed that these changes are relatively small and not predicted to be harmful, but deeper studies are warranted to evaluate these risks fully. (ANI)
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