Previous clinical trials based on the genetic correction of purified CD34(+) cells with gamma-retroviral vectors have demonstrated clinical efficacy in different monogenic diseases, including X-linked severe combined immunodeficiency, adenosine deaminase deficient severe combined immunodeficiency and chronic granulomatous disease. Similar protocols, however, failed to engraft Fanconi anemia (FA) patients with genetically corrected cells. In this study, we first aimed to correlate the hematological status of 27 FA patients with CD34(+) cell values determined in their bone marrow (BM). Strikingly, no correlation between these parameters was observed, although good correlations were obtained when numbers of colony-forming cells (CFCs) were considered. Based on these results, and because purified FA CD34(+) cells might have suboptimal repopulating properties, we investigated the possibility of genetically correcting unselected BM samples from FA patients. Our data show that the lentiviral transduction of unselected FA BM cells mediates an efficient phenotypic correction of hematopoietic progenitor cells and also of CD34(-) mesenchymal stromal cells (MSCs), with a reported role in hematopoietic engraftment. Our results suggest that gene therapy protocols appropriate for the treatment of different monogenic diseases may not be adequate for stem cell diseases like FA. We propose a new approach for the gene therapy of FA based on the rapid transduction of unselected hematopoietic grafts with lentiviral vectors (LVs).
Fanconi anemia (FA) is an inherited genetic disease characterized mainly by bone marrow failure and cancer predisposition. Although gene therapy may constitute a good therapeutic option for many patients with FA, none of the clinical trials so far developed has improved the clinical status of these patients. We have proposed strategies for the genetic correction of bone marrow grafts from patients with FA, using lentiviral vectors (LVs). Here we investigate the relevance of the expression of FANCA to confer a therapeutic effect in cells from patients with FA-A, the most frequent complementation group in FA. Our data show that relatively weak promoters such as the vav or phosphoglycerate kinase (PGK) promoter confer, per copy of FANCA, physiological levels of FANCA mRNA in lymphoblastoid cell lines, whereas the cytomegalovirus and, more significantly, spleen focus-forming virus (SFFV) promoters mediated the expression of supraphysiological levels of FANCA mRNA. Insertion of the woodchuck hepatitis virus posttranscriptional regulatory element (WPRE) or a mutated WPRE into the 3' region of PGK-FANCA LVs significantly increased FANCA mRNA levels. At the protein level, however, all tested vectors conferred, per copy of FANCA, similar and physiological levels of the protein, except SFFV LVs, which again conferred supraphysiological levels of FANCA. In spite of their different activity, all tested vectors mediated a similar phenotypic correction in FA-A lymphoblastoid cell lines and also in hematopoietic progenitors from patients with FA-A. On the basis of the efficacy and safety properties of PGK LVs, a PGK LV carrying FANCA and a mutant WPRE is proposed as an optimized vector for the gene therapy of patients with FA-A.
Current screening methods for ovarian cancer can only detect advanced disease. Earlier detection has proved difficult because the molecular precursors involved in the natural history of the disease are unknown. To identify early driver mutations in ovarian cancer cells, we used dense whole genome sequencing of micrometastases and microscopic residual disease collected at three time points over three years from a single patient during treatment for high-grade serous ovarian cancer (HGSOC). The functional and clinical significance of the identified mutations was examined using a combination of population-based whole genome sequencing, targeted deep sequencing, multi-center analysis of protein expression, loss of function experiments in an in-vivo reporter assay and mammalian models, and gain of function experiments in primary cultured fallopian tube epithelial (FTE) cells. We identified frequent mutations involving a 40 kb distal repressor region for the key stem cell differentiation gene SOX2. In the apparently normal FTE, the region was also mutated. This was associated with a profound increase in SOX2 expression (p < 2−16), which was not found in patients without cancer (n = 108). Importantly, we show that SOX2 overexpression in FTE is nearly ubiquitous in patients with HGSOCs (n = 100), and common in BRCA1-BRCA2 mutation carriers (n = 71) who underwent prophylactic salpingo-oophorectomy. We propose that the finding of SOX2 overexpression in FTE could be exploited to develop biomarkers for detecting disease at a premalignant stage, which would reduce mortality from this devastating disease.
These investigations indicate that integration of lentiviral vectors in human repopulating cells capable of engrafting NOD/SCID mice preferentially occur in coding regions of the human genome. Nevertheless, the clustering of integrations at the transcriptional start is not as high as that observed for gammaretroviral vectors.
The chemokine receptor CCR6 is expressed by CD4+ T cell effector/memory and regulatory effector/memory (TREM) subsets. Here we show that CCR6 modulates graft-versus-host-disease (GVHD) responses in both alloreactive CD4+ T effector cells and regulatory T (Treg) cells. Mortality and morbidity due to acute GVHD were drastically reduced and delayed when naïve T cells were derived from CCR6-deficient donor mice. This deficiency also affected the suppressive ability of Treg cells in GVHD. CCR6-/- Treg cells were able to suppress T cell proliferation in vitro, but their in vivo capacity to downregulate target tissue damage induced by naïve wild type (WT) T cells was impaired. The data demonstrate a requirement for CCR6 in CD4+ T cell function in GVHD, in both effector and regulatory cell subsets.
Fanconi anemia (FA) is a complex genetic disease associated with a defective DNA repair pathway known as the FA pathway. In contrast to many other FA proteins, BRCA 2 participates downstream in this pathway and has a critical role in homology-directed recombination (HDR). In our current studies, we have observed an extremely low reprogramming efficiency in cells with a hypomorphic mutation in Brca2 (Brca2), that was associated with increased apoptosis and defective generation of nuclear RAD51 foci during the reprogramming process. Gene complementation facilitated the generation of Brca2 D27/D27 induced pluripotent stem cells (iPSCs) with a disease-free FA phenotype. Karyotype analyses and comparative genome hybridization arrays of complemented Brca2 D27/D27 iPSCs showed, however, the presence of different genetic alterations in these cells, most of which were not evident in their parental Brca2 D27/D27 mouse embryonic fibroblasts. Gene-corrected Brca2 D27/D27 iPSCs could be differentiated in vitro toward the hematopoietic lineage, although with a more limited efficacy than WT iPSCs or mouse embryonic stem cells, and did not engraft in irradiated Brca2 D27/D27 recipients. Our results are consistent with previous studies proposing that HDR is critical for cell reprogramming and demonstrate that reprogramming defects characteristic of Brca2 mutant cells can be efficiently overcome by gene complementation. Finally, based on analysis of the phenotype, genetic stability, and hematopoietic differentiation potential of gene-corrected Brca2 D27/D27 iPSCs, achievements and limitations in the application of current reprogramming approaches in hematopoietic stem cell therapy are also discussed. STEM CELLS 2014;32:436-446
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