Silencing of OB-RGRP in mouse hypothalamic arcuate nucleus increases leptin receptor signaling and prevents diet-induced obesity.

Obesity is a major public health problem and is often associated with type 2 diabetes mellitus, cardiovascular disease, and metabolic syndrome. Leptin is the crucial adipostatic hormone that controls food intake and body weight through the activation of specific leptin receptors (OB-R) in the hypothalamic arcuate nucleus (ARC). However, in most obese patients, high circulating levels of leptin fail to bring about weight loss. The prevention of this "leptin resistance" is a major goal for obesity research. We report here a successful prevention of diet-induced obesity (DIO) by silencing a negative regulator of OB-R function, the OB-R gene-related protein (OB-RGRP), whose transcript is genetically linked to the OB-R transcript. We provide in vitro evidence that OB-RGRP controls OB-R function by negatively regulating its cell surface expression. In the DIO mouse model, obesity was prevented by silencing OB-RGRP through stereotactic injection of a lentiviral vector encoding a shRNA directed against OB-RGRP in the ARC. This work demonstrates that OB-RGRP is a potential target for obesity treatment. Indeed, regulators of the receptor could be more appropriate targets than the receptor itself. This finding could serve as the basis for an approach to identifying potential new therapeutic targets for a variety of diseases, including obesity.

Identification of new drug sensitivity genes using genetic suppressor elements: protein arginine N-methyltransferase mediates cell sensitivity to DNA-damaging agents.

Genetic suppressor elements (GSEs) are cDNA fragments encoding either truncated proteins, acting as dominant-negative mutants, or inhibitory antisense RNA segments counteracting with the gene from which they are derived. To identify genes controlling the cell response to cytotoxic agents, a normalized retroviral library of randomly fragmented cDNAs from Chinese hamster cell line DC-3F was screened for GSEs conferring resistance to the topoisomerase II inhibitor 9-OH-ellipticine. From 218 cDNA fragments isolated, 11 functional GSEs, corresponding to at least 8 independent genes, were selected. The gene corresponding to the most abundant GSE encodes two proteins, p77 and p82, highly homologous to proteins detected in various species and carrying the sequence motifs characteristic of the protein arginine N-methyltransferase family. Furthermore, a methylase activity was observed on myelin basic protein in immunoprecipitates of hemagglutinin-tagged p77 and p82. Therefore, p77 and p82 are the first identified members of a new protein arginine N-methyltransferase family. A decreased expression of these enzymes is associated with either resistance or hypersensitivity to a broad range of DNA-damaging agents. Our data indicate that down-regulation of these enzymes in the GSE-expressing cells would alter one or several steps downstream of the drug-target interaction in the drug-response pathway.