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Gene therapy

Gene therapy. Fabrizia Urbinati 01/12/2010. Outline. Gene therapy introduction: Delivery method Vectors Candidate Diseases ADA-SCID clinical trial b -Thalassemia. What is gene therapy?. Introduction of normal genes into an individual’s cells and tissue to treat a genetic disease.

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Gene therapy

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  1. Gene therapy Fabrizia Urbinati 01/12/2010

  2. Outline • Gene therapy introduction: • Delivery method • Vectors • Candidate Diseases • ADA-SCID clinical trial • b-Thalassemia

  3. What is gene therapy? Introduction of normal genes into an individual’s cells and tissue to treat a genetic disease.

  4. Different strategies for delivering a therapeutic gene into a patient organ In vivo Ex vivo

  5. Gene Therapy Vectors Non Viral Vectors Viral Vectors • Naked DNA • Liposome • Oligonucleotides • Adeno Virus • Adeno Associated virus • RetrovirusLentivirus • Herpes virus • …

  6. Vectors used in gene therapy clinical trial

  7. Retrovirus • ssRNA virus • Infect proliferating cells • Integrate in the host genome (stable expression) • 7.5 Kb insert size

  8. Retroviral Vector: production Long Terminal Repeat (LTR): Regulatory sequence (promoter and enhancer) 5’ LTR 3’ LTR 3’ LTR 5’ LTR

  9. Retroviral vector: infection • The virus enter the target cell • the viral genome is integrated • in the host genome • The therapeutic protein is produced

  10. Diseases addressed by Gene Therapy clinical trials • It must be caused by a single gene defect (some exceptions apply) • Gene causing the disease must be identified and cloned • The tissue/organ has to be accessible for gene delivery • No effective conventional treatment is available for that disease

  11. Number of Gene Therapy Clinical Trails approved worldwide 1989-2009

  12. Two examples of Gene Therapy for hematologic diseases. • ADA-SCID • b-thalassemia

  13. Replacement of the gene in Hematopoietic Stem Cells (HSC) Blood and Tissues Bone Marrow

  14. Adenosine-Deaminase (ADA) Deficiency • ADA is an enzyme involved in purine metabolism; It is needed for the breakdown of adenosine from food and for the turnover of nucleic acid in tissues. • ADA deficiency is an autosomal recessive disorder • Lack of B and T cell function • Immune system is severely compromised and the disease is often fatal, if untreated, due to infections

  15. ADA-SCID : treatment • Bone Marrow Transplantation • ADA enzyme therapy • Gene Therapy

  16. Gene Therapy Clinical Trial for ADA-SCID in Italy (Aiuti et al. Science 2002)

  17. Gene Therapy Clinical Trial for ADA- SCID in Italy: vector Retroviral vector production Sv40 ADA NeoR LTR LTR

  18. Blood Retroviral vector T-Lymphocyte NK cells B-Lymphocyte Erythrocyte Platelets Granulocytes Monocytes Bone Marrow Macrophages Bone Marrow Stem Cells (CD34+) Dendritic Cells Tissue Gene Therapy Clinical Trial for ADA- SCID in Italy: protocol. • Bone Marrow stem cells collection from 2 patients • Infection of BM stem cells with Retroviral vector • Busulfan prior to BM infusion (“non-myeloablative conditioning”). • Re-infusion of corrected BM cells into the patient

  19. Gene Therapy Clinical Trial for ADA- SCID in Italy: results • ADA enzyme activity was restored and lymphoid reconstitution was shown after gene therapy treatment • Immune reconstitution by 6 months. • T cells gene-marked at 100% (Aiuti et. Al Science 2002)

  20. ADA-SCID gene therapy (Aiuti at al. Hematology 2009)

  21. Setbacks • In the French trial for X-SCID gene therapy a total of 4 patients from 10 treated developed leukemia due to uncontrolled proliferation of mature T lymphocytes after gene therapy treatment. Three of the patients were treated and recovered; one unfortunately died. (Science 2003)

  22. Retroviral integration into the host genome: insertional mutagenesis Leukemia was caused by the retroviral vector carrying the therapeutic gene (IL2RG) In the first 2 patients that developed leukemia, the integration of the retroviral vector close to the LMO-2 oncogene lead to over-expression of the gene and uncontrolled proliferation of T-cells

  23. Follow up study in ADA-SCID patients from the italian trial (Journal of Clinical Investigation, 2007)

  24. Follow up study in ADA-SCID patients from the italian trial Retroviral integration site in patient with ADA-SCID: many oncogenes were hit by the provirus Expression of LMO-2 gene in pt. treated with gene therapy: The expression of the oncogene did not change (Aiuti et al. JCI 2007)

  25. Results of the follow-up study (Aiuti et al. JCI 2007) • the analysis revealed a nonrandom distribution of integrated proviruses, with a strong preference for gene-dense regions and a tendency to hit genes that are highly expressed in CD34+ cells at the time of transduction. • Expression of the oncogenes hit by the viral integration did not change : insertions in potentially dangerous genomic sites are not sufficient per se to induce a proliferative advantage in T cells in vivo, confirming that multiple cooperating events are required to promote oncogenic transformation in humans • In summary, the data show that transplantation of ADA-transduced HSCs does not result in selection of expanding or malignant cell clones, despite the occurrence of insertions near potentially oncogenic loci.

  26. Need for improving the safety of viral vectors. • Gene therapy of genetic diseases require the development of safer gene-transfer such as: • self-inactivating viral vectors • the use of physiologically controlled gene expression cassettes. • Use of “Insulator” sequences in viral vectors

  27. Improving the safety of viral vectors: the example of b-thalassemia Gene Therapy • Thalassemias are hereditary anemias and are the most common single gene defects worldwide. • b-thalassemia result from mutations in the -globin gene cluster • There is reduced hemoglobin production leading to ineffective erythropoiesis • Currently, the only curative therapy is allogeneic Bone Marrow Transplantation (BMT). • However, allogenic BMT is limited by the availability of donors and potentially serious side effects. • Insertion of a normal β-globin gene could have a therapeutic potential in β -thalassemia .

  28. b-thalassemia Gene Therapy • There are no current Gene Therapy trials for b-thalassemia. • Many studies have been focused on the optimization of the vectors carrying the b-globin gene. • Latest vector of choice for b-globin gene is SIN-lentiviral vector

  29. b-Globin HS2 HS3 HS4 R U5 R U5 bP U3 U3 SIN-Lentiviral vector forb-thalassemia gene therapy • Lentiviral vector: • retrovirus family • ssRNA • Integrate in the host genome • 8Kb insert size • Infect also quiescent cells Safety features: • SIN=Self Inactivating vector: a portion of the viral LTR has been deleted to prevent transcription of the viral vector sequence after integration (increase safety of the vector) • The expression of the b-globin gene is driven by the b-globin promoter and its enhancer (increase safety of the vector) that are lineage specific

  30. (Felsenfeld et al., Science 2001) Use of “Insulator” in a b-globin lentiviral vector for Gene Therapy of b-Thalassemia Insulator is a sequence found in the genome and it is a genetic boundary element. The need for them arises where two adjacent genes on a chromosome have very different transcription patterns, and it is critical that the inducing or repressing mechanisms of one do not interfere with the neighbouring gene.

  31. b-Globin HS2 HS3 HS4 I I ?Oncogene U3 U3 R U5 R U5 bP Use of “Insulator” in a b-globin lentiviral vector for Gene Therapy of b-Thalassemia Insertion of insulator sequences in a Lentiviral Vector to increase the safety of the vector, blocking the activity of the enhancer towards surrounding genes.

  32. Gene therapy: summary • Gene therapy overview • Different delivery methods, vectors, diseases, • 2 Gene Therapy studies: • ADA-SCID trial : successful but need to find safer delivery vectors • b-Thalassemia Gene Therapy as an example of optimization of safer vectors

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