Your search keyword '"Géronimi, F"' showing total 6 results

1. Hematopoietic stem cell gene therapy of murine protoporphyria by methylguanine-DNA-methyltransferase-mediated in vivo drug selection.

Author

Richard E, Robert E, Cario-André M, Ged C, Géronimi F, Gerson SL, de Verneuil H, and Moreau-Gaudry F

Subjects

Animals, Antineoplastic Agents therapeutic use, Carmustine therapeutic use, Female, Ferrochelatase genetics, Genetic Engineering, Genetic Vectors administration & dosage, Genetic Vectors genetics, Guanine therapeutic use, Lentivirus genetics, Male, Mice, Mice, Inbred BALB C, Models, Animal, Protoporphyria, Erythropoietic enzymology, Stem Cells enzymology, Transduction, Genetic methods, Genetic Therapy methods, Guanine analogs & derivatives, O(6)-Methylguanine-DNA Methyltransferase genetics, Protoporphyria, Erythropoietic therapy, Stem Cell Transplantation

Abstract

Erythropoietic protoporphyria (EPP) is an inherited defect of the ferrochelatase (FECH) gene characterized by the accumulation of toxic protoporphyrin in the liver and bone marrow resulting in severe skin photosensitivity. We previously described successful gene therapy of an animal model of the disease with erythroid-specific lentiviral vectors in the absence of preselection of corrected cells. However, the high-level of gene transfer obtained in mice is not translatable to large animal models and humans if there is no selective advantage for genetically modified hematopoietic stem cells (HSCs) in vivo. We used bicistronic SIN-lentiviral vectors coexpressing EGFP or FECH and the G156A-mutated O6-methylguanine-DNA-methyltransferase (MGMT) gene, which allowed efficient in vivo selection of transduced HSCs after O6-benzylguanine and BCNU treatment. We demonstrate for the first time that the correction and in vivo expansion of deficient transduced HSC population can be obtained by this dual gene therapy, resulting in a progressive increase of normal RBCs in EPP mice and a complete correction of skin photosensitivity. Finally, we developed a novel bipromoter SIN-lentiviral vector with a constitutive expression of MGMT gene to allow the selection of HSCs and with an erythroid-specific expression of the FECH therapeutic gene.

Published

2004

2. A bicistronic SIN-lentiviral vector containing G156A MGMT allows selection and metabolic correction of hematopoietic protoporphyric cell lines.

Author

Richard E, Géronimi F, Lalanne M, Ged C, Redonnet-Vernhet I, Lamrissi-Garcia I, Gerson SL, de Verneuil H, and Moreau-Gaudry F

Subjects

Animals, Antigens, CD34 immunology, Antineoplastic Agents pharmacology, Carmustine pharmacology, Cell Line, DNA, Complementary genetics, DNA, Complementary metabolism, Drug Resistance, Neoplasm, Ferrochelatase genetics, Ferrochelatase metabolism, Gene Expression Regulation, Gene Expression Regulation, Viral, Green Fluorescent Proteins, Humans, Luminescent Proteins genetics, Luminescent Proteins metabolism, Mice, O(6)-Methylguanine-DNA Methyltransferase metabolism, Point Mutation, Porphyria, Hepatoerythropoietic genetics, Porphyria, Hepatoerythropoietic metabolism, Promoter Regions, Genetic, T-Lymphocytes immunology, Time Factors, Transgenes, Genetic Therapy, Genetic Vectors, Lentivirus genetics, O(6)-Methylguanine-DNA Methyltransferase genetics, Porphyria, Hepatoerythropoietic therapy

Abstract

Background: Erythropoietic protoporphyria (EPP) is an inherited disease characterised by a ferrochelatase (FECH) deficiency, the latest enzyme of the heme biosynthetic pathway, leading to the accumulation of toxic protoporphyrin in the liver, bone marrow and spleen. We have previously shown that a successful gene therapy of a murine model of the disease was possible with lentiviral vectors even in the absence of preselection of corrected cells, but lethal irradiation of the recipient was necessary to obtain an efficient bone marrow engraftment. To overcome a preconditioning regimen, a selective growth advantage has to be conferred to the corrected cells., Methods: We have developed a novel bicistronic lentiviral vector that contains the human alkylating drug resistance mutant O(6)-methylguanine DNA methyltransferase (MGMT G156A) and FECH cDNAs. We tested their capacity to protect hematopoietic cell lines efficiently from alkylating drug toxicity and correct enzymatic deficiency., Results: EPP lymphoblastoid (LB) cell lines, K562 and cord-blood-derived CD34(+) cells were transduced at a low multiplicity of infection (MOI) with the bicistronic constructs. Resistance to O(6)-benzylguanine (BG)/N,N'-bis(2-chloroethyl)-N-nitrosourea (BCNU) was clearly shown in transduced cells, leading to the survival and expansion of provirus-containing cells. Corrected EPP LB cells were selectively amplified, leading to complete restoration of enzymatic activity and the absence of protoporphyrin accumulation., Conclusions: This study demonstrates that a lentiviral vector including therapeutic and G156A MGMT genes followed by BG/BCNU exposure can lead to a full metabolic correction of deficient cells. This vector might form the basis of new EPP mouse gene therapy protocols without a preconditioning regimen followed by in vivo selection of corrected hematopoietic stem cells., (Copyright 2003 John Wiley & Sons, Ltd.)

Published

2003

3. Lentivirus-mediated gene transfer of uroporphyrinogen III synthase fully corrects the porphyric phenotype in human cells.

Author

Géronimi F, Richard E, Lamrissi-Garcia I, Lalanne M, Ged C, Redonnet-Vernhet I, Moreau-Gaudry F, and de Verneuil H

Subjects

Adult, Cell Culture Techniques, Cell Differentiation, Erythroblasts metabolism, Fluorescence, Gene Expression, Genetic Vectors, Humans, Phenotype, Porphyria, Erythropoietic genetics, Transduction, Genetic, Virus Replication, Genetic Therapy, Lentivirus genetics, Porphyria, Erythropoietic therapy, Uroporphyrinogen III Synthetase genetics

Abstract

Congenital erythropoietic porphyria (CEP) is an inherited disease due to a deficiency in the uroporphyrinogen III synthase, the fourth enzyme of the heme biosynthesis pathway. It is characterized by accumulation of uroporphyrin I in the bone marrow, peripheral blood and other organs. The prognosis of CEP is poor, with death often occurring early in adult life. For severe transfusion-dependent cases, when allogeneic cell transplantation cannot be performed, the autografting of genetically modified primitive/stem cells may be the only alternative. In vitro gene transfer experiments have documented the feasibility of gene therapy via hematopoietic cells to treat this disease. In the present study lentiviral transduction of porphyric cell lines and primary CD34(+) cells with the therapeutic human uroporphyrinogen III synthase (UROS) cDNA resulted in both enzymatic and metabolic correction, as demonstrated by the increase in UROS activity and the suppression of porphyrin accumulation in transduced cells. Very high gene transfer efficiency (up to 90%) was achieved in both cell lines and CD34(+) cells without any selection. Expression of the transgene remained stable over long-term liquid culture. Furthermore, gene expression was maintained during in vitro erythroid differentiation of CD34(+) cells. Therefore the use of lentiviral vectors is promising for the future treatment of CEP patients by gene therapy.

Published

2003

4. Highly efficient lentiviral gene transfer in CD34+ and CD34+/38-/lin- cells from mobilized peripheral blood after cytokine prestimulation.

Author

Géronimi F, Richard E, Redonnet-Vernhet I, Lamrissi-Garcia I, Lalanne M, Ged C, Moreau-Gaudry F, and De Verneuil H

Subjects

ADP-ribosyl Cyclase 1, Cell Line, Fetal Blood metabolism, Flow Cytometry, Genetic Therapy, Genetic Vectors, Green Fluorescent Proteins, Humans, Interleukin-3 metabolism, Leukocytes, Mononuclear metabolism, Luminescent Proteins metabolism, Membrane Glycoproteins, Membrane Proteins metabolism, Peptide Elongation Factor 1 metabolism, Promoter Regions, Genetic, Proviruses genetics, Purines chemistry, Thrombopoietin metabolism, Time Factors, ADP-ribosyl Cyclase biosynthesis, Antigens, CD biosynthesis, Antigens, CD34 biosynthesis, Cytokines metabolism, Gene Transfer Techniques, Lentivirus genetics

Abstract

Because mobilized peripheral blood (mPB) represents an attractive source of cells for gene therapy, we investigated lentiviral gene transfer in CD34(+) cells and the stem/progenitor-cell-enriched CD34(+)/38(-)/lin(-) cell subset isolated from mPB. In this study, we used an optimized third-generation self-inactivating lentiviral vector containing both the central polypurine tract and the woodchuck hepatitis posttranscriptional regulatory element sequences and encoding enhanced green fluorescent protein (EGFP) under the control of the elongation factor lalpha promoter. This lentivector was first used to compare multiplicity of infection (MOI)-dependent gene transfer efficiency in cord blood (CB) versus mPB CD34(+)-derived cells, colony-forming cells (CFCs), and long-term culture-initiating cells (LTC-ICs). Results showed a difference in the percentage of transduced cells particularly significant at low MOIs. A plateau was reached where 15% and 25% of CB and mPB cells, respectively, remained refractory to lentiviral trans-duction. Effects of a cytokine prestimulation period (18 hours) with interleukin-3, stem cell factor, Flt-3 ligand, and thrombopoietin were then analyzed in total cells, CFCs, and LTC-ICs derived from mPB CD34(+) cells. Transduction levels in those conditions demonstrated a two- and fourfold increase in CFCs and LTC-ICs, respectively, compared with unstimulated (<3 hours) control cells. Moreover, using the same transduction protocol, we were able to efficiently transduce CD34(+)/38(-)/lin(-) cells isolated from mPB, with up to >85% of colonies derived from LTC-ICs expressing EGFP and gene transfer levels remaining stable for 10 weeks in liquid culture. We therefore demonstrate a highly efficient gene transfer in this therapeutically relevant target cell population.

Published

2003

5. Successful therapeutic effect in a mouse model of erythropoietic protoporphyria by partial genetic correction and fluorescence-based selection of hematopoietic cells.

Author

Fontanellas A, Mendez M, Mazurier F, Cario-André M, Navarro S, Ged C, Taine L, Géronimi F, Richard E, Moreau-Gaudry F, Enriquez De Salamanca R, and de Verneuil H

Subjects

Animals, Cell Line, DNA, Complementary genetics, Disease Models, Animal, Female, Ferrochelatase genetics, Flow Cytometry, Genetic Vectors, Hematopoiesis, Interleukin-3 physiology, Liver Diseases therapy, Male, Mice, Mice, Inbred BALB C, Phenotype, Photosensitivity Disorders therapy, Porphyria, Hepatoerythropoietic physiopathology, Retroviridae genetics, Cell Separation methods, Genetic Therapy methods, Hematopoietic Stem Cell Transplantation methods, Porphyria, Hepatoerythropoietic therapy

Abstract

Erythropoietic protoporphyria is characterized clinically by skin photosensitivity and biochemically by a ferrochelatase deficiency resulting in an excessive accumulation of photoreactive protoporphyrin in erythrocytes, plasma and other organs. The availability of the Fech(m1Pas)/Fech(m1Pas) murine model allowed us to test a gene therapy protocol to correct the porphyric phenotype. Gene therapy was performed by ex vivo transfer of human ferrochelatase cDNA with a retroviral vector to deficient hematopoietic cells, followed by re-injection of the transduced cells with or without selection in the porphyric mouse. Genetically corrected cells were separated by FACS from deficient ones by the absence of fluorescence when illuminated under ultraviolet light. Five months after transplantation, the number of fluorescent erythrocytes decreased from 61% (EPP mice) to 19% for EPP mice engrafted with low fluorescent selected BM cells. Absence of skin photosensitivity was observed in mice with less than 20% of fluorescent RBC. A partial phenotypic correction was found for animals with 20 to 40% of fluorescent RBC. In conclusion, a partial correction of bone marrow cells is sufficient to reverse the porphyric phenotype and restore normal hematopoiesis. This selection system represents a rapid and efficient procedure and an excellent alternative to the use of potentially harmful gene markers in retroviral vectors.

Published

2001

6. Correction of deficient CD34+ cells from peripheral blood after mobilization in a patient with congenital erythropoietic porphyria.

Author

Mazurier F, Géronimi F, Lamrissi-Garcia I, Morel C, Richard E, Ged C, Fontanellas A, Moreau-Gaudry F, Morey M, and de Verneuil H

Subjects

Antigens, CD34 genetics, Bone Marrow enzymology, Gene Expression, Gene Transfer Techniques, Genetic Vectors, Humans, Lentivirus genetics, Porphyrins metabolism, Transduction, Genetic, Tumor Cells, Cultured, Antigens, CD34 metabolism, Genetic Therapy, Hematopoietic Stem Cells metabolism, Porphyria, Erythropoietic therapy, Retroviridae genetics, Uroporphyrinogen III Synthetase genetics

Abstract

Congenital erythropoietic porphyria (CEP) is an inherited disease due to a deficiency in the uroporphyrinogen III synthase (UROS), the fourth enzyme of the heme pathway. It is characterized by accumulation of uroporphyrin I in the bone marrow, peripheral blood, and other organs. The onset of most cases occurs in infancy and the main symptoms are cutaneous photosensitivity and hemolysis. For severe transfusion-dependent cases, when allogeneic cell transplantation cannot be performed, autografting of genetically modified primitive/stem cells is the only alternative. In the present study, efficient mobilization of peripheral blood primitive CD34(+) cells was performed on a young adult CEP patient. Retroviral transduction of this cell population with the therapeutic human UROS (hUS) gene resulted in both enzymatic and metabolic correction of CD34(+)-derived cells, as demonstrated by the increase in UROS activity and by a 53% drop in porphyrin accumulation. A 10-24% gene transfer efficiency was achieved in the most primitive cells, as demonstrated by the expression of enhanced green fluorescent protein (EGFP) in long-term culture-initiating cells (LTC-IC). Furthermore, gene expression remained stable during in vitro erythroid differentiation. Therefore, these results are promising for the future treatment of CEP patients by gene therapy.

Published

2001