Functional conservation of a forebrain enhancer from the elephant shark (<Emphasis Type="Italic">Callorhinchus milii</Emphasis>) in zebrafish and mice

Background  

The phylogenetic position of the elephant shark (Callorhinchus milii ) is particularly relevant to study the evolution of genes and gene regulation in vertebrates. Here we examine the evolution of Dlx homeobox gene regulation during vertebrate embryonic development with a particular focus on the forebrain. We first identified the elephant shark sequence orthologous to the URE2 cis -regulatory element of the mouse Dlx1/Dlx2 locus (herein named CmURE2). We then conducted a comparative study of the sequence and enhancer activity of CmURE2 with that of orthologous regulatory sequences from zebrafish and mouse.     

Numerous nuclear proteins bind the long control region of human papillomavirus type 16: a subset of 6 of 23 DNase I-protected segments coincides with the location of the cell-type-specific enhancer.

The long control region of the human papillomavirus type 16 genome is 856 base pairs (bp) long. It contains a cell-type-specific enhancer, a glucocorticoid response element, and sequences mediating the response to the viral gene products of open reading frame E2; all three regulate the promoter P97. We mapped binding sites of trans-acting proteins relevant for the cell-type-specific enhancer and other cis-acting elements by DNase I footprint experiments with nuclear extracts from HeLa cells. Throughout the human papillomavirus type 16 long control region 23 footprints protect 557 of 900 bp. Nine footprints fall into a 400-bp segment that was previously identified to contain the cell-type-specific enhancer. Variations of the protein concentration in the footprint reaction do not affect six of these nine footprints. At high protein concentrations, three footprints fuse to a 106-bp protected region, suggesting that this segment specifically binds several proteins of lower affinity or abundance. Unexpectedly, extracts from human MCF7 and mouse 3T3 cells, in which the enhancer is inactive, give footprints identical to those obtained with HeLa extracts. Seven footprints contain the sequence 5'-TTGGC-3'. Footprint competition experiments suggest that factor NFI binds to these seven motifs. Competition with cloned oligonucleotides in transfections suggests that these elements contribute to the enhancer function. Subcloning identifies a 232-bp fragment between positions 7524 and 7755 as sufficient for full enhancer activity. Several of the six footprinted elements on this segment may cooperate functionally, since subclones of this region show decreased or no cell-type-specific enhancer function.     

A eukaryotic nuclear protein of 130 kDa binds to a bacterial cAMP responsive element.

It has been known that one of the signal transduction mechanisms in Escherichia coli is mediated by cAMP which binds to the receptor protein (CAP), and that CAP complexed with cAMP facilitates gene expression by binding to the specific sequences. To identify a molecular mechanism in eukaryotes similar to a cAMP-mediated pathway in E. coli, the function of the CAP binding site of lac gene in E. coli and the protein(s) interacting with it were examined in a mammalian system. From transient expression studies of the fusion gene between the chloramphenicol acetyltransferase and lac genes, it was found that the lacCAP binding site could act as an enhancer activity on the SV40 promoter, and also as an additive enhancer activity to the SV40 enhancer in HeLa cells. However, the activity was not stimulated by cpt-cAMP (a highly stable analogue of cAMP) in HeLa cells, although it was induced in PC12 cells. These results suggest that a bacterial cAMP responsive element may function also in eukaryotes as a cis-acting element in a cell type dependent manner. Results from gel mobility shift assays showed that a protein(s) exists that specifically binds to the lacCAP binding site in eukaryotic nuclear extracts. As one of the proteins binding to the above site, we have identified a 130 kDa protein by using the Southwestern method. Although a function of the 130 kDa protein has not yet been understood, there is a possibility that the 130 kDa protein may play a role in the regulation of cAMP-dependent gene expression.     

Molecular evolution and genome divergence at <Emphasis Type="Italic">RPB2</Emphasis> gene of the St and H genome in <Emphasis Type="Italic">Elymus</Emphasis> species

Molecular evolution of the second largest subunit of low copy nuclear RNA polymerase II (RPB2) in allotetrploid StH genomic species of Elymus is characterized here. Our study first reported a 39-bp MITE stowaway element insertion in the genic region of RPB2 gene for all tetraploid Elymus St genome and diploid Pseudoroegneria spicata and P. stipifolia St genome. The sequences on 3′-end are highly conserved, with AGTA in all sequences but H10339 (E. fibrosis), in which the AGTA was replaced with AGAA. All 12 Stowaway-containing sequences encompassed a 9 bp conserved TIRs (GAGGGAGTA). Interestingly, the 5′-end sequence of GGTA which was changed to AGTA or deleted resulted in Stowaway excision in the H genome of Elymus sepcies, in which Stowaway excision did not leave footprint. Another two large insertions in all St genome sequences are also transposable-like elements detected in the genic region of RPB2 gene. Our results indicated that these three transposable element indels have occurred prior to polyploidization, and shaped the homoeologous RPB2 loci in St and H genome of Eymus species. Nucleotide diversity analysis suggested that the RPB2 sequence may evolve faster in the polyploid species than in the diploids. Higher level of polymorphism and genome-specific amplicons generated by this gene indicated that RPB2 is an excellent tool for investigating the phylogeny and evolutionary dynamics of speciation, and the mode of polyploidy formation in Elymus species.     

Purification and properties of a protein from the nuclear fraction of HeLa cells binding to a cloned fragment of human satellite DNA III

In nuclear extract of HeLa cells two proteins were identified having the specific binding activity to cloned 1.8kb fragment of human satellite DNA III (HS3). One of the satellite binding proteins (SBP1) purified by column chromatography using DEAE-, phospho- and DNA-cellulose steps interacted also with adenovirus 5 replication enhancer (ARE), another protein (SBP2) was separated during phosphocellulose chromatography from ARE-binding protein. It is suggested that SBP1 is possibly identical to the nuclear factor I purified earlier from the nuclear extract of HeLa cells by other authors.