ZEITLUPE Contributes to a Thermoresponsive Protein Quality Control System in Arabidopsis

Gil, Kyung-Eun; Kim, Woe‐Yeon; Lee, Hyo‐Jun; Faisal, Mohammad; Saquib, Quaiser; Alatar, Abdulrahman A.; Park, Chung‐Mo

doi:10.1105/tpc.17.00612

Cited by 48 publications

(50 citation statements)

References 51 publications

(96 reference statements)

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“…Multiple studies have shown that the ability to clean up unfolded proteins corresponds to the ability of plants to survive exposure to extreme HT. For example, plants deficient in the expression of proteasome subunits (Li et al ), E3 ligases, and autophagy‐related genes (Zhou et al , ; Liu et al ; Gil et al ) are susceptible to HS. Moreover, transgenic plants overexpressing genes encoding either ubiquitin (Tian et al ) or ubiquitin E3 ligases (Lim et al ; Liu et al ; Liu et al ) exhibit enhanced basal and/or acquired heat tolerance.…”

Section: Heat Shock Signaling Mechanismsmentioning

confidence: 99%

Molecular mechanisms governing plant responses to high temperatures

Kang

Ren

et al. 2018

JIPB

202

162

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The increased prevalence of high temperatures (HTs) around the world is a major global concern, as they dramatically affect agronomic productivity. Upon HT exposure, plants sense the temperature change and initiate cellular and metabolic responses that enable them to adapt to their new environmental conditions. Decoding the mechanisms by which plants cope with HT will facilitate the development of molecular markers to enable the production of plants with improved thermotolerance. In recent decades, genetic, physiological, molecular, and biochemical studies have revealed a number of vital cellular components and processes involved in thermoresponsive growth and the acquisition of thermotolerance in plants. This review summarizes the major mechanisms involved in plant HT responses, with a special focus on recent discoveries related to plant thermosensing, heat stress signaling, and HT-regulated gene expression networks that promote plant adaptation to elevated environmental temperatures.

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Section: Heat Shock Signaling Mechanismsmentioning

confidence: 99%

Molecular mechanisms governing plant responses to high temperatures

Kang

Ren

et al. 2018

JIPB

202

162

View full text Add to dashboard Cite

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“…Such disruption of metabolism additionally perturbs hormone biosynthesis and signalling, alters calcium signalling and induces the accumulation of metabolic intermediaries that can subsequently be transported from the mitochondria or chloroplasts to the nucleus (Chan et al ., ; Mullineaux et al ., ). With regard to circadian rhythmicity, high temperatures are sufficient to slow the circadian oscillator, and the circadian system is also delayed by osmotic stress (Gil et al ., ; Litthauer et al ., ). As with many stress responses, the question now facing the field is whether the clock is slowed under these environmental conditions as part of a generalized reaction to cellular damage, or whether specific retrograde signals delay circadian progression as part of an adaptive response.…”

Section: Retrograde Signals Contribute To Circadian Timingmentioning

confidence: 99%

Retrograde signalling as an informant of circadian timing

Jones

2018

New Phytologist

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Contents Summary1749I.The circadian system is responsive to environmental change1749II.Photoassimilates regulate circadian timing1750III.Retrograde signals contribute to circadian timing1750IV.Conclusions1752Acknowledgements1752References1752 Summary The circadian system comprises interlocking transcriptional–translational feedback loops that regulate gene expression and consequently modulate plant development and physiology. In order to maximize utility, the circadian system is entrained by changes in temperature and light, allowing endogenous rhythms to be synchronized with both daily and seasonal environmental change. Although a great deal of environmental information is decoded by a suite of photoreceptors, it is also becoming apparent that changes in cellular metabolism also contribute to circadian timing, through either the stimulation of metabolic pathways or the accumulation of metabolic intermediates as a consequence of environmental stress. As the source of many of these metabolic byproducts, mitochondria and chloroplasts have begun to be viewed as environmental sensors, and rapid advancement of this field is revealing the complex web of signalling pathways initiated by organelle perturbation. This review highlights recent advances in our understanding of how this metabolic regulation influences circadian timing.

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“…These experiments were performed at 23°C, so clearly HSP90 is critical for proper maturation of ZTL outside of a possible role in heat responses, but this does not preclude a role for ZTL in heat stress responses through its interaction with HSP90. Gil et al (2017) now provide evidence that ZTL is an important player in thermotolerance.…”

mentioning

confidence: 99%

“…Among them, HSP90 ensures proper folding of the auxin receptor, disease resistance proteins, and the F-box protein ZEITLUPE (ZTL), a central component of the circadian system in Arabidopsis thaliana. New findings by Gil et al (2017) add a circadian dimension to plant responses to heat stress and show that ZTL mediates polyubiquitination of aggregated proteins, marking them for degradation by the 26S proteasome.…”

mentioning

confidence: 99%

“…Seedlings were exposed to heat stress (40°C for 4.5 h in the middle of the day) and allowed to recover at 23°C for 5 d. Loss of ZTL function is associated with poor tolerance of heat stress, while overexpression of ZTL results in better performance. (Adapted from Gil et al [2017] The Plant Cell, Vol. 29: 2685-2686, November 2017, www.plantcell.org 2017 A number of questions remain.…”

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confidence: 99%

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