An organ-specific role for ethylene in rose petal expansion during dehydration and rehydration

Dehydration is a major factor resulting in huge loss from cut flowers during transportation. In the present study, dehydration inhibited petal cell expansion and resulted in irregular flowers in cut roses, mimicking ethylene-treated flowers. Among the five floral organs, dehydration substantially el...

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Bibliographic Details
Published in:Journal of experimental botany 2013-05, Vol.64 (8), p.2333-2344
Main Authors: Liu, Daofeng, Liu, Xiaojing, Meng, Yonglu, Sun, Cuihui, Tang, Hongshu, Jiang, Yudong, Khan, Muhammad Ali, Xue, Jingqi, Ma, Nan, Gao, Junping
Format: Article
Language:English
Subjects:
analysis
Arabidopsis
Arabidopsis - metabolism
Arabidopsis - physiology
beta-glucuronidase
Biological and medical sciences
Biosynthesis
Calyx
chemistry
corolla
cut flowers
Dehydration
Dehydration - metabolism
ethylene
Ethylene production
Ethylenes
Ethylenes - analysis
Ethylenes - metabolism
Flowers
Flowers - chemistry
Flowers - growth & development
Flowers - metabolism
Flowers - physiology
Fundamental and applied biological sciences. Psychology
Genes
genetically modified organisms
growth & development
metabolism
Oral rehydration
Petals
physiology
pistil
Plant physiology and development
Plant Proteins
Plant Proteins - metabolism
Plants
Plants, Genetically Modified
Plants, Genetically Modified - metabolism
Plants, Genetically Modified - physiology
Receptors
rehydration
RESEARCH PAPER
Rosa
Rosa - metabolism
Rosa - physiology
stamens
transportation
Water
Water - metabolism
Water - physiology
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Summary:Dehydration is a major factor resulting in huge loss from cut flowers during transportation. In the present study, dehydration inhibited petal cell expansion and resulted in irregular flowers in cut roses, mimicking ethylene-treated flowers. Among the five floral organs, dehydration substantially elevated ethylene production in the sepals, whilst rehydration caused rapid and elevated ethylene levels in the gynoecia and sepals. Among the five ethylene biosynthetic enzyme genes (RhACS1-5), expression of RhACS1 and RhACS2 was induced by dehydration and rehydration in the two floral organs. Silencing both RhACS1 and RhACS2 significantly suppressed dehydration- and rehydration-induced ethylene in the sepals and gynoecia. This weakened the inhibitory effect of dehydration on petal cell expansion. β-glucuronidase activity driven by both the RhACS1 and RhACS2 promoters was dramatically induced in the sepals, pistil, and stamens, but not in the petals of transgenic Arabidopsis. This further supports the organ-specific induction of these two genes. Among the five rose ethylene receptor genes (RhETR1-5), expression of RhETR3 was predominantly induced by dehydration and rehydration in the petals. RhETR3 silencing clearly aggravated the inhibitory effect of dehydration on petal cell expansion. However, no significant difference in the effect between RhETR3-silenced flowers and RhETR-genes-silenced flowers was observed. Furthermore, RhETR-genes silencing extensively altered the expression of 21 cell expansion-related downstream genes in response to ethylene. These results suggest that induction of ethylene biosynthesis by dehydration proceeds in an organ-specific manner, indicating that ethylene can function as a mediator in dehydration-caused inhibition of cell expansion in rose petals.
ISSN:0022-0957
1460-2431
DOI:10.1093/jxb/ert092