The role of PTF1-P48 in pancreatic acinar gene expression.

The 100-base pair ELA1 transcriptional enhancer drives high level transcription to pancreatic acinar cells of transgenic mice and in transfected pancreatic acinar cells in culture. The A element within the enhancer is the sole positively acting element for acinar specificity. We show that the acinar cell-specific bHLH protein PTF1-P48 and the common bHLH cofactor HEB are part of the PTF1 complex that binds the A element and mediates its activity. Acinar-like activity of the enhancer can be reconstituted in HeLa cells by the introduction of P48, HEB, and the PDX1-containing trimeric homeodomain complex that binds the second pancreatic element of the enhancer. The 5' region of the mouse Ptf1-p48 gene from -12.5 to +0.2 kilobase pairs contains the regulatory information to direct expression in transgenic mice to the pancreas and other organs of the gut that express the endogenous Ptf1-p48 gene. The 5'-flanking sequence contains two activating regions, one of which is specific for acinar cells, and a repressing domain active in non-pancreatic cells. Comparison of the 5'-gene flanking regions of the mouse, rat, and human genes identified conserved sequence blocks containing binding sites for known gut transcription factors within the acinar cell-specific control region.

DNA binding and transcriptional activation by a PDX1.PBX1b.MEIS2b trimer and cooperation with a pancreas-specific basic helix-loop-helix complex.

In pancreatic acinar cells, the HOX-like factor PDX1 acts as part of a trimeric complex with two TALE class homeodomain factors, PBX1b and MEIS2b. The complex binds to overlapping half-sites for PDX1 and PBX. The trimeric complex activates transcription in cells to a level about an order of magnitude greater than PDX1 alone. The N-terminal PDX1 activation domain is required for detectable transcriptional activity of the complex, even though PDX1 truncations bearing only the PDX1 C-terminal homeodomain and pentapeptide motifs can still participate in forming the trimeric complex. The conserved N-terminal PBC-B domain of PBX, as well as its homeodomain, is required for both complex formation and transcriptional activity. Only the N-terminal region of MEIS2, including the conserved MEIS domains, is required for formation of a trimer on DNA and transcriptional activity: the MEIS homeodomain is dispensable. The activity of the pancreas-specific ELA1 enhancer requires the cooperation of the trimer-binding element and a nearby element that binds the pancreatic transcription factor PTF1. We show that the PDX1. PBX1b.MEIS2b complex cooperates with the PTF1 basic helix-loop-helix complex to activate an ELA1 minienhancer in HeLa cells and that this cooperation requires all three homeoprotein subunits, including the PDX1 activation domain.

A binary mechanism for the selective action of a pancreatic beta -cell transcriptional silencer.

The pancreatic elastase I gene (ELA1) is selectively transcribed to high levels in pancreatic acinar cells. Pancreatic specificity is imparted by a 100-base pair enhancer that activates transcription in beta-cells of the islets of Langerhans as well as in acinar cells. Adjacent to the enhancer is a silencer that renders transcription specific to acinar cells by selectively suppressing the inherent beta-cell activity of the enhancer. We show that the selective repression of beta-cell transcription is due neither to a beta-cell specific activity of the silencer nor to selective interference with beta-cell-specific transcriptional activators acting on the enhancer. Rather, the silencer is effective in both pancreatic endocrine and acinar cell types against all low and moderate strength enhancers and promoters tested. The silencer appears to act in a binary manner by reducing the probability that a promoter will be active without affecting the rate of transcription from active promoters. We propose that the ELA1 silencer is a weak off switch capable of inactivating enhancer/promoter combinations whose strength is below a threshold level but ineffective against stronger enhancer/promoters. The apparent cell-specific effects on the ELA1 enhancer appear due to the ability of the silencer to inactivate the weak beta-cell activity of the enhancer but not the stronger acinar cell activity.

Assessment of RNA quality by semi-quantitative RT-PCR of multiple regions of a long ubiquitous mRNA.

A simple method to assess the degree of degradation present in a total RNA preparation from cells or tissues is based on the increasing probability of RNA cleavage with increasing length of an RNA molecule. Under ideal conditions, reverse transcription of a particular mRNA species with oligo-dT as the primer generates a population of cDNAs, terminating at the 5' end of the mRNA if all template RNA molecules are intact, or at the first cleavage site 5' to the polyA if some template RNAs are partially degraded. Consequently, for cellular RNA preparations with some degradation, the 5' end of an mRNA is represented in the cDNA population to a lesser extent than the 3' end of the mRNA. We describe a sensitive assay of mRNA quality that compares the relative PCR amplification of 5' and 3' regions of a long and ubiquitous mRNA following oligo-dT-primed reverse transcription.

Analysis of transcriptional regulatory regions in vivo.

Understanding the transcriptional regulation of development and tissue-specific gene expression is a central goal of modern biology. Although the analysis of gene transcription in transfected cultured cells has been essential in establishing many key aspects of this gene control, only analysis in animals can determine developmental timing and cell-specificity of expression within a complex organ and in all the tissues of an animal. The advent of transgenesis made in vivo studies possible. A summary of the in vivo regulatory properties of the pancreas-specific transcriptional enhancer of the rat elastase 1 gene (ELA1) and the role individual elements in this enhancer play in directing high level, cell-specific transcription illustrates the nature, revelations and limitations of transgenic analysis.

An endocrine-exocrine switch in the activity of the pancreatic homeodomain protein PDX1 through formation of a trimeric complex with PBX1b and MRG1 (MEIS2).

HOX proteins and some orphan homeodomain proteins form complexes with either PBX or MEIS subclasses of homeodomain proteins. This interaction can increase the binding specificity and transcriptional effectiveness of the HOX partner. Here we show that specific members of both PBX and MEIS subclasses form a multimeric complex with the pancreatic homeodomain protein PDX1 and switch the nature of its transcriptional activity. The two activities of PDX1 are exhibited through the 10-bp B element of the transcriptional enhancer of the pancreatic elastase I gene (ELA1). In pancreatic acinar cells the activity of the B element requires other elements of the ELA1 enhancer; in beta-cells the B element can activate a promoter in the absence of other enhancer elements. In acinar cell lines the activity is mediated by a complex comprising PDX1, PBX1b, and MRG1 (MEIS2). In contrast, beta-cell lines are devoid of PBX1b and MRG1, so that a trimeric complex does not form, and the beta-cell-type activity is mediated by PDX1 without PBX1b and MRG1. The presence of specific nuclear isoforms of PBX and MEIS is precisely regulated in a cell-type-specific manner. The beta-cell-type activity can be detected in acinar cells if the B element is altered to retain binding of PDX1 but prevent binding of the PDX1-PBX1b-MRG1 complex. These observations suggest that association with PBX and MEIS partners controls the nature of the transcriptional activity of the organ-specific PDX1 transcription factor in exocrine versus endocrine cells.

Cooperation between elements of an organ-specific transcriptional enhancer in animals.

The elastase I gene enhancer that specifies high levels of pancreatic transcription comprises three functional elements (A, B, and C). When assayed individually in transgenic mice, homomultimers of A are acinar cell specific, those of B are islet specific, and those of C are inactive. To determine how the elements interact in the elastase I enhancer and to investigate further the role of the C element, we have examined the activity of the three possible combinations of synthetic double elements in transgenic animals. Combining the A and B elements reconstitutes the exocrine plus endocrine specificity of the intact enhancer with an increased activity in acinar cells compared with that in the A homomultimer. The B element therefore plays a dual role: in islet cells it is capable of activating transcription, whereas in acinar cells it is inactive alone but greatly augments the activity specified by the A element. The C element augments the activity of either the A or B element without affecting their pancreatic cell type specificity. The roles of each element were verified by examining the effects of mutational inactivation of each element within the context of the elastase I enhancer. These results demonstrated that when tested in animals, the individual enhancer elements can perform discrete, separable functions that combine additively for cell type specificity and cooperatively for the overall strength of a multielement stage- and site-specific transcriptional enhancer.

An element of the elastase I enhancer is an overlapping bipartite binding site activated by a heteromeric factor.

The B element of the elastase I transcriptional enhancer is active in both exocrine and endocrine cells of the pancreas. Cell transfection experiments revealed that in an acinar cell line the active sequence of the element is more extensive than in an endocrine cell line. Electrophoretic mobility shift assays identified three major complexes (designated C, M, and L) from acinar cell nuclear extracts bound to the element. The C complex appears to be responsible for the activity of the element in acinar cells because its binding site, determined by methylation interference and mobility shift competition experiments, matches the critical sequence identified by cell transfection analysis of mutated B elements. The DNA sequence requirements for formation of the C complex is the sum of those for the M and L complexes. Methylation interference experiments indicated that the sensitivity of the C complex to guanine methylation also was the sum of that of the M and L complexes. Diagonal electrophoretic mobility shift assays confirmed that L is a component of complex C. However, the M complex, which we identified as GATA-4, is not part of the C complex, because the C complex was neither competed by GATA-binding sites nor super-shifted by anti-GATA-4 antiserum. Both the C and L complexes are specific to the pancreatic acinar cell line.

A single element of the elastase I enhancer is sufficient to direct transcription selectively to the pancreas and gut.

The elastase I (EI) gene is expressed at high levels in the exocrine pancreas and at lower levels in other regions of the gut. The transcriptional enhancer of the EI gene, from nucleotides -205 to -72, recapitulates the expression of the endogenous gene in transgenic mice; it directs not only pancreatic acinar cell expression of a human growth hormone (hGH) transgene but also expression to the stomach, duodenum, and colon. This pattern of selective expression limited to the gastroenteropancreatic organ system is specified by the A element, one of three functional elements in the EI enhancer. When multimerized, the A element directed expression of a hGH reporter gene selectively to the pancreas, stomach, and intestine in transgenic mice. Immunofluorescent localization of hGH indicated that the A element multimer transgenes were expressed in the acinar cells of the pancreas as well as in Brunner's gland cells of the duodenum. The A element binds a pancreatic acinar cell-specific factor, PTF1. Our results show that while the A element is responsible for directing tissue and cell type specificity, other elements of the enhancer must be involved in the regulation of the level of gene expression.

An endocrine-specific element is an integral component of an exocrine-specific pancreatic enhancer.

We have analyzed the function of individual elements of the elastase I transcriptional enhancer in transgenic animals. This pancreas-specific enhancer comprises three functional elements, one of which (the B element) plays a dual role. Within the context of the enhancer, the B element contributes to appropriate acinar cell expression. However, when separated from the other enhancer components, the B element selectively directs transcription in islet cells of transgenic animals. This islet-specific activity is normally suppressed by an upstream repressor domain. The B element binds a novel islet-specific factor, and similar B-like elements are present in other pancreatic genes, both exocrine and endocrine specific. We suggest that a principal role of this transcriptional element and its associated factors is to activate many pancreatic genes as part of the program of pancreatic determination prior to the divergence of the acinar and islet cell lineages.