Mechanisms for flexibility in DNA sequence recognition and VP16-induced complex formation by the Oct-1 POU domain.

DNA binding by the Oct-1 protein is directed by its POU domain, a bipartite DNA-binding domain made up of a POU-specific (POUS) domain and a POU-homeo (POUH) domain, two helix-turn-helix-containing DNA-binding modules that cooperate in DNA recognition. Although the best-characterized DNA target for Oct-1 binding is the octamer sequence ATGCAAAT, Oct-1 also binds a number of different DNA sequence elements. For example, Oct-1 recognizes a form of the herpes simplex virus VP16-responsive TAATGARAT element, called the (OCTA-)TAATGARAT site, that lacks octamer site similarity. Our studies suggest two mechanisms by which Oct-1 achieves flexible DNA sequence recognition. First, an important arginine found in the Oct-1 POUS domain tolerates substitutions of its base contacts within the octamer site. Second, on the (OCTA-)TAATGARAT site, the POUS domain is located on the side of the POUH domain opposite from where it is located on an octamer site. This flexibility of the Oct-1 POU domain in DNA binding also has an impact on its participation in a multiprotein-DNA complex with VP16. We show that Oct-1 POUS domain residues that contact DNA have different effects on VP16-induced complex formation depending on whether the VP16-responsive element involved has overlapping octamer similarity or not.     

In vivo footprinting studies suggest a role for chromatin in transcription of the human 7SK gene

Mutation and deletion analyses of mammalian class III small nuclear RNA genes transcribed by RNA polymerase (pol) III have defined three functional promoter elements: a distal sequence element (DSE) at around -220, a proximal sequence element (PSE) at around -60 and a TATA box at around -30. Although binding studies have identified factors that bind to these sites in vitro, it is not known exactly how proteins interact with the promoters of these genes in vivo. In this study, we have used dimethyl sulphate and DNase I treatment of HeLa cells and nuclei, respectively, followed by linker-mediated polymerase chain reaction, to obtain in vivo footprints of proteins binding to the promoter of the Pol III-transcribed 7SK gene. Our results show that most of the characterised promoter elements of this gene are protected in vivo in these cells, and the pattern of DNase I protection suggests that a nucleosome lies between the DSE and the PSE. Methylation protection was also seen upstream of the DSE over a sequence corresponding to the binding site of a POZ domain-containing protein, ZID, which interacts with components of histone deacetylase complexes. These findings suggest that chromatin structure plays a role in the cascade of protein-DNA interactions that regulate expression of this pol III-transcribed gene.