In vivo DNA-protein interactions at hypersensitive site 3.5 of the human beta-globin locus control region.

Using ligation-mediated polymerase chain reaction and in vivo footprinting methods to study the status of DNA-protein interactions at hypersensitive site 3.5 (HS3.5) of the locus control region in K562 and HEL cells, we found that there was protein occupancy in vivo at HS3.5 in both cell lines and the status of DNA-protein interaction was different between K562 and HEL. These data provide direct evidence that specific nuclear factor-DNA complexes form in vivo at functionally important sequence motifs of the HS3.5 in erythroid cells. This indicates that HS3.5 may play an important role in the regulation of the beta-globin gene cluster. K562 is a human erythroleukemia cell line in which the embryonic epsilon-globin gene is predominantly expressed, while the HEL cell line expresses predominantly the fetal beta-globin genes. Thus, HS3.5 might also be involved in the regulation of developmental stage-specific expression of beta-globin genes. Our results are also consistent with the model that each hypersensitive site acts as a functional unit and HS3.5 may facilitate the formation of the HS3 functional unit.     

Uracil-DNA glycosylase as a probe for protein--DNA interactions.

The DNA repair enzyme Uracil-DNA Glycosylase (UDG) can be used to investigate three different features of protein-DNA interactions. Complexes can be probed by simple protection experiments ('footprinting') or by two kinds of interference assays: a missing thymine site (MT-site) experiment and a missing thymine methyl site (MTM-site) experiment. The three probing methods are assessed using the well-characterized in vitro systems of lambda repressor and lac repressor binding to their respective operator sites. The results obtained with UDG probing agree well with previous probing experiments on the same systems and, in certain cases, extend previous interpretations: for example, comparison of the results obtained with the two interference assays shows that formation of the lac repressor-operator complex requires interactions with the methyl group of one particular thymine residue (T-13) in the operator but also requires interactions with other parts of the thymine base at operator positions 7, 8, 9, 21, 23 and 24. Overall, the properties of UDG recommend it as a versatile and convenient method to investigate DNA-protein interactions both in vitro and possibly in vivo.     

Exploring the use of dimethylsulfate for in vivo proteome footprinting

Protein footprinting is a new methodology that is based on probing, typically with the use of MS, of reactivity of different amino acid residues to a modifying reagent. Data thus obtained allow one to make inferences about protein conformations and their intermolecular interactions. Most of the protein footprinting studies so far have been performed on individual proteins in vitro. We explore whether a similar approach is possible with the proteins inside of living cells, employing dimethylsulfate (DMS), a reagent widely used for the in vivo footprinting of nucleic acids. DMS can induce methylation of the lysine, histidine and glutamate residues on proteins. Using models of the histone H2B/H2AZ heterodimer assembled in vitro and from chromatin treated in vivo, we show that the methylation by deuterated DMS allows one to distinguish the accessibility of a particular residue in and out of the protein's environmental/structural context. The detection of changes in protein conformations or their interactions in vivo can provide a new approach to the identification of proteins involved in various intracellular pathways and help in the search for perspective drug targets and biomarkers of diseases.     

A large nucleoprotein assembly at the ends of the viral DNA mediates retroviral DNA integration.

We have probed the nucleoprotein organization of Moloney murine leukemia virus (MLV) pre-integration complexes using a novel footprinting technique that utilizes a simplified in vitro phage Mu transposition system. We find that several hundred base pairs at each end of the viral DNA are organized in a large nucleoprotein complex, which we call the intasome. This structure is not formed when pre-integration complexes are made by infecting cells with integrase-minus virus, demonstrating a requirement for integrase. In contrast, footprinting of internal regions of the viral DNA did not reveal significant differences between pre-integration complexes with and without integrase. Treatment with high salt disrupts the intasome in parallel with loss of intermolecular integration activity. We show that a cellular factor is required for reconstitution of the intasome. Finally, we demonstrate that DNA-protein interactions involving extensive regions at the ends of the viral DNA are functionally important for retroviral DNA integration activity. Current in vitro integration systems utilizing purified integrase lack the full fidelity of the in vivo reaction. Our results indicate that both host factors and long viral DNA substrates may be required to reconstitute an in vitro system with all the hallmarks of DNA integration in vivo.     

Telomere structure in Euplotes crassus: characterization of DNA-protein interactions and isolation of a telomere-binding protein.

The nucleoprotein structure of telomeres from Euplotes crassus was studied by using nuclease and chemical footprinting. The macronuclear telomeres were found to exist as DNA-protein complexes that are resistant to micrococcal nuclease digestion. Each complex encompassed 85 to 130 base pairs of macronuclear DNA and appeared to consist of two structural domains that are characterized by dissimilar DNA-protein interactions. Dimethyl sulfate footprinting demonstrated that very sequence-specific and salt-stable interactions occur in the most terminal region of each complex. DNase I footprinting indicated that DNA in the region 30 to 120 base-pairs from the 5' end lies on a protein surface; the interactions in this region of the complex are unlikely to be sequence specific. A 50-kilodalton telomere-binding protein was isolated. Binding of this protein protected telomeric DNA from BAL 31 digestion and gave rise to many of the sequence-specific DNA-protein interactions that were observed in vivo. The telomeric complexes from E. crassus were very similar in overall structure to the complexes found at Oxytricha telomeres. However, telomeric complexes from the two ciliates showed significant differences in internal organization. The telomeric DNA, the telomere-binding proteins, and the resultant DNA-protein interactions were all somewhat different. The telomere-binding proteins from the two ciliates were found to be less closely conserved than might have been expected. It appears that the proteins are tailored to match their cognate telomeric DNA.     

Evidence of the formation of G-quadruplex structures in the promoter region of the human vascular endothelial growth factor gene

The polypurine/polypyrimidine (pPu/pPy) tract of the human vascular endothelial growth factor (VEGF) gene is proposed to be structurally dynamic and to have potential to adopt non-B DNA structures. In the present study, we further provide evidence for the existence of the G-quadruplex structure within this tract both in vitro and in vivo using the dimethyl sulfate (DMS) footprinting technique and nucleolin as a structural probe specifically recognizing G-quadruplex structures. We observed that the overall reactivity of the guanine residues within this tract toward DMS was significantly reduced compared with other guanine residues of the flanking regions in both in vitro and in vivo footprinting experiments. We also demonstrated that nucleolin, which is known to bind to G-quadruplex structures, is able to bind specifically to the G-rich sequence of this region in negatively supercoiled DNA. Our chromatin immunoprecipitation analysis further revealed binding of nucleolin to the promoter region of the VEGF gene in vivo. Taken together, our results are in agreement with our hypothesis that secondary DNA structures, such as G-quadruplexes, can be formed in supercoiled duplex DNA and DNA in chromatin in vivo under physiological conditions similar to those formed in single-stranded DNA templates.     

Multiple proteins bind to the P2 promoter region of the zein gene pMS1 of maize

Summary A 216 by promoter fragment of the 19 kDa protein zein gene pMS1, containing the CCAAT and TATA boxes, was analysed by a variety of techniques for in vitro interactions with nuclear proteins from endosperm tissue. HMG proteins were found to form stable complexes with these A/T-rich promoter sequences and several specific DNA-binding proteins appear to be involved in the formation of DNA-protein complexes with this fragment. A 29 bp region spanning the two CCAAT boxes was protected from DNase I digestion in footprinting experiments.     

Both locus control region and proximal regulatory elements direct the developmental regulation of beta-globin gene cluster

Using ligation-mediated PCR and in vivo footprinting methods to study the status of DNA-protein interaction at hypersensitive site 2 of locus control region and beta(maj) promoter of erythroid cells of fetal liver and adult bone marrow, we found that during different developmental periods, the status of DNA-protein interaction at both hypersensitive site 2 and beta(maj) promoter changed significantly, and indicated that locus control region might function through a looping mechanism to regulate the expression of downstream genes, and that distal regulatory elements (locus control region, hypersensitive sites) as well as proximal regulatory elements (promoter, enhancer) of beta-globin gene cluster participate in the regulation of developmental specificity.     

T cell-specific expression of the human TNF-alpha gene involves a functional and highly conserved chromatin signature in intron 3

Using a phylogenetic approach, we identified highly conserved sequences within intron 3 of the human TNF-alpha gene. These sequences form cell type-specific DNase I hypersensitivity sites and display cell type-specific DNA-protein contacts in in vivo genomic footprints. Consistent with these results, intron 3 confers specific activity upon a TNF-alpha reporter gene in Jurkat T cells, but not THP-1 monocytic cells. Thus, using a combinatorial approach of phylogenetic analysis, DNase I hypersensitivity analysis, in vivo footprinting, and transfection analysis, we demonstrate that intronic regulatory elements are involved in the cell type-specific regulation of TNF-alpha gene expression.