Coordinated β-globin expression and α2-globin reduction in a multiplex lentiviral gene therapy vector for β-thalassemia

Nualkaew, Tiwaporn; Sii-Felice, Karine; Giorgi, Marie-Laurence; McColl, Bradley; Gouzil, Julie; Glaser, Astrid; Voon, Hsiao P.J.; Tee, Hsin Y.; Grigoriadis, George; Svasti, Saovaros; Fucharoen, Suthat; Hongeng, Suradej; Leboulch, Philippe; Payen, Emmanuel; Vadolas, Jim

doi:10.1016/j.ymthe.2021.04.037

Cited by 12 publications

(12 citation statements)

References 62 publications

(110 reference statements)

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“…For instance, pharmacological activation of UPS and autophagy pathways have further exemplified the role of clearing toxic α‐globin protein aggregates to alleviate the manifestation of disease 110 . Gene therapy/RNAi/gene editing strategies have been used to alter the expression of α‐globin while increasing β‐globin expression and reversing the α/β‐globin chain imbalance in β‐thalassemia 146,147,151 . Pharmacological silencing of α‐globin and induction of γ‐globin gene expression has demonstrated synergistic activity without affecting erythroid cell viability and differentiation in cord blood‐derived HSCs 141 .…”

Section: Discussionmentioning

confidence: 99%

“… 80 , 148 Alternatively, the transduction of HSC with lentiviral (LV) vectors harboring short hairpin RNA (shRNAs) has emerged as an effective delivery strategy for the clinical translation of RNAi‐based therapies. 149 , 150 , 151 , 152 In this strategy, the artificial miRNA scaffold is used to express a shRNA in the cell type of interest. 151 , 152 , 153 , 154 , 155 Such a design principle permits the shRNA to be processed in the same pathway as natural miRNAs and mediate silencing of target mRNA.…”

Section: Novel Therapies Targeting α‐Globin Expressionmentioning

confidence: 99%

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Interplay between α‐thalassemia and β‐hemoglobinopathies: Translating genotype–phenotype relationships into therapies

Vadolas,

Nualkaew,

Voon

et al. 2024

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Abstractα‐Thalassemia represents one of the most important genetic modulators of β‐hemoglobinopathies. During this last decade, the ongoing interest in characterizing genotype–phenotype relationships has yielded incredible insights into α‐globin gene regulation and its impact on β‐hemoglobinopathies. In this review, we provide a holistic update on α‐globin gene expression stemming from DNA to RNA to protein, as well as epigenetic mechanisms that can impact gene expression and potentially influence phenotypic outcomes. Here, we highlight defined α‐globin targeted strategies and rationalize the use of distinct molecular targets based on the restoration of balanced α/β‐like globin chain synthesis. Considering the therapies that either increase β‐globin synthesis or reactivate γ‐globin gene expression, the modulation of α‐globin chains as a disease modifier for β‐hemoglobinopathies still remains largely uncharted in clinical studies.

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Section: Discussionmentioning

confidence: 99%

Section: Novel Therapies Targeting α‐Globin Expressionmentioning

confidence: 99%

Interplay between α‐thalassemia and β‐hemoglobinopathies: Translating genotype–phenotype relationships into therapies

Vadolas,

Nualkaew,

Voon

et al. 2024

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“…Interestingly, our results are in line with a recent study describing a similar LV expressing simultaneously the T87Q β-globin (carrying only one anti-sickling amino acid) and an amiR targeting BCL11A-XL (Pires Lourenco et al, 2021). Of note, in the case of β-thalassemia, this strategy could be combined with the introduction of a second amiR targeting the α-globin, which was recently shown to improve the α/β ratio in erythrocytes derived from β-thalassemia HSPCs (Nualkaew et al, 2021). Another miR-based gene therapy strategy has recently been developed to further boost HbF expression by expressing two amiRs targeting both BCL11A or ZNF410 γ-globin repressors (Liu et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

Novel lentiviral vectors for gene therapy of sickle cell disease combining gene addition and gene silencing strategies

Brusson

Chalumeau

Martinucci

et al. 2022

Preprint

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Sickle cell disease (SCD) is due to a mutation in the β-globin (HBB) gene causing the production of the toxic sickle hemoglobin (HbS, α2βS2). Transplantation of autologous hematopoietic stem/progenitor cells (HSPCs) transduced with lentiviral vectors (LVs) expressing an anti-sickling β-globin (βAS) is a promising treatment; however, it is only partially effective and patients still present elevated HbS levels. Here, we developed a bifunctional LV expressing βAS3-globin and an artificial microRNA (amiR) specifically downregulating βS-globin expression with the aim of reducing HbS levels and favoring βAS3 incorporation into Hb tetramers. Efficient transduction of SCD HSPC by the bifunctional LV led to a substantial decrease of βS-globin transcripts in HSPC-derived erythroid cells, a significant reduction of HbS+ red cells and effective correction of the sickling phenotype, outperforming βAS gene addition and BCL11A gene silencing strategies. The bifunctional LV showed a standard integration profile and neither the HSPC viability, engraftment and multi-lineage differentiation nor the erythroid transcriptome and miRNAome were affected by the treatment, confirming the safety of this therapeutic strategy. In conclusion, the combination of gene addition and gene silencing strategies can improve the efficacy of current LV-based therapeutic approaches without increasing the mutagenic vector load, thus representing a novel treatment for SCD.

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“…LVβ-shα2 demonstrates reduction of α2-globin expression while maintaining expression of the therapeutic β A−T87Q -globin gene, which improves α/β-globin balance and decreases cellular damage from unbound α-globin chains in erythroid cells (Figure 2B). Compared with LentiGlobin BB305, LVβ-shα2 also requires a lower VCN of the viral vector for equivalent efficacy, which could improve safety (Nualkaew et al, 2021). This gene therapy approach is promising for curative treatment of the β0/β0 disease, but further studies are required to explore efficacy and reliability in a clinical setting.…”

Section: Therapeutic Option For β0/β0 Thalassemiamentioning

confidence: 99%

The Future of Gene Therapy for Transfusion-Dependent Beta-Thalassemia: The Power of the Lentiviral Vector for Genetically Modified Hematopoietic Stem Cells

et al. 2021

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β-thalassemia, a disease that results from defects in β-globin synthesis, leads to an imbalance of β- and α-globin chains and an excess of α chains. Defective erythroid maturation, ineffective erythropoiesis, and shortened red blood cell survival are commonly observed in most β-thalassemia patients. In severe cases, blood transfusion is considered as a mainstay therapy; however, regular blood transfusions result in chronic iron overload with life-threatening complications, e.g., endocrine dysfunction, cardiomyopathy, liver disease, and ultimately premature death. Therefore, transplantation of healthy hematopoietic stem cells (HSCs) is considered an alternative treatment. Patients with a compatible human leukocyte antigen (HLA) matched donor can be cured by allogeneic HSC transplantation. However, some recipients faced a high risk of morbidity/mortality due to graft versus host disease or graft failure, while a majority of patients do not have such HLA match-related donors. Currently, the infusion of autologous HSCs modified with a lentiviral vector expressing the β-globin gene into the erythroid progenitors of the patient is a promising approach to completely cure β-thalassemia. Here, we discuss a history of β-thalassemia treatments and limitations, in particular the development of β-globin lentiviral vectors, with emphasis on clinical applications and future perspectives in a new era of medicine.

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Coordinated β-globin expression and α2-globin reduction in a multiplex lentiviral gene therapy vector for β-thalassemia

Cited by 12 publications

References 62 publications

Interplay between α‐thalassemia and β‐hemoglobinopathies: Translating genotype–phenotype relationships into therapies

Interplay between α‐thalassemia and β‐hemoglobinopathies: Translating genotype–phenotype relationships into therapies

Novel lentiviral vectors for gene therapy of sickle cell disease combining gene addition and gene silencing strategies

The Future of Gene Therapy for Transfusion-Dependent Beta-Thalassemia: The Power of the Lentiviral Vector for Genetically Modified Hematopoietic Stem Cells

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