Researchers develop 'in vivo' RNA-based gene editing model for blood disorders

"Right now, if you want to treat hematologic diseases like sickle cell disease and beta thalassemia with gene therapy, patients must receive conditioning treatments like chemotherapy to make space for the new, corrected blood cells, which is both expensive and comes with risks," said co-senior author Stefano Rivella, PhD, Kwame Ohene-Frempong Chair on Sickle Cell Anemia and Professor of Pediatrics at Children's Hospital of Philadelphia. "In our paper, we have shown that it is possible to replace diseased blood cells with corrected ones directly within the body in a 'one-and-done' therapy, eliminating the need for myeloablative conditioning treatments and streamlining the delivery of these potentially life-changing treatments. This is a big step forward in how we think about treating genetic diseases and could expand the access of gene therapies to patients who need them most."

"Targeted delivery of mRNA-encoded therapeutics to specific tissues and cell types will have an immense impact on the way diseases will be treated with nucleic acids in the future," said senior author Hamideh Parhiz, PharmD, PhD, a research assistant professor of Infectious Diseases at Penn. "In our study, we are providing a cell-specific targeted lipid nanoparticle encapsulating mRNA therapeutics/editors as a platform technology that can be used for in vivo cellular reprogramming in many diseases in need of a precisely targeted gene therapy modality. Here, we combined the targeted platform with advances in mRNA therapeutics and RNA-based genomic editing tools to provide a new way of controlling hematopoietic stem cell fate and correcting genetic defects. A targeted mRNA-encoded genomic editing methodology could lead to controlled expression, high editing efficacy, and potentially safer in vivo genomic modification compared to currently available technologies."

Hematopoietic stem cells (HSCs) reside in the bone marrow, where they divide throughout life to produce all cells within the blood and immune system. In patients with non-malignant hematopoietic disorders like sickle cell disease and immunodeficiency disorders, these blood cells don't function correctly because they carry a genetic mutation.

For these patients, there are currently two avenues for potentially curative treatments, both of which involve a bone marrow transplant: a stem cell transplant with HSCs from a healthy donor, or gene therapy in which the patient's own HSCs are modified outside of the body and transplanted back in (often referred to as ex vivo gene therapy). The former approach comes with the risk of graft versus host disease, given that the HSCs come from a donor, and both processes involve a conditioning regimen of chemotherapy or radiation to eliminate the patient's diseased HSCs and prepare them to receive the new cells. These conditioning procedures come with significant toxic side effects, underscoring the need to investigate less-toxic approaches.

One option that would eliminate the need for the above methods would be in vivo gene editing, in which gene editing tools are infused directly into the patient, allowing HSCs to be edited and corrected without the need for conditioning regimens.

To validate this approach, a research team led by Laura Breda, PhD, and Michael P. Triebwasser, MD, PhD at CHOP (presently at the University of Michigan), Tyler E. Papp, BS at Penn, and Drew Weissman, MD, PhD, the Roberts Family Professor in Vaccine Research, the director of the Penn Institute for RNA Innovation, and a pioneer of mRNA-vaccine research, used liquid nanoparticle (LNP) to deliver mRNA gene editing tools. LNP are highly effective at packaging and delivering mRNA to cells and became widely utilized in 2020, due to the LNP-mRNA platform for two leading COVID-19 vaccines.

However, in the case of the COVID-19 vaccines, the LNP-mRNA construct did not target specific cells or organs within the body. Given that the researchers wanted to target HSCs specifically, they decorated the surface of their experimental LNPs with antibodies that would recognize CD117, a receptor on the surface of HSCs. They then pursued three approaches to test the efficacy of their CD117/LNP formulation.

First, the researchers tested CD117/LNP encapsulating reporter mRNA to show successful in vivo mRNA expression and gene editing.

Next, the researchers investigated whether this approach could be used as a therapy for hematologic disease. They tested CD117/LNP encapsulating mRNA encoding a cas9 gene editor targeting the mutation that causes sickle cell disease. This type of gene editing converts the disease-causing hemoglobin mutation into a non-disease-causing variant. Testing their construct on cells from donors with sickle cell disease, the researchers showed that CD117/LNP facilitated efficient base editing in vitro, leading to a corresponding increase in functional hemoglobin of up to 91.7%. They also demonstrated a nearly complete absence of sickled cells, the crescent-shaped blood cells that cause the symptoms of the disease.

Finally, the researchers explored whether LNPs could be used for in vivo conditioning, which would allow bone marrow to be depleted without chemotherapy or radiation. To do so, they used CD117/LNP encapsulating mRNA for PUMA, a protein that promotes cell death. In a series of in vitro, ex vivo, and in vivo experiments, the researchers showed that in vivo targeting with CD117/LNP-PUMA effectively depleted HSC, allowing for successful infusion and uptake of new bone marrow cells, a process known as engraftment, without need of chemotherapy or radiation. The engraftment rates observed in animal models were consistent with those reported to be sufficient for the cure of severe combined immunodeficiency (SCID) using healthy donor bone marrow cells, suggesting this technique could be used for severe immunodeficiences.

"These findings may potentially transform gene therapy, not only by allowing cell-type specific gene modification in vivowith minimal risk, which could allow for previously impossibly manipulations of blood stem cell physiology but also by providing a platform that, if properly tuned, can correct many different monogenic disorders," said Dr. Breda, a research assistant professor with the Division of Hematology at Children's Hospital of Philadelphia. "Such novel delivery systems may help translate the promise of decades of concerted genetic and biomedical research to ablate a wide array of human diseases."

This research was supported by the National Institutes of Health (NIH grants 5T32HL007150 and 5T32HL007622), The Thomas B. and Jeannette E. Laws McCabe Fund at the University of Pennsylvania, and W.W. Smith Charitable Trust Fund.