Nondestructive Phenomic Tools for the Prediction of Heat and Drought Tolerance at Anthesis in
            <i>Brassica</i>
            Species

Chen, Sheng; Guo, Yiming; Sirault, Xavier; Stefanova, Katia; Saradadevi, Renu; Turner, Neil C.; Nelson, Matthew N.; Furbank, Robert T.; Siddique, Kadambot H. M.; Cowling, Wallace

doi:10.34133/2019/3264872

Cited by 27 publications

(38 citation statements)

References 48 publications

(81 reference statements)

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“…Nonetheless, the relative effect of the combined heat and drought stress treatment was consistently more dramatic than the impact of drought or heat applied individually. This finding highlights the importance of studies that specifically address heat and drought stress combination (Mittler 2006, Chen et al 2019, Zandalinas et al 2017, 2020, Mazdiyasni and AghaKouchak 2015, Lobell and Gourdji 2012, Lawas et al 2018b. Importantly, the results presented here underscore the need to focus on stress combinations occurring during the reproductive growth stages, as the impact on yield is more severe than when stress combination occurs during vegetative development (Fig.…”

Section: Discussionmentioning

confidence: 85%

“…While growing on non‐irrigated lands, these crops are potentially subjected to different environmental stress conditions such as drought, heat stress and their combination. Heat waves combined with acute and prolonged drought stress can have a devastating outcome for agriculture, as well as economic and social stability, primarily impacting drylands used for grain production worldwide (Ciais et al 2005, Mittler 2006, Chen et al 2019, Zandalinas et al 2020). The 2003 drought and heat episode across Europe, for example, caused a 30% reduction in agricultural production (Ciais et al 2005).…”

Section: Introductionmentioning

confidence: 99%

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Meta‐analysis of drought and heat stress combination impact on crop yield and yield components

Cohen

Zandalinas

Huck

et al. 2020

Physiologia Plantarum

211

153

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Episodes of prolonged drought coupled with heat waves (i.e. drought and heat combination) can have a devastating impact on agricultural production and crop yield. It is therefore not surprising that improving tolerance to drought and heat combination has been a major goal for breeders and biotech companies. Although much is known about the physiological and molecular responses of vegetative tissues to a combination of drought and heat stress, less is known about the impact of this stress combination on yield and different yield components. Here, we used a meta-analysis approach to synthesize results from over 120 published case studies of crop responses to combined drought and heat stress. Our findings reveal that drought and heat stress combination significantly impacts yield by decreasing harvest index, shortening the life cycle of crops, and altering seed number, size and composition. Furthermore, these impacts are more severe when the stress combination is applied during the reproductive stage of plants. We further identify differences in how legumes and cereals respond to the stress combination and reveal that utilizing C3 or C4 metabolism may not provide an advantage to plants during stress combinations. Taken together our study highlights a need to focus future studies, as well as breeding efforts, on crop responses to drought and heat combination at the reproductive stage of different crop species.

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Section: Discussionmentioning

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Meta‐analysis of drought and heat stress combination impact on crop yield and yield components

Cohen

Zandalinas

Huck

et al. 2020

Physiologia Plantarum

211

153

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“…From the A n -c i response measurements, we modelled V cmax and J max to gauge the efficiency of carboxylation by Rubisco and the rate of electron transport, respectively. These parameters are frequently assessed to determine the photo-physiological response to heat stress (Perdomo et al, 2016;Haworth et al, 2018;Thomey et al, 2019;Chen et al, 2019); however, we believe that this is the first instance of genetic variation in these parameters being tested under heat stress in rice in a substantial and genetically diverse set of lines. All accessions demonstrated a downregulation in V cmax (Figure 8a), which is likely to be linked to Rubisco activase thermosensitivity (Feller et al, 1998;Makino and Sage, 2007), as well the degradation of other Calvin-cycle enzymes (Sharkey, 2005) and general metabolic reprogramming in the chloroplasts (Wang et al, 2018).…”

Section: Model Typementioning

confidence: 99%

Rapid temperature responses of photosystem II efficiency forecast genotypic variation in rice vegetative heat tolerance

et al. 2020

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A key target for the improvement of Oryza sativa (rice) is the development of heat-tolerant varieties. This necessitates the development of high-throughput methodologies for the screening of heat tolerance. Progress has been made to this end via visual scoring and chlorophyll fluorescence; however, these approaches demand large infrastructural investments to expose large populations of adult plants to heat stress. To address this bottleneck, we investigated the response of the maximum quantum efficiency of photosystem II (PSII) to rapidly increasing temperatures in excised leaf segments of juvenile rice plants. Segmented models explained the majority of the observed variation in response. Coefficients from these models, i.e. critical temperature (T crit) and the initial response (m 1), were evaluated for their usability for forecasting adult heat tolerance, measured as the vegetative heat tolerance of adult rice plants through visual (stay-green) and chlorophyll fluorescence (ɸPSII) approaches. We detected substantial variation in heat tolerance of a randomly selected set of indica rice varieties. Both T crit and m 1 were associated with measured heat tolerance in adult plants, highlighting their usability as high-throughput proxies. Variation in heat tolerance was associated with daytime respiration but not with photosynthetic capacity, highlighting a role for the non-photorespiratory release of CO 2 in heat tolerance. To date, this represents the first published instance of genetic variation in these key gas-exchange traits being quantified in response to heat stress in a diverse set of rice accessions. These results outline an efficient strategy for screening heat tolerance and accentuate the need to focus on reduced rates of respiration to improve heat tolerance in rice.

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“…The mechanism of heat stress sensitivity in oilseed rape was related to disruptions in gametogenesis, pollination, fertilization, and early embryogenesis (Angadi et al., 2000; Chen et al., 2019; Singh et al., 2008) and seed development during the development of pods (siliques) (Morrison, 1993; Weymann et al., 2015; Young et al., 2004). Transient daily heat stress (with temperatures ramping up and down each day from minimum to maximum) for 3 days after first open flower did not reduce leaf stomatal conductance, fresh weight of above‐ground biomass, whole plant volume, and flower volume compared with the control, but significantly decreased seed yield (Chen et al., 2019). Also, heat stress was not associated with a reduction in vegetative growth or photosynthetic activity of Brassica species, and Vcmax , the maximum carboxylation rate of photosynthesis, was double the value in the control treatment during the first 3 days of heat treatment (Chen et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

Transient daily heat stress during the early reproductive phase disrupts pod and seed development in Brassica napus L.

Chen

Stefanova

Siddique

et al. 2020

Food and Energy Security

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Transient daily heat stress during flowering of canola (Brassica napus L.) as a result of global warming is an increasing threat to grain production in this important oilseed crop. We investigated the intensity and duration of transient daily heat stress treatment at different stages of reproductive development in three B. napus genotypes under controlled environment conditions. Heat stress treatments during the week before first open flower on the main stem (S0) or during the first week (S1) or second week (S2) following first open flower greatly reduced pod number and seed yield on the main stem. Heat stress treatment during the third week (S3), fourth week (S4), or fifth week (S5) reduced seed yield more on the branches and less on the main stem as time progressed. Pod number and seed yield were reduced by moderate heat stress (TC2; 32°C/22°C) and high heat stress (TC3; 35°C/25°C), compared with the control (TC1, 25°C/15°C). Each duration of heat stress treatment (3, 5 or 7 days) caused the same reduction in pod number and seed per pod on the main stem. Leaf stomatal conductance, leaf chlorophyll index, plant height, and dry weight of above‐ground biomass increased from TC1 to TC3, which indicates that heat stress in the absence of drought stress does not inhibit vegetative growth. Cool night temperatures (15°C) resulted in recovery of pod number and seed yield after moderate (32°C) but not high (35°C) daily transient heat stress. The range of genotype responses to heat stress was greater under TC2 than under TC3. This research brings forward the critical period for heat stress sensitivity in B. napus to one week before first open flower and defines the conditions for controlled environment screening for heat tolerance in B. napus.

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Nondestructive Phenomic Tools for the Prediction of Heat and Drought Tolerance at Anthesis in Brassica Species

Cited by 27 publications

References 48 publications

Meta‐analysis of drought and heat stress combination impact on crop yield and yield components

Meta‐analysis of drought and heat stress combination impact on crop yield and yield components

Rapid temperature responses of photosystem II efficiency forecast genotypic variation in rice vegetative heat tolerance

Transient daily heat stress during the early reproductive phase disrupts pod and seed development in Brassica napus L.

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