Phytochromes and Cryptochromes in the Entrainment of the Arabidopsis Circadian Clock
Circadian clocks are synchronized by environmental cues such as light. Photoreceptor-
deficient Arabidopsis thaliana mutants were used to measure the effect of light fluence rate
on circadian period in plants. Phytochrome B is the primary high-intensity red light
photoreceptor for circadian control, and phytochrome A acts under low-intensity red light.
Cryptochrome 1 and phytochrome A both act to transmit low-fluence blue light to the clock.
Cryptochrome 1 mediates high-intensity blue light signals for period length control. The …
deficient Arabidopsis thaliana mutants were used to measure the effect of light fluence rate
on circadian period in plants. Phytochrome B is the primary high-intensity red light
photoreceptor for circadian control, and phytochrome A acts under low-intensity red light.
Cryptochrome 1 and phytochrome A both act to transmit low-fluence blue light to the clock.
Cryptochrome 1 mediates high-intensity blue light signals for period length control. The …
Circadian clocks are synchronized by environmental cues such as light. Photoreceptor-deficient Arabidopsis thaliana mutants were used to measure the effect of light fluence rate on circadian period in plants. Phytochrome B is the primary high-intensity red light photoreceptor for circadian control, and phytochrome A acts under low-intensity red light. Cryptochrome 1 and phytochrome A both act to transmit low-fluence blue light to the clock. Cryptochrome 1 mediates high-intensity blue light signals for period length control. The presence of cryptochromes in both plants and animals suggests that circadian input pathways have been conserved throughout evolution.
AAAS