PRDM16

PR domain containing 16, also known as PRDM16, is a is_associated_with::protein which in humans is encoded by the PRDM16 is_associated_with::gene.

PRDM16 acts as a transcription coregulator that controls the development of brown adipocytes in is_associated_with::brown adipose tissue. Previously, this coregulator was believed to be present only in brown adipose tissue, but more recent studies have shown that PRDM16 is highly expressed in subcutaneous is_associated_with::white adipose tissue as well.

Function
The protein encoded by this gene is a is_associated_with::zinc finger is_associated_with::transcription factor. PRDM16 controls the cell fate between muscle and brown fat cells. Loss of PRDM16 from brown fat precursors causes a loss of brown fat characteristics and promotes muscle differentiation.

Clinical significance
The reciprocal translocation t(1;3)(p36;q21) occurs in a subset of is_associated_with::myelodysplastic syndrome (MDS) and is_associated_with::acute myeloid leukemia (AML). This gene is located near the 1p36.3 breakpoint and has been shown to be specifically expressed in the t(1:3)(p36,q21)-positive MDS/AML. The protein encoded by this gene contains an N-terminal PR domain. The translocation results in the overexpression of a truncated version of this protein that lacks the PR domain, which may play an important role in the pathogenesis of MDS and AML. Alternatively spliced transcript variants encoding distinct isoforms have been reported.

PRDM16 in BAT
Brown adipose tissue (BAT) oxidizes chemical energy to produce heat. This heat energy can act as a defense against hypothermia and obesity. PRDM16 is highly enriched in brown adipose cells as compared to white adipose cells, and plays a role in these is_associated_with::thermogenic processes in brown adipose tissue. PRDM16 activates brown fat cell identity and can control the determination of brown adipose fate. A knock-out of PRDM16 in mice shows a loss of brown cell characteristics, showing that PRDM16 activity is important in determining brown adipose fate. Brown adipocytes consist of densely packed mitochondria that contain is_associated_with::uncoupling protein 1 (UCP-1). UCP-1 plays a key role in brown adipocyte thermogenesis. The presence of PRDM16 in adipose tissue causes a significant up-regulation of thermogenic genes, such as UCP-1 and is_associated_with::CIDEA, resulting in thermogenic heat production. Understanding and stimulating the thermogenic processes in brown adipocytes provides possible therapeutic options for treating is_associated_with::obesity.

PRDM16 in WAT
White adipose tissue (WAT) primarily stores excess energy in the form of triglycerides. Recent research has shown that PRDM16 in present in subcutaneous white adipose tissue. The activity of PRDM16 in white adipose tissue leads to the production of brown fat-like adipocytes within white adipose tissue, called Brite Cells (Brown in White cells, or beige cells). These brite cells have a brown adipose tissue-like phenotype and actions, including thermogenic processes seen in BAT. In mice, the levels of PRDM16 within WAT, specifically anterior subcutaneous WAT and inguinal subcutaneous WAT, is about 50% that of interscapular BAT, both in protein expression and in mRNA quantity. This expression takes place primarily within mature adipocytes. is_associated_with::Transgenic aP2-PRDM16 mice were used in a study to observe the effects of PRDM16 expression in WAT. The study found that the presence of PRDM16 in subcutaneous WAT leads to an significant up-regulation of brown-fat selective genes UCP-1, CIDEA, and is_associated_with::PPARGC1A. This up-regulation lead to the development of a BAT-like phenotype within the white adipose tissue. Expression of PRDM16 has also been shown to protect against high-fat diet induced weight gain. Seale et al.’s experiment with aP2-PRDM16 transgenic mice and wild type mice showed that transgenic mice eating a 60% high-fat diet had significantly less weight gain than wild type mice on the same diet. Seale et al. determined the weight difference was not due to differences in food intake, as both transgenic and wild type mice were consuming the same amount of food on a daily basis. Rather, the weight difference stemmed from higher energy expenditure in the transgenic mice. Another of Seale et al.’s experiments showed the transgenic mice consumed a greater volume of oxygen over a 72-hour period than the wild type mice, showing a greater amount of energy expenditure in the transgenic mice. This energy expenditure in turn is attributed to PRDM16’s ability to up-regulate UCP-1 and CIDEA gene expression, resulting in thermogenesis.

If human WAT expresses PRDM16 as in mice, this WAT could be a potential target for stimulating energy expenditure and combating obesity.