Graphite Bio Presents Preclinical Gene Replacement Data for GPH102 for Beta-thalassemia at the ASGCT
25th Annual Meeting
Trial-in-progress poster of Phase 1/2 CEDAR trial evaluating GPH101 for sickle cell disease to be presented as an encore
SOUTH SAN FRANCISCO, Calif., May 16, 2022Graphite Bio, Inc. (Nasdaq: GRPH), a clinical-stage, next-generation gene editing company harnessing the power of high-efficiency precision gene repair to develop therapies with the potential to treat or cure serious diseases, today presented preclinical data for GPH102, the companys differentiated gene replacement program for beta-thalassemia, in an oral presentation at the American Society of Gene and Cell Therapy (ASGCT) 25th Annual Meeting. The hybrid meeting is taking place virtually and at the Walter E. Washington Convention Center in Washington, D.C., from May 16-19.
Our gene replacement program for beta-thalassemia is a natural application of our powerful gene editing platform and the result of our own internal discovery efforts. With GPH102, we aim to replace the mutated beta-globin gene with a functional gene. This is the first approach that has the potential to normalize the hundreds of mutations in the beta-globin gene that cause beta-thalassemia and restore adult hemoglobin expression to healthy levels, thereby directly addressing the underlying cause of the disease, said Josh Lehrer, M.D., M.Phil., chief executive officer of Graphite Bio. We believe our gene replacement approach could be the optimal way to treat beta-thalassemia and potentially provide a definitive cure to patients. We look forward to continuing to build the body of preclinical evidence supporting this program and plan to submit an Investigational New Drug Application by mid-2024, pending feedback from regulatory authorities.
GPH102: An optimal approach to treat beta-thalassemia by replacing the mutated beta-globin gene with a functional gene
The oral presentation (Abstract #66) provides an overview of the development of a precise beta-globin gene replacement strategy that could be the optimal approach to treat beta-thalassemia, a genetic disorder caused by more than 300 mutations in the beta-globin gene. By replacing the mutated beta-globin gene with a functional gene, GPH102 aims to restore expression of adult hemoglobin to levels similar to those who do not have the disease.
Graphite Bio researchers sought to develop a gene replacement approach using the companys UltraHDR gene editing platform to overcome the challenge of achieving high levels of gene replacement that result in high adult hemoglobin (HbA) expression. In particular, where the donor gene shares high nucleotide sequence identity with the targeted mutant allele, undesired partial recombination events can lead to incomplete or unsuccessful integration of the entirety of the intended donor sequence.
To address this challenge, researchers devised a novel knock-in strategy that uses heterologous introns and diverged coding sequences. These were screened using a T2A-EGFP reporter system, which served as a predictive screening tool for protein expression. After screening 39 versions of T2A-EGFP-tagged beta-globin coding sequences containing various heterologous introns and polyadenylation signals, two top DNA donor candidates for beta-globin gene replacement were identified. The selected DNA donors were then further optimized by truncating the introns to create a smaller donor cassette.
The optimized DNA donors were tested in hematopoietic stem and progenitor cells (HSPCs) from sickle cell disease (SCD) patients, which served as a therapeutically relevant model to determine if the DNA donors can effectively replace a dysfunctional beta-globin gene. Use of the optimized DNA donors resulted in homology directed repair (HDR) rates of up to 40% in the sickle cell HSPCs and restoration of HbA expression. These results support further advancement of GPH102 for beta-thalassemia.
An encore of this abstract detailing the preclinical gene replacement data for GPH102 was accepted as a poster presentation at the European Hematology Association (EHA) 2022 Hybrid Congress, which will take place virtually and at the Messe Wien Exhibition & Congress Center in Vienna from June 9-12. The encore abstract is now available online at https://ehaweb.org with additional details following:
Abstract P1436: Development of a Beta-Globin Gene Replacement Strategy as a Therapeutic Approach for Beta-Thalassemia
Presenting Author: Beeke Wienert, Ph.D., associate director, gene engineering, Graphite Bio
Date and Time: Friday, June 10, 16:30-17:45 CEST
GPH101: Gene correction for sickle cell disease Phase 1/2 CEDAR trial encore poster presentation
At the ASGCT Annual Meeting, Graphite Bio will present an encore of the trial-in-progress poster (Abstract #806) for the companys Phase 1/2 CEDAR trial for GPH101, an investigational therapy designed to directly correct the genetic mutation responsible for SCD. The CEDAR trial is an open-label, single-dose, multi-site clinical trial evaluating GPH101 in approximately 15 participants with severe SCD. The trial-in-progress poster is being presented by John DiPersio, M.D., Ph.D., professor of medicine at Washington University School of Medicine and an investigator in the CEDAR trial. Information about this trial was previously presented at the 63rd American Society of Hematology (ASH) Annual Meeting & Exposition in December 2021.
About GPH102 for Beta-Thalassemia
GPH102 is Graphite Bios research program for the treatment of beta-thalassemia, one of the most common autosomal recessive disorders with approximately 68,000 people worldwide born with the disease each year. Beta-thalassemia is a genetic blood disorder characterized by reduced production of beta-globin, a protein that forms oxygen-carrying hemoglobin with alpha-globin. Individuals with the most severe form of beta-thalassemia fail to produce functional beta-globin, which results in severe anemia and transfusion dependency. Using Graphite Bios gene replacement approach, GPH102 is designed to replace the mutated beta-globin gene with a functional gene and restore adult hemoglobin (HbA) expression to levels similar to individuals who do not have the disease.
About GPH101 for Sickle Cell Disease
GPH101 is an investigational next-generation gene-edited autologous hematopoietic stem cell (HSC) therapy designed to directly correct the genetic mutation that causes sickle cell disease (SCD). SCD is a serious, life-threatening inherited blood disorder that affects approximately 100,000 people in the United States and millions of people around the world, making it the most prevalent monogenic disease worldwide. GPH101 is the first investigational therapy to use a highly differentiated gene correction approach that seeks to efficiently and precisely correct the mutation in the beta-globin gene to decrease sickle hemoglobin (HbS) production and restore adult hemoglobin (HbA) expression, thereby potentially curing SCD.
Graphite Bio is evaluating GPH101 in the CEDAR trial, an open-label, multi-center Phase 1/2 clinical trial designed to assess the safety, engraftment success, gene correction rates, total hemoglobin, as well as other clinical and exploratory endpoints and pharmacodynamics in patients with severe SCD.
About Graphite Bio
Graphite Bio is a clinical-stage, next-generation gene editing company harnessing the power of high-efficiency precision gene repair to develop a new class of therapies to potentially cure a wide range of serious and life-threatening diseases. Graphite Bio is pioneering a precision gene editing approach that could enable a variety of applications to transform human health through its potential to achieve one of medicines most elusive goals: to precisely find & replace any gene in the genome. Graphite Bios UltraHDR gene editing platform is designed to precisely correct genetic mutations, replace entire disease-causing genes with functional genes or insert new genes into predetermined, safe locations. The company was co-founded by academic pioneers in the fields of gene editing and gene therapy, including Maria Grazia Roncarolo, M.D., and Matthew Porteus, M.D., Ph.D.
Learn more about Graphite Bio by visiting www.graphitebio.com and following the company on LinkedIn.
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