Cloning of BUG demonstrates the existence of a brown preadipocyte distinct from a white one.

BACKGROUND: Several indirect arguments agree with the existence of a brown preadipocyte distinct from a white one. Nevertheless, to date, no molecular marker has been available to directly in vivo demonstrate this hypothesis. OBJECTIVE: The aim of this study was to find a gene expressed in brown preadipocyte but not in white and to use it as a molecular marker to analyse brown preadipocyte recruitment in different physiological and physiopathological situations. METHOD: Differential display was performed on stromal-vascular and adipocyte fractions of white and brown adipose tissues in rat. RESULTS: We identified a new gene, BUG, preferentially expressed in the stromal-vascular fraction of brown fat vs other adipose tissues fractions in adult rat. This RNA is also highly expressed in heart and, to a lesser extent, in other tissues such as kidney and brain. The BUG transcript is detected by in situ hybridization in putative preadipocytes within brown adipose tissue. Its level is transiently and specifically up-regulated during early stages of brown preadipocyte differentiation in a primary culture system, before the acquisition of late brown adipocyte phenotype. During development, BUG can be detected before the emergence of UCP-1 expression. In adult rats, BUG expression is inversely associated to brown adipose tissue (BAT) activation during cold exposure as well as in obese animals. CONCLUSIONS: The pattern of BUG expression agrees with an early divergence between brown and white adipocyte lineages. It also reveals the existence of a pool of committed brown preadipocytes within BAT that are recruited during cold exposure. BUG expression is increased in obese animals, suggesting that an early defect in brown preadipocyte differentiation could account for impaired BAT function in genetically obese rats.

Brown fat UCP1 is specifically expressed in uterine longitudinal smooth muscle cells.

Until now, uncoupling protein 1 (UCP1) was considered as unique to brown adipocytes. It supports a highly regulated uncoupling of oxidative phosphorylation that is associated with diet as well as with non-shivering thermogenesis. Here we report that UCP1 is not specific to brown adipocytes and can be expressed in longitudinal smooth muscle layers. In the uterus, this conclusion was drawn from different convergent data. A specific antibody against mouse UCP1 revealed, in mitochondrial fractions, a protein with the same molecular weight as brown fat UCP1. Sensitive and specific reverse transcriptase-polymerase chain reaction detected a mRNA whose sequence was totally homologous to that of brown fat UCP1 mRNA. Antibody against UCP1 as well as a UCP1 antisense probe specifically stained uterine longitudinal smooth muscles. UCP1 was also expressed in longitudinal smooth muscle of digestive and male reproductive tracts but was never expressed in other types of smooth muscle, including those of arterial vessels. In uterine tract, UCP1 content was increased after cold exposure or beta-adrenergic agonist treatment. It was also up-regulated during the postovulatory period after sexual cycle synchronization. Its content transiently increased during gestation and decreased markedly after birth. These regulations strongly argue about a role for UCP1 in thermogenesis as well as in relaxation of longitudinal smooth muscle layers.

Emergence during development of the white-adipocyte cell phenotype is independent of the brown-adipocyte cell phenotype.

In mammals, two types of adipose tissue are present, brown and white. They develop sequentially, as brown fat occurs during late gestation whereas white fat grows mainly after birth. However, both tissues have been shown to have great plasticity. Thus an apparent transformation of brown fat into white fat takes place during post-natal development. This observation raises questions about a possible conversion of brown into white adipocytes during development, although indirect data argue against this hypothesis. To investigate such questions in vivo, we generated two types of transgenic line. The first carried a transgene expressing Cre recombinase specifically in brown adipocytes under the control of the rat UCP1 promoter. The second corresponded to an inactive lacZ gene under the control of the human cytomegalovirus promoter. This dormant gene is inducible by Cre because it contains a Stop sequence between two loxP sequences, separating the promoter from the coding sequence. Adipose tissues of progeny derived by crossing independent lines established from both constructs were investigated. LacZ mRNA corresponding to the activated reporter gene was easily detected in brown fat and not typically in white fat, even by reverse transcriptase PCR experiments. These data represent the first direct experimental proof that, during normal development, most white adipocytes do not derive from brown adipocytes.

Inverse distribution of uncoupling proteins expression and oxidative capacity in mature adipocytes and stromal-vascular fractions of rat white and brown adipose tissues.

To investigate relationships between the uncoupling protein (UCP) family and oxidative metabolism in fat pads, we measured the cytochrome oxidase activity, used as an index of oxidative capacity, and the mRNA content encoding UCP1, UCP2 and UCP3. Most oxidative potential was found in the stromal-vascular fraction (SVF) of brown fat and in mature adipocytes of white fat (inguinal and periovarian). Considering the whole fat pads, the oxidative potential observed in mature white adipocytes fraction was not negligible compared with that of brown adipocytes fraction. UCP1 and UCP3 were expressed exclusively in mature brown adipocytes. Whatever the deposit, UCP2 mRNA was mainly localized in the SVF. These results indicate that, in fat, high oxidative potential is not necessarily linked to high UCPs transcripts content and point out the oxidative capacity of SVF from brown fat.