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Project description:Plants in temperate regions have evolved mechanisms to survive sudden temperature drops. Previous reports have indicated that the cold acclimation mechanism is light-dependent and does not fully operate under a low light intensity. In these studies, plants were grown under a long-day photoperiod and were more sensitive to freezing stress. However, winter annuals like Arabidopsis thaliana Col-0 germinate in the fall, overwinter as rosettes, and therefore must acclimate under short photoperiods and low irradiance. The role of light intensity was analysed in plants grown under a short-day photoperiod at the growth stage 1.14. Plants were acclimated at 4 °C for seven days under 100 and 20 μmol m-2s-1 PPFD for control and limited-light conditions, respectively. All cold acclimated plants accumulated molecular markers reportedly associated with acquired freezing tolerance, including proline, sucrose, CBFs, and COR gene protein products dehydrins and low-temperature-responsive proteins LTIs. Observed changes indicated that low PPFD did not inhibit the cold acclimation process, and the freezing stress experiment confirmed similar survival rates. The molecular analysis found distinct PPFD-specific adaptation mechanisms that were manifested in contrasting content of anthocyanins, cytokinin conjugates, abundances of proteins forming photosystems, and enzymes of protein, energy, and ROS metabolism pathways. Finally, this study led to the identification of putative proteins and metabolite markers correlating with susceptibility to freezing stress of non-acclimated plants grown under low PPFD. Our data show that Arabidopsis plants grown under short-day photoperiod can be fully cold-acclimated under limited light conditions, employing standard and PPFD-specific pathways.

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Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:We used ChIP sequencing to measure genome-wide binding of transcription factors in the cyanobacterium Synechococcus elongatus PCC 7942 grown under dynamic light regimes that mimic the rapid changes in light intensity that accompany changes in shading. Our analysis reveals that rapid changes in light intensity modulate the binding of RNA polymerase (RNAP) upstream of genes in a way that correlates with changes in downstream gene expression, suggesting that changes in transcriptional regulation control light-responsive gene expression changes. Also, binding of the circadian clock-controlled transcription factor RpaA and the light-responsive transcription factor RpaB change upstream of genes in a manner correlating with RNAP enrichment and downstream gene expression. This suggests that changes in RpaA and RpaB binding upstream of genes regulate the light-responsive expression of genes in cyanobacteria.

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Project description:This experiment profiled a time series of gene expression in leaf 7 of Arabidopsis thaliana plants grown in a controlled environment under 8 h light: 16 h dark (i.e. short days) to compare to the profiles analysed in Breeze et al. (2011) Plant Cell 23(3):873-94 under long day conditions.