Fluorescent Differential Display Identifies Circadian Clock-Regulated Genes in Arabidopsis thaliana

Circadian rhythms in gene expression were first observed in plants more than 13 years ago, but the underlying mechanism controlling rhythmic gene expression is still not understood. The isolation of novel circadian clock-controlled genes (ccgs) is likely to provide new tools for studying circadian r...

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Bibliographic Details
Published in:Journal of biological rhythms 2000-06, Vol.15 (3), p.208-217
Main Authors: Kreps, Joel A., Muramatsu, Takamichi, Furuya, Masaki, Kay, Steve A.
Format: Article
Language:English
Subjects:
Arabidopsis - genetics
Arabidopsis thaliana
Biological Clocks - genetics
Circadian rhythm
Circadian Rhythm - genetics
Data Display
Flowers & plants
Fluorescence
Gene Expression - physiology
Genes
Light
Polymerase Chain Reaction
Space life sciences
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Summary:Circadian rhythms in gene expression were first observed in plants more than 13 years ago, but the underlying mechanism controlling rhythmic gene expression is still not understood. The isolation of novel circadian clock-controlled genes (ccgs) is likely to provide new tools for studying circadian rhythms. Fluorescent differential display (FDD) was used to screen Arabidopsis thaliana mRNAs for cycling transcripts. Seventy PCR primer pairs were screened, and 17 different cycling bands were observed out of an estimated 10,500 bands screened. The identities of 10 bands were determined, and the rhythmic gene expression was confirmed using northern blot analysis. The 10 cycling bands represent 7 different genes, 6 of which are present in the databases and 1 that does not match anything in current databases. The rhythmic expression of the 7 genes is composed of four distinct phases of clock regulation. The results demonstrate that FDD can be used to isolate ccgs. The genes identified in this screen range from known A. thaliana ccgs, as well as genes shown to be clock controlled in other plant species, to a novel gene that may encode a pioneer protein. Further study of these ccgs is likely to increase our understanding of circadian-regulated gene expression.
ISSN:0748-7304
1552-4531
DOI:10.1177/074873040001500302