High Temperature‐Induced Repression of the Rice Sucrose Transporter (<i>Os<scp>SUT</scp>1</i>) and Starch Synthesis‐Related Genes in Sink and Source Organs at Milky Ripening Stage Causes Chalky Grains

Phan, Thuy; Ishibashi, Yoshihiro; Miyazaki, Masaru; Tran, Hoang-Dung; Okamura, Kenta; Tanaka, Shun–ichiro; Nakamura, Junya; Yuasa, Takashi; Iwaya‐Inoue, Mari

doi:10.1111/jac.12006

Cited by 70 publications

(40 citation statements)

References 34 publications

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“…The sharply decreased amylase activities account for decreases in starch content in WS-6. In addition, higher SPS activity under heat stress might contribute to a carbon gradient flux from starch to sucrose [43], causing accumulation of sucrose in WS-1, which was consisted with the report of Phan et al [44]. Products from degraded starch by SuSy and AI were exported to cytosol and were again converted to sucrose via SPS [45].…”

Section: Discussionsupporting

confidence: 62%

Influence of heat stress on leaf morphology and nitrogen–carbohydrate metabolisms in two wucai (Brassica campestris L.) genotypes

et al. 2017

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Heat stress is a major environmental stress that limits plant growth and yield worldwide. The present study was carried out to explore the physiological mechanism of heat tolerant to provide the theoretical basis for heat-tolerant breeding. The changes of leaf morphology, anatomy, nitrogen assimilation, and carbohydrate metabolism in two wucai genotypes (WS-1, heat tolerant; WS-6, heat sensitive) grown under heat stress (40°C/30°C) for 7 days were investigated. Our results showed that heat stress hampered the plant growth and biomass accumulation in certain extent in WS-1 and WS-6. However, the inhibition extent of WS-1 was significantly smaller than WS-6. Thickness of leaf lamina, upper epidermis, and palisade mesophyll were increased by heat in WS-1, which might be contributed to the higher assimilation of photosynthates. During nitrogen assimilation, WS-1 possessed the higher nitrogenrelated metabolic enzyme activities, including nitrate reductase (NR), glutamine synthetase (GS), glutamate synthase (GOGAT), and glutamate dehydrogenase (GDH), which were reflected by higher photosynthetic nitrogen-use efficiency (PNUE) with respect to WS-6. The total amino acids level had no influence in WS-1, whereas it was reduced in WS-6 by heat. And the proline contents of both wucai genotypes were all increased to respond the heat stress. Additionally, among all treatments, the total soluble sugar content of WS-1 by heat got the highest level, including higher contents of sucrose, fructose, and starch than those of WS-6. Moreover, the metabolism efficiency of sucrose to starch in WS-1 was greater than WS-6 under heat stress, proved by higher activities of sucrose phosphate synthase (SPS), sucrose synthase (SuSy), acid invertase (AI), and amylase. These results demonstrated that leaf anatomical alterations resulted in higher nitrogen and carbon assimilation in heat-tolerant genotype WS-1, which exhibited a greater performance to resist heat stress.

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Section: Discussionsupporting

confidence: 62%

Influence of heat stress on leaf morphology and nitrogen–carbohydrate metabolisms in two wucai (Brassica campestris L.) genotypes

et al. 2017

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“…Perlakuan peningkatan suhu tidak berpengaruh terhadap jumlah gabah total dan persentase jumlah gabah hampa per rumpun (Tabel 3). Hal tersebut sesuai dengan (Phan et al, 2013;Cao et al, 2016). Penurunan akumulasi bahan kering ini yang dapat menyebabkan hasil gabah yang diproduksi akan berukuran lebih kecil dan berisi tidak penuh atau tidak sempurna.…”

Section: Hasil Dan Pembahasanunclassified

Respon Pertumbuhan dan Hasil Padi (Oryza sativa L.) terhadap Cekaman Suhu Tinggi

et al. 2019

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Global climate change will imply to increase in atmospheric temperature, which can affect the sensitive stadia and decrease rice yield. The objective of this research was to study the growth and production of rice varieties under hightemperature stress. This research was conducted using a split-plot design under partitioned polyethylene house in order to create temperature differences among main-plots. The partitioned treatment successfully increased by 1.7 °C of average temperature with a maximum temperature of 35.0 °C (T1) and 37.6 °C (T2). Rice varieties, namely IR64, Ciherang, IPB-3S, Way Apo Buru, Jatiluhur, Menthik Wangi and Silugonggo were randomized as sub-plot. The results showed that increasing temperature had no significant effect on plant height, tiller number, SPAD-value, leaf area index, and crop growth rate, but significantly decreased 1,000 grains weight by 4.57% and harvest index by 20%. The interaction between temperature and varieties significantly affected a percentage of a productive tiller and partially filled spikelets. Ciherang variety produced the lowest percentage of productive tillers on T2 by 57.6%. Way Apo Buru variety produced the lowest percentage of partially filled spikelets on T2 by 3.01%.

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“…Among these enzymes, SBEII (particularly the isoform, SBEIIb) has been reported to be heat‐labile. The repressed expression of SBEIIb during grain‐filling due to elevated temperature has been thought to be responsible for decreased branching and enhanced elongation of amylopectin chains .…”

Section: Impact Of Air Temperaturementioning

confidence: 99%

Impact of environmental factors on rice starch structure: A review

2014

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Among cereal grains, rice is the world's leading source of caloric energy in the human diet. About 90% of a milled rice kernel is starch (dry weight basis), thus justifying the need to understand the impacts of factors affecting starch composition and behavior when processed. This review presents past and current perspectives regarding the effects of growing environment on the macro, micro, and nano level structures of rice starch. The environmental elements considered in this work are: air temperature, atmospheric carbon dioxide, light, water, and soil nutrients. All these elements are essential for plant development and reproduction. The effect of air temperature is the most widely explored aspect of the environment in relation to rice production and grain quality. This could be attributed in part to the recently purported and highly publicized global warming phenomenon. Amylose content has remained a major predictor of rice starch quality but emerging instrumental techniques have facilitated more thorough research addressing the fine structure of amylopectin, which constitutes ∼70% of the starch present in a milled rice kernel. Kernel chalkiness appears to be the most common visual manifestation of environment‐related stress. Typically, there are genotype by environment interactions; this may result in inconsistent temporal and spatial findings. However, such interactions may prove useful in identifying particular genotypes that are adaptable and stable across growing locations.

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High Temperature‐Induced Repression of the Rice Sucrose Transporter (OsSUT1) and Starch Synthesis‐Related Genes in Sink and Source Organs at Milky Ripening Stage Causes Chalky Grains

Cited by 70 publications

References 34 publications

Influence of heat stress on leaf morphology and nitrogen–carbohydrate metabolisms in two wucai (Brassica campestris L.) genotypes

Influence of heat stress on leaf morphology and nitrogen–carbohydrate metabolisms in two wucai (Brassica campestris L.) genotypes

Respon Pertumbuhan dan Hasil Padi (Oryza sativa L.) terhadap Cekaman Suhu Tinggi

Impact of environmental factors on rice starch structure: A review

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