Tomato fruit stored below 12°C lose quality and can develop chilling injury upon subsequent transfer to a shelf temperature of 20°C. The more severe symptoms of altered fruit softening, uneven ripening and susceptibility to rots can cause postharvest losses. We compared the effects of exposure to mild (10°C) and severe chilling (4°C) on the fruit quality and transcriptome of ‘Angelle’, a cherry-type tomato, harvested at the red ripe stage. Storage at 4°C (but not at 10°C) for 27 days plus an additional 6 days at 20°C caused accelerated softening and the development of mealiness, both of which are commonly related to cell wall metabolism. Transcriptome analysis using RNA-Seq identified a range of transcripts encoding enzymes putatively involved in cell wall disassembly whose expression was strongly down-regulated at both 10 and 4°C, suggesting that accelerated softening at 4°C was due to factors unrelated to cell wall disassembly, such as reductions in turgor. In fruit exposed to severe chilling, the reduced transcript abundances of genes related to cell wall modification were predominantly irreversible and only partially restored upon rewarming of the fruit. Within 1 day of exposure to 4°C, large increases occurred in the expression of alternative oxidase, superoxide dismutase and several glutathione S-transferases, enzymes that protect cell contents from oxidative damage. Numerous heat shock proteins and chaperonins also showed large increases in expression, with genes showing peak transcript accumulation after different times of chilling exposure. These changes in transcript abundance were not induced at 10°C, and were reversible upon transfer of the fruit from 4 to 20°C. The data show that genes involved in cell wall modification and cellular protection have differential sensitivity to chilling temperatures, and exhibit different capacities for recovery upon rewarming of the fruit.
Plants use seasonal cues to initiate flowering at an appropriate time of year to ensure optimal reproductive success. The circadian clock integrates these daily and seasonal cues with internal cues to initiate flowering. The molecular pathways that control the sensitivity of flowering to photoperiods (daylengths) are well described in the model plant Arabidopsis. However, much less is known for crop species, such as legumes. Here, we performed a flowering time screen of a TILLING population of Medicago truncatula and found a line with late-flowering and altered light-sensing phenotypes. Using RNA sequencing, we identified a nonsense mutation in the Phytochromobilin synthase (MtPΦBS) gene, which encodes an enzyme that carries out the final step in the biosynthesis of the chromophore required for phytochrome (phy) activity. The analysis of the circadian clock in the MtpΦbs mutant revealed a shorter circadian period, which was shared with the MtphyA mutant. The MtpΦbs and MtphyA mutants showed downregulation of the FT floral regulators MtFTa1 and MtFTb1/b2 and a change in phase for morning and night core clock genes. Our findings show that phyA is necessary to synchronize the circadian clock and integration of light signalling to precisely control the timing of flowering.
Plants use seasonal cues to initiate flowering at an appropriate time of
year to ensure optimal reproductive success. The circadian clock
integrates these daily and seasonal cues with internal cues to initiate
flowering. The molecular pathways that control the sensitivity of
flowering to photoperiod (daylength) are well described in the model
plant Arabidopsis. However, much less is known in crop species, such as
the legume family species. Here we performed a flowering time screen of
a TILLING population of Medicago truncatula and found a line with
late-flowering and altered light-sensing phenotypes. Using
RNA-sequencing, we identified a nonsense mutation in the
Phytochromobilin Synthase (MtPΦBS) gene, which encodes an enzyme
that carries out the final step in the biosynthesis of the chromophore
required for phytochrome (PHY) activity. The analysis of the
circadian clock in the MtpΦbs mutant revealed a shorter circadian
period, which was shared with the phyA mutant. The MtpΦbs
and MtphyA mutants showed downregulation of FT floral
regulators MtFTa1, MtFTb1/b2 and a shift in phase for morning and
night core clock genes. Our findings show that PHYA is necessary to
synchronize the circadian clock and integration of light signaling to
promote expression of the MtFT genes to precisely time flowering.
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