ALBERT

Description: Background: In patients with hemoglobinopathies, hematopoietic stem cell (HSC) gene therapy has the potential to induce production of functional β-globin in the red blood cell lineage with the aim of reducing or eliminating the symptoms of disease. Previous results from 1 subject with severe sickle cell disease (SCD; 6 months follow-up) and 2 subjects with β0/βE-thalassemia major (up to 15 months follow-up) treated in clinical study HGB-205 suggested that transplantation with autologous CD34+ cells transduced with the LentiGlobin BB305 lentiviral vector containing an engineered βA-T87Q-globin gene (LentiGlobin BB305 Drug Product) resulted in near-normal levels of total hemoglobin (Hb) and rapid clinical improvement. Here we provide data on a new subject enrolled and additional follow-up data on the 3 subjects previously presented in Study HGB-205. Subjects and Methods: Subjects with severe SCD underwent HSC collection via bone marrow harvest, while subjects with β-thalassemia major underwent HSC collection via peripheral blood apheresis following mobilization. CD34+ cells were selected and transduced with LentiGlobin BB305 lentiviral vector to produce the drug product. Subjects underwent myeloablation with intravenous busulfan, followed by infusion of drug product. Subjects were monitored for hematological engraftment, vector copy number, βA-T87Q-globin expression, adverse events and transfusion requirements. Integration site analysis (ISA) and replication-competent lentivirus (RCL) assays were performed. Prophylactic RBC transfusions were continued in subjects with SCD who were on chronic transfusion pre-transplant to maintain HbS

Description: Background: In patients with β-thalassemia major, hematopoietic stem cell (HSC) gene therapy has the potential to induce production of β-globin, γ-globin or modified β-globin in the red blood cell lineage and reduce or stop the need for blood transfusions. We have previously presented early results for 2 subjects with β0/βE -thalassemia major that suggested that transplantation with autologous CD34+ cells transduced with a replication-defective, self-inactivating LentiGlobin BB305 lentiviral vector containing an engineered β-globin gene (βA-T87Q) resulted in near-normal levels of total hemoglobin (Hb) early after HSC infusion. Herein, we provide additional follow-up data on these two subjects. Subjects and Methods: After obtaining informed consent, subjects with β-thalassemia major underwent HSC collection via peripheral blood apheresis and CD34+ cells were selected. Estimation of the mean ex- vivo vector copy number (VCN) was obtained by quantitative PCR performed on pooled colony-forming progenitors. Subjects underwent myeloablation with intravenous busulfan, followed by infusion of transduced CD34+ cells. Subjects were monitored for hematological engraftment, βA-T87Q-globin expression (by high performance liquid chromatography) and transfusion requirements. Integration site analysis (ISA, by linear amplification-mediated PCR and high-throughput sequencing on nucleated cells) and replication-competent lentivirus (RCL) assays were performed. Results: As of 31 July 2014, two subjects with β0/βE thalassemia major (Subjects 1201 and 1202) have undergone infusion with drug product. The outcome of these two subjects to date is shown in Table 1. The initial safety profile is consistent with myeloablation, without serious adverse events or drug product-related adverse events. Both subjects remain transfusion independent. ISA analyses in both the subjects at 3 months shows polyclonal reconstitution. An additional 2 subjects have been enrolled in this study but have not yet undergone drug product infusion. Conclusion: In the first two subjects, early transfusion independence was achieved and has been maintained as of 31 July 2014. Further follow up data on these two subjects and additional data on subjects who have undergone drug product infusion in this study will be presented. Gene therapy using autologous HSC transduced with LentiGlobin BB305 lentiviral vector is a promising approach for the treatment of patients with β-thalassemia major. Abstract 4797. Table 1. Preliminary Results of Dosing Parameters and Transplantation Outcomes Subject Age (years) and gender Genotype BB305 Drug Product Day of Neutrophil Engraftment Drug Product-related Adverse Events Day of last pRBC transfusion Day of last follow up βA-T87Q-Hb at last follow-up visit /Total Hb (g/dL) VCNa CD34+ cell dose (x106 per kg) 1201 19 F β0/βE 1.5 8.9 Day +13 None Day +10 Day +180 7.2/10.2 1202 16 M β0/βE 2.1 13.6 Day +15 None Day +12 Day +90 6.8/11.0 As of 31 July 2014 a VCN, mean vector copy number Disclosures Payen: bluebird bio, Inc: Consultancy. Beuzard:bluebird bio, Inc: Consultancy, Equity Ownership. Sandler:bluebird bio, Inc: Employment, Equity Ownership. Soni:bluebird bio, Inc.: Employment, Equity Ownership. De Montalembert:Novartis : Speakers Bureau. Leboulch:bluebird bio: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding.

Description: Background LentiGlobin gene therapy contains autologous CD34+ hematopoietic stem cells (HSCs) transduced with the BB305 lentiviral vector (LVV), encoding human β-globin with a T87Q substitution. This substitution confers anti-sickling properties to the gene therapy-derived hemoglobin (HbAT87Q) and allows for its quantification in transduced HSCs. The proof of concept for LentiGlobin gene therapy in patients with transfusion-dependent β-thalassemia (TDT) and sickle cell disease (SCD) was established in the recently completed HGB-205 study (NCT02151526). Herein, we provide the safety and efficacy outcomes and long-term follow-up data for all 7 treated patients, 4 with TDT and 3 with SCD. Methods Patients 5−35 years old with TDT (≥ 100 mL/kg of packed red blood cells [pRBCs]/year) or severe SCD (e.g., ≥ 2 acute chest syndromes [ACS] or ≥ 2 vaso-occlusive crises in the preceding year or the year before regular transfusions) were enrolled. CD34+ HSCs were obtained by mobilization and apheresis in patients with TDT or by bone marrow harvest in patients with SCD. Following collection, cells were transduced with the BB305 LVV. Patients underwent busulfan myeloablative conditioning and were infused with transduced cells. Patients were monitored for engraftment, adverse events (AEs), HbAT87Q levels, and other hematologic and clinical parameters. After 2 years in HGB-205, patients transitioned into the long-term follow-up study, LTF-303 (NCT02633943). Summary statistics are shown as median (min-max). Results As of June 2019, patients with TDT (n=4) and SCD (n=3) had a median follow-up of 49.6 (40.5-60.6) and 28.5 (25.5-52.5) months, respectively. Table 1 shows patient and drug product characteristics and several key efficacy outcomes. All patients achieved HSC engraftment. LentiGlobin safety profile was consistent with busulfan myeloablative conditioning and, in case of SCD, with the underlying disease state. The most common non-hematologic Grade ≥ 3 AEs post-LentiGlobin gene therapy (≥ 2 patients) for patients with TDT were stomatitis (n=4) and increased aspartate aminotransferase (n=2), and for patients with SCD were ACS (n=2) and vaso-occlusive pain (n=2). In all 4 patients with TDT, total Hb and HbAT87Q levels remained generally stable up to 5 years post-LentiGlobin infusion. Three of 4 patients achieved transfusion independence (TI; defined as weighted average Hb ≥ 9g/dL without pRBC transfusions for ≥ 12 months), for an ongoing duration of 56.3 (38.2-57.6) months. Weighted average total Hb during TI was 11.4 (10.5-13.0) g/dL. One patient has been off transfusions for 37.5 months and had total Hb of 7.7 g/dL, which was below the ≥ 9 g/dL requirement to meet the protocol definition of TI. At last visit, HbAT87Q levels in these 4 patients ranged from 6.2-11.2 g/dL, which contributed 73.8-86.8% of the total Hb. The first patient treated with LentiGlobin for SCD experienced one vaso-occlusive pain episode, which developed at 30 months after LentiGlobin gene therapy following a case of acute gastroenteritis with fever and dehydration. The second SCD patient had 2 serious AEs (SAEs) of ACS approximately 6 and 8 months after LentiGlobin gene therapy. The patient resumed chronic pRBC transfusions and hydroxyurea treatment and subsequently experienced 2 SAEs of vaso-occlusive pain; no additional SAEs of vaso-occlusive pain or ACS were reported during the last 16 months of follow-up after LentiGlobin infusion. The third SCD patient had no episodes of vaso-occlusive pain or ACS during 25.5 months of follow-up post-LentiGlobin gene therapy as of the data cut-off. Two patients with SCD who have been off chronic pRBC transfusions, showed improvement in hemolysis markers post-LentiGlobin treatment and stabilization of HbAT87Q expression at approximately 6 months post-LentiGlobin infusion. Total Hb levels for patients with SCD at last visit were 13.0 g/dL (patient 1), 9.4 g/dL (patient 2), and 9.8 g/dL (patient 3), with corresponding HbAT87Q contributions of 47.9%, 7.9%, and 25.8%, respectively. Summary With up to 5 years of follow-up, treatment with LentiGlobin gene therapy was well tolerated and resulted in improvement in hematologic parameters and disease-related symptoms. Further results from the completed study will be presented. Disclosures Hermine: Celgene: Research Funding; Novartis: Research Funding; AB science: Consultancy, Equity Ownership, Honoraria, Research Funding. Brousse:bluebird bio, Inc: Consultancy; AddMedica: Consultancy. El Nemer:Hemanext: Other: Other. Bartolucci:Novartis: Membership on an entity's Board of Directors or advisory committees; AddMedica: Honoraria, Membership on an entity's Board of Directors or advisory committees; Global Blood Therapeutics: Membership on an entity's Board of Directors or advisory committees; Agios: Membership on an entity's Board of Directors or advisory committees; Roche: Membership on an entity's Board of Directors or advisory committees; HEMANEXT: Membership on an entity's Board of Directors or advisory committees. Asmal:bluebird bio, Inc: Employment, Equity Ownership. Whitney:bluebird bio, Inc: Employment, Equity Ownership. Gayron:bluebird bio, Inc: Employment, Equity Ownership. Huang:bluebird bio, Inc.: Employment, Equity Ownership. de Montalembert:AddMedica: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees; bluebird bio, Inc: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees; Novartis: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees. Ribeil:bluebird bio, Inc: Employment, Equity Ownership. Cavazzana:SmartImmune: Other: Founder.

Description: Translocations in hematologic disease of myeloid or lymphoid origin with breakpoints at chromosome band 12p13 frequently result in rearrangements of the Ets variant gene 6 (ETV6). As a consequence either the ETS DNA-binding domain or the Helix-Loop-Helix (HLH) oligomerization domain of ETV6 is fused to different partner genes. We show here that a t(9; 12)(p24; p13) in a case of early pre-B acute lymphoid leukemia and a t(9; 15; 12)(p24; q15; p13) in atypical chronic myelogenous leukemia in transformation involve the ETV6 gene at 12p13 and the JAK2 gene at 9p24. In each case different fusion mRNAs were found, with only one resulting in an open reading frame for a chimeric protein consisting of the HLH oligomerization domain of ETV6 and the protein tyrosine kinase (PTK) domain of JAK2. The cloning of the complete human JAK2 coding and genomic sequences and of the genomic junction fragments of the translocations allowed a characterization of the different splice events leading to the various mRNAs. JAK2 plays a central role in non–protein tyrosine kinase receptor signaling pathways, which could explain its involvement in malignancies of different hematologic lineages. Besides hop in Drosophila no member of the JAK family has yet been implicated in tumorigenesis.

Description: Translocations in hematologic disease of myeloid or lymphoid origin with breakpoints at chromosome band 12p13 frequently result in rearrangements of the Ets variant gene 6 (ETV6). As a consequence either the ETS DNA-binding domain or the Helix-Loop-Helix (HLH) oligomerization domain of ETV6 is fused to different partner genes. We show here that a t(9; 12)(p24; p13) in a case of early pre-B acute lymphoid leukemia and a t(9; 15; 12)(p24; q15; p13) in atypical chronic myelogenous leukemia in transformation involve the ETV6 gene at 12p13 and the JAK2 gene at 9p24. In each case different fusion mRNAs were found, with only one resulting in an open reading frame for a chimeric protein consisting of the HLH oligomerization domain of ETV6 and the protein tyrosine kinase (PTK) domain of JAK2. The cloning of the complete human JAK2 coding and genomic sequences and of the genomic junction fragments of the translocations allowed a characterization of the different splice events leading to the various mRNAs. JAK2 plays a central role in non–protein tyrosine kinase receptor signaling pathways, which could explain its involvement in malignancies of different hematologic lineages. Besides hop in Drosophila no member of the JAK family has yet been implicated in tumorigenesis.