Cornelia de Lange syndrome (CdLS) is a clinically heterogeneous developmental disorder characterized by facial dysmorphia, upper limb malformations, growth and cognitive retardation. Mutations in the sister chromatid cohesion factor genes NIPBL, SMC1A and SMC3 are present in 65% of CdLS patients. In addition to their canonical roles in chromosome segregation, the cohesin proteins are involved in other biological processes such as regulation of gene expression, DNA repair and maintenance of genome stability. To gain insights into the molecular basis of CdLS, we analyzed the affinity of mutated SMC1A and SMC3 hinge domains for DNA. Mutated hinge dimers bind DNA with higher affinity than wild-type proteins. SMC1A-and SMC3-mutated CdLS cell lines display genomic instability and sensitivity to ionizing radiation and interstrand crosslinking agents. We propose that SMC1A and SMC3 CdLS mutations affect the dynamic association between SMC proteins and DNA, providing new clues to the underlying molecular cause of CdLS.
Mutations in LMNA , which encodes the nuclear proteins Lamin A/C, can cause cardiomyopathy and conduction disorders. Here, we employ induced pluripotent stem cells (iPSCs) generated from human cells carrying heterozygous K219T mutation on LMNA to develop a disease model. Cardiomyocytes differentiated from these iPSCs, and which thus carry K219T- LMNA , have altered action potential, reduced peak sodium current and diminished conduction velocity. Moreover, they have significantly downregulated Na v 1.5 channel expression and increased binding of Lamin A/C to the promoter of SCN5A , the channel’s gene. Coherently, binding of the Polycomb Repressive Complex 2 (PRC2) protein SUZ12 and deposition of the repressive histone mark H3K27me3 are increased at SCN5A . CRISPR/Cas9-mediated correction of the mutation re-establishes sodium current density and SCN5A expression. Thus, K219T- LMNA cooperates with PRC2 in downregulating SCN5A , leading to decreased sodium current density and slower conduction velocity. This mechanism may underlie the conduction abnormalities associated with LMNA-cardiomyopathy.
Allogeneic fetal‐derived human neural stem cells (hfNSCs) that are under clinical evaluation for several neurodegenerative diseases display a favorable safety profile, but require immunosuppression upon transplantation in patients. Neural progenitors derived from patient‐specific induced pluripotent stem cells (iPSCs) may be relevant for autologous ex vivo gene‐therapy applications to treat genetic diseases with unmet medical need. In this scenario, obtaining iPSC‐derived neural stem cells (NSCs) showing a reliable “NSC signature” is mandatory. Here, we generated human iPSC (hiPSC) clones via reprogramming of skin fibroblasts derived from normal donors and patients affected by metachromatic leukodystrophy (MLD), a fatal neurodegenerative lysosomal storage disease caused by genetic defects of the arylsulfatase A (ARSA) enzyme. We differentiated hiPSCs into NSCs (hiPS‐NSCs) sharing molecular, phenotypic, and functional identity with hfNSCs, which we used as a “gold standard” in a side‐by‐side comparison when validating the phenotype of hiPS‐NSCs and predicting their performance after intracerebral transplantation. Using lentiviral vectors, we efficiently transduced MLD hiPSCs, achieving supraphysiological ARSA activity that further increased upon neural differentiation. Intracerebral transplantation of hiPS‐NSCs into neonatal and adult immunodeficient MLD mice stably restored ARSA activity in the whole central nervous system. Importantly, we observed a significant decrease of sulfatide storage when ARSA‐overexpressing cells were used, with a clear advantage in those mice receiving neonatal as compared with adult intervention. Thus, we generated a renewable source of ARSA‐overexpressing iPSC‐derived bona fide hNSCs with improved features compared with clinically approved hfNSCs. Patient‐specific ARSA‐overexpressing hiPS‐NSCs may be used in autologous ex vivo gene therapy protocols to provide long‐lasting enzymatic supply in MLD‐affected brains. Stem Cells Translational Medicine 2017;6:352–368
Friedreich’s ataxia (FRDA) is an autosomal-recessive neurodegenerative and cardiac disorder which occurs when transcription of the FXN gene is silenced due to an excessive expansion of GAA repeats into its first intron. Herein, we generate dorsal root ganglia organoids (DRG organoids) by in vitro differentiation of human iPSCs. Bulk and single-cell RNA sequencing show that DRG organoids present a transcriptional signature similar to native DRGs and display the main peripheral sensory neuronal and glial cell subtypes. Furthermore, when co-cultured with human intrafusal muscle fibers, DRG organoid sensory neurons contact their peripheral targets and reconstitute the muscle spindle proprioceptive receptors. FRDA DRG organoids model some molecular and cellular deficits of the disease that are rescued when the entire FXN intron 1 is removed, and not with the excision of the expanded GAA tract. These results strongly suggest that removal of the repressed chromatin flanking the GAA tract might contribute to rescue FXN total expression and fully revert the pathological hallmarks of FRDA DRG neurons.
In the last decades the molecular basis of monogenic diseases has been largely unraveled, although their treatment has often remained unsatisfactory. Autosomal recessive osteopetrosis (ARO) belongs to the small group of genetic diseases that are usually treated with hematopoietic stem cell transplantation (HSCT). However, this approach is not effective in the recently identified form carrying mutations in the receptor activator of NF-kB ligand (RANKL) gene. In this subset, therapy replacement approach based on RANKL delivery has a strong rationale. Here we demonstrate that the systematic administration of RANKL for 1 month to Rankl À/À mice, which closely resemble the human disease, significantly improves the bone phenotype and has beneficial effects on bone marrow, spleen and thymus; major adverse effects arise only when mice are clearly overtreated. Overall, we provide evidence that the pharmacological administration of RANKL represents the appropriate treatment option for RANKL-deficient ARO patients, to be validated in a pilot clinical trial. ß
Omenn syndrome (OS) is an atypical primary immunodeficiency characterized by severe autoimmunity because of activated T cells infiltrating target organs. The impaired recombinase activity in OS severely affects expression of the pre-T-cell receptor complex in immature thymocytes, which is crucial for an efficient development of the thymic epithelial component. Anti-CD3 monoclonal antibody (mAb) treatment in RAG2 ؊/؊ mice was previously shown to mimic pre-TCR signaling promoting thymic expansion. Here we show the effect of anti-CD3 mAb administration in the RAG2 R229Q mouse model, which closely recapitulates human OS. These animals, in spite of the inability to induce the autoimmune regulator, displayed a significant amelioration in thymic epithelial compartment and an important reduction of peripheral T-cell activation and tissue infiltration. IntroductionAs opposed to the classic T Ϫ B Ϫ severe combined immunodeficiencies (SCIDs), Omenn syndrome (OS) represents an atypical type of primary immunodeficiency (PID) associated with autoimmune manifestations because of activated oligoclonal T cells that infiltrate peripheral tissues and provoke generalized erythroderma, alopecia, lymphadenopathy, hepatosplenomegaly, and intractable diarrhea. 1 Patients have high levels of serum IgE despite the absence of circulating B cells. From the genetic point of view, most OS cases result from hypomorphic mutations in RAG genes 2,3 that decrease but do not completely abolish V(D)J recombination activity, allowing the generation of an oligoclonal autoreactive T-cell repertoire. [4][5][6][7] To date, allogeneic hematopoietic stem cell transplantation (HSCT) is the only beneficial therapeutic approach, although at high risk because of the myeloablative conditioning regimens necessary to eliminate autoreactive T lymphocytes and achieve successful engraftment. [8][9][10] We have recently generated and characterized a knock-in Rag2 R229Q mouse model, carrying a hypomorphic mutation in the Rag2 gene (R229Q), initially identified in patients with OS or with leaky SCID. [10][11][12] The RAG2 R229Q mouse model closely recapitulates the human disease as mice display an expansion of oligoclonal and activated T cells which infiltrate target organs including skin, gut, liver, and lung, 13 and high levels of serum IgE, despite a severe arrest of B-cell development in the bone marrow. 14 This mouse model shows an arrest at the CD4 Ϫ CD8 Ϫ CD44 Ϫ CD25 ϩ double-negative 3 (DN3) stage of thymocyte differentiation, resulting in thymic atrophy and severe depletion of CD4 ϩ CD8 ϩ double-positive (DP) and mature CD4 ϩ or CD8 ϩ single-positive (SP) cells. As previously observed in OS patients, 15,16 thymi from RAG2 R229Q mice are small, lack corticomedullary demarcation, and show a significant decrease in the expression of autoimmune regulator (AIRE), which induce the transcription of tissue-restricted antigens (TRAs) and plays a key role in the negative selection of autoreactive thymocytes. 17,18 This observation has raised the hypothesis that a defe...
Fragile sites are hot spots for sister chromatid exchanges, translocations, deletions, complex rearrangements, and gene amplification. It has been hypothesized that rearrangements at fragile sites derive from unreplicated regions resulting from stalled forks that escape the ATR replication checkpoint. In the present study, we investigated the role of the Claspin (CLSPN) gene, which codes for an adaptor protein in the ATR pathway, during DNA replication stress in human cells. We show that the inhibition of the CLSPN gene leads to both genome instability and fragile site expression. Following aphidicolin treatment, we found a transient increase of Claspin synthesis due to its requirement to checkpoint activation. However, Claspin synthesis decreased after a prolonged aphidicolin treatment. We propose that CLSPN modulation, following an extreme replication block, allows rare cells to escape checkpoint mechanisms and enter mitosis with a defect in genome assembly. Our observations provide the basis for a better understanding of cell cycle checkpoints deregulation in cancer.
Cell fusion between neoplastic and normal cells has been suggested to play a role in the acquisition of a malignant phenotype. Several studies have pointed to the macrophage as the normal partner in this fusion, suggesting that the fused cells could acquire new invasive properties and become able to disseminate to distant organs. However, this conclusion is mainly based on studies with transplantable cell lines. We tested the occurrence of cell fusion in the MMTV-neu model of mouse mammary carcinoma. In the first approach, we generated aggregation chimeras between GFP/neu and RFP/neu embryos. Tumor cells would display both fluorescent proteins only if cell fusion with normal cells occurred. In addition, if cell fusion conferred a growth/dissemination advantage, cells with both markers should be detectable in lung metastases at increased frequency. We confirmed that fused cells are present at low but consistent levels in primary neoplasms and that the macrophage is the normal partner in the fusion events. Similar results were obtained using a second approach in which bone marrow from mice carrying the Cre transgene was transplanted into MMTV-neu/LoxP-tdTomato transgenic animals, in which the Tomato gene is activated only in the presence of CRE recombinase. However, no fused cells were detected in lung metastases in either model. We conclude that fusion between macrophages and tumor cells does not confer a selective advantage in our spontaneous model of breast cancer, although these data do not rule out a possible role in models in which an inflammation environment is prominent.
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