1982
DOI: 10.1104/pp.69.3.597
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Phase Shift in the Circadian Rhythm of Floral Promotion by Far Red Energy in Hordeum vulgare L.

Abstract: Eight-day-old barley seedlings (Hordeum vulgare L. cv. Wintex) were pretreated with a single 24-hour daylight fluorescent photoperiod that was supplemented with sufficient far-red energy (FR) to produce a relative red (R)/FR ratio of 0.5. These plants undergo floral initiation about a week after they are returned to 12-hour daylight fluorescent photoperiods (R/ FR ratio, 5.5), but floral development does not begin for an additional 2 weeks. Addition of FR light to a subsequent 12-hour photoperiod decreases the… Show more

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Cited by 22 publications
(3 citation statements)
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“…Because GI regulates light input to the circadian clock (Huq et al, 2000;Martin-Tryon et al, 2007;Oliverio et al, 2007) and functions within the clock oscillator (Park et al, 1999;Edwards et al, 2005;Locke et al, 2005;Gould et al, 2006), changes in its phase could also alter the phase of other clock-associated factors. Not all outputs are affected (CO and FT phases are unchanged), but phase changes in particular rhythms in response to Pfr reduction have been reported in sorghum (Sorghum bicolor; Foster and Morgan, 1995) and barley (Hordeum vulgare; Deitzer et al, 1982), so this phenomenon may not be specific to GI.…”
Section: Discussionmentioning
confidence: 99%
“…Because GI regulates light input to the circadian clock (Huq et al, 2000;Martin-Tryon et al, 2007;Oliverio et al, 2007) and functions within the clock oscillator (Park et al, 1999;Edwards et al, 2005;Locke et al, 2005;Gould et al, 2006), changes in its phase could also alter the phase of other clock-associated factors. Not all outputs are affected (CO and FT phases are unchanged), but phase changes in particular rhythms in response to Pfr reduction have been reported in sorghum (Sorghum bicolor; Foster and Morgan, 1995) and barley (Hordeum vulgare; Deitzer et al, 1982), so this phenomenon may not be specific to GI.…”
Section: Discussionmentioning
confidence: 99%
“…108, 1995 break in the SD Pkarbitis nil (Lumsden and Furuya, 1986;Lumsden, 1991). Phytochrome has not been directly demonstrated to affect photoperiod time-keeping in LDPs, but in Hordeum vulgare FR can phase shift the rhythmic response to FR promotion of flowering (Deitzer et al, 1982). The entrainment of the circadian oscillator is clearly regulated by phytochrome in circadian leaf movements in Samanea saman (Simon et al, 1976), the circadian release of CO, by leaves of Bryopkyllum fedtsckenkoi (Harris and Wilkins, 1976), and circadian Lhcb gene expression in Pkaseolus vulgaris (Tavladoraki et al, 1989).…”
mentioning
confidence: 99%
“…Little is known about the phase-control of such rhythms but it appears to be different from that seen in dark-dominant responses, where the rhythm seems to be 'suspended' after several hours in continuous light and released at a constant phase point on transfer to darkness (Papenfuss & Salisbury, 1967;Lumsden, Thomas & Vince-Prue, 1982). It has, however, been established for Hordeum that a 6 h pulse of FR during continuous light not only enhances the flowering response directly but also causes a phase-shift in the rhythm of sensitivity to FR (Deitzer, Hayes & Jabben, 1982). In this, the system resembles some dark-dominant responses, as for example in Pharbitis nil, where a R pulse during darkness inhibits flowering directly and also causes a phase-shift in the rhythm of sensitivity to R (Lumsden et al, 1982).…”
Section: Discussionmentioning
confidence: 92%