Phytochrome controls the number of endoreduplication cycles in the Arabidopsis thaliana hypocotyl

Summary A majority of the cells in the Arabidopsis hypocotyl undergo endoreduplication. The number of endocycles in this organ is partially controlled by light. Up to two cycles occur in light‐grown hypocotyls, whereas in the dark about 30% of the cells go through a third cycle. Is the inhibition of...

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Bibliographic Details
Published in:The Plant journal : for cell and molecular biology 1998-01, Vol.13 (2), p.221-230
Main Authors: Gendreau, Emmanuel, Höfte, Herman, Grandjean, Olivier, Brown, Spencer, Traas, Jan
Format: Article
Language:English
Subjects:
Arabidopsis - cytology
Arabidopsis - genetics
Arabidopsis - physiology
Arabidopsis Proteins
Biological and medical sciences
Carrier Proteins - genetics
Carrier Proteins - physiology
Cytochromes - genetics
Cytochromes - physiology
Darkness
DNA, Plant - genetics
Feedback
Fundamental and applied biological sciences. Psychology
Gene Amplification
Genetics
Genic rearrangement. Recombination. Transposable element
Genome, Plant
Hypocotyl - cytology
Hypocotyl - genetics
Hypocotyl - physiology
Life Sciences
Light
Molecular and cellular biology
Molecular genetics
Mutation
Phytochrome - genetics
Phytochrome - physiology
Plant Proteins - genetics
Plant Proteins - physiology
Plants genetics
Ploidies
Ubiquitin-Protein Ligases
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Summary:Summary A majority of the cells in the Arabidopsis hypocotyl undergo endoreduplication. The number of endocycles in this organ is partially controlled by light. Up to two cycles occur in light‐grown hypocotyls, whereas in the dark about 30% of the cells go through a third cycle. Is the inhibition of the third endocycle in the light an indirect result of the reduced cell size in the light‐grown hypocotyl, or is it under independent light control? To address this question, the authors examined the temporal and spacial patterns of endoreduplication in light‐ or dark‐grown plants and report here on the following observations: (i) during germination two endocycles take place prior to any significant cell expansion; (ii) in the dark the third cycle is completed very early during cell growth; and (iii) a mutation that dramatically reduces cell size does not interfere with the third endocycle. The authors then used mutants to study the way light controls the third endocycle and found that the third endocycle is completely suppressed in far red light through the action of phytochrome A and, to a lesser extent, in red light by phytochrome B. Furthermore, no 16C nuclei were observed in dark‐grown constitutive photomorphogenic 1 seedlings. And, finally the hypocotyl of the cryptochrome mutant, hy4, grown in blue light was about three times longer than that of the wild‐type without a significant difference in ploidy levels. Together, the results support the view that the inhibition of the third endocycle in light‐grown hypocotyls is not the consequence of a simple feed‐back mechanism coupling the number of cycles to the cell volume, but an integral part of the phytochrome‐controlled photomorphogenic program.
ISSN:0960-7412
1365-313X
DOI:10.1046/j.1365-313X.1998.00030.x