Pleiotropic effects of BAFF on the senescence-associated secretome and growth arrest.

Senescent cells release a variety of cytokines, proteases, and growth factors collectively known as the senescence-associated secretory phenotype (SASP). Sustained SASP contributes to a pattern of chronic inflammation associated with aging and implicated in many age-related diseases. Here, we investigated the expression and function of the immunomodulatory cytokine BAFF (B-cell activating factor; encoded by the TNFSF13B gene), a SASP protein, in multiple senescence models. We first characterized BAFF production across different senescence paradigms, including senescent human diploid fibroblasts (WI-38, IMR-90) and monocytic leukemia cells (THP-1), and tissues of mice induced to undergo senescence. We then identified IRF1 (interferon regulatory factor 1) as a transcription factor required for promoting TNFSF13B mRNA transcription in senescence. We discovered that suppressing BAFF production decreased the senescent phenotype of both fibroblasts and monocyte-like cells, reducing IL6 secretion and SA-ß-Gal staining. Importantly, however, the influence of BAFF on the senescence program was cell type-specific: in monocytes, BAFF promoted the early activation of NF-κB and general SASP secretion, while in fibroblasts, BAFF contributed to the production and function of TP53 (p53). We propose that BAFF is elevated across senescence models and is a potential target for senotherapy.

Rescue of common exon-skipping mutations in cystic fibrosis with modified U1 snRNAs.

In cystic fibrosis (CF), the correction of splicing defects represents an interesting therapeutic approach to restore normal CFTR function. In this study, we focused on 10 common mutations/variants 711+3A>G/C, 711+5G>A, TG13T3, TG13T5, TG12T5, 1863C>T, 1898+3A>G, 2789+5G>A, and 3120G>A that induce skipping of the corresponding CFTR exons 5, 10, 13, 16, and 18. To rescue the splicing defects we tested, in a minigene assay, a panel of modified U1 small nuclear RNAs (snRNAs), named Exon Specific U1s (ExSpeU1s), that was engineered to bind to intronic sequences downstream of each defective exon. Using this approach, we show that all 10 splicing mutations analyzed are efficiently corrected by specific ExSpeU1s. Using complementary DNA-splicing competent minigenes, we also show that the ExspeU1-mediated splicing correction at the RNA level recovered the full-length CFTR protein for 1863C>T, 1898+3A>G, 2789+5G>A variants. In addition, detailed mutagenesis experiments performed on exon 13 led us to identify a novel intronic regulatory element involved in the ExSpeU1-mediated splicing rescue. These results provide a common strategy based on modified U1 snRNAs to correct exon skipping in a group of disease-causing CFTR mutations.