Extinction of tyrosine aminotransferase gene activity in somatic cell hybrids involves modification and loss of several essential transcriptional activators.

111

110

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 (GIRE) of the L-PK gene is built around two noncanonical E boxes (element IA) 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 COUPITF-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 GIRE function. Mutations transforming one or two noncanonical E boxes of element LA 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 GIRE 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 GIRE seems to require the cooperation between two putative MLTF/USF binding sites located in the vicinity of an HNF4 binding site.The L-type pyruvate kinase (L-PK) is a key enzyme of the glycolytic pathway. It is coordinately regulated at the transcriptional and posttranscriptional levels, positively by carbohydrates in the presence of insulin and negatively by glucagon via cyclic AMP (8,32). The regulatory region of the L-PK gene, responsible for its transcriptional response to carbohydrates and hormones, has been ascribed to a -120/ -183-bp proximal promoter fragment (2, 30), ex vivo by transient expression assays in hepatocytes in primary culture, and in vivo in transgenic mice (7). We had previously characterized the important cis-acting DNA elements in the L-PK gene promoter: in the 3'-5' direction upstream from the TATA box, we found, respectively, box Li, a binding site for hepatocyte nuclear factor 1 (HNF1); box L2, a binding site for nuclear factor 1; box L3, a binding site for HNF4; and box LA, a weak in vitro binding site for major late transcription factor (MLTF)/USF ( Fig. 1) (33). Box IA contains the L-PK gene glucose/insulin response element (GlRE) and is also indispensable for the action of glucagon and cyclic AMP. When L4 is oligomerized, it is able to confer glucose/insulin and cyclic AMP responsiveness on a

Section: Discussionmentioning

confidence: 99%

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

Guerra¹,

Bergot²,

Martinez³

et al. 1993

111

110

“…The HNF3 proteins bind to the same DNA sequences in vitro; however, differences in affinity have been observed among them (39 HTC cell line is that HNF3a and/or --y but not HNF3, are involved in activating the TAT gene via the enhancer at -11 kb. Functional differences between the three HNF3 proteins are also suggested by the differential expression of the respective genes in hepatoma x fibroblast hybrids, in which expression of HNF30 and --y but not HNF3aL is downregulated (50).…”

Section: Discussionmentioning

confidence: 99%

The distal enhancer implicated in the developmental regulation of the tyrosine aminotransferase gene is bound by liver-specific and ubiquitous factors.

Nitsch¹,

Schütz²

1993

Self Cite

Tyrosine aminotransferase gene expression is confined to parenchymal cells of the liver, is inducible by glucocorticoids and glucagon, and is repressed by insulin. Three enhancers control this tissue-specific and hormone-dependent activity, one of which, located at -11 kb, is implicated in establishing an active expression domain. We have studied in detail this important regulatory element and have identified a 221-bp fragment containing critical enhancer sequences which stimulated the heterologous thymidine kinase promoter more than 100-fold in hepatoma cells. Within this region, we have characterized two essential liver-specific enhancer domains, one of which was bound by proteins of the hepatocyte nuclear factor 3 (HNF3) family. Analyses with the dedifferentiated hepatoma cell line HTC suggested that HNF3a and/or -y, but not HNF31, are involved in activating the tyrosine aminotransferase gene via the -11-kb enhancer. Genomic footprinting and in vitro protein-DNA binding studies documented cell-type-specific binding of ubiquitous factors to the second essential enhancer domain, which by itself stimulated the thymidine kinase promoter preferentially in hepatoma cells.These results will allow further characterization of the role of these enhancer sequences in developmental activation of the tyrosine aminotransferase gene.Differential gene expression is the basis of cellular diversity in complex organisms. Work from many laboratories has established that gene activity is regulated by the combinatorial action of sequence-specific DNA-binding proteins which, together with the basic transcription apparatus, control the frequency of transcription initiation at the promoter. Binding sites for transcriptional activator proteins, which mediate cell-type-specific, hormone-dependent, and developmentally regulated gene expression, can be found in the vicinity of the transcription start site and in enhancer sequences located several kilobases upstream or downstream (33, 43). More recently, cofactors or adaptors which couple activator proteins to the basal transcription factors by protein-protein interaction have been described (reference 42 and references therein).Studies on liver-specific genes have led to the identification of several liver-enriched transcriptional activators, the majority of which can be grouped into four families (see references 14 and 61 for reviews): hepatocyte nuclear factor 1 (HNF1) hierarchical order of liver-specific transcription factors (37,65).Tyrosine aminotransferase (TAT) is a gluconeogenic enzyme which has been studied as a classical system for more than 20 years (reviewed in reference 51). The TAT gene is switched on in the parenchymal cells of the liver shortly after birth, when hormone levels change dramatically (26, 28). Gene activity is induced by glucocorticoids and by glucagon, acting via its intracellular mediator cyclic AMP (cAMP) (25,29,58), and is repressed by insulin (60). Our analyses have defined three enhancers which are responsible for the liverspecific and hormone-inducibl...

“…Three additional lines of evidence support the idea that HNF-3 proteins occupy a primary position in the transcriptional hierarchy that leads to lineage commitment and cell-type-specific gene expression for endodermal derivatives. First, dedifferentiated hepatocyte cell lines and somatic cell hybrids typically lack expression of most known transcription factors for liver-specific genes (1,39,54). Peculiarly, HNF-3 proteins often continue to be expressed in the dedifferentiated cells (1,39,54), and in response to a differentiation signal, these cells express a cascade of other known liver transcription factors and progress to a differentiated hepatic cell type (1).…”

Section: Discussionmentioning

confidence: 99%

“…First, dedifferentiated hepatocyte cell lines and somatic cell hybrids typically lack expression of most known transcription factors for liver-specific genes (1,39,54). Peculiarly, HNF-3 proteins often continue to be expressed in the dedifferentiated cells (1,39,54), and in response to a differentiation signal, these cells express a cascade of other known liver transcription factors and progress to a differentiated hepatic cell type (1). Second, HNF-3,B is capable of binding to and activating its own promoter (57) (47).…”

Section: Discussionmentioning

confidence: 99%

The lung-specific surfactant protein B gene promoter is a target for thyroid transcription factor 1 and hepatocyte nuclear factor 3, indicating common factors for organ-specific gene expression along the foregut axis.

Bohinski¹,

Lauro²,

Whitsett³

1994

494

410

We used the lung epithelial cell-specific surfactant protein B (SPB) gene promoter as a model with which to investigate mechanisms involved in transcriptional control of lung-specific genes. In a previous study, we showed that the SPB promoter specifically activated expression of a linked reporter gene in the continuous H441 lung cell line and that H441 nuclear proteins specifically protected a region of this promoter from bp -111 to -73. In this study, we further show that this region is a complex binding site for thyroid transcription factor 1 (TTF-1) and hepatocyte nuclear factor 3 (HNF-3). Whereas TTF-1 bound two highly degenerate and closely spaced sites, HNF-3 proteins bound a TGT3 motif (TGTTTGT) that is also found in several liver-specific gene regulatory regions, where it appears to be a weak affinity site for HNF-3. Point mutations of these binding sites eliminated factor binding and resulted in significant decreases in transfected SPB promoter activity. In addition, we developed a cotransfection assay and showed that a family of lung-specific gene promoters that included the SPB, SPC, SPA, and Clara cell secretory protein (CCSP) gene promoters were specifically activated by cotransfected TTF-1. We conclude that TTF-1 and HNF-3 are major activators of lung-specific genes and propose that these factors are involved in a general mechanism of lung-specific gene transcription. Importantly, these data also show that common factors are involved in organ-specific gene expression along the mammalian foregut axis.The lung forms as an endodermal bud from the anteromedian foregut wall. Mesenchymal tissue interacts with this bud, inducing a process of branching morphogenesis that establishes a highly branched network of epithelially lined airways. Cellular differentiation in the lung is complex, and several morphologically distinct cell types comprise the airway epithelium. By definition, the onset of cellular differentiation is signalled by expression of differentiated gene products; hence, one fruitful approach to understanding mechanisms of cellular differentiation in mammals has been to identify factors that control expression of genes that define the cellular phenotype (14,22,34,41,71 (513) 559-7868. sue-specific genes are often sufficient to target expression of a reporter gene to the appropriate tissue in vivo (36). Extensive study has shown that DNA-binding proteins specifically interact with these sequences to stimulate gene transcription (37,46,50). One model suggests that the mechanism by which these proteins act depends on their restricted cellular distribution and interaction with only one type of tissue-specific gene family. The control of skeletal muscle cell differentiation by the MyoD family of transcription factor proteins supports this model. The expression of these proteins is restricted to the skeletal muscle cell lineage, and ectopic expression in vitro or in vivo is sufficient to convert most cell types to skeletal muscle-like cells (22,49,73,74). This property of myogenic conversion d...