F. Moreau-Gaudry

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

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.

Gene transfer of the uroporphyrinogen III synthase cDNA into haematopoietic progenitor cells in view of a future gene therapy in congenital erythropoietic porphyria

Congenital erythropoietic porphyria (CEP) is an inherited metabolic disorder characterized by an overproduction and accumulation of porphyrins in bone marrow. This autosomal recessive disease results from a deficiency of uroporphyrinogen III synthase (UROIIIS), the fourth enzyme of the haem biosynthetic pathway. It is phenotypically heterogeneous: patients with mild disease have cutaneous involvement, while more severely affected patients are transfusion dependent. The cloning of UROIIIS cDNA and genomic DNA has allowed the molecular characterization of the genetic defect in a number of families. To date, 22 different mutations have been characterized. Allogeneic bone marrow transplantation is the only curative treatment available for the severe, transfusion-dependent, cases. When bone marrow transplantation cannot be performed owing to the absence of a suitable donor, the autografting of genetically modified cells is an appealing alternative. The best approach to somatic gene therapy in this disease involves the use of recombinant retroviral vectors to transduce cells ex vivo, followed by autologous transplantation of the genetically modified cells. We investigated retroviral transfer in deficient human fibroblasts, immortalized lymphoblasts as well as bone marrow cells, and obtained a complete restoration of the enzymatic activity and full metabolic correction.Using K562 cells, an erythroleukaemic cell line, the expression of the transgene remained stable during 3 months and during erythroid differentiation of the cells. Finally, a 1.6- to 1.9-fold increase in enzyme activity compared to the endogenous level was found in normal CD34+ cells, a population of heterogeneous cells known to contain the progenitor/stem cells for long-term expression. The future availability of a mouse model of the disease will permit ex vivo gene therapy experiments on the entire animal.

Prenatal diagnosis in congenital erythropoietic porphyria by metabolic measurement and DNA mutation analysis

Identification of uroporphyrinogen III synthase (UROIIIS) gene mutations in patients with congenital erythropoietic porphyria (CEP) allows fast and reliable carrier detection and prenatal diagnosis. We describe here the first case of prenatal diagnosis by concomitant measurement of uroporphyrin I in amniotic fluid and direct detection of the gene mutation. A French couple, whose first child was diagnosed with CEP, requested prenatal diagnosis at 16 weeks of gestation. Uroporphyrin I was dramatically increased in amniotic fluid and the fetus was homozygous for the C73R mutation, the most common mutation in this disease. The pregnancy was then terminated.

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

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 Fechm1Pas/Fechm1Pas 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.

Porphyrias: Animal models and prospects for cellular and gene therapy

The rapid progress in the development of molecular technology has resulted in the identification of most of the genes of the heme biosynthesis pathway. Important problems in the pathogenesis and treatment of porphyrias now seem likely to be solved by the possibility of creating animal models and by the transfer of normal genes or cDNAs to target cells. Animal models of porphyrias naturally occur for erythropoietic protoporphyria and congenital erythropoietic porphyria, and different murine models have been or are being created for erythropoietic and hepatic porphyrias. The PBGD knock-out mouse will be useful for the understanding of nervous system dysfunction in acute porphyrias. Murine models of erythropoietic porphyrias are being used for bone-marrow transplantation experiments to study the features of erythropoietic and hepatic abnormalities. Gene transfer experiments have been startedin vitro to look at the feasibility of somatic gene therapy in erythropoietic porphyrias. In particular, we have documented sufficient gene transfer rate and metabolic correction in different CEP disease cells to indicate that this porphyria is a good candidate for treatment by gene therapy in hematopoietic stem cells. With the rapid advancement of methods that may allow more precise and/or efficient gene targeting, gene therapy will become a new therapeutic option for porphyrias.

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

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.

Rapid analysis and efficient selection of human transduced primitive hematopoietic cells using the humanized S65T green fluorescent protein

We have developed an efficient and rapid method to analyze transduction in human hematopoietic cells and to select them. We constructed two retroviral vectors using the recombinant humanized S65T green fluorescent protein (rHGFP) gene. Transduced cells appeared with specific green fluorescence on microscopy or fluorescence-activated cell sorting (FACS) analysis. The rHGFP gene was placed under the control of two different retroviral promotors (LTR) in the LGSN vector and in the SF-GFP vector. Amphotropic retroviruses were tested on NIH/3T3 fibroblasts or human hematopoietic (K562, TF-1) cell lines. Then CD34+ cells isolated from cord blood were infected three times after a 48-h prestimulation with IL-3, IL-6, SCF or with IL-3, IL-6, SCF, GM-CSF, Flt3-L and TPO. After 6 days of expansion, a similar number of total CD34+-derived cells, CD34+ cells and CFC was obtained in non-transduced and transduced cells, demonstrating the absence of toxicity of the GFP. A transduction up to 46% in total CD34+-derived cells and 21% of CD34+ cells was shown by FACS analysis. These results were confirmed by fluorescence of colonies in methyl-cellulose (up to 36% of CFU-GM and up to 25% of BFU-E). The FACS sorting of GFP+ cells led to 83–100% of GFP-positive colonies after 2 weeks of methyl-cellulose culture. Moreover, a mean gene transfer efficiency of 8% was also demonstrated in long-term culture initiating cells (LTC-IC). This rapid and efficient method represents a substantial improvement to monitor gene transfer and retroviral expression of various vectors in characterized human hematopoietic cells.

MYB–GATA1 fusion promotes basophilic leukaemia: involvement of interleukin-33 and nerve growth factor receptors

Acute basophilic leukaemia (ABL) is a rare subtype of acute myeloblastic leukaemia. We previously described a recurrent t(X;6)(p11;q23) translocation generating an MYB–GATA1 fusion gene in male infants with ABL. To better understand its role, the chimeric MYB–GATA1 transcription factor was expressed in CD34‐positive haematopoietic progenitors, which were transplanted into immunodeficient mice. Cells expressing MYB–GATA1 showed increased expression of markers of immaturity (CD34), of granulocytic lineage (CD33 and CD117), and of basophilic differentiation (CD203c and FcϵRI). UT‐7 cells also showed basophilic differentiation after MYB–GATA1 transfection. A transcriptomic study identified nine genes deregulated by both MYB–GATA1 and basophilic differentiation. Induction of three of these genes (CCL23, IL1RL1, and NTRK1) was confirmed in MYB–GATA1‐expressing CD34‐positive cells by reverse transcription quantitative polymerase chain reaction. Interleukin (IL)‐33 and nerve growth factor (NGF), the ligands of IL‐1 receptor‐like 1 (IL1RL1) and neurotrophic receptor tyrosine kinase 1 (NTRK1), respectively, enhanced the basophilic differentiation of MYB–GATA1‐expressing UT‐7 cells, thus demonstrating the importance of this pathway in the basophilic differentiation of leukaemic cells and CD34‐positive primary cells. Finally, gene reporter assays confirmed that MYB and MYB–GATA1 directly activated NTRK1 and IL1RL1 transcription, leading to basophilic skewing of the blasts. MYB–GATA1 is more efficient than MYB, because of better stability. Our results highlight the role of IL‐33 and NGF receptors in the basophilic differentiation of normal and leukaemic cells. Copyright

Effect of tyrosine kinase inhibitors on stemness in normal and chronic myeloid leukemia cells.

Although tyrosine kinase inhibitors (TKIs) efficiently cure chronic myeloid leukemia (CML), they can fail to eradicate CML stem cells (CML-SCs). The mechanisms responsible for CML-SC survival need to be understood for designing therapies. Several previous studies suggest that TKIs could modulate CML-SC quiescence. Unfortunately, CML-SCs are insufficiently available. Induced pluripotent stem cells (iPSCs) offer a promising alternative. In this work, we used iPSCs derived from CML patients (Ph+). Ph+ iPSC clones expressed lower levels of stemness markers than normal iPSCs. BCR–ABL1 was found to be involved in stemness regulation and ERK1/2 to have a key role in the signaling pathway. TKIs unexpectedly promoted stemness marker expression in Ph+ iPSC clones. Imatinib also retained quiescence and induced stemness gene expression in CML-SCs. Our results suggest that TKIs might have a role in residual disease and confirm the need for a targeted therapy different from TKIs that could overcome the stemness-promoting effect caused by TKIs. Interestingly, a similar pro-stemness effect was observed in normal iPSCs and hematopoietic SCs. These findings could help to explain CML resistance mechanisms and the teratogenic side-effects of TKIs in embryonic cells.

Gene Therapy of Pancreatic Cancer

Pancreatic ductal adenocarcinoma (PDAC) is one of the most aggressive tumors with a 5-year survival rate of less than 5%. The poor prognosis of the disease is associated with late diagnosis and a high degree of drug resistance has not been overcome during the past decades. Gemcitabine-based regimens are the first line therapy for advanced pancreatic cancer but are not curative. Recent new combination chemotherapies achieved significant benefits but toxicity makes their use controversial. Novel approaches are currently being developed; in particular cancer gene therapies are undergoing preclinical and clinical validation and are the topic of the present review. We will present different ways to design gene therapy against pancreatic cancers that have been validated in preclinical studies. We also reviewed the clinical trials already published or still ongoing.