Sequence-specific and general transcriptional activation by the bovine papillomavirus-1 E2 trans-activator require an N-terminal amphipathic helix-containing E2 domain.

The sequence-specific trans-activator protein of bovine papillomavirus (BPV)-1, E2, strongly increases transcription at promoters containing papillomaviral ACCG(N)4CGGT (E2P) cis motifs, but can also activate a wide range of co-transfected promoters without E2P cores to a lower extent. Analysis of multiple E2 mutants in transfected cells revealed that the C-terminal DNA binding E2 domain binds to the E2P cis sequences in the form of pre-existing nuclear dimers. The DNA binding function of E2 was required for specific trans-activation of the E2P elements, as well as for the function of the previously described C-terminal 'short E2' transrepressor. In addition to the C terminus, specific trans-activation also required an intact N-terminal half of the E2 protein. When expressed alone, the N-terminal E2 domain was found to activate heterologous promoters without E2P elements to an extent comparable to wild-type E2, and therefore represents the functional transcription activation domain of the E2 factor. In contrast to other DNA-binding activator proteins described to date, the transcriptional activation by the E2 factor can occur without specific DNA binding. Its mechanism may thus involve protein--protein interactions between common transcription factors and the N-terminal E2 domain which contains amphipathic helix motifs.

Site-directed antisera to the chromophore binding site of phytochrome: characterization and cross-reactivity.

The preparation and characterization of antisera to a synthetic undecapeptide which encompasses the chromophore binding site on oat phytochrome are described. By direct enzyme-linked immunosorbent assay, this antiserum recognizes bilin-linked peptides in proteolytic digestion mixtures of phytochrome from several plant species including the monocot species, oat and maize, and the dicot species, pea. Competitive enzyme-linked immunosorbent assays have been used to establish the specificity of the site-directed antisera for those peptides homologous with the synthetic undecapeptide which are present in complex mixtures. These results show that the local environment of the phytochromobilin prosthetic group is structurally conserved.

Structure function studies on phytochrome. Identification of light-induced conformational changes in 124-kDa Avena phytochrome in vitro.

Light-mediated conformational changes in highly purified 124-kDa phytochrome preparations from etiolated oat seedlings have been identified by steric exclusion high performance liquid chromatography and limited proteolytic studies. Steric exclusion high performance liquid chromatography studies of oat and rye phytochromes show photoreversible changes in retention times, with the red absorbing form of phytochrome (Pr form) eluting later than the far red absorbing form of phytochrome produced by saturating red light illumination of Pr (Pfr form) in a variety of different mobile phase buffers. Molecular mass calibration with globular protein standards in Tris-glycol buffers provides estimates of 318-349 and 363-366 kDa for the molecular sizes of the Pr and Pfr forms, respectively. These analyses support earlier studies that phytochrome is a nonglobular homodimer of 124-kDa subunits in vitro. Limited proteolytic dissection of phytochrome in nondenaturing buffers with seven different endoproteases provides evidence for two "operational" domains within the 124-kDa subunit with molecular mass values of 69-72 and 52-55 kDa. The larger 69-72-kDa domain contains the site for the chromophore attachment as shown by gel electrophoresis derived enzyme-linked immunosorbent assay utilizing site-directed rabbit antiserum to a synthetic undecapeptide which is homologous with the chromophore binding site on oat phytochrome. This chromophore domain exhibits a compact structure, resistant to further proteolysis except near its N terminus. By contrast, the 52-55-kDa nonchromophore domain contains multiple sites for further proteolytic cleavage as revealed by rapid cleavage to smaller polypeptide fragments. Detailed kinetic analyses of the limited proteolytic cleavage of phytochrome with four endoproteases, subtilisin BPN', thermolysin, trypsin, and clostripain, has mapped specific regions within the 124-kDa subunit that participate in light-induced conformational changes. These include a 4-10-kDa region near the N terminus of the chromophore binding domain and at least two regions within the nonchromophore domain. A comprehensive peptide map of the oat phytochrome subunit is presented, which incorporates the results of these proteolytic studies with the recent, yet unpublished sequence analyses of Avena phytochrome cDNA clones which show the N-terminal localization of the chromophore binding site (Hershey, H. P., Colbert, J. T., Lissemore, J. L., Barker, R. F., and Quail, P. H. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 2332-2336).