Functional characterization of the L-type pyruvate kinase gene glucose response complex.

L-type pyruvate kinase (L-PK) gene expression is modulated by hormonal and nutritional conditions. We have previously shown that the glucose/insulin response element (GlRE) of the L-PK gene is built around two noncanonical E boxes (element L4) that cooperate closely with a contiguous binding site (element L3). We present in this report the identification of proteins that interact with both elements. The L3 site binds hepatocyte nuclear factor 4 (HNF4)- and COUP/TF-related proteins. In fibroblasts, the overexpression of HNF4 transactivates the L-PK promoter. On the contrary, COUP/TF strongly inhibits the active promoter in hepatocytes. The L4 site binds the major late transcription factor (MLTF) in vitro and ex vivo; mutations that suppress this binding activity also inactivated the GlRE function. Mutations transforming one or two noncanonical E boxes of element L4 into consensus MLTF/USF binding sites strongly increase the affinity for MLTF/USF and do not impair the glucose responsiveness. However, merely the ability to bind MLTF/USF does not seem to be sufficient to confer a GlRE activity: those elements in which one E box has been destroyed and the other has been transformed into a consensus MLTF/USF sequence bind MLTF/USF efficiently but do not confer a high glucose responsiveness on the L-PK gene promoter. Consequently, the full activity of the L-PK GlRE seems to require the cooperation between two putative MLTF/USF binding sites located in the vicinity of an HNF4 binding site.

Cis-regulation of the L-type pyruvate kinase gene promoter by glucose, insulin and cyclic AMP.

The glucose/insulin response element of the L-pyruvate kinase gene is a perfect palindrome located from nt -168 to -144 with respect to the cap site. This element (L4) is partially homologous to MLTF binding sites. Its full efficiency requires cooperation with a contiguous binding site for HNF4, termed L3 and located from nt -145 to -125. In the presence of the L4 element contiguous to L3, cyclic AMP inhibits activity of the L-PK promoter while in its absence, or when the normal L4-L3 contiguity is modified, cyclic AMP behaves as a transcriptional activator that does not seem to be sequence-specific. Therefore, we propose that the mechanism of inhibition of the L-PK gene by cyclic AMP requires precise interactions between the nucleoprotein complex built up at sites L4 and L3 and other components of the L-PK transcription initiation complex.

cis-acting DNA elements regulating expression of the liver pyruvate kinase gene in hepatocytes and hepatoma cells. Evidence for tissue-specific activators and extinguisher.

To identify the DNA sequences that cis-regulate the expression of the rat liver pyruvate kinase (L-PK) genes, a series of constructs in which the chloramphenicol acetyltransferase reporter genes is driven by various deleted fragments of the 3200 base pairs (bp) upstream of the L-PK gene cap site have been assayed for transient expression after introduction into hepatoma HepG2 cells, rat hepatocytes in primary culture, fibroblast LTK- cells, myogenic C2C12 cells, and CHO cells. Four distinct regulatory domains have been characterized. A proximal promoter region containing a binding site for the hepatocyte nuclear factor 1 (HNF1) which is sufficient to confer liver specificity, even in the presence of a ubiquitous enhancer. A distal promoter region (-96 to -283 bp) containing binding sites for the liver-specific factor A1 (LFA1), the ubiquitous nuclear factor 1 (NF1), the major late transcriptional factor (MLTF), and so far unidentified proteins binding to the L5-PK region which is essential to maximally activate expression of the construct in HepG2 cells. An extinguisher region, located between positions -2082 and -1170 bp, which decreases efficiency of the L-PK promoter in HepG2 cells, but not in hepatocytes in primary culture. Finally, a far upstream region (-2900 to -2500 bp) which seems to correspond to a liver-specific DNase I hypersensitive site and which behaves in HepG2 cells as an activating sequence efficient in the absence of the extinguisher.

Positive and negative regulation of gene expression by insulin and glucagon: the model of L-type pyruvate kinase gene.

L-type pyruvate kinase gene regulation is an excellent model of gene control by hormones and diet. In vivo and ex vivo experiments allowed us to established that thyroid hormones and glucocorticoids act on pyruvate kinase gene expression at the post-transcriptional level. In contrast, glucose and insulin together stimulate transcription of this gene while glucagon inhibits it. Insulin or glucose are individually inefficient and glucagon-dependent transcriptional inhibition seems to be dominant in insulin + glucose-dependent activation. A 14-kbp fragment encompassing the entire pyruvate kinase gene and 3.2-kbp of 5' flanking sequences is expressed in transgenic mice exactly like the endogenous gene; the 3.2-kbp upstream region is sufficient to confer this tissue-specific and hormone/diet-regulated expression to reporter genes. In vivo, DNAse I hypersensitivity analysis revealed the presence of 3 liver-specific groups of hypersensitive sites (HSS). The proximal sites, between + 1 and -183 bp with respect to the start site of transcription, were, in addition, transcription-dependent. The nature and functional role of proteins binding to this proximal upstream sequence were analyzed by in vitro binding and cell free transcription experiments. The existence of more upstream cis-acting elements was investigated by transient transfection assays using differentiated hepatoma cell lines and hepatocytes in primary culture. These experiments permitted the detection of an extinguisher active in hepatoma Hep G2 cells but not in hepatocytes, and of an activating element which could correspond to a distal HSS. Unfortunately, this investigation has not yet allowed us to determine with accuracy the DNA elements responsible for response to diet and hormones.