In vitro RBC production from stem cells could represent an alternative to classic transfusion products. Until now the clinical feasibility of this concept has not been demonstrated. We addressed the question of the capacity of cultured RBCs (cRBCs) to survive in humans. By using a culture protocol permitting erythroid differentiation from peripheral CD34 ؉ HSC, we generated a homogeneous population of cRBC functional in terms of their deformability, enzyme content, capacity of their hemoglobin to fix/release oxygen, and expression of blood group antigens. We then demonstrated in the nonobese diabetes/severe combined immunodeficiency mouse that cRBC encountered in vivo the conditions necessary for their complete maturation. These data provided the rationale for injecting into one human a homogeneous sample of 10 10 cRBCs generated under good manufacturing practice conditions and labeled with 51
The online version of this article has a a Supplementary Appendix. BackgroundEx vivo manufacture of red blood cells from stem cells is a potential means to ensure an adequate and safe supply of blood cell products. Advances in somatic cell reprogramming of human induced pluripotent stem cells have opened the door to generating specific cells for cell therapy. Human induced pluripotent stem cells represent a potentially unlimited source of stem cells for erythroid generation for transfusion medicine. Design and MethodsWe characterized the erythroid differentiation and maturation of human induced pluripotent stem cell lines obtained from human fetal (IMR90) and adult fibroblasts (FD-136) compared to those of a human embryonic stem cell line (H1). Our protocol comprises two steps: (i) differentiation of human induced pluripotent stem cells by formation of embryoid bodies with indispensable conditioning in the presence of cytokines and human plasma to obtain early erythroid commitment, and (ii) differentiation/maturation to the stage of cultured red blood cells in the presence of cytokines. The protocol dispenses with major constraints such as an obligatory passage through a hematopoietic progenitor, co-culture on a cellular stroma and use of proteins of animal origin. ResultsWe report for the first time the complete differentiation of human induced pluripotent stem cells into definitive erythrocytes capable of maturation up to enucleated red blood cells containing fetal hemoglobin in a functional tetrameric form. ConclusionsRed blood cells generated from human induced pluripotent stem cells pave the way for future development of allogeneic transfusion products. This could be done by banking a very limited number of red cell phenotype combinations enabling the safe transfusion of a great number of immunized patients. © F e r r a t a S t o r t i F o u n d a t i o n
The online version of this article has a Supplementary Appendix. BackgroundHuman induced pluripotent stem cells offer perspectives for cell therapy and research models for diseases. We applied this approach to the normal and pathological erythroid differentiation model by establishing induced pluripotent stem cells from normal and homozygous sickle cell disease donors. Design and MethodsWe addressed the question as to whether these cells can reach complete erythroid terminal maturation notably with a complete switch from fetal to adult hemoglobin. Sickle cell disease induced pluripotent stem cells were differentiated in vitro into red blood cells and characterized for their terminal maturation in terms of hemoglobin content, oxygen transport capacity, deformability, sickling and adherence. Nucleated erythroblast populations generated from normal and pathological induced pluripotent stem cells were then injected into non-obese diabetic severe combined immunodeficiency mice to follow the in vivo hemoglobin maturation. ResultsWe observed that in vitro erythroid differentiation results in predominance of fetal hemoglobin which rescues the functionality of red blood cells in the pathological model of sickle cell disease. We observed, in vivo, the switch from fetal to adult hemoglobin after infusion of nucleated erythroid precursors derived from either normal or pathological induced pluripotent stem cells into mice. ConclusionsThese results demonstrate that human induced pluripotent stem cells: i) can achieve complete terminal erythroid maturation, in vitro in terms of nucleus expulsion and in vivo in terms of hemoglobin maturation; and ii) open the way to generation of functionally corrected red blood cells from sickle cell disease induced pluripotent stem cells, without any genetic modification or drug treatment. ABSTRACT© F e r r a t a S t o r t i F o u n d a t i o n
While enucleation is a critical step in the terminal differentiation of human red blood cells, the molecular mechanisms underlying this unique process remain unclear. To investigate erythroblast enucleation, we studied the erythroid differentiation of human embryonic stem cells (hESCs), which provide a unique model for deeper understanding of the development and differentiation of multiple cell types. First, using a two-step protocol, we demonstrated that terminal erythroid differentiation from hESCs is directly dependent on the age of the embryoid bodies. Second, by choosing hESCs in two extreme conditions of erythroid culture, we obtained an original differentiation model which allows one to study the mechanisms underlying the enucleation of erythroid cells by analyzing the gene and miRNA (miR) expression profiles of cells from these two culture conditions. Third, using an integrated analysis of mRNA and miR expression profiles, we identified five miRs potentially involved in erythroblast enucleation. Finally, by selective knockdown of these five miRs we found miR-30a to be a regulator of erythroblast enucleation in hESCs.
Polymerization of the sickle hemoglobin (HbS) is a key determinant of sickle cell disease (SCD), an inherited blood disorder. Fetal hemoglobin (HbF) is a major modulator of the disease severity by both decreasing HbS intracellular concentration and inhibiting its polymerization. However, heterocellular distribution of HbF is common in SCD. For HbS polymerization inhibition, the hypothesis of an "HbF per red blood cell (HbF/RBC) threshold" requires accurate measurement of HbF in individual RBC. To date, HbF detection methods are limited to a qualitative measurement of RBC populations containing HbF-the F cells, which are variable. We developed
Lentiviral modification combined with ex vivo erythroid differentiation was used to stably inhibit RhAG expression, a critical component of the Rh(rhesus) membrane complex defective in the Rh null syndrome. The cultured red cells generated recapitulate the major alterations of native Rh null cells regarding antigen expression, membrane deformability, and gas transport function, providing the proof of principle for their use as model of Rh null syndrome and to investigate Rh complex biogenesis in human primary erythroid cells. Using this model, we were able to reveal for the first time that RhAG extinction alone is sufficient to explain ICAM-4 and CD47 loss observed on native Rh null RBCs. Together with the effects of RhAG forced expression in Rh null progenitors, this strongly strengthens the hypothesis that RhAG is critical to Rh complex formation. The strategy is also promising for diagnosis purpose in order to overcome the supply from rare blood donors and is applicable to other erythroid defects and rare phenotypes, providing models to dissect membrane biogenesis of multicomplex proteins in erythroid cells, with potential clinical applications in transfusion medicine. Am. J. Hematol. 88:343-349, 2013. V C 2013 Wiley Periodicals, Inc. IntroductionLarge-scale approach to generate ex vivo mature erythroid cells sharing all functional characteristics with native adult RBCs [1] is well suited to investigate erythroidrestricted human disorders [2], particularly if coupled with lentiviral modification to modulate specific gene expression. The purpose of this study was to provide a proof of principle to reproduce a phenotype with functional alterations of RBC. Accordingly, we choose to mimic blood group Rhdeficiency (also called Rh null ), a rare autosomal recessive disorder affecting the RBC membrane in humans, which is associated with a hemolytic anemia of varying severity, abnormal red cell shape (stomato-spherocytosis), and osmotic fragility [3,4]. RBCs from Rh-deficient individuals basically lack Rh and LW blood group antigens, and Ss antigens expression is reduced [5]. Biochemical analysis have shown that these RBCs are severely deficient in the Rh complex, an oligomeric assembly of two erythroidspecific proteins, Rh (Rhesus), and RhAG (Rh-Associated Glycoprotein), to which accessory chains such as ICAM-4 (carrier of LW antigens), CD47 and glycophorin B (carrier of Ss antigens) are linked by noncovalent bonds. Molecular studies have revealed that Rh-deficiency is caused by different mutations that occur in either the RHAG or RH locus, but the genes encoding the accessory chains remain unaltered [3,4]. This is consistent with the inheritance of Rh null phenotypes by two distinct genetic backgrounds. The "amorph" type is caused by homozygosity for mutant alleles at the RH locus (1p34-36) and the "regulator" type by homozygosity (or composite heterozygosity) for mutants alleles at the genetically independent RHAG locus (6p12-21) encoding the RhAG protein subunit [6]. These findings suggest that when either the Rh...
BCL11A regulates the fetal-adult hemoglobin switch by repressing expression at the gamma (γ)-globin locus (Sankaran et al., Science, 2008), and thus it represents an appealing therapeutic target for sickle cell disease (SCD). BCH-BB694 is a lentiviral vector (LVV) encoding a shRNA targeting BCL11A embedded in a microRNA scaffold (shmiR) allowing erythroid-specific knockdown to induce γ-globin expression and concomitantly and coordinately repress β-sickle globin expression (Brendel et al. JCI, 2016). In a pilot and feasibility gene therapy study we are evaluating the safety of infusion of BCH-BB694-transduced autologous CD34+ cells in patients with severe SCD. The study is an IND enabled and IRB approved open label, non-randomized, single center trial (NCT 03282656). We report here data from the full adult cohort which has completed enrollment with > 6 months of follow up in all patients. The adult cohort included three patients >/= 18 years old. Autologous CD34+ cells were collected by plerixafor mobilization and then transduced ex vivo with the BCH-BB694 shmiR lentiviral vector. Cell doses and vector copy number (VCN) are shown in the Table. After testing and release, gene modified cells were infused into subjects who had received busulfan conditioning. There were no Grade 3 or 4 AEs associated with mobilization, collection or infusion. All three adults (age 21-26 years old) demonstrated neutrophil engraftment on day +22 with adverse events consistent with busulfan conditioning. These patients are now 7, 9, and 17 months post infusion. One subject resumed red cell transfusions at 3 months due to pre-existing moyamoya using a pre-defined conservative trigger value of 40% sickle Hb in whole blood and will be detailed separately. There have been no adverse events related to the gene therapy product. VCN has been stable in bone marrow (BM) and peripheral blood (PB) in all cell lineages during the length of the study, with the latest time point studied at 15 months (BCL002) and ranged from 0.45-2.85 copies per cell in erythroid progenitor cells. BCL11A protein levels evaluated by immunoblot in subject BCL002 at 30 days (PB) and 6 months (BM) post-infusion showed highly effective and selective knockdown of BCL11A in erythroid progenitors with no reduction in BCL11A expression in B lymphoid cells. The number of HbF-containing cells (F cells) was assessed by flow cytometry and the kinetics of F cell production was remarkably similar in all subjects. The two untransfused subjects (BCL002 and BCL004) produced 70% F-cells in PB at 3 and 5 months, which has remained stable until the last point assayed (15 months and 7.5 months, respectively) (table). Calculated average HbF per F cell was >10pg in all subjects (table) and quantitative single cell HbF flow analysis showed the majority of F cells had >4pg F/cell, a level that is believed to prevent sickling under physiological oxygen saturation (Rakotoson et al., ASH 2017). In both untransfused subjects, total Hb remained stable with evidence of reduced hemolysis by reticulocyte count (slightly elevated) and LDH (normal in one subject, slightly elevated in the other). At the 3-month timepoint before re-starting transfusions, the subject with moyamoya (BCL003) had a pre-transfusion Hb of 11 g/dL with 76% of non-transfused cells containing on average 17pg F/F cell. For all subjects, we estimated the fraction of RBCs containing significant Hb sickle polymers and the amount of polymer in each sickled RBC at physiologic oxygen tension (where 50% of monomeric hemoglobin was oxygen saturated, or the P50) (Di Caprio et al. PNAS 2019, in press). The results for all 3 subjects in this adult cohort showed fewer RBCs with significant Hb polymer than two hydroxyurea-responsive treated comparators and significantly less Hb polymer per sickled RBC than a third highly responsive hydroxyurea-treated comparator. In conclusion, these data demonstrate successful and sustained engraftment in three adult patients treated with LVV-delivered shmiR technology targeting BCL11A. Early results suggest an acceptable safety profile, validation of BCL11A as effective target for HbF induction in humans with high numbers of F cells in circulation containing high levels of HbF per F cell, and mitigation of cellular pathology of SCD. Disclosures Achebe: Global Blood Therapeutics: Membership on an entity's Board of Directors or advisory committees; Pharmacosmos: Membership on an entity's Board of Directors or advisory committees; Fulcrum Therapeutics: Membership on an entity's Board of Directors or advisory committees; Bluebird Bio: Membership on an entity's Board of Directors or advisory committees. 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; Roche: Membership on an entity's Board of Directors or advisory committees; HEMANEXT: 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. Heeney:AstraZeneca: Research Funding; Micelle Biopharma: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding; Pfizer: Research Funding; Novartis: Consultancy, Research Funding; Ironwood / Cyclerion: Research Funding; Vertex / Crisper Therapeutics: Other: Data Safety Monitoring Board. Higgins:Sanofi: Consultancy, Research Funding. Nikiforow:Kite/Gilead: Honoraria; Novartis: Honoraria; NKarta: Honoraria. Wood:Sanofi: Consultancy, Research Funding. Williams:Alerion Biosciences: Other: Co-founder; Novartis: Membership on an entity's Board of Directors or advisory committees; Orchard Therapeutics: Membership on an entity's Board of Directors or advisory committees, Other: Co-founder, Patents & Royalties: Potential for future royalty/milestone income, X-SCID., Research Funding; bluebird bio: Patents & Royalties: Licensed certain IP relevant to hemoglobinopathies to bluebird bio. Received payment in the past bluebird bio through a BCH institutional licensing agreement and there is a potential for future royalty/milestone income from this agreement., Research Funding.
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