Mechanism of delayed seed germination caused by high temperature during grain filling in rice (Oryza sativa L.)

Suriyasak, Chetphilin; Oyama, Yui; Ishida, Toshiaki; Mashiguchi, Kiyoshi; Yamaguchi, Shinjiro; Hamaoka, Norimitsu; Iwaya‐Inoue, Mari; Ishibashi, Yoshihiro

doi:10.1038/s41598-020-74281-9

Cited by 33 publications

(27 citation statements)

References 50 publications

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“…In rice ( Oryza sativa ), heat stress during seed filling has been described to delay germination even after dormancy release treatment and this delay is correlated with an increased expression of NCED genes and a decreased expression of CYP707A genes in imbibed seeds. Hot temperatures have been also shown to affect methylation of catabolism gene promoters and therefore have been suggested to influence catabolism gene expression, ABA levels and germination rates [ 79 ].…”

Section: Aba Metabolism and Seed Dormancy Inductionmentioning

confidence: 99%

ABA Metabolism and Homeostasis in Seed Dormancy and Germination

Sano

Marion‐Poll

2021

IJMS

116

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Abscisic acid (ABA) is a key hormone that promotes dormancy during seed development on the mother plant and after seed dispersal participates in the control of dormancy release and germination in response to environmental signals. The modulation of ABA endogenous levels is largely achieved by fine-tuning, in the different seed tissues, hormone synthesis by cleavage of carotenoid precursors and inactivation by 8′-hydroxylation. In this review, we provide an overview of the current knowledge on ABA metabolism in developing and germinating seeds; notably, how environmental signals such as light, temperature and nitrate control seed dormancy through the adjustment of hormone levels. A number of regulatory factors have been recently identified which functional relationships with major transcription factors, such as ABA INSENSITIVE3 (ABI3), ABI4 and ABI5, have an essential role in the control of seed ABA levels. The increasing importance of epigenetic mechanisms in the regulation of ABA metabolism gene expression is also described. In the last section, we give an overview of natural variations of ABA metabolism genes and their effects on seed germination, which could be useful both in future studies to better understand the regulation of ABA metabolism and to identify candidates as breeding materials for improving germination properties.

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Section: Aba Metabolism and Seed Dormancy Inductionmentioning

confidence: 99%

ABA Metabolism and Homeostasis in Seed Dormancy and Germination

Sano

Marion‐Poll

2021

IJMS

116

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“…DOG-1 boosts ABA signaling through interacting with the protein phosphatase 2C ABA HYPERSENSITIVE GERMINATION, where DOG-1 (by using DOG1–heme complex) inhibits its activity to elevate ABA sensitivity and imposes primary dormancy. Heat stress during grain filling had almost no effect on OsDOG1-like gene expression in imbibed embryos, but the genes OsNCED2 and OsABA8′OH3 play the most important roles in ABA biosynthesis [ 30 , 31 ]. During early grain filling, the resistant cultivars slow the seed germination and are independent of primary dormancy release, though susceptible cultivars generate greater grain chalkiness when subjected to heat stress [ 32 ].…”

Section: Seed Dormancy and Germination—a Game Of Hormonesmentioning

confidence: 99%

“…During early grain filling, the resistant cultivars slow the seed germination and are independent of primary dormancy release, though susceptible cultivars generate greater grain chalkiness when subjected to heat stress [ 32 ]. DNA methylation of ABA catabolism-related and alpha amylase gene promoters inhibits the germination of heat-stressed embryos in plants toward abiotic stress, notably during the grain filling process [ 31 ]. The functions of two new genes, viz.…”

Section: Seed Dormancy and Germination—a Game Of Hormonesmentioning

confidence: 99%

Seed Dormancy and Pre-Harvest Sprouting in Rice—An Updated Overview

Sohn

Subramanian

Thamilarasan

et al. 2021

IJMS

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Pre-harvest sprouting is a critical phenomenon involving the germination of seeds in the mother plant before harvest under relative humid conditions and reduced dormancy. As it results in reduced grain yield and quality, it is a common problem for the farmers who have cultivated the rice and wheat across the globe. Crop yields need to be steadily increased to improve the people’s ability to adapt to risks as the world’s population grows and natural disasters become more frequent. To improve the quality of grain and to avoid pre-harvest sprouting, a clear understanding of the crops should be known with the use of molecular omics approaches. Meanwhile, pre-harvest sprouting is a complicated phenomenon, especially in rice, and physiological, hormonal, and genetic changes should be monitored, which can be modified by high-throughput metabolic engineering techniques. The integration of these data allows the creation of tailored breeding lines suitable for various demands and regions, and it is crucial for increasing the crop yields and economic benefits. In this review, we have provided an overview of seed dormancy and its regulation, the major causes of pre-harvest sprouting, and also unraveled the novel avenues to battle pre-harvest sprouting in cereals with special reference to rice using genomics and transcriptomic approaches.

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“…Moderately elevated temperatures will affect all stages and processes of plant development (Lippmann et al., 2019). The expected adverse effects of high temperature on crop growth include decreased seed development and germination (Suriyasak et al., 2020), increased incidence of plant disease and herbivory (Ristaino et al., 2021), altered rates of respiration (Scafaro et al., 2021), photosynthesis (Moore et al., 2021) and photorespiration (Dusenge et al., 2019), and alterations in flowering time (Cao et al., 2021). Moreover, the effects of increased night‐time temperature are expected to be particularly detrimental for crop yield (Sadok and Jagadish, 2020).…”

Section: Predicted Climate‐change Scenarios and Their Impact On Agriculturementioning

confidence: 99%

Enhancing crop diversity for food security in the face of climate uncertainty

et al. 2021

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SUMMARY Global agriculture is dominated by a handful of species that currently supply a huge proportion of our food and feed. It additionally faces the massive challenge of providing food for 10 billion people by 2050, despite increasing environmental deterioration. One way to better plan production in the face of current and continuing climate change is to better understand how our domestication of these crops included their adaptation to environments that were highly distinct from those of their centre of origin. There are many prominent examples of this, including the development of temperate Zea mays (maize) and the alteration of day‐length requirements in Solanum tuberosum (potato). Despite the pre‐eminence of some 15 crops, more than 50 000 species are edible, with 7000 of these considered semi‐cultivated. Opportunities afforded by next‐generation sequencing technologies alongside other methods, including metabolomics and high‐throughput phenotyping, are starting to contribute to a better characterization of a handful of these species. Moreover, the first examples of de novo domestication have appeared, whereby key target genes are modified in a wild species in order to confer predictable traits of agronomic value. Here, we review the scale of the challenge, drawing extensively on the characterization of past agriculture to suggest informed strategies upon which the breeding of future climate‐resilient crops can be based.

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Mechanism of delayed seed germination caused by high temperature during grain filling in rice (Oryza sativa L.)

Cited by 33 publications

References 50 publications

ABA Metabolism and Homeostasis in Seed Dormancy and Germination

ABA Metabolism and Homeostasis in Seed Dormancy and Germination

Seed Dormancy and Pre-Harvest Sprouting in Rice—An Updated Overview

Enhancing crop diversity for food security in the face of climate uncertainty

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