Phytochrome and the regulation of the expression of its genes

In attempting to understand the mechanism of phytochrome action we are studying structural properties of the photoreceptor molecule and the autoregulation of expression of phytochrome genes. Run-off transcription assays in isolated nuclei from Avena indicate that phytochrome decreases the transcript...

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Bibliographic Details
Published in:Philosophical transactions of the Royal Society of London. Series B, Biological sciences Biological sciences, 1986-11, Vol.314 (1166), p.469-480
Main Authors: Quail, P.H, Colbert, J.T, Peters, N.K, Christensen, A.H, Sharrock, R.A, Lissemore, J.L
Format: Article
Language:English
Subjects:
Amino acids
Biological and medical sciences
Chromophores
developmental stages
Edible Grain - genetics
Fundamental and applied biological sciences. Psychology
Gene expression
Gene expression regulation
Gene Expression Regulation - radiation effects
Genes
Irradiation
Messenger RNA
Molecular and cellular biology
Molecular genetics
Molecules
Nucleic Acid Hybridization
Oats
phytochrome
Phytochrome - genetics
Plant Proteins - genetics
plants
Quails
regulation
RNA
RNA, Messenger - biosynthesis
Sequence Homology, Nucleic Acid
Transcription, Genetic
Vegetables - genetics
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Summary:In attempting to understand the mechanism of phytochrome action we are studying structural properties of the photoreceptor molecule and the autoregulation of expression of phytochrome genes. Run-off transcription assays in isolated nuclei from Avena indicate that phytochrome decreases the transcription of its own genes threefold in less than 15 min from Pfr formation. The extent of this decrease is insufficient to account for the observed 10- to 50-fold decrease in mature phytochrome mRNA levels, suggesting that enhanced degradation may also play a significant role in determining the level of this mRNA. Structural analysis of native phytochrome from Avena indicates that the molecule is an elongated dimer of 124 kDa monomers, each consisting of a globular, 74 kDa, NH$_2$-terminal domain bearing the single chromophore at Cys-321, and a more open COOH-terminal domain that bears the dimerization site. Controlled proteolysis and binding of monoclonal antibodies to mapped epitopes has identified two regions, one in the 6-10 kDa NH$_2$-terminal segment and the other ca. 70 kDa from the NH$_2$-terminus, that undergo photoconversion-induced conformational changes and are therefore candidates for involvement in the molecule's regulatory function. Comparison of the full-length amino acid sequences of Avena and Cucurbita phytochromes, derived from nucleotide sequence analysis, indicates overall homology of 65%. The most highly conserved regions are those immediately surrounding the chromophore attachment site, where 29 residues are invariant, and a hydrophobic region between residues 150 and 300, postulated to form a cavity containing the chromophore. In contrast, a strikingly lower level of homology exists at the COOH-terminus of the polypeptide between residues 800 and 1128, indicating a possible lack of involvement of this region in phytochrome function.
ISSN:0080-4622
0962-8436
1471-2970
2054-0280
DOI:10.1098/rstb.1986.0066