1. Photoperiodic flowering and AFT/FTL3 gene expression in flowering-time varieties in chrysanthemum.
- Author
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Takahashi S, Nakano Y, Sumitomo K, Hisamatsu T, Oda A, Onoue N, Mizubayashi T, and Yamakawa H
- Subjects
- Seasons, Chrysanthemum genetics, Chrysanthemum physiology, Flowers genetics, Flowers physiology, Photoperiod, Gene Expression Regulation, Plant, Plant Proteins genetics, Plant Proteins metabolism
- Abstract
Chrysanthemum (Chrysanthemum morifolium Ramat.) is a short-day plant, and flowering is stimulated when the photoperiod is shorter than a variety-specific threshold (critical day length). In Japan, summer-to-autumn-flowering cultivars (SA-cvs.) flower from July to September. Little research has been conducted to understand why SA-cvs. bloom earlier than autumn-flowering cultivars (A-cvs.). We conducted a comparative study of the relationship between the photoperiodic response of flowering and the gene expression of florigen FLOWERING LOCUS T-like 3 (FTL3) and antiflorigen anti-florigenic FT/TFL1 (AFT). SA-cvs. had a longer critical day length than A-cvs. However, in both groups, a decrease in AFT and increase in FTL3 were consistently observed below the critical day length when flowering was promoted. The opposite responses (less flowering, low FTL3, and high AFT) were observed for longer than the critical day lengths. This indicated that flowering in SA-cvs. was controlled by the regulation of AFT/FTL3 expression, similar to that in A-cvs. Next, we studied the mechanism that causes a variation in critical day lengths. In SA-cvs., the photosensitive phase, which occurs at night, occurs earlier than that in A-cvs. This indicates a variation in the endogenous time-keeping mechanism. This was supported by the fact that the circadian rhythmicity of leaf movement was weaker in SA-cvs. than that in A-cvs. Thus, variation in the endogenous time-keeping mechanism may cause a longer critical day length and earlier flowering time in SA-cvs., (© 2025 Scandinavian Plant Physiology Society.) more...
- Published
- 2025
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