A reversible light- and genotype-dependent acquired thermotolerance response protects the potato plant from damage due to excessive temperature

Trapero-Mozos, Almudena; Ducreux, Laurence J. M.; Bita, Craita E.; Morris, Wayne L.; Wiese, Cosima; Morris, Jenny; Paterson, Christy; Hedley, Pete E.; Hancock, Robert D.; Taylor, Mark A.

doi:10.1007/s00425-018-2874-1

Cited by 19 publications

(16 citation statements)

References 43 publications

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“…Adopting more realistic regimes and justifying these with data from relevant natural settings, as well as providing better descriptions of the temperature ranges around set points would enable a more nuanced investigation of the differences between acute and chronic stress responses, and between facultative protective responses and signs of irreparable damage (Lai & He, 2016; Trapero‐Mozos et al ., 2018). At present, the definition and use of ‘stress’ and ‘stressful events’ is somewhat ad hoc and impedes our ability to compare results or derive generalizations (Jansen & Potters, 2017).…”

Section: Considerations When Designing Thermal Tolerance Experimentsmentioning

confidence: 99%

The thermal tolerance of photosynthetic tissues: a global systematic review and agenda for future research

et al. 2020

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Summary Understanding plant thermal tolerance is fundamental to predicting impacts of extreme temperature events that are increasing in frequency and intensity across the globe. Extremes, not averages, drive species evolution, determine survival and increase crop performance. To better prioritize agricultural and natural systems research, it is crucial to evaluate how researchers are assessing the capacity of plants to tolerate extreme events. We conducted a systematic review to determine how plant thermal tolerance research is distributed across wild and domesticated plants, growth forms and biomes, and to identify crucial knowledge gaps. Our review shows that most thermal tolerance research examines cold tolerance of cultivated species; c. 5% of articles consider both heat and cold tolerance. Plants of extreme environments are understudied, and techniques widely applied in cultivated systems are largely unused in natural systems. Lastly, we find that lack of standardized methods and metrics compromises the potential for mechanistic insight. Our review provides an entry point for those new to the methods used in plant thermal tolerance research and bridges often disparate ecological and agricultural perspectives for the more experienced. We present a considered agenda of thermal tolerance research priorities to stimulate efficient, reliable and repeatable research across the spectrum of plant thermal tolerance.

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Section: Considerations When Designing Thermal Tolerance Experimentsmentioning

confidence: 99%

The thermal tolerance of photosynthetic tissues: a global systematic review and agenda for future research

et al. 2020

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“…Recent work has demonstrated the mechanisms by which tuberization signaling and initiation is impaired at elevated temperature (Lehretz et al, 2019;Morris et al, 2019). However, there is wide variation for heat stress tolerance across potato germplasm that could be exploited to ensure the sustainability of yield in warmer climates (Levy and Veilleux, 2007;Trapero-Mozos et al, 2018a).…”

Section: Introductionmentioning

confidence: 99%

Physiological, Biochemical, and Transcriptional Responses to Single and Combined Abiotic Stress in Stress-Tolerant and Stress-Sensitive Potato Genotypes

et al. 2020

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“…Also, an adverse effect on photosynthesis resulting from chlorophyll loss and reduced CO 2 fixation has been reported for tuber-forming Solanum species (Reynolds et al 1990). A large number of differentially expressed genes involved in many biological processes and molecular functions as well as differential metabolite accumulation have been identified in response to mild to moderate heat stress in potato leaves and tubers (Hancock et al 2014;Trapero-Mozos et al 2018). Tolerance to elevated temperatures in potato is likely a polygenic trait and, thus expected to be substantially influenced by genotype-environment interactions.…”

Section: Introductionmentioning

confidence: 99%

Physiological and growth responses of potato cultivars to heat stress

Tang

Niu

Zhang

et al. 2018

Botany

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Climate warming is subjecting plants to heat stress, which can affect their physiological processes thereby impacting their growth, development, and productivity. Potato (Solanum tuberosum L.) is a staple food worldwide, but potato crops are very sensitive to heat stress. We have studied the effects of heat stress on the leaf chlorophyll content, plant growth, and tuber yield of 55 commercial potato cultivars in clonal tests under heat-stress conditions [HS; 35 °C (day), 28 °C (night)] and control (non-stress) conditions [CK; 22 °C (day), 18 °C (night)]. The potato cultivars varied in their response to heat stress. Overall, heat stress reduced leaf size, increased the SPAD index values for leaf chlorophyll by up to 65%, and increased plant height by 64%, but severely reduced (by 93%) the mass of the largest tuber. The HS:CK SPAD ratios positively correlated with the HS:CK plant height ratio, mass of the largest tuber under heat stress, and the HS:CK ratio for mass of the largest tuber. Potato cultivars displayed a correlated response to heat stress for their leaf chlorophyll content, plant height, and tuber mass. We have identified the most heat-tolerant and heat-susceptible cultivars for these traits. Under heat-stress conditions, potato cultivars tend not to show as much reduction in tuber mass if the plants have greater increases in leaf chlorophyll content and plant height.

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A reversible light- and genotype-dependent acquired thermotolerance response protects the potato plant from damage due to excessive temperature

Cited by 19 publications

References 43 publications

The thermal tolerance of photosynthetic tissues: a global systematic review and agenda for future research

The thermal tolerance of photosynthetic tissues: a global systematic review and agenda for future research

Physiological, Biochemical, and Transcriptional Responses to Single and Combined Abiotic Stress in Stress-Tolerant and Stress-Sensitive Potato Genotypes

Physiological and growth responses of potato cultivars to heat stress

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