Physiological and molecular attributes contribute to high night temperature tolerance in cereals

Schaarschmidt, Stephanie; Lawas, Lovely Mae F; Kopka, Joachim; Jagadish, S. V. Krishna; Zuther, Ellen

doi:10.1111/pce.14055

Cited by 20 publications

(16 citation statements)

References 106 publications

(321 reference statements)

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“…Our analyses showed that rice phenology responded differently to T min , T max and T mean , and T min affected more significantly the GPs for all the three rice types, which was well supported by chambers and field-based studies in cereals across major cropping regions of the world (Peng et al 2004, Impa et al 2021, Schaarschmidt et al 2021, Sakai et al 2022. The stronger negative effects of T min may mostly result from its greater increasing rate (supplementary figure S3).…”

Section: The Different Effects Of Daily Mean Daytime and Night-time W...supporting

confidence: 77%

Response of rice phenology to climate warming weakened across China during 1981–2018: did climatic or anthropogenic factors play a role?

Zhang

et al. 2022

Environ. Res. Lett.

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Climate warming has substantially shifted plant phenology, which alters the length of growing season and consequently affects plant productivity. Recent studies showed a stalled or reversed impact of climate change on vegetation phenology since 1998, as well as an asymmetric warming effect. However, how field crop phenology responded to the recent climate warming and the asymmetric warming remains unknown. In addition, the relative roles of climate change, sowing date and cultivars shifts in the spatiotemporal changes of crop phenology at different regions need to be better understood. Here, using the latest 9,393 phenological records at 249 agro-meteorological stations across China over 1981-2018, we critically investigated the spatiotemporal dynamics of rice phenology and disentangled the effects of different drivers by exploiting the physiological relationship between crop phenology and thermal accumulation. The results showed that length of growing period (GP) increased by 3.24 ± 0.15 days/decade for single rice, 1.90 ± 0.22 days/decade for early rice and 0.47 ± 0.14 days/decade for late rice. Although climate warming during rice GP did not slow down, the trends in rice GP and the correlations between GP and temperature decreased generally from 1981-1999 to 2000-2018. The weakened phenological response to climate change was mainly caused by agronomic managements, especially cultivar shifts. Climate warming shortened GP by 0.84 ± 1.80, 1.23 ± 0.77, and 1.29 ± 1.24 days/decade for single rice, early rice and late rice, respectively. However, cultivar shifts prolonged it respectively by 3.28 ± 3.68, 2.15 ± 2.38, and 2.31 ± 3.36 days/decade, totally offsetting the negative effects of climate warming. Rice responded to daytime and night-time warming differently with night-time temperature affecting GPs more. Our study provided new insights that rice phenology responded to night-time warming more than daytime warming across China however the response to climate warming weakened, and cultivar shifts outweighed climate change in affecting rice phenology.

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Section: The Different Effects Of Daily Mean Daytime and Night-time W...supporting

confidence: 77%

Response of rice phenology to climate warming weakened across China during 1981–2018: did climatic or anthropogenic factors play a role?

Zhang

et al. 2022

Environ. Res. Lett.

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“…A new paradigm in the form of metabolomics has emerged as a potential approach to establish signature metabolites as markers associated with agronomically important traits ( Schaarschmidt et al, 2021 ). Metabolite levels are a quantitative trait and hence in QTL mapping and GWAS they are considered as quantitative phenotypic trait.…”

Section: Metabolomics: An Underutilized Technique In Lentil Breedingmentioning

confidence: 99%

Omics Path to Increasing Productivity in Less-Studied Crops Under Changing Climate—Lentil a Case Study

et al. 2022

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Conventional breeding techniques for crop improvement have reached their full potential, and hence, alternative routes are required to ensure a sustained genetic gain in lentils. Although high-throughput omics technologies have been effectively employed in major crops, less-studied crops such as lentils have primarily relied on conventional breeding. Application of genomics and transcriptomics in lentils has resulted in linkage maps and identification of QTLs and candidate genes related to agronomically relevant traits and biotic and abiotic stress tolerance. Next-generation sequencing (NGS) complemented with high-throughput phenotyping (HTP) technologies is shown to provide new opportunities to identify genomic regions and marker-trait associations to increase lentil breeding efficiency. Recent introduction of image-based phenotyping has facilitated to discern lentil responses undergoing biotic and abiotic stresses. In lentil, proteomics has been performed using conventional methods such as 2-D gel electrophoresis, leading to the identification of seed-specific proteome. Metabolomic studies have led to identifying key metabolites that help differentiate genotypic responses to drought and salinity stresses. Independent analysis of differentially expressed genes from publicly available transcriptomic studies in lentils identified 329 common transcripts between heat and biotic stresses. Similarly, 19 metabolites were common across legumes, while 31 were common in genotypes exposed to drought and salinity stress. These common but differentially expressed genes/proteins/metabolites provide the starting point for developing high-yielding multi-stress-tolerant lentils. Finally, the review summarizes the current findings from omic studies in lentils and provides directions for integrating these findings into a systems approach to increase lentil productivity and enhance resilience to biotic and abiotic stresses under changing climate.

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“…A large genetic diversity exists in crop plants, with different level of sensitivity observed in response to heat stress, but exploiting higher levels of heat tolerance for crop improvement has been a challenge due to limitations related to phenotyping large populations (Impa et al, 2021). Using metabolomics and transcriptomics approaches, Schaarschmidt, Lawas, Kopka, Jagadish, and Zuther (2021) show the relevance of deriving molecular markers to enhance our ability to capture large genetic diversity for heat stress responses. Schaarschmidt et al (2021) reveal underlying metabolites and transcripts that differentiate heat‐tolerant rice and wheat from susceptible genotypes, indicating the possibility of developing molecular markers to complement ongoing efforts to breed crops with increased heat tolerance.…”

Section: Synthesis Of Plant Responses To Heatmentioning

confidence: 99%

“…Using metabolomics and transcriptomics approaches, Schaarschmidt, Lawas, Kopka, Jagadish, and Zuther (2021) show the relevance of deriving molecular markers to enhance our ability to capture large genetic diversity for heat stress responses. Schaarschmidt et al (2021) reveal underlying metabolites and transcripts that differentiate heat‐tolerant rice and wheat from susceptible genotypes, indicating the possibility of developing molecular markers to complement ongoing efforts to breed crops with increased heat tolerance.…”

Section: Synthesis Of Plant Responses To Heatmentioning

confidence: 99%

Scaling plant responses to high temperature from cell to ecosystem

Jagadish

Way

Sharkey

2021

Plant Cell & Environment

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Physiological and molecular attributes contribute to high night temperature tolerance in cereals

Cited by 20 publications

References 106 publications

Response of rice phenology to climate warming weakened across China during 1981–2018: did climatic or anthropogenic factors play a role?

Response of rice phenology to climate warming weakened across China during 1981–2018: did climatic or anthropogenic factors play a role?

Omics Path to Increasing Productivity in Less-Studied Crops Under Changing Climate—Lentil a Case Study

Scaling plant responses to high temperature from cell to ecosystem

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