Directed Alternative Splicing in Nijmegen Breakage Syndrome: Proof of Principle Concerning Its Therapeutical Application.

Over 90% of patients with Nijmegen breakage syndrome (NBS), a hereditary cancer disorder, are homoallelic for a 5 bp deletion in the NBN gene involved in the cellular response to DNA damage. This hypomorphic mutation leads to a carboxy-terminal protein fragment, p70-nibrin, with some residual function. Average age at malignancy, typically lymphoma, is 9.7 years. NBS patients are hypersensitive to chemotherapeutic and radiotherapeutic treatments, thus prevention of cancer development is of particular importance. Expression of an internally deleted NBN protein, p80-nibrin, has been previously shown to be associated with a milder cellular phenotype and absence of cancer in a 62-year-old NBS patient. Here we show that cells from this patient, unlike other NBS patients, have DNA replication and origin firing rates comparable to control cells. We used here antisense oligonucleotides to enforce alternative splicing in NBS patient cells and efficiently generate the same internally deleted p80-nibrin protein. Injecting the same antisense sequences as morpholino oligomers (VivoMorpholinos) into the tail vein of a humanized NBS murine mouse model also led to efficient alternative splicing in vivo. Thus, proof of principle for the use of antisense oligonucleotides as a potential cancer prophylaxis has been demonstrated.

Body mass index affects connexin43 remodeling in patients with atrial fibrillation.

BACKGROUND: Increased body mass index (BMI) is often found to be a risk factor for cardiac disease. However, it is unclear whether BMI also affects the gap junction remodeling process in atrial fibrillation (AF). The aim of the study was to see if BMI can influence the connexin43 (Cx43) distribution in patients with sinus rhythm (SR) and AF. METHODS: We investigated a total of 51 white Caucasian patients of both gender (mean age: 69 years, 30% diabetes mellitus, ejection fraction [EF] > 50%) with SR or AF, with either BMI < 27 or ≥ 27 undergoing cardiac surgery for mitral valve repair, aortic valve repair, or coronary heart disease. We obtained human right atrial tissue for immunohistochemistry and investigated the CX43-positive polar and lateral membrane length in the different BMI (BMI < 27, BMI ≥ 27) and rhythm groups (SR or AF). RESULTS: In lean SR patients, Cx43 (BMI < 27) was found mainly at the cell poles while only 2% of the lateral membrane stained positive for Cx43. In obese SR patients (BMI > 27), 6.7 ± 0.7% of the lateral membrane was positive (p < 0.05). In AF generally, there was significantly more lateral Cx43 staining, which was significantly enhanced in obese AF patients. In lean AF patients, lateral Cx43 positivity increased to 14 ± 1% (p < 0.05), while in BMI > 27 AF patients, this was significantly enhanced to 22 ± 2% (p < 0.05). The BMI effect was independent from left atrial diameter, EF, and comorbidity. CONCLUSIONS: Enhanced BMI is associated with increased remodeling effects of AF on irregular Cx43 distribution.

Sterol regulatory element-binding proteins are regulators of the rat thyroid peroxidase gene in thyroid cells.

Sterol regulatory element-binding proteins (SREBPs)-1c and -2, which were initially discovered as master transcriptional regulators of lipid biosynthesis and uptake, were recently identified as novel transcriptional regulators of the sodium-iodide symporter gene in the thyroid, which is essential for thyroid hormone synthesis. Based on this observation that SREBPs play a role for thyroid hormone synthesis, we hypothesized that another gene involved in thyroid hormone synthesis, the thyroid peroxidase (TPO) gene, is also a target of SREBP-1c and -2. Thyroid epithelial cells treated with 25-hydroxycholesterol, which is known to inhibit SREBP activation, had about 50% decreased mRNA levels of TPO. Similarly, the mRNA level of TPO was reduced by about 50% in response to siRNA mediated knockdown of both, SREBP-1 and SREBP-2. Reporter gene assays revealed that overexpression of active SREBP-1c and -2 causes a strong transcriptional activation of the rat TPO gene, which was localized to an approximately 80 bp region in the intron 1 of the rat TPO gene. In vitro- and in vivo-binding of both, SREBP-1c and SREBP-2, to this region in the rat TPO gene could be demonstrated using gel-shift assays and chromatin immunoprecipitation. Mutation analysis of the 80 bp region of rat TPO intron 1 revealed two isolated and two overlapping SREBP-binding elements from which one, the overlapping SRE+609/InvSRE+614, was shown to be functional in reporter gene assays. In connection with recent findings that the rat NIS gene is also a SREBP target gene in the thyroid, the present findings suggest that SREBPs may be possible novel targets for pharmacological modulation of thyroid hormone synthesis.

Sterol regulatory element-binding proteins are regulators of the NIS gene in thyroid cells.

The uptake of iodide into the thyroid, an essential step in thyroid hormone synthesis, is an active process mediated by the sodium-iodide symporter (NIS). Despite its strong dependence on TSH, the master regulator of the thyroid, the NIS gene was also reported to be regulated by non-TSH signaling pathways. In the present study we provide evidence that the rat NIS gene is subject to regulation by sterol regulatory element-binding proteins (SREBPs), which were initially identified as master transcriptional regulators of lipid biosynthesis and uptake. Studies in FRTL-5 thyrocytes revealed that TSH stimulates expression and maturation of SREBPs and expression of classical SREBP target genes involved in lipid biosynthesis and uptake. Almost identical effects were observed when the cAMP agonist forskolin was used instead of TSH. In TSH receptor-deficient mice, in which TSH/cAMP-dependent gene regulation is blocked, the expression of SREBP isoforms in the thyroid was markedly reduced when compared with wild-type mice. Sterol-mediated inhibition of SREBP maturation and/or RNA interference-mediated knockdown of SREBPs reduced expression of NIS and NIS-specific iodide uptake in FRTL-5 cells. Conversely, overexpression of active SREBPs caused a strong activation of the 5'-flanking region of the rat NIS gene mediated by binding to a functional SREBP binding site located in the 5'-untranslated region of the rat NIS gene. These findings show that TSH acts as a regulator of SREBP expression and maturation in thyroid epithelial cells and that SREBPs are novel transcriptional regulators of NIS.

Clinical variability and novel mutations in the NHEJ1 gene in patients with a Nijmegen breakage syndrome-like phenotype.

We have previously shown that mutations in the genes encoding DNA Ligase IV (LIGIV) and RAD50, involved in DNA repair by nonhomologous-end joining (NHEJ) and homologous recombination, respectively, lead to clinical and cellular features similar to those of Nijmegen Breakage Syndrome (NBS). Very recently, a new member of the NHEJ repair pathway, NHEJ1, was discovered, and mutations in patients with features resembling NBS were described. Here we report on five patients from four families of different ethnic origin with the NBS-like phenotype. Sequence analysis of the NHEJ1 gene in a patient of Spanish and in a patient of Turkish origin identified homozygous, previously reported mutations, c.168C>G (p.Arg57Gly) and c.532C>T (p.Arg178Ter), respectively. Two novel, paternally inherited truncating mutations, c.495dupA (p.Asp166ArgfsTer20) and c.526C>T (p.Arg176Ter) and two novel, maternal genomic deletions of 1.9 and 6.9 kb of the NHEJ1 gene, were found in a compound heterozygous state in two siblings of German origin and in one Malaysian patient, respectively. Our findings confirm that patients with NBS-like phenotypes may have mutations in the NHEJ1 gene including multiexon deletions, and show that considerable clinical variability could be observed even within the same family.

SV40 large T-antigen disturbs the formation of nuclear DNA-repair foci containing MRE11.

The accumulation of DNA repair proteins at the sites of DNA damage can be visualized in mutagenized cells at the single cell level as discrete nuclear foci by immunofluorescent staining. Formation of nuclear foci in irradiated human fibroblasts, as detected by antibodies directed against the DNA repair protein MRE11, is significantly disturbed by the presence of the viral oncogene, SV40 large T-antigen. The attenuation of foci formation was found in both T-antigen immortalized cells and in cells transiently expressing T-antigen, indicating that it is not attributable to secondary mutations but to T-antigen expression itself. ATM-mediated nibrin phosphorylation was not altered, thus the disturbance of MRE11 foci formation by T-antigen is independent of this event. The decrease in MRE11 foci was particularly pronounced in T-antigen immortalized cells from the Fanconi anaemia complementation group FA-D2. FA-D2 cells produce essentially no MRE11 DNA repair foci after ionizing irradiation and have a significantly increased cellular radiosensitivity at low radiation doses. The gene mutated in FA-D2 cells, FANCD2, codes for a protein which also locates to nuclear foci and may, therefore, be involved in MRE11 foci formation, at least in T-antigen immortalized cells. This finding possibly links Fanconi anaemia proteins to the frequently reported increased sensitivity of Fanconi anaemia cells to transformation by SV40. From a practical stand point these findings are particularly relevant to the many studies on DNA repair which exploit the advantages of SV40 immortalized cell lines. The interference of T-antigen with DNA repair processes, as demonstrated here, should be borne in mind when interpreting such studies.

Attenuation of the formation of DNA-repair foci containing RAD51 in Fanconi anaemia.

The role of the Fanconi anaemia genes in DNA repair was examined by a quantitative analysis of nuclear DNA repair foci in FA primary fibroblasts after ionising irradiation using antibodies directed against RAD51, MRE11 and BRCA1 for visualisation. IR induced foci detected with anti-RAD51, but not those detected with anti-MRE11, are reduced in fibroblasts of all eight FA complementation groups in comparison to control cells. Correction of FA-A, FA-C and FA-G cells by retroviral cDNA transfer specifically corrected the RAD51-foci response but did not affect formation of foci containing BRCA1 or MRE11. Since all FA cells, except FA-D1, lack the monoubiquitinated FANCD2-L protein, this isoform is likely to be involved in the formation of nuclear foci containing RAD51 in diploid FA cells. FA-D1 cells show the same attenuation in RAD51 foci formation, suggesting that the unknown FANCD1 protein is similarly involved in RAD51 foci formation, either independently or as a subsequent step in the FANCD2 pathway. These findings indicate that Fanconi anaemia cells have an impairment in the RAD51-dependent homologous recombination pathway for DNA repair, explaining their chromosomal instability and extreme sensitivity to DNA cross-linking agents.