Amplification of phytochrome induced morphogenesis in plants by the cryptic red light signal (CRS)

The regulation of endogenous levels of ascorbic acid in soybean by far-red absorbing form of phytochrome (Pfr) and by cryptic red light signal (CRS) was studied. Cryptic red light signal is produced by red light pre-irradiation of a photoreceptor other than far-red absorbing form of phytochrome (Pfr) and CRS amplifies the action of phytochrome. The endogenous level of ascorbic acid levels enhanced by phytochrome was amplified by CRS. The lifetime of CRS was from 0 to 2 h and the peak of enhancement of ascorbic acid due to CRS was between 16 to 24 h of dark incubation after the end of the treatment. CRS was found to be ineffective on UV-B enhanced endogenous levels of ascorbic acid.Key words: ascorbic acid, cryptic red light signal, glycine max, phytochrome, ultraviolet-BThe phytochrome mediated morphogenesis involves the conversion of Pr red absorbing form] to Pfr far-red absorbing form] and the magnitude of the response is dependent on Pfr/P tot ratio established at the end of the irradiation.¹ In broom Sorghum anthocyanin synthesis induced by red light R₁] is reversible with far-red light. But a second red pulse R₂] given after the reversal resulted in increased anthocyanin production compared to the first pulse R₁]. When the red pulse was repeatedly given after every reversal with far-red, the anthocyanin production increased proportionately to the number of previously given pulses.² Thus red pre-treatment induced a change in the cellular physiological state or change in content of a relevant substances] which is designated as Cryptic Red Light Signal CRS] associated with red signal transduction.² CRS was first characterized in detail in Broom Sorghum as Pfr amplifying signal produced by red pre-irradiation. CRS is inactive in the absence of Pfr but enhances the action of Pfr. CRS escapes reversal when the plants are exposed to far-red and is probably produced by a different species of phytochrome, distinct from the conventional reversible phytochrome.³We have investigated whether CRS influences other phytochrome regulated processes in plants in addition to anthocyanin synthesis. We chose another process, the synthesis of endogenous ascorbic acid, which is also regulated by conventional phytochrome.⁴ In soybean, the endogenous level of ascorbic acid is enhanced by conventional far-red reversible form of phytochrome. In addition, an independent UV-B photoreceptor non reversible with far-red light] also enhances the endogenous synthesis of ascorbic acid in soybean. By using repeated pulses of red light, we have demonstrated that the Cryptic Red Signal is operative in soybean also and it amplifies the red light induced enhancement in the level of ascorbic acid. That CRS is active only in the presence of Pfr is demonstrated by the fact that pre-irradiation with red light is ineffective in amplifying UV-B induced enhancement of ascorbic acid levels. A similar observation on UV-B induced anthocyanin synthesis has been made in Broom Sorghum.² A separate UV-B photoreceptor independent of phytochrome operates in the plants.⁵ Although CRS is presumably produced by pre-irradiation with red light, it does not enhance UV-B induced anthocyanin synthesis or ascorbic acid synthesis in the absence of formation of Pfr by the second red pulse.The life-time of CRS was determined as 6 h in 20°C and 3 h in 24°C grown seedlings of Broom Sorghum with reference to anthocyanin synthesis.² The life-time of CRS determined in soybean seedlings grown at 25°C was upto 1 h.⁶ Since growing seedlings at a low temperature enhanced the effectiveness of CRS in Broom Sorghum, it was concluded that low temperature may either extend the lifetime of CRS or generate higher amount of CRS.² Although the exact nature of CRS is yet to be analyzed, work in our laboratory has established the universal nature of this signal and evidences have been obtained for CRS effect in promoting red light induced hypocotyls inhibition in Cucumber seedlings and also red light induced synthesis of betacyanins in Amaranthus seedlings (submitted for publication).