Hepatic expression of the SPOT 14 (S14) paralog S14-related (Mid1 interacting protein) is regulated by dietary carbohydrate.

The Spot 14 (S14) gene is rapidly up-regulated by signals that induce lipogenesis such as enhanced glucose metabolism and thyroid hormone administration. Previous studies in S14 null mice show that S14 is required for normal lipogenesis in the lactating mammary gland, but not the liver. We speculated that the lack of a hepatic phenotype was due to the expression of a compensatory gene. We recently reported that this gene is likely an S14 paralog that we named S14-Related (S14-R). S14-R is expressed in the liver, but not in the mammary gland. If S14-R compensates for the absence of S14 in the liver, we hypothesized that, like S14, S14-R expression should be glucose responsive. Here, we report that hepatic S14-R mRNA levels increase with high-carbohydrate feeding in mice or within 2 h of treating cultured hepatocytes with elevated glucose. A potential carbohydrate response element (ChoRE) was identified at position -458 of the S14-R promoter. Deletion of or point mutations within the putative S14-R ChoRE led to 50-95% inhibition of the glucose response. Gel-shift analysis revealed that the glucose-activated transcription complex carbohydrate responsive element-binding protein/Max-like protein X (Mlx) binds to the S14-R ChoRE. Finally, S14-R glucose induction is completely blocked when a dominant-negative form of Mlx is overexpressed in primary hepatocytes. In conclusion, our results indicate that the S14-R gene is a glucose-responsive target of carbohydrate responsive element-binding protein/Mlx and suggest that the S14-R protein is a compensatory factor, at least partially responsible for the normal liver lipogenesis observed in the S14 null mouse.

Identification and function of phosphorylation in the glucose-regulated transcription factor ChREBP.

In the liver, induction of genes encoding enzymes involved in de novo lipogenesis occurs in response to increased glucose metabolism. ChREBP (carbohydrate-response-element-binding protein) is a basic helix-loop-helix/leucine zipper transcription factor that regulates expression of these genes. To evaluate the potential role of ChREBP phosphorylation in its regulation, we used MS to identify modified residues. In the present paper, we report the detection of multiple phosphorylation sites of ChREBP expressed in hepatocytes, several of which are only observed under high-glucose conditions. Mutation of each of these serine/threonine residues of ChREBP did not alter its ability to respond to glucose. However, mutation of five N-terminal phosphoacceptor sites resulted in a major decrease in activity under high-glucose conditions. These phosphorylated residues are located within a region of ChREBP (amino acids 1-197) that is critical for glucose regulation. Mutation of Ser(56) within this region to an aspartate residue resulted in increased nuclear accumulation and activity under high-glucose conditions. Together, these data suggest that ChREBP activity is regulated by complex multisite phosphorylation patterns involving its N-terminal regulatory region.

Glucose activation of ChREBP in hepatocytes occurs via a two-step mechanism.

Carbohydrate response element binding protein (ChREBP) is a transcription factor that mediates glucose-responsive changes in gene expression in hepatocytes. In the current model for glucose regulation, inhibition of ChREBP in low glucose occurs in response to cAMP-dependent protein kinase (PKA)-mediated phosphorylation of residues S196, S626, and/or T666. Activation of ChREBP in conditions of increased glucose results simply from reversal of these inhibitory phosphorylations. To test this model, we analyzed mutant forms of ChREBP that lack one or more of the proposed PKA sites and found that these forms of ChREBP still require glucose for activation. Additionally, cAMP levels in cultured hepatocytes were negligible in low glucose conditions, indicating PKA should not be active. Finally, overall ChREBP phosphorylation did not change in response to altered glucose levels. We conclude that in addition to its repression by PKA, glucose activation of ChREBP involves a second mechanism that is independent of PKA phosphorylation.

Direct role of ChREBP.Mlx in regulating hepatic glucose-responsive genes.

Enzymes required for de novo lipogenesis are induced in mammalian liver after a meal high in carbohydrates. In addition to insulin, increased glucose metabolism initiates an intracellular signaling pathway that transcriptionally regulates genes encoding lipogenic enzymes. A cis-acting sequence, the carbohydrate response element (ChoRE), has been found in the promoter region of several of these genes. ChREBP (carbohydrate response element-binding protein) was recently identified as a candidate transcription factor in the glucose-signaling pathway. We reported that ChREBP requires the heterodimeric partner Max-like factor X (Mlx) to bind to ChoRE sequences. In this study we provide further evidence to support a direct role of Mlx in glucose signaling in the liver. We constructed two different dominant negative forms of Mlx that could dimerize with ChREBP but block its binding to DNA. When introduced into hepatocytes, both dominant negative forms of Mlx inhibited the glucose response of a transfected ChoRE-containing promoter. The glucose response was rescued by adding exogenous wild type Mlx or ChREBP, but not MondoA, a paralog of ChREBP that can also form a heterodimer with Mlx. Furthermore, dominant negative Mlx blocked the induction of glucose-responsive genes from their natural chromosomal context under high glucose conditions. In contrast, genes induced by the insulin and thyroid hormone-signaling pathways were unaffected by dominant negative Mlx. Mlx was present in the glucose-responsive complex of liver nuclear extract from which ChREBP was purified. In conclusion, Mlx is an obligatory partner of ChREBP in regulating lipogenic enzyme genes in liver.