Lentivirus-mediated gene therapy corrects ribosomal biogenesis and shows promise for Diamond Blackfan anemia
Yari Giménez, Manuel Palacios, Rebeca Sánchez-Domínguez, Christiane Zorbas, Jorge Peral, Alexander Puzik, Laura Ugalde, Omaira Alberquilla, Mariela Villanueva, Paula Río, Eva Gálvez, Lydie Da Costa, Marion Strullu, Albert Catala, Anna Ruiz-Llobet, Jose Carlos Segovia, Julián Sevilla, Brigitte Strahm, Charlotte M. Niemeyer, Cristina Beléndez, Thierry Leblanc, Denis L.J. Lafontaine, Juan Bueren, Susana Navarro
Yari Giménez, Manuel Palacios, Rebeca Sánchez-Domínguez, Christiane Zorbas, Jorge Peral, Alexander Puzik, Laura Ugalde, Omaira Alberquilla, Mariela Villanueva, Paula Río, Eva Gálvez, Lydie Da Costa, Marion Strullu, Albert Catala, Anna Ruiz-Llobet, Jose Carlos Segovia, Julián Sevilla, Brigitte Strahm, Charlotte M. Niemeyer, Cristina Beléndez, Thierry Leblanc, Denis L.J. Lafontaine, Juan Bueren, Susana Navarro
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Research Article Hematology Therapeutics

Lentivirus-mediated gene therapy corrects ribosomal biogenesis and shows promise for Diamond Blackfan anemia

Abstract

This study lays the groundwork for future lentivirus-mediated gene therapy in patients with Diamond Blackfan anemia (DBA) caused by mutations in ribosomal protein S19 (RPS19), showing evidence of a new safe and effective therapy. The data show that, unlike patients with Fanconi anemia (FA), the hematopoietic stem cell (HSC) reservoir of patients with DBA was not significantly reduced, suggesting that collection of these cells should not constitute a remarkable restriction for DBA gene therapy. Subsequently, 2 clinically applicable lentiviral vectors were developed. In the former lentiviral vector, PGK.CoRPS19 LV, a codon-optimized version of RPS19 was driven by the phosphoglycerate kinase promoter (PGK) already used in different gene therapy trials, including FA gene therapy. In the latter one, EF1α.CoRPS19 LV, RPS19 expression was driven by the elongation factor alpha short promoter, EF1α(s). Preclinical experiments showed that transduction of DBA patient CD34+ cells with the PGK.CoRPS19 LV restored erythroid differentiation, and demonstrated the long-term repopulating properties of corrected DBA CD34+ cells, providing evidence of improved erythroid maturation. Concomitantly, long-term restoration of ribosomal biogenesis was verified using a potentially novel method applicable to patients’ blood cells, based on ribosomal RNA methylation analyses. Finally, in vivo safety studies and proviral insertion site analyses showed that lentivirus-mediated gene therapy was nontoxic.

Authors

Yari Giménez, Manuel Palacios, Rebeca Sánchez-Domínguez, Christiane Zorbas, Jorge Peral, Alexander Puzik, Laura Ugalde, Omaira Alberquilla, Mariela Villanueva, Paula Río, Eva Gálvez, Lydie Da Costa, Marion Strullu, Albert Catala, Anna Ruiz-Llobet, Jose Carlos Segovia, Julián Sevilla, Brigitte Strahm, Charlotte M. Niemeyer, Cristina Beléndez, Thierry Leblanc, Denis L.J. Lafontaine, Juan Bueren, Susana Navarro

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Figure 3

Phenotypic hematopoietic correction mediated by transduction of BM CD34+ cells from DBA patients with PGK.CoRPS19 LV or EF1α(s).CoRPS19 LV.

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Phenotypic hematopoietic correction mediated by transduction of BM CD34+...
(A) Transduction efficiency of DBA patient hematopoietic progenitors: PGK.EGFP LV (n = 4), PGK.CoRPS19 LV (n = 6), or EF1α.CoRPS19 LV (n = 4). The data are presented as means with standard deviation. CFCs, colony-forming cells. (B) Vector copy number (VCN) in cells maintained in liquid culture (LC) and in CFCs at 14 days of culture. PGK.EGFP LV (n = 4), PGK.CoRPS19 LV (n = 5), and EF1α.CoRPS19 LV (n = 3). (C) Number of HSPCs after 0, 7, and 14 days of LC expansion specific for HSCs. (D and E) Number of CFU-GM and BFU-E colonies per 10 × 10–5 mononuclear cells seeded. n = 3 PGK.EGFP LV, n = 5 PGK.CoRPS19 LV, and n = 5 EF1α.CoRPS19 LV. (F) Flow cytometry strategy used to analyze erythroid progenitors, (G) percentage of CD71/CD235a+, and (H) increment of CD71/CD235a+ mature erythroid progenitors, obtained in BM CD34+ DBA cells from 3 patients posttransduction at day 14 of specific erythroid expansion culture. The graph shows the mean and standard deviation obtained in 3 patients. (I) Left: percentage of hCD45+ engrafted cells at 30, 60, and 90 days posttransplantation with 10 × 10–5 BM CD34+ transduced cells from DBA patients. Right: myeloid cells (CD33+), lymphoid cells (CD19+), and HSCs (CD34+) of DBA patient cells transplanted posttransduction into NSG mice. Each symbol represents 1 specific patient. (J) VCN at day 90 posttransplantation. The graph shows the mean and standard error of the mean. (K) Left: Percentage of hCD45+ cells measured 30, 60, and 90 days (indicated below the graph) after transplantation of 8 × 10–5 BM CD34+ cells from patient DBA-37. Right: Myeloid cells (CD33+), lymphoid cells (CD19+), and HSCs (CD34+) of DBA patient cells transduced and transplanted into NSG mice. (L) VCN, at day 90 posttransplantation, in hCD45+ cells (from patient DBA-37). Multiple-comparison Kruskal-Wallis test (P value; * ≤ 0.017).