Fmr1 exon 14 skipping in late embryonic development of the rat forebrain.

BACKGROUND: Fragile X syndrome, the major cause of inherited intellectual disability among men, is due to deficiency of the synaptic functional regulator FMR1 protein (FMRP), encoded by the FMRP translational regulator 1 (FMR1) gene. FMR1 alternative splicing produces distinct transcripts that may consequently impact FMRP functional roles. In transcripts without exon 14 the translational reading frame is shifted. For deepening current knowledge of the differential expression of Fmr1 exon 14 along the rat nervous system development, we conducted a descriptive study employing quantitative RT-PCR and BLAST of RNA-Seq datasets. RESULTS: We observed in the rat forebrain progressive decline of total Fmr1 mRNA from E11 to P112 albeit an elevation on P3; and exon-14 skipping in E17-E20 with downregulation of the resulting mRNA. We tested if the reduced detection of messages without exon 14 could be explained by nonsense-mediated mRNA decay (NMD) vulnerability, but knocking down UPF1, a major component of this pathway, did not increase their quantities. Conversely, it significantly decreased FMR1 mRNA having exon 13 joined with either exon 14 or exon 15 site A. CONCLUSIONS: The forebrain in the third embryonic week of the rat development is a period with significant skipping of Fmr1 exon 14. This alternative splicing event chronologically precedes a reduction of total Fmr1 mRNA, suggesting that it may be part of combinatorial mechanisms downregulating the gene's expression in the late embryonic period. The decay of FMR1 mRNA without exon 14 should be mediated by a pathway different from NMD. Finally, we provide evidence of FMR1 mRNA stabilization by UPF1, likely depending on FMRP.

The pulsed dye laser for the treatment of basal cell carcinoma.

Basal cell carcinomas (BCC) have a specialized microvasculature system that can be targeted by the 585-nm pulsed dye laser (PDL) utilizing the theory of selective photothermolysis. Seven volunteers with nine well-defined, biopsy-proven BCCs, were treated with the PDL (585-nm wavelength, a single 450-µs pulse, 7-mm spot size, and 9.0 J/cm(2) energy). The lesions, along with a 4-mm border of normal skin were treated. Pain assessment was carried out immediately after the laser treatment. A deep shave biopsy with histological examination occurred 4 weeks after the laser treatment. Pain was assessed on a scale of 0 (no pain) to 10 (worst pain possible). The average patient score was 2.1 (range 1-4). On histology, 5/9 (55.6%) sites demonstrated no evidence of BCC; however, 4/9 (44.4%) sites showed residual BCC. Although the PDL was able to clear over half of the BCCs in this study, there was an unacceptably high persistence rate of 44.4%. The PDL did not achieve the clearance rate that can be attained with current standard BCC treatment modalities. At this time, we do not recommend that a single treatment with the 585-nm PDL can be used as a primary therapy for BCC.

Epigenetic signature of differentially methylated genes in cutaneous melanoma

Background: Cutaneous melanoma (CM) is the most aggressive subtype of skin cancer, with increasing incidence over the past several decades. DNA methylation is a key element of several biological processes such as genomic imprinting, cell differentiation and senescence, and deregulation of this mechanism has been implicated in several diseases, including cancer. In order to understand the relationship of DNA methylation in CMs, we searched for an epigenetic signature of cutaneous melanomas by comparing the DNA methylation profiles between tumours and benign melanocytes, the precursor cells of CM. Methods: We used 20 primary CMs and three primary cell cultures of melanocytes as a discovery cohort. The tumours mutational background was collected as previously reported. Methylomes were obtained using the HM450K DNA methylation assay, and differential methylation analysis was performed. DNA methylation data of CMs from TCGA were recovered to validate our findings. Results: A signature of 514 differentially methylated genes (DMGs) was evident in CMs compared to melanocytes, which was independent of the presence of driver mutations. Pathway analysis of this CM signature revealed an enrichment of proteins involved in the binding of DNA regulatory regions (hypermethylated sites), and related to transmembrane signal transducer activities (hypomethylated sites). The methylation signature was validated in an independent dataset of primary CMs, as well as in lymph node and distant metastases (correlation of DNA methylation level: r > 0,95; Pearson's test: p < 2.2e-16). Conclusions: CMs exhibited a DMGs signature, which was independent of the mutational background and possibly established prior to genetic alterations. This signature provides important insights into how epigenetic deregulation contributes to melanomagenesis in general (AU)