Endogenous gibberellin A<sub>1</sub> levels control thermoperiodic stem elongation in <i>Pisum sativum</i>

Grindal, G.; Ernstsen, Arild; Reid, James B.; Junttila, Olavi; Lindgård, Bente; Moe, R.

doi:10.1034/j.1399-3054.1998.1020406.x

Cited by 32 publications

(49 citation statements)

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“…The enhanced inhibition of internode elongation correlated with a marked reduction in GA1 levels in these seedlings suggesting that regulation of GA biosynthesis is a major control point for this response. Further analysis showed that pea plants dwarfed by paclobutrazol had a higher rate of 2β-hydroxylation of GA1, leading to lower levels of endogenous GA1 and shorter stems and internodes under negative DIF (Grindal, 1998a). Together these results indicate that, for pea at least, thermoperiodic responses are mediated by changes in the endogenous levels of GA1, via GA biosynthetic and inactivation steps.…”

Section: Diurnal Temperature Effectsmentioning

confidence: 66%

“…Particularly in the horticultural industry, plant morphology is routinely manipulated by altering day length (photoperiod) and temperature of the growth conditions. Plant development can also be influenced by the topical application of hormones, for example, GA, is known to control stem elongation and is often applied to control crop morphology (Grindal et al, 1998a). However, as chemical applications are becoming increasingly less acceptable for use in a commercial environment, thermoperiodic manipulation, i.e.…”

Section: Diurnal Temperature Effectsmentioning

confidence: 99%

“…Auxin levels increase as ambient temperature rises, therefore, auxin-mediated effects on elongation growth are highly temperature-dependent (Gray et al, 1998). Furthermore, GA biosythesis and signaling have been shown to be altered in plants exposed to differing day time and night temperatures (Myster and Moe, 1995;Grindal et al, 1998a;1998b). This has a marked impact on plant stature as adjustment of this pathway can have considerable affects on stem elongation.…”

Section: Introductionmentioning

confidence: 99%

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The highs and lows of plant life: temperature and light interactions in development

Heggie¹,

Halliday²

2005

Int. J. Dev. Biol.

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Plants must constantly respond to changes in the environment whilst maintaining developmental and growth processes if they are to survive into the next generation. A complex network of signals from temperature and light must correctly converge to achieve successful development, through vegetative to reproductive growth. Temperature can be thought of as an environmental factor that provides both 'inductive' and 'maintenance' signals in development. It can stimulate developmental processes such as seed dormancy release, germination and vernalization. However, when temperature is not regarded as inductive, an accommodating network of genes work in concert to ensure growth responses occur regardless of fluctuating microclimate conditions. Many of the temperature-regulated developmental pathways are intimately linked with light signaling. For example, light-temperature interactions are major determinants in the timing of reproductive development. Indeed, the ability to process and react to complex environmental cues is crucial for both normal and adaptive development in a changing environment. These responses are frequently mediated by manipulating the phytohormone network, which serves as a powerful, yet adaptable controller of development. This paper illustrates the influential role temperature perception plays throughout plant development and the close interaction between temperature, light and hormone signaling.

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Section: Diurnal Temperature Effectsmentioning

confidence: 66%

Section: Diurnal Temperature Effectsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The highs and lows of plant life: temperature and light interactions in development

Heggie¹,

Halliday²

2005

Int. J. Dev. Biol.

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“…Jensen et al (1996) reported higher levels of GA 1 in Campanula isophylla grown under positive DIF than negative DIF. It has been suggested that altered stem elongation of pea (Pisum sativum) plants in response to diurnal temperature alternations may be mediated by changes in the endogenous levels of GA 1 (Grindal et al, 1998a). GA 1 levels were found reduced by almost 60% under a temperature regime with low DT and high NT compared to a temperature regime with high DT and 1 This work was supported by the Norwegian Research Council (grant no.…”

mentioning

confidence: 99%

“…GA 1 levels were found reduced by almost 60% under a temperature regime with low DT and high NT compared to a temperature regime with high DT and low NT, with both temperature treatments having the same daily average temperature. The study of GA metabolites suggested that thermoperiodicity could affect both biosynthesis and inactivation steps of GA 1 (Grindal et al, 1998a). Furthermore, based on experiments with GA biosynthesis inhibitors and applications of GA 1 and GA 3 (GA 3 is protected from deactivation by enzymatic 2-oxidation), it has been hypothesized that reduced GA 1 levels in stem tissue under negative DIF are caused by enhanced inactivation of GA 1 by 2-oxidation in pea (Grindal et al, 1998b).…”

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confidence: 99%

Thermoperiodic Stem Elongation Involves Transcriptional Regulation of Gibberellin Deactivation in Pea

et al. 2005

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The physiological basis of thermoperiodic stem elongation is as yet poorly understood. Thermoperiodic control of gibberellin (GA) metabolism has been suggested as an underlying mechanism. We have investigated the influence of different day and night temperature combinations on GA levels, and diurnal steady-state expression of genes involved in GA biosynthesis (LS, LH, NA, PSGA20ox1, and PsGA3ox1) and GA deactivation (PsGA2ox1 and PsGA2ox2), and related this to diurnal stem elongation in pea (Pisum sativum L. cv Torsdag). The plants were grown under a 12-h light period with an average temperature of 17°C. A day temperature/night temperature combination of 13°C/21°C reduced stem elongation after 12 d by 30% as compared to 21°C/13°C. This was correlated with a 55% reduction of GA 1 . Although plant height correlated with GA 1 content, there was no correlation between diurnal growth rhythms and GA 1 content. NA, PsGA20ox1, and PsGA2ox2 showed diurnal rhythms of expression. PsGA2ox2 was up-regulated in 13°C/21°C (compared to 21°C/13°C), at certain time points, by up to 19-fold. Relative to PsGA2ox2, the expression of LS, LH, NA, PSGA20ox1, PsGA3ox1, and PsGA2ox1 was not or only slightly affected by the different temperature treatments. The sln mutant having a nonfunctional PsGA2ox1 gene product showed the same relative stem elongation response to temperature as the wild type. This supports the importance of PsGA2ox2 in mediating thermoperiodic stem elongation responses in pea. We present evidence for an important role of GA catabolism in thermoperiodic effect on stem elongation and conclude that PsGA2ox2 is the main mediator of this effect in pea.The ability of plants to discriminate between temperature during the day and night in their response to flowering, fruiting, and growth is referred to as thermoperiodism (Went, 1944). Erwin et al. (1989) showed that the effects of diurnal temperature alternation on stem length in Lilium longiflorum could best be described by the mathematical difference (DIF) between day temperature (DT) and night temperature (NT). Stem elongation thus increases with an increase in DIF, from a negative to a positive value. Stem elongation in many species is affected by the relationship between DT and NT, and the DIF concept is widely used for growth control in production of ornamental plants propagated in a greenhouse (Erwin and Heins, 1995;Myster and Moe, 1995;Moe and Heins, 2000). A negative DIF treatment (low DT and high NT) is a tool to produce compact flower plants and vegetable seedlings with short internodes without a delay in production time. Also, negative DIF treatments have largely replaced the use of chemical growth retardants in a number of commercial cultures.Thus, the use of such temperature regimes has substantial practical and economic implications in addition to representing an environmentally more sustainable method than chemical growth control. However, very little is known about the mechanisms underlying the thermoperiodic responses in plants. Such knowledge will be of gr...

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Gibberellin Metabolism and Signal Transduction

Thomas¹,

Hedden²

2006

Annual Plant Reviews Volume 24: Plant Hormone Signaling

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Endogenous gibberellin A₁ levels control thermoperiodic stem elongation in Pisum sativum

Cited by 32 publications

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The highs and lows of plant life: temperature and light interactions in development

The highs and lows of plant life: temperature and light interactions in development

Thermoperiodic Stem Elongation Involves Transcriptional Regulation of Gibberellin Deactivation in Pea

Gibberellin Metabolism and Signal Transduction

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Endogenous gibberellin A1 levels control thermoperiodic stem elongation in Pisum sativum

Cited by 32 publications

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The highs and lows of plant life: temperature and light interactions in development

The highs and lows of plant life: temperature and light interactions in development

Thermoperiodic Stem Elongation Involves Transcriptional Regulation of Gibberellin Deactivation in Pea

Gibberellin Metabolism and Signal Transduction

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Endogenous gibberellin A₁ levels control thermoperiodic stem elongation in Pisum sativum