Abstract
Sickle cell disease (SCD) and transfusion-dependent β-thalassemia (TDT) are the most prevalent monogenic disorders worldwide. Trial HGB-205 (NCT02151526) aimed at evaluating gene therapy by autologous CD34+ cells transduced ex vivo with lentiviral vector BB305 that encodes the anti-sickling βA-T87Q-globin expressed in the erythroid lineage. HGB-205 is a phase 1/2, open-label, single-arm, non-randomized interventional study of 2-year duration at a single center, followed by observation in long-term follow-up studies LTF-303 (NCT02633943) and LTF-307 (NCT04628585) for TDT and SCD, respectively. Inclusion and exclusion criteria were similar to those for allogeneic transplantation but restricted to patients lacking geno-identical, histocompatible donors. Four patients with TDT and three patients with SCD, ages 13–21 years, were treated after busulfan myeloablation 4.6–7.9 years ago, with a median follow-up of 4.5 years. Key primary endpoints included mortality, engraftment, replication-competent lentivirus and clonal dominance. No adverse events related to the drug product were observed. Clinical remission and remediation of biological hallmarks of the disease have been sustained in two of the three patients with SCD, and frequency of transfusions was reduced in the third. The patients with TDT are all transfusion free with improvement of dyserythropoiesis and iron overload.
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Data availability
Data in the published article have been presented where possible in aggregated form. Any data presented from individual patients have been de-identified. The study protocol and statistical plan are available at https://clinicaltrials.gov/ct2/show/NCT02151526, and the datasets generated and/or analyzed during HGB-205 and follow-up studies LTF-303 for TDT and LTF-307 for SCD are available from the study sponsor, Bluebird Bio (clinicaltrials@bluebirdbio.com), for trial and LTF datasets, and from the corresponding authors (M.C. or P.L.) for investigator-provided data, as applicable and upon reasonable request, although restrictions might apply due to patient privacy and the General Data Protection Regulation. Source data are provided with this paper.
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Acknowledgements
We thank all the patients who participated in this study and staff members at the clinical and laboratory sites and at Bluebird Bio, including D. Davidson, P. Gregory, G. Veres and M. Finer. We also thank R. Pawliuk, K. A. Westerman, K. J. Takekoshi, C. J. Eaves, R. K. Humphries, S. P. Goff, R. Dorazio, E. Gluckman, F. Bernaudin, F. Galactéros, V. Jolaine and R. L. Maas for their contributions to this project through the years. This work was supported by Bluebird Bio; by grants from France’s Agence Nationale de la Recherche under ‘Investissements d’avenir’ program (ANR-10-IAHU-01, M.C. and A. Miccio) and the Paris Ile de France Region under the ‘DIM Thérapie génique’ initiative (M.C., P. Bartolucci and A. Miccio); by Assistance Publique-Hôpitaux de Paris, INSERM, Etablissement Français du Sang (P. Bartolucci and W.E.N.) and the Imagine Institute (M.C. and A. Miccio); by Commissariat à l’Energie Atomique et aux Energies Alternatives (P.L. and E.P.); by the Dior chair for tailored medicine to M.C.; and by ANR’s Chair of Excellence and Industrial Chair of Excellence and Industrial Chair grants to P.L. from the Agence National de la Recherche. The funders had no role in study design, data collection and analysis, decision to publish or preparation of the manuscript, except Bluebird Bio, the study sponsor. This article is dedicated to the memory of Irving London, Dorothy Tuan Lo, Ronald Nagel, Arthur Bank and Bill Solomon.
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Authors and Affiliations
Contributions
M.C. was the principal investigator and P.L. the scientific director of the trial, which they designed together with Bluebird Bio, the sponsor, and with contributions from Y.B. and E.P. P.L. designed the βA-T87Q-globin gene, the LentiGlobin BB305 vector and the packaging plasmids; P.L. also led preclinical studies and regulatory filing. J.A.R., M. Semeraro and M.C. supervised the trial on behalf of the sponsor, with contributions from M.A. and C.W. M. Semeraro and L.J. were involved in patient inclusion and follow-up. E.P. was involved in preclinical studies and designed key biological assays, with contributions from O.N. F.T., E.M. and A.M. performed vector transduction of patient cells and some biological analysis in the follow-up. E.M. was in charge of production, and A.M. was in charge of quality control at the hospital site. F.L., J.-S.D., B.N., I.F.-B., S.R., V.B., C.P. and S.B. performed transplantation and/or clinical services during hospitalization. M. Semeraro, L.J. and M.d.M. provided clinical follow-up. N.H., A.C., L.K., P. Bourget, W.E.N., A. Miccio, P. Bartolucci, P.L. and M.C. performed biological assays and/or analyzed and interpreted data. M. Schmidt, E.S. and A.D. performed the analysis of integration sites. E.M., M. Semeraro, N.H., A. Miccio, P. Bartolucci, M.C. and P.L. wrote the manuscript. All authors provided input to the manuscript.
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Competing interests
P.L. is a scientific founder of Bluebird Bio, with stock options. P.L. is an inventor of awarded patents that claim the βA-T87Q-globin gene, the LentiGlobin BB305 vector and packaging plasmids. O.N., M.A., C.W. and J.A.R. are current or former employees of Bluebird Bio, with stock options. The remaining authors declare no competing interests.
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Extended data
Extended Data Fig. 1 Integration site analysis (ISA) for the patients with SCD.
ISA kinetics for each of the 3 SCD patients, showing relative abundance of vector-marked cell clones. Each of the most represented unique integration sites (UISs) is indicated by a different color, with white showing the cumulative proportion of all other UISs and their names as a side table. The total number of UISs is indicated at the top of each column. SCD-2 M54 provided post datacut.
Extended Data Fig. 2 Integration site analysis (ISA) for the patients with TDT.
Same legend as for Supplementary Fig. 2. TDT-2 M84, TDT-3 M60, and TDT-4 M60 provided post datacut.
Extended Data Fig. 3 VCN kinetics (c/dg) in SCD patients.
(a) In blood cell sub-populations. The values are investigator’s provided and are lower than the qualified values in Extended Data Table 1, due to different standards; they are provided here to compare VCN in cell sub-fractions in a time-dependent manner. (b) In erythroid burst-forming units (BFU-E). (c) In granulocyte-macrophage colony-forming units (CFU-GM).
Extended Data Fig. 4 Flow cytometry analyses of RBCs in SCD patients.
(a) Controls showing that the Pacific Blue (PB) labeled anti-HbA monoclonal antibody (Rockland) does not cross react with HbS in individualized RBCs by flow cytometry analysis. S/S RBC exhibit low level of fluorescence because the anti-HbA antibody also reacts with HbA2 (data from Rockland). However, the anti-HbA antibody does not cross react with HbF (data from Rockland). Because the epitope recognized by the anti-HbA antibody is also present on HbAT87Q, the latter is equally well recognized (data not shown). (b) Distribution of γ-globin and βA-T87Q-globin expressing RBCs in SCD patients’ blood by flow cytometry using antibodies that recognize either βA-T87Q-globin (anti-HbA PB-labeled) or γ-globin (anti-HbF PE-labeled). Co-stainings performed at M36, M14 and M15 for SCD-1, SCD-2 and SCD-3, respectively, showing reduced levels of HbF in high containing HbAT87Q RBCs, and inversely, for SCD-2 and SCD-3. (c) Distribution of βA-T87Q-globin vs. γ-globin expressing RBCs in SCD patients’ blood by flow cytometry using antibodies that recognize either βA-T87Q-globin (left) or γ-globin (right). M, months after GT; PB, Pacific Blue; PE, phycoerythrin. Corresponding datasets are represented in Tables 2a and b.
Extended Data Fig. 5
VCN kinetics (c/dg) in blood cell sub-populations of TDT patients.
Extended Data Fig. 6 Non-invasive in vivo quantification of tissue iron levels by 1.5 Tesla magnetic resonance imaging (MRI).
(a) In SCD patients’ liver (R2*/T2* relaxometry) (left) and heart (T2*) (right). (b) In TDT patients, as in (A).
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Magrin, E., Semeraro, M., Hebert, N. et al. Long-term outcomes of lentiviral gene therapy for the β-hemoglobinopathies: the HGB-205 trial. Nat Med 28, 81–88 (2022). https://doi.org/10.1038/s41591-021-01650-w
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DOI: https://doi.org/10.1038/s41591-021-01650-w
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