10 research outputs found
Approaches to link RNA secondary structures with splicing regulation
In higher eukaryotes, alternative splicing is usually regulated by protein
factors, which bind to the pre-mRNA and affect the recognition of splicing
signals. There is recent evidence that the secondary structure of the pre-mRNA
may also play an important role in this process, either by facilitating or by
hindering the interaction with factors and small nuclear ribonucleoproteins
(snRNPs) that regulate splicing. Moreover, the secondary structure could play a
fundamental role in the splicing of yeast species, which lack many of the
regulatory splicing factors present in metazoans. This review describes the
steps in the analysis of the secondary structure of the pre-mRNA and its
possible relation to splicing. As a working example, we use the case of yeast
and the problem of the recognition of the 3-prime splice site.Comment: 21 pages, 7 figure
The Calm Mouse: An Animal Model of Stress Reduction
Chronic stress is associated with negative health outcomes and is linked with neuroendocrine changes, deleterious effects on innate and adaptive immunity, and central nervous system neuropathology. Although stress management is commonly advocated clinically, there is insufficient mechanistic understanding of how decreasing stress affects disease pathogenesis. Therefore, we have developed a “calm mouse model” with caging enhancements designed to reduce murine stress. Male BALB/c mice were divided into four groups: control (Cntl), standard caging; calm (Calm), large caging to reduce animal density, a cardboard nest box for shelter, paper nesting material to promote innate nesting behavior, and a polycarbonate tube to mimic tunneling; control exercise (Cntl Ex), standard caging with a running wheel, known to reduce stress; and calm exercise (Calm Ex), calm caging with a running wheel. Calm, Cntl Ex and Calm Ex animals exhibited significantly less corticosterone production than Cntl animals. We also observed changes in spleen mass, and in vitro splenocyte studies demonstrated that Calm Ex animals had innate and adaptive immune responses that were more sensitive to acute handling stress than those in Cntl. Calm animals gained greater body mass than Cntl, although they had similar food intake, and we also observed changes in body composition, using magnetic resonance imaging. Together, our results suggest that the Calm mouse model represents a promising approach to studying the biological effects of stress reduction in the context of health and in conjunction with existing disease models