Publications (2)31.2 Total impact
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Article: Thyroid hormone receptor repression is linked to type I pneumocyte-associated respiratory distress syndrome.
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ABSTRACT: Although the lung is a defining feature of air-breathing animals, the pathway controlling the formation of type I pneumocytes, the cells that mediate gas exchange, is poorly understood. In contrast, the glucocorticoid receptor and its cognate ligand have long been known to promote type II pneumocyte maturation; prenatal administration of glucocorticoids is commonly used to attenuate the severity of infant respiratory distress syndrome (RDS). Here we show that knock-in mutations of the nuclear co-repressor SMRT (silencing mediator of retinoid and thyroid hormone receptors) in C57BL/6 mice (SMRTmRID) produces a previously unidentified respiratory distress syndrome caused by prematurity of the type I pneumocyte. Though unresponsive to glucocorticoids, treatment with anti-thyroid hormone drugs (propylthiouracil or methimazole) completely rescues SMRT-induced RDS, suggesting an unrecognized and essential role for the thyroid hormone receptor (TR) in lung development. We show that TR and SMRT control type I pneumocyte differentiation through Klf2, which, in turn, seems to directly activate the type I pneumocyte gene program. Conversely, mice without lung Klf2 lack mature type I pneumocytes and die shortly after birth, closely recapitulating the SMRTmRID phenotype. These results identify TR as a second nuclear receptor involved in lung development, specifically type I pneumocyte differentiation, and suggest a possible new type of therapeutic option in the treatment of RDS that is unresponsive to glucocorticoids.Nature medicine 01/2011; 17(11):1466-72. · 27.14 Impact Factor -
Article: Two isoforms of the cold-inducible mRNA-binding protein RBM3 localize to dendrites and promote translation.
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ABSTRACT: A diverse set of mRNA-binding proteins (BPs) regulate local translation in neurons. However, little is known about the role(s) played by a family of cold-inducible, glycine-rich mRNA-BPs. Unlike neuronal mRNA-BPs characterized thus far, these proteins are induced by hypothermia and are comprised of one RNA recognition motif and an adjacent arginine- and glycine-rich domain. We studied the expression and function of the RNA-binding motif protein 3 (RBM3), a member of this family, in neurons. RBM3 was expressed in multiple brain regions, with the highest levels in cerebellum and olfactory bulb. In dissociated neurons, RBM3 was observed in nuclei and in a heterogeneous population of granules within dendrites. In sucrose gradient assays, RBM3 cofractionated with heavy mRNA granules and multiple components of the translation machinery. Two alternatively spliced RBM3 isoforms that differed by a single arginine residue were identified in neurons; both were post-translationally modified. The variant lacking the spliced arginine exhibited a higher dendritic localization and was the only isoform present in astrocytes. When overexpressed in neuronal cell lines, RBM3 isoforms-enhanced global translation, the formation of active polysomes, and the activation of initiation factors. These data suggest that RBM3 plays a distinctive role in enhancing translation in neurons.Journal of Neurochemistry 06/2007; 101(5):1367-79. · 4.06 Impact Factor
