Reverse genetic system for the analysis of parvovirus telomeres reveals interactions between transcription factor binding sites in the hairpin stem

The left-hand or 3'-terminal hairpin of minute virus of mice (MVM) contains sequence elements essential for both viral DNA replication at the left-hand origin (oriL) and for the modulation of the P4 promoter, from which the viral nonstructural gene cassette is transcribed. This hairpin sequence has proven difficult to manipulate in the context of the viral genome. Here we describe a system for generating mutant viruses using synthetic hairpin oligonucleotides and a truncated form of the infectious clone. This allows manipulation of the sequence of the left-hand hairpin and examination of the effects in the context of the viral life cycle. We have confirmed the requirement for a functional parvovirus initiation factor (PIF) binding site and determined that an optimized PIF binding site, with 6 bases between the half-sites, was actually detrimental to viral growth. The distal PIF half-site overlaps a cyclic AMP-responsive element (CRE), which was shown to play an important role in initiating infection, particularly in 324K simian virus 40-transformed human fibroblasts. Interestingly, reducing the spacing of the PIF half-sites, and thus the affinity of the binding site for PIF, increased viral fitness relative to wild type in 324K cells, but not in murine A9 cells. These results indicate that the relative importance of factor binding to the CRE and PIF sites during the establishment of an infection differs markedly between these two host cells and suggest that the suboptimal spacing of PIF half-sites found in wild-type virus represents a necessary reduction in the affinity of the PIF interaction in favor of CRE function.     

Estrogen receptor alpha interaction with estrogen response element half-sites from the rat prolactin gene

Estrogen regulation of the rat prolactin gene requires sequences within the DNase I hypersensitive site II (HSII). We have used overexpressed mouse estrogen receptor alpha (ERalpha) protein to study interactions of ERalpha with an imperfect estrogen response element (ERE) and four ERE half-site sequences from HSII. We confirmed that ERalpha has higher affinity for ERE half-sites than for the imperfect ERE. As expected, the imperfect ERE formed a complex with ERalpha similar to that between mERalpha and a consensus ERE in gel shift assays. The ERalpha complex with half-sites, however, had faster mobility on a 4% polyacrylamide gel than the ERalpha complex with a consensus ERE, indicating that the complexes had different compositions. Ferguson analysis revealed that the ERalpha/half-site complex had a larger molecular weight and higher negative charge than the ERalpha/consensus ERE complex. Similar results were observed with purified human ERalpha, showing that the ERalpha/half-site complex contained only ERalpha and oligonucleotides. These results are best explained by a model in which a dimer of ERalpha is bound to two half-site oligonucleotides. We propose that two ERalpha dimers may interact with the four ERE half-sites in HSII to influence estrogen regulation of this gene.     

Functional cis-element sequence requirements for suppression of gene expression by the TNPA protein of the Zea mays transposon En/Spm

TNPA, one of the two transposition proteins encoded by the En/Spm transposable elements of Zea mays, suppresses the expression of genes that contain an appropriate cis element. Suppression can be monitored in tobacco protoplasts in a transient expression assay as follows. The plant promoter-driven expression of the Escherichia coli-glucuronidase (GUS)-encoding gene, uidA, is repressed in the presence of TNPA if the GUS gene contains a functional cis element in the untranslated RNA leader sequence. Earlier, we found that the minimal cis element is composed of two 12 by sequences in a tail-to-tail inverted orientation. Each 12 by sequence is sufficient to bind TNPA in vitro and can be thought of as a half-site in the cis element. Here, we investigated the sequence requirements of the minimal cis element. Our observations support our expectations that a functional cis element must provide a template to which two TNPA molecules can bind in the correct orientation. Sequences within the half-sites can be altered as long as the eight bases that make up the consensus binding sites are not changed. However, we found the following unexpected sequence specificities. Firstly, some changes to the consensus binding sequence can be tolerated in one half-site, as long as the other site matches the consensus. Secondly, although the region between the half-sites can vary in sequence and in length between two and four bases, a thymidine residue is not tolerated directly 5′ preceding the second half-site. Since many variants of the cis element sequence remain functional, the suppressor response element provides a flexible tool for artificially manipulating the expression of genes.     

Protein-protein interactions facilitate DNA binding by the glucocorticoid receptor DNA-binding domain

We have studied the interaction of the DNA-binding domain of the glucocorticoid receptor with a glucocorticoid response element from the tyrosine aminotransferase gene. This response element consists of two binding sites (half-sites) for the glucocorticoid receptor DNA-binding domain. The sequences of these two half-sites are not identical, and we have previously shown that binding occurs preferentially to one of the half-sites (Tsai, S.-Y., Carlstedt-Duke, J., Weigel, N. L., Dahlman, K., Gustafsson, J.-A., Tsai, M.-J., and O'Malley, B. W. (1988) Cell 55, 361-369). We show here that binding to the low affinity half-site is dependent on previous occupancy of the high affinity half-site. This facilitated binding is dependent on the distance between the two half-sites and their relative orientation but is not dependent on the integrity of the DNA backbone. This is consistent with a model where DNA binding is not only dependent on interactions between the protein and its DNA target sequence but is also influenced by interactions between the protein molecules bound.     

A functional glucocorticoid-responsive unit composed of two overlapping inactive receptor-binding sites: evidence for formation of a receptor tetramer.

An unusual glucocorticoid-responsive element (called GRE A) was found to mediate the induction of the cytosolic aspartate aminotransferase gene by glucocorticoids and was bound by the glucocorticoid receptor in a DNase I footprinting assay. GRE A consists of two overlapping GREs, each comprising a conserved half-site and an imperfect half-site. The complete unit was able to confer glucocorticoid inducibility to a heterologous promoter (delta MTV-CAT). Mutation of any of the half-sites, including the imperfect ones, abolished inducibility by the hormone, demonstrating that each of the isolated GREs was inactive. In electrophoretic mobility shift assays, purified rat liver glucocorticoid receptor (GR) formed a low-mobility complex with GRE A, presumably containing a GR tetramer. When purified bacterially expressed DBD was used, low-mobility complexes as well as dimer and monomer complexes were formed. In inactive mutated oligonucleotides, no GR tetramer formation was detected. Modification of the imperfect half-sites in order to increase their affinity for GR gave a DNA sequence that bound a GR tetramer in a highly cooperative manner. This activated unit consisting of two overlapping consensus GREs mediated glucocorticoid induction with a higher efficiency than consensus GRE.     

Functional cis-element sequence requirements for suppression of gene expression by the TNPA protein of the Zea mays transposon En/Spm

TNPA, one of the two transposition proteins encoded by the En/Spm transposable elements of Zea mays, suppresses the expression of genes that contain an appropriate cis element. Suppression can be monitored in tobacco protoplasts in a transient expression assay as follows. The plant promoter-driven expression of the Escherichia coli-glucuronidase (GUS)-encoding gene, uidA, is repressed in the presence of TNPA if the GUS gene contains a functional cis element in the untranslated RNA leader sequence. Earlier, we found that the minimal cis element is composed of two 12 by sequences in a tail-to-tail inverted orientation. Each 12 by sequence is sufficient to bind TNPA in vitro and can be thought of as a half-site in the cis element. Here, we investigated the sequence requirements of the minimal cis element. Our observations support our expectations that a functional cis element must provide a template to which two TNPA molecules can bind in the correct orientation. Sequences within the half-sites can be altered as long as the eight bases that make up the consensus binding sites are not changed. However, we found the following unexpected sequence specificities. Firstly, some changes to the consensus binding sequence can be tolerated in one half-site, as long as the other site matches the consensus. Secondly, although the region between the half-sites can vary in sequence and in length between two and four bases, a thymidine residue is not tolerated directly 5 preceding the second half-site. Since many variants of the cis element sequence remain functional, the suppressor response element provides a flexible tool for artificially manipulating the expression of genes.     

Structural determinants of a glucocorticoid receptor recognition element

Analysis of the relative inducibility of an extensive series of mutant glucocorticoid response elements (GREs) defines features critical to the constitution of an active GRE. Assuming that function as a GRE reflects binding of glucocorticoid receptor, our activity data are consistent with the recognition of the GRE as two hexamer half-sites, each half-site recognized by a single subunit of a receptor dimer, probably in a cooperative fashion. Integrity of both half-sites is necessary for an active element, and spacing of the half-sites is critical. The identity of 1 basepair within the hexamer half-site is unconstrained; the receptor probably makes no base-specific contacts at this position. In contrast, at other positions within the half-site, limited substitutions (if any) can be tolerated. These results along with data from certain insertion mutations suggest that the receptor recognizes each hexamer half-site as two separable subelements. A further implication is that the DNA-binding domain of the glucocorticoid receptor is composed of distinct subdomains, which interact with the subelements of the recognition sequence.     

UV cross-linking/immunoprecipitation assay: glucocorticoid receptor-adrenergic receptor gene sequence interaction

The rat beta 1-adrenergic receptor (beta 1-AR) gene contains glucocorticoid response element (GRE) half-sites at positions -2767 and -945. In electrophoretic mobility shift assay (EMSA) experiments, neither beta 1-AR GRE half-site recognized glucocorticoid receptors (GRs) obtained from baculovirus high-level expression systems or from mammalian cells. We have developed a sensitive UV cross-linking/immunoprecipitation assay, using a 524-bp fragment containing the prototypical GRE obtained from the rat tyrosine aminotransferase promoter sequence and using antibodies recognizing mammalian GR. Using this assay, we provide evidence that rat beta 1-AR gene sequences recognize mammalian GRs expressed in mouse 3T3 cells and that the site of GR interaction does not appear to specifically contain the beta 1-AR GRE half-sites. This represents one of the first reports demonstrating the utility of a UV cross-linking/immunoprecipitation assay in the detection of mammalian GR interaction with beta 1-AR sequences, is consistent with the lack of specific DNA-GR protein complexes observed in EMSA experiments using oligonucleotide probes containing the beta 1-AR GRE half-sites, and provides evidence that mammalian GR interaction occurs at complex rate beta 1-AR gene sequences.     

Cloning and characterization of hGMEB1, a novel glucocorticoid modulatory element binding protein.

A 21-bp element called glucocorticoid modulatory element (GME) modulates the glucocorticoid receptor-mediated responses via the binding of an as yet poorly characterized transacting complex of proteins containing the 88-kDa GMEB1 and the 67-kDa GMEB2. Using heat shock protein 27 (HSP27) as bait in the yeast two-hybrid assay, we cloned a 1.83-kb cDNA encoding a novel 573-amino acid protein called human GMEB1 (hGMEB1). hGMEB1 possesses a KDWK domain, contains sequences almost identical (36/38) to three tryptic peptides of rat GMEB1 and shares 38% identity with rat GMEB2. hGMEB1 is ubiquitously expressed as a 85-kDa protein in all cell lines and tissues examined. In vitro translated hGMEB1 bound specifically to GME oligonucleotides yielding a complex of similar size to the complex obtained using rat liver nuclear extracts. Both complexes were supershifted with an antibody specific to hGMEB1. Co-immunoprecipitation experiments confirmed the in vivo interaction of HSP27 with hGMEB1.     

Cyclic amplification and selection of targets (CASTing) for the myogenin consensus binding site.

The consensus binding site for the muscle regulatory factor myogenin was determined from an unbiased set of degenerate oligonucleotides using CASTing (cyclic amplification and selection of targets). Stretches of totally random sequence flanked by polymerase chain reaction priming sequences were mixed with purified myogenin or myotube nuclear extracts, DNA-protein complexes were immunoprecipitated with an antimyogenin antibody, and the DNA was amplified by polymerase chain reaction. Specific binding was obtained after four to six cycles of CASTing. The population of selected binding sites was then cloned, and a consensus was determined from sequencing individual isolates. Starting from a pool with 14 random bases, purified myogenin yielded a consensus binding site of AACAG[T/C]TGTT, while nuclear extracts retrieved the sequence TTGCACCTGTTNNTT from a pool containing 35 random bases. The latter sequence is consistent with that predicted from combining an E12/E47 half-site (N[not T]CAC) with the purified myogenin half-site ([T/C] TGTT). The presence of paired E boxes in many of the sequences isolated following CASTing with nuclear extracts proves that myogenin can bind cooperatively with other E-box-binding factors.     

How p53 binds DNA as a tetramer.

The p53 tumor suppressor protein is a tetramer that binds sequence-specifically to a DNA consensus sequence consisting of two consecutive half-sites, with each half-site being formed by two head-to-head quarter-sites (--><-- --><--). Each p53 subunit binds to one quarter-site, resulting in all four DNA quarter-sites being occupied by one p53 tetramer. The tetramerization domain forms a symmetric dimer of dimers, and two contrasting models have the two DNA-binding domains of each dimer bound to either consecutive or alternating quarter-sites. We show here that the two monomers within a dimer bind to a half-site (two consecutive quarter-sites), but not to separated (alternating) quarter-sites. Tetramers bind similarly, with the two dimers within each tetramer binding to pairs of half-sites. Although one dimer within the tetramer is sufficient for binding to one half-site in DNA, concurrent interaction of the second dimer with a second half-site in DNA drastically enhances binding affinity (at least 50-fold). This cooperative dimer-dimer interaction occurs independently of tetramerization and is a primary mechanism responsible for the stabilization of p53 DNA binding. Based on these findings, we present a model of p53 binding to the consensus sequence, with the tetramer binding DNA as a pair of clamps.