AB3036 Sigma-AldrichAnti-Uncoupling Protein 1 Antibody

The functional contribution of CNV to human biology and disease pathophysiology has undergone limited exploration. Recent observations in humans indicate a tentative link between CNV and weight regulation. Smith-Magenis syndrome (SMS), manifesting obesity and hypercholesterolemia, results from a deletion CNV at 17p11.2, but is sometimes due to haploinsufficiency of a single gene, RAI1. The reciprocal duplication in 17p11.2 causes Potocki-Lupski syndrome (PTLS). We previously constructed mouse strains with a deletion, Df(11)17, or duplication, Dp(11)17, of the mouse genomic interval syntenic to the SMS/PTLS region. We demonstrate that Dp(11)17 is obesity-opposing; it conveys a highly penetrant, strain-independent phenotype of reduced weight, leaner body composition, lower TC/LDL, and increased insulin sensitivity that is not due to alteration in food intake or activity level. When fed with a high-fat diet, Dp(11)17/+ mice display much less weight gain and metabolic change than WT mice, demonstrating that the Dp(11)17 CNV protects against metabolic syndrome. Reciprocally, Df(11)17/+ mice with the deletion CNV have increased weight, higher fat content, decreased HDL, and reduced insulin sensitivity, manifesting a bona fide metabolic syndrome. These observations in the deficiency animal model are supported by human data from 76 SMS subjects. Further, studies on knockout/transgenic mice showed that the metabolic consequences of Dp(11)17 and Df(11)17 CNVs are not only due to dosage alterations of Rai1, the predominant dosage-sensitive gene for SMS and likely also PTLS. Our experiments in chromosome-engineered mouse CNV models for human genomic disorders demonstrate that a CNV can be causative for weight/metabolic phenotypes. Furthermore, we explored the biology underlying the contribution of CNV to the physiology of weight control and energy metabolism. The high penetrance, strain independence, and resistance to dietary influences associated with the CNVs in this study are features distinct from most SNP-associated metabolic traits and further highlight the potential importance of CNV in the etiology of both obesity and MetS as well as in the protection from these traits.

PPARgamma and pRB play an important role in the development of adipose cells, and functional modification of these proteins may lead to beneficial changes in adipose cell physiology. In the present work, we show that over-expression of EID1 (E1A-like inhibitor of differentiation), an inhibitor of muscle cell differentiation, reduces PPARgamma ligand-dependent transactivation and decreases triglyceride stores in pre-adipocytes (3T3-L1 cells). Additionally, we found that EID1 binds to pRB at the onset of adipocyte differentiation and may act to reduce pRB levels. Over-expression of EID1 in 3T3-L1 cells leads to increased expression of UCP1 and PGC-1alpha, both of which are involved in caloric dissipation and thermogenesis, in brown adipose tissue. These results indicate that EID1 is able to reduce fat accumulation in adipose cells and induce expression of brown fat genes in pre-adipocytes (3T3-L1 cells) normally destined to become white fat cells. The functional reduction of PPARgamma and pRB mediated by EID1 in adipose cells may play an important role in insulin resistance and the metabolic syndrome.

A mitochondrial protein called uncoupling protein (UCP1) plays an important role in generating heat and burning calories by creating a pathway that allows dissipation of the proton electrochemical gradient across the inner mitochondrial membrane in brown adipose tissue, without coupling to any other energy-consuming process. This pathway has been implicated in the regulation of body temperature, body composition and glucose metabolism. However, UCP1-containing brown adipose tissue is unlikely to be involved in weight regulation in adult large-size animals and humans living in a thermoneutral environment (one where an animal does not have to increase oxygen consumption or energy expenditure to lose or gain heat to maintain body temperature), as there is little brown adipose tissue present. We now report the discovery of a gene that codes for a novel uncoupling protein, designated UCP2, which has 59% amino-acid identity to UCP1, and describe properties consistent with a role in diabetes and obesity. In comparison with UCP1, UCP2 has a greater effect on mitochondrial membrane potential when expressed in yeast. Compared to UCP1, the gene is widely expressed in adult human tissues, including tissues rich in macrophages, and it is upregulated in white fat in response to fat feeding. Finally, UCP2 maps to regions of human chromosome 11 and mouse chromosome 7 that have been linked to hyperinsulinaemia and obesity. Our findings suggest that UCP2 has a unique role in energy balance, body weight regulation and thermoregulation and their responses to inflammatory stimuli.

The uncoupling protein (UCP) of brown adipose tissue mitochondria is a specialized member of the family of evolutionarily related mitochondrial membrane transporters, which also includes the ADP/ATP translocator and the phosphate carrier. We have generated a library of bacterial clones randomly expressing short subsequences of the UCP fused to the MalE periplasmic protein of Escherichia coli. Anti-UCP sera were used to select clones expressing antigenic sequences of the UCP. Ten different fusion proteins representing eight non-overlapping subsequences of the UCP were obtained. The ability of fusion proteins to select antibodies directed against a short segment of the UCP was used to study the topological organization of the UCP in the inner mitochondrial membrane. Four different fusion proteins were used to determine the orientation of the N-terminal extremities of the first, second, third and fourth predicted alpha-helices of the UCP. This topological study together with previous data on the UCP provides an experimental basis for the predicted structure of the UCP and for other homologous carrier proteins.

The mitochondrial uncoupling protein, a protein essential for the thermogenic properties of brown fat in mammals, is inserted in the inner mitochondrial membrane by means of six alpha-helical hydrophobic transmembrane domains. We have sequenced a complete cDNA and parts of the gene to determine that the mitochondrial uncoupling protein gene is composed of six exons, each of which encodes a transmembrane domain. We also show that transcription of the uncoupling protein gene is from a single start site; however, the use of alternative poly(A) addition signal sequences results in two mRNAs, the major species of 1221 nucleotides, not including the poly(A) tail, and a minor species of about 1600 nucleotides. The 5'-untranslated region of the mRNA is composed of 231 nucleotides, and the 3'-untranslated region contains 81 nucleotides prior to addition of the poly(A) tail.