Binding of a pancreatic nuclear protein is correlated with amylase enhancer activity.

The mouse amylase gene Amy-2.2 is expressed at high levels specifically in the acinar cells of the pancreas. The region between -172 and -110 of this gene includes sequence elements common to pancreas-specific genes. Nuclear proteins with specific affinity for this region were partially purified from rat pancreas. The consensus element of another pancreas-specific gene, elastase 1, competes for protein binding to the amylase sequences. Binding was localized by DNase I protection to the sequence -156 to -122. Site-directed mutagenesis of this sequence resulted in concomitant loss of protein binding and enhancer activity. Photo-affinity labelling of pancreatic nuclear extracts identified one predominant binding protein with a molecular weight of approximately 75 kDa. The data indicate that binding of this nuclear protein is essential for the enhancer activity of this pancreas-specific element.     

The cell-specific elastase I enhancer comprises two domains.

Two separate domains within the 134-base-pair rat elastase I enhancer and a third domain at the enhancer-promoter boundary are required for selective expression in pancreatic acinar cells. The domains were detected by a series of 10-base-pair substitution mutations across the elastase I gene regulatory region from positions -200 to -61. The effect of each mutant on the pancreas-specific expression of a linked chloramphenicol acetyltransferase gene was assayed by transfection into pancreatic 266-6 acinar cells and control NIH/3T3 cells. The two enhancer domains are nonredundant, because mutations in either eliminated (greater than 100-fold reduction) expression in 266-6 cells. DNase I protection studies of the elastase I enhancer-promoter region with partially purified nuclear extracts from pancreatic tissue and 266-6 cells revealed nine discrete protected regions (footprints) on both DNA strands. One of three footprints that lie within the two functional domains of the enhancer contained a sequence, conserved among several pancreas-specific genes, which when mutated decreased linked chloramphenicol acetyltransferase expression up to 170-fold in 266-6 cells. This footprint may represent a binding site for one or more pancreas-specific regulatory proteins.     

Polyomavirus DNA replication in the pancreas and in a transformed pancreas cell line has distinct enhancer requirements.

The regulatory DNA (enhancer) of polyomavirus (Py) is a major determinant of tissue-specific DNA replication during acute infection of newborn mice. Previously, we reported that the combination of one of the two Py enhancers (A enhancer) and the repeated Moloney murine leukemia virus (Mo-MuLV) enhancer gave a chimeric Py genome (Py-MuLV) that replicates predominantly in the acinar cells of the pancreas, a tissue not permissive for wild-type PyA2 replication (R. Rochford, B. A. Campbell, and L. P. Villareal. Proc. Nat. Acad. Sci. USA 84:449-453,1987). In this report, we further examine the combined enhancer requirements for acinar cell-specific Py replication. We also compare enhancer requirements for Py replication in the acinar cells of the pancreas with those of a transformed acinar cell line (266-6 cells). The deletion of sequences within the A enhancer of Py-MuLV (nucleotides 5098 to 5132) results in a virus with 10-fold-reduced levels of pancreas-specific replication. The deletion, however, of one of the 72-bp repeated Mo-MuLV enhancer sequences from Py-MuLV results in a complete loss of pancreas-specific DNA replication. Thus, the Py A enhancer is required for efficient replication of Py in the pancreas without otherwise altering organ specificity, but both of the repeated copies of the Mo-MuLV enhancer are essential for pancreas-specific Py replication. In contrast to the enhancer requirements for in vivo pancreas replication, in transformed acinar cells (266-6), PyA2 wild-type replicated efficiently and the Py-MuLV recombinant replicated inefficiently. These data suggest that the cell-specific control of DNA replication is different between normal pancreas cells and their transformed cell line counterparts and that this difference is apparent in the enhancer requirement of cell-specific Py DNA replication.     

Inducible DNA-protein interactions of the murine kappa immunoglobulin enhancer in intact cells: comparison with in vitro interactions.

The large intron of the kappa immunoglobulin gene contains a cis-acting enhancer element, which is important in the tissue-specific expression of the gene. We have confirmed the binding activity of a sequence-specific factor present in lymphoid extracts derived from cell lines expressing, or induced to express, the kappa gene. We have extended these studies to show the binding activity is present in normal activated splenic B cells as well as lambda producing cells, and have demonstrated by DNAse footprint analysis full protection of a sequence containing the 11 bp homology to the SV-40 core enhancer. We have compared these in vitro binding studies with an analysis of protein-DNA interactions in intact murine cell lines using genomic sequencing techniques. We demonstrate significant alterations in DMS reactivity of DNA in the murine 70Z/3 cell line after it is induced to kappa expression. These alterations occur at guanine residues which are part of the the 11 bp core sequence, and are identical to those observed in cells constitutively expressing kappa. This provides direct evidence for the induced binding of the tissue specific factor to intact chromatin. In intact chromatin we also observed significant alteration in the reactivity of a guanine, 3' of the core sequence, which is part of a potential secondary DNA structure, and protection of four residues that are part of a region homologous to the heavy chain enhancer.     

Protein factors specifically binding to the regulatory elements of non-transcribed spacer of rat ribosomal genes

Mouse, rat and human protein factors recognizing regulatory elements of nontranscribed spacer of rat ribosomal genes were studied by gel retardation assay. Protein factors bind specifically to the DNA fragments containing the core promoter sequence of RNA-polymerase I, to "spacer" promoter and to a putative enhancer sequence. Factors of mouse, rat and human nuclear extracts that recognize the region containing the core promoter sequence have similar molecular masses and are not identical to the previously described protein factor TIF-1B. Two factors that bind the "spacer" promoter region differ from the factors of the core promoter. "Spacer" promoter factors of mouse and rat nuclear extracts are probably identical, but differ from those of human extract. Protein factors, recognizing the putative enhancer region of rat and human extracts are alike but were not detected in mouse extract. Regions of nontranscribed spacer containing dispersed and tandem repeats do not bind any specific protein factors.     

The mast cell-specific expression of a protease gene, RMCP II, is regulated by an enhancer element that binds specifically to mast cell trans-acting factors

The rat mast cell protease gene, RMCP II, is specifically expressed in the mucosal subclass of rat mast cells. We show here that the 5'-flanking region of this gene contains a mast cell-specific enhancer that directs preferential expression of a linked reporter gene (human growth hormone) transfected into rat basophilic leukemia cells. A DNA fragment containing the enhancer sequence is capable of binding specifically to mast cell nuclear trans-acting factors. The sequence of this enhancer element contains a region of homology to a consensus core sequence present in the enhancer region of the pancreatic protease genes.