The distal elements, OCT and SPH, stimulate the formation of preinitiation complexes on a human U6 snRNA gene promoter in vitro.

The distal control region of a human U6 small nuclear RNA (snRNA) gene promoter contains two separable elements, octamer (OCT) and SPH, found in many vertebrate snRNA genes. Complete distal regions generally account for a 4- to 100-fold stimulation of snRNA gene promoters. We examined the mechanism of transcriptional stimulation by each element when linked to the proximal U6 promoter. Multimers of either OCT or SPH did not increase transcriptional levels above that with a single copy, either in transfected human cells or after in vitro transcription in a HeLa S100 extract. The orientation of a single SPH element differentially stimulated transcription in transfected cells, whereas the orientation of an octamer element was not important. Using Sarkosyl to limit transcription to a single-round, we concluded that promoters containing either OCT or SPH elements supported an increased number of preinitiation complexes in vitro. Furthermore, the rate of formation of U6 promoter preinitiation complexes resistant to low (0.015%) concentrations of Sarkosyl was accelerated on templates containing either OCT or SPH. However, neither element had a significant effect on the number of rounds of reinitiation in the S100 extract.

Intrinsic fluorescence studies of the chaperonin GroEL containing single Tyr --> Trp replacements reveal ligand-induced conformational changes.

Two mutants of GroEL containing the single tyrosine to tryptophan replacement of either residue 203 or 360 in the apical domain have been purified, characterized, and used for fluorescence studies. Both mutants can facilitate the in vitro refolding of rhodanese in an ATP- and GroES-dependent manner, producing yields of recoverable activity comparable to the wild-type chaperonin. Y203W shows some increased hydrophobic exposure and easier urea-induced disassembly compared with wild-type or Y360W, although the unfolding of all the species was similar at high concentrations of urea. Intrinsic fluorescence studies of the two mutants reveal that nucleotide binding (ADP or AMP-PNP (adenosine 5'-(beta,gamma-imino)triphosphate)) induces conformational changes in the tetradecamer that are independent of the presence of the co-chaperonin, GroES. The K1/2 for this transition is approximately 5 microM for both mutants. Energy transfer experiments show that the tryptophan fluorescence of the Y360W mutant is partially quenched ( approximately 50%) upon binding of the fluorescent, hydrophobic probe 4,4'-bis(1-anilino-8-naphthalenesulfonic acid), while the fluorescence of the Y203W mutant is significantly quenched ( approximately 75%). These results are discussed in relation to the molecular mechanism for GroEL function.