Carbon balance and source‐sink metabolic changes in winter wheat exposed to high night‐time temperature

Impa, Somayanda M.; Sunoj, V. S. John; Krassovskaya, Inga; Bheemanahalli, Raju; Obata, Toshihiro; Jagadish, Krishna

doi:10.1111/pce.13488

Cited by 97 publications

(134 citation statements)

References 66 publications

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“…HNT induced rapid senescence resulting in early maturity observed in this study and other reports, led to shortened grain‐filling duration (Figure ; Hurkman & Wood, ; Impa et al, ). SY Monument despite recording 12‐ and 14‐days early maturity under HNT (25°C and 27°C, respectively) compared with 15°C maintained its grain weight and number per plant, supported by the extended chlorophyll index and flag leaves and the spike QY (Figure ).…”

Section: Discussionsupporting

confidence: 75%

“…This response from SY Monument provides rationale for a possible whole plant functional stay green phenomenon having a positive impact on minimizing HNT‐induced yields and quality losses. Because HNT enhances carbon loss due to increased respiration (Impa et al, ), the ability of the plant to minimize or meet the carbon demand by maintaining photosynthesis is a possible option to minimize HNT damage in wheat.…”

Section: Discussionmentioning

confidence: 99%

“…However, significant negative effects on the physiological traits were recorded at a night temperature of 23°C, whereas grain weight and harvest index were negatively affected at 20 and 23°C compared with 14°C night-time temperature (Prasad et al, 2008). due to increased respiration (Impa et al, 2019), the ability of the plant to minimize or meet the carbon demand by maintaining photosynthesis is a possible option to minimize HNT damage in wheat.…”

Section: Identification Of Thresholds For Hnt Damage In Winter Wheatmentioning

confidence: 99%

“…Our recent study has explored the alterations in carbon balance and whole‐plant metabolic changes in wheat leaves, stems and spikes exposed to HNT of 23 o C (Impa et al, ). HNT induced higher night‐time respiration and alterations in whole‐plant carbon balance and affected starch and sucrose metabolism in wheat spikes and tricarboxylic acid cycle related metabolites in leaves (Impa et al, ). Our study, and others quantifying the response of HNT in wheat, have compared genotypic responses using an arbitrary HNT versus optimum conditions (Impa et al, –23°C vs. 15°C; Narayanan, Prasad, Fritz, Boyle, & Gill, –24°C vs. 15°C).…”

Section: Introductionmentioning

confidence: 99%

“…HNT induced higher night‐time respiration and alterations in whole‐plant carbon balance and affected starch and sucrose metabolism in wheat spikes and tricarboxylic acid cycle related metabolites in leaves (Impa et al, ). Our study, and others quantifying the response of HNT in wheat, have compared genotypic responses using an arbitrary HNT versus optimum conditions (Impa et al, –23°C vs. 15°C; Narayanan, Prasad, Fritz, Boyle, & Gill, –24°C vs. 15°C). However, these studies, do not address the critical night‐time temperature threshold, beyond which yield and quality losses are observed.…”

Section: Introductionmentioning

confidence: 99%

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High night temperature induced changes in grain starch metabolism alters starch, protein, and lipid accumulation in winter wheat

Impa

Vennapusa

Bheemanahalli

et al. 2019

Plant Cell & Environment

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Unlike sporadic daytime heat spikes, a consistent increase in night‐time temperatures can potentially derail the genetic gains being achieved. Ten winter wheat genotypes were exposed to six different night‐time temperatures (15–27°C) during flowering and grain‐filling stages in controlled environment chambers. We identified the night‐time temperature of 23oC as the critical threshold beyond which a consistent decline in yields and quality was observed. Confocal laser scanning micrographs of central endosperm, bran, and germ tissue displayed differential accumulation of protein, lipid, and starch with increasing night‐time temperatures. KS07077M‐1 recorded a decrease in starch and an increase in protein and lipid in central endosperm with increasing night‐time temperatures, whereas the same was significantly lower in the tolerant SY Monument. Expression analysis of genes encoding 21 enzymes (including isoforms) involved in grain–starch metabolism in developing grains revealed a high night‐time temperature (HNT)‐induced reduction in transcript levels of adenosine diphosphate glucose pyrophosphorylase small subunit involved in starch synthesis and a ≥2‐fold increase in starch degrading enzymes isoamylase III, alpha‐, and beta‐amylase. The identified critical threshold, grain compositional changes, and the key enzymes in grain starch metabolism that lead to poor starch accumulation in grains establish the foundational knowledge for enhancing HNT tolerance in wheat.

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Section: Discussionsupporting

confidence: 75%

Section: Discussionmentioning

confidence: 99%

Section: Identification Of Thresholds For Hnt Damage In Winter Wheatmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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High night temperature induced changes in grain starch metabolism alters starch, protein, and lipid accumulation in winter wheat

Impa

Vennapusa

Bheemanahalli

et al. 2019

Plant Cell & Environment

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Phenotypic and Developmental Plasticity in Plants

Bush

2023

Encyclopedia of Life Sciences

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Plants have a remarkable ability to alter their development in response to a multitude of environmental cues or stressors. This phenotypic plasticity allows them to continually adapt to their local environment, a necessity for plants as immobile, sessile organisms. A host of environmental cues can be interpreted by plants, including light, temperature, water, and nutrient levels, and these inputs are integrated and translated into a range of developmental outputs from shoot elongation, regulation of root gravitropism, altered flowering time, timing of germination, and overall plant yield. Plasticity enables growth optimisation for a plant's local environment, allows expansion of a species' range into heterogeneous habitats, and may provide an advantage as the changing climate affects growth conditions around the globe. Studies in the model organism Arabidopsis thaliana , as well as in economically important crop plants like tomato and wheat, are helping to more thoroughly define molecular mechanisms for plastic growth responses. Moving forward, studies of growth and plasticity of plants under multiple, integrated stress conditions will help expand our knowledge and abilities to grow crops in a changing climate and feed our ever‐expanding population. Key Concepts Phenotypic plasticity is the ability of a single genotype to produce a range of phenotypes in response to different environmental conditions. The type and degree of a plant's developmental plasticity will help determine future success of individuals and species in changing climates or altered habitats. Multiple environmental signals are integrated to regulate plant growth, development, and yield. Developmental plasticity comes from the meristem, which continuously produces organs throughout the plant's life cycle. Environmental cues can lead to changes in a plant's gene expression and protein abundance, phytohormone‐responsive signalling, and also epigenetic modifications to the plant's genome. Natural genetic variation within a plant species can confer variable plasticity of development in response to a single abiotic stressor, causing some varieties of plants to be hardier than others.

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Post‐flowering high night‐time temperature stress impacts physiology and starch metabolism in field‐grown maize

Hein,

Tiwari,

Kumar

et al. 2024

Agrosystems Geosci & Env

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The global average daily minimum temperatures are increasing at a quicker pace than the average daily maximum temperatures, which are predicted to increase in severity impacting global food production. This study focuses on elucidating the physiological and transcriptional response to high night‐time temperature (HNT) stress in 12 US commercial maize (Zea mays) hybrids using unique field‐based infrastructure. Our experimental objectives were to (i) impose an accurate and uniformly distributed post‐flowering HNT stress of +4.0°C until physiological maturity, (ii) quantify the impact of HNT stress on physiological and yield‐related traits, (iii) establish the impact on end‐use quality of maize kernels formed under HNT stress, and (iv) analyze the differential expression of genes involved in grain starch metabolism. Accurate and uniformly distributed HNT stress of 3.8°C higher than the ambient night‐time temperature throughout the grain‐filling period reduced yield (−14%), kernel weight (−8%), and significantly reduced kernel nutrient content, specifically magnesium in the susceptible hybrids. HNT significantly increased the expression of key genes involved in starch metabolism in the tolerant hybrid. Although HNT stress had a negative impact on yield and quality in field grown maize, two hybrids had physiological and transcriptional regulation that favored higher level of resilience which lays the platform for developing climate smart maize hybrids.

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Carbon balance and source‐sink metabolic changes in winter wheat exposed to high night‐time temperature

Cited by 97 publications

References 66 publications

High night temperature induced changes in grain starch metabolism alters starch, protein, and lipid accumulation in winter wheat

High night temperature induced changes in grain starch metabolism alters starch, protein, and lipid accumulation in winter wheat

Phenotypic and Developmental Plasticity in Plants

Post‐flowering high night‐time temperature stress impacts physiology and starch metabolism in field‐grown maize

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