Insulin-responsive nuclear proteins facilitate Sp1 interactions with the insulin-like growth factor-I gene.

The diabetes-induced decrease in insulin-like growth factor-I transcription appears to be mediated by footprint region V in exon 1. Since region V contains both an Sp1 site and an AT-rich element that recognizes an insulin-responsive binding protein (IRBP), we tested the hypothesis that Sp1 interactions are facilitated by an IRBP. Binding of nuclear extracts to region V probes was reduced by mutational or chemical interference with the AT-rich element. Blocking the AT site also reduced interactions of Sp1 with region V in vitro and blunted transactivation of region V reporter constructs by Sp1 in vivo. Sp1 binding was enhanced by small quantities of hepatic nuclear extracts, but enhancement was reduced by the AT mutation and abolished by a 5-base pair insertion between the AT-rich and GC-rich sites, and transactivation by Sp1 in vivo was diminished by inserting bases between the AT-rich and GC-rich elements. However, treating cells with insulin increased the ability of nuclear extracts to enhance Sp1 binding. These findings indicate that the presence of the AT-rich element is essential for the actions of Sp1 in vitro and in vivo, and the combination of both spacing requirements and insulin responsiveness suggests that IRBP may interact directly with Sp1.

Physiological concentrations of insulin promote binding of nuclear proteins to the insulin-like growth factor I gene.

Limitations in understanding the mechanism of transcriptional regulation by insulin are due in part to lack of models in which there is insulin-responsive binding of nuclear factors to critical promoter regions. The insulin-like growth factor I (IGF-I) gene responds to diabetes status via a footprinted sequence, region V, which contains an AT-rich element and a GC-rich site. We tested the hypothesis that insulin regulates nuclear factor binding to the AT-rich site. Gel shift analysis with liver nuclear extracts and a region V probe showed binding of Sp1, Sp3, and B(1), which persisted despite the presence of antibodies against Sp1 and Sp3. B(1) was detected by a probe mutated in the GC-rich site (VmSp1), but not by a probe mutated at the AT-rich site (VmAT). We then asked whether B(1) was responsive to insulin. For both region V and VmSp1 probes, nuclear extracts from normal rat hepatocytes, H4IIE cells, and CHO-IR cells exposed to 10(-6) M insulin exhibited an increase in binding, designated insulin-responsive binding protein (IRBP); IRBP comigrated with B(1) from liver extracts. IRBP binding to region V was competed by VmSp1, but not by VmAT, indicating specific interactions with the AT-rich sequence; insulin response elements from other genes also failed to compete. After addition of insulin, IRBP began to increase by 1 h and rose further at 24 h, suggesting involvement of both posttranslational and transcriptional mechanisms. IRBP responded to as little as 10(-10) M insulin, indicating physiological relevance. Induction of IRBP was blunted by the phosphatidylinositol 3'-kinase inhibitor LY294002, whereas other signal transduction inhibitors had little effect. IRBP interacts with an important sequence in the IGF-I gene and may participate in the metabolic regulation of IGF-I expression. As most insulin-responsive genes do not exhibit insulin-responsive nuclear factor binding, further studies of IRBP may also contribute to understanding of the mechanism of insulin action on gene transcription.

Involvement of Sp1 in the transcriptional regulation of the rat insulin-like growth factor-1 gene.

UNLABELLED: Most insulin-like growth factor-I (IGF-I) transcripts are initiated in exon 1, but mechanisms of regulation are not well understood. Since potential Sp1 sites are found in footprinted regions within approximately 360 bp upstream and downstream from the major initiation sites in exon 1, we explored the involvement of Sp1 and Sp3 in regulation of IGF-1 expression. Gel shift assays showed strong Sp1 binding to the downstream site, but binding to the upstream site was weak; Sp1 bound to a CCTGCCCA sequence in downstream footprint region V, and Sp3 binding was centered on the same sequence. IGF-I basal promoter constructs containing a mutation in the downstream Sp1 site exhibited a 32% decrease in expression in CHO cells and a 75% decrease in HepG2 cells, indicating the importance of Sp1 for expression in vivo. Sp1 and Sp3 expression vectors provided three- to five-fold stimulation of wild-type IGF-I constructs, but had little effect on a construct containing a mutation in the downstream Sp1 site, and Sp1 had comparable effects in Drosophila SL2 cells. IGF-I heterologous promoter constructs exhibited similar responses: in both SL2 cells and CHO cells, stimulation by Sp1 was enhanced with constructs containing downstream region V. Since Sp1 also stimulated expression of concatamers of putative cis-acting sites fused to the SV40 promoter enhancer in pGL3, the results in combination indicate that the presence of IGF-I region V is sufficient to permit stimulation by Sp1. CONCLUSION: Sp1 and related factors may play an important role in the regulation of IGF-I gene transcription, through interactions with region V downstream from the major initiation sites in exon 1.

An indirect role for upstream stimulatory factor in glucose-mediated induction of pyruvate kinase and S14 gene expression.

Transcription of the L-type pyruvate kinase (L-PK) and S14 genes is induced in hepatocytes in response to increased glucose metabolism. The regulatory sequences of these genes responsible for induction by glucose have been mapped to related E-box containing motifs in the promoters. Similarly, L-PK promoter activity is stimulated in a differentiated pancreatic beta-cell line, INS-1, in response to elevated glucose. By mutational analysis, we demonstrate that the sequence requirements for glucose induction in the INS-1 cell are identical to those observed in the hepatocyte, suggesting that the same transcriptional factor(s) is responsible for regulation of L-PK expression in the two cell types. One nuclear factor that binds to the glucose regulatory sequences of both of these genes is the Upstream Stimulatory Factor (USF), a ubiquitous E-box binding protein. Mice deleted for the USF2 gene display a severely delayed response to carbohydrate feeding (Vallet et al. [26]). This observation, however, does not differentiate between a direct and an indirect role for USF in the process. To gain further insight into the possible involvement of USF in glucose signaling, we have used a recombinant adenoviral construct that expresses a dominant negative form of USF. This dominant negative can dimerize with endogenous USF and is shown to inhibit DNA binding of USF in hepatocytes and INS-1 cells. However, expression of the dominant negative USF did not block the ability of glucose to stimulate L-PK or S14 gene expression in hepatocytes or L-PK promoter activity in INS-1 cells. We conclude that USF does not act by binding to the glucose regulatory sequences of the S14 or L-PK genes and the role of USF in the process of glucose induction is indirect.

Upstream stimulatory factor regulates Pdx-1 gene expression in differentiated pancreatic beta-cells.

The homeobox gene Pdx-1 plays a key role in the development of the pancreas. In the adult, however, expression of the Pdx-1 gene is restricted to pancreatic beta-cells and endocrine cells of duodenal epithelium. Recently, the transcription factor, upstream stimulatory factor (USF), has been shown to bind in vitro to a mutationally sensitive E-box motif within the 5'-flanking region of the Pdx-1 gene [Sharma, Leonard, Lee, Chapman, Leiter and Montminy (1996) J. Biol. Chem. 271, 2294-2299]. In the present study, we show that USF not only binds to the Pdx-1 gene promoter but also functionally regulates the expression of the Pdx-1 gene in differentiated pancreatic beta-cells. Adenovirus-mediated overexpression of a dominant negative form of USF2 decreased binding of endogenous USF to the E-box element by approximately 90%. This reduction in endogenous USF binding led to a greater than 50% decrease in Pdx-1 gene promoter activity, which, in turn, resulted in marked reductions in Pdx-1 mRNA and protein levels. Importantly, the lower Pdx-1 protein levels led to a greater than 50% reduction in Pdx-1 binding activity to the A3 element on the insulin gene promoter, and a significant reduction in insulin mRNA levels. Overall, our results show that USF functionally regulates Pdx-1 gene expression in differentiated pancreatic beta-cells and provide the first functional data for a role of USF in the regulation of a normal cellular gene.

Carbohydrate regulation of hepatic gene expression. Evidence against a role for the upstream stimulatory factor.

Hepatic expression of the genes encoding L-type pyruvate kinase (L-PK) and S14 is induced in rats upon feeding them a high carbohydrate, low fat diet. A carbohydrate response element (ChoRE) containing two CACGTG-type E boxes has been mapped in the 5'-flanking region of both of these genes. The nature of the ChoRE suggests that a member of the basic/helix-loop-helix/leucine zipper family of proteins may be responsible for mediating the response to carbohydrate. Indeed, the upstream stimulatory factor (USF), a ubiquitous basic/helix-loop-helix/leucine zipper protein, is present in hepatic nuclear extracts and binds to the ChoREs of L-PK and S14 in vitro. We have conducted experiments to determine whether USF is involved in the carbohydrate-mediated regulation of L-PK and S14. For this purpose, dominant negative forms of USF that are capable of heterodimerizing with endogenous USF but not of binding to DNA were expressed in primary hepatocytes. Expression of these forms did not block either S14 or L-PK induction by glucose. In addition, we have constructed mutant ChoREs that retain their carbohydrate responsiveness but have lost the ability to bind USF. Together, these data suggest that USF is not the carbohydrate-responsive factor that stimulates S14 and L-PK expression and that a distinct hepatic factor is likely to be responsible for the transcriptional response.

Regulation of the expression of lipogenic enzyme genes by carbohydrate.

Diets high in simple carbohydrates and low in fats lead in the mammalian liver to induction of a set of enzymes involved in lipogenesis. This induction occurs, in part, through transcriptional mechanisms that lead to elevated levels of the mRNA for these enzymes. For most of the lipogenic enzymes, an increase in glucose metabolism is required to trigger the transcriptional response. The intracellular mediator of this signaling pathway is unknown, although evidence suggests either glucose-6-phosphate or xylulose-5-phosphate. Studies to map the regulatory sequences of lipogenic enzyme genes involved in the transcriptional response have been performed for the L-type pyruvate kinase, S14, and acetyl-coenzyme A carboxylase genes. These studies have identified the DNA sequences necessary to link the signal generated by carbohydrate metabolism to specific nuclear transcription factors.