Protection from ß-cell apoptosis by inhibition of TGF-ß/Smad3 signaling.

Prevailing insulin resistance and the resultant hyperglycemia elicits a compensatory response from pancreatic islet beta cells (ß-cells) that involves increases in ß-cell function and ß-cell mass. However, the sustained metabolic stress eventually leads to ß-cell failure characterized by severe ß-cell dysfunction and progressive loss of ß-cell mass. Whereas, ß-cell dysfunction is relatively well understood at the mechanistic level, the avenues leading to loss of ß-cell mass are less clear with reduced proliferation, dedifferentiation, and apoptosis all potential mechanisms. Butler and colleagues documented increased ß-cell apoptosis in pancreas from lean and obese human Type 2 diabetes (T2D) subjects, with no changes in rates of ß-cell replication or neogenesis, strongly suggesting a role for apoptosis in ß-cell failure. Here, we describe a permissive role for TGF-ß/Smad3 in ß-cell apoptosis. Human islets undergoing ß-cell apoptosis release increased levels of TGF-ß1 ligand and phosphorylation levels of TGF-ß's chief transcription factor, Smad3, are increased in human T2D islets suggestive of an autocrine role for TGF-ß/Smad3 signaling in ß-cell apoptosis. Smad3 phosphorylation is similarly increased in diabetic mouse islets undergoing ß-cell apoptosis. In mice, ß-cell-specific activation of Smad3 promotes apoptosis and loss of ß-cell mass in association with ß-cell dysfunction, glucose intolerance, and diabetes. In contrast, inactive Smad3 protects from apoptosis and preserves ß-cell mass while improving ß-cell function and glucose tolerance. At the molecular level, Smad3 associates with Foxo1 to propagate TGF-ß-dependent ß-cell apoptosis. Indeed, genetic or pharmacologic inhibition of TGF-ß/Smad3 signals or knocking down Foxo1 protects from ß-cell apoptosis. These findings reveal the importance of TGF-ß/Smad3 in promoting ß-cell apoptosis and demonstrate the therapeutic potential of TGF-ß/Smad3 antagonism to restore ß-cell mass lost in diabetes.

Functional and structural characterization of the chikungunya virus translational recoding signals.

Climate change and human globalization have spurred the rapid spread of mosquito-borne diseases to naïve populations. One such emerging virus of public health concern is chikungunya virus (CHIKV), a member of the Togaviridae family, genus Alphavirus CHIKV pathogenesis is predominately characterized by acute febrile symptoms and severe arthralgia, which can persist in the host long after viral clearance. CHIKV has also been implicated in cases of acute encephalomyelitis, and its vertical transmission has been reported. Currently, no FDA-approved treatments exist for this virus. Recoding elements help expand the coding capacity in many viruses and therefore represent potential therapeutic targets in antiviral treatments. Here, we report the molecular and structural characterization of two CHIKV translational recoding signals: a termination codon read-through (TCR) element located between the nonstructural protein 3 and 4 genes and a programmed -1 ribosomal frameshift (-1 PRF) signal located toward the 3' end of the CHIKV 6K gene. Using Dual-Luciferase and immunoblot assays in HEK293T and U87MG mammalian cell lines, we validated and genetically characterized efficient TCR and -1 PRF. Analyses of RNA chemical modification data with selective 2'-hydroxyl acylation and primer extension (SHAPE) assays revealed that CHIKV -1 PRF is stimulated by a tightly structured, triple-stem hairpin element, consistent with previous observations in alphaviruses, and that the TCR signal is composed of a single large multibulged hairpin element. These findings illuminate the roles of RNA structure in translational recoding and provide critical information relevant for design of live-attenuated vaccines against CHIKV and related viruses.