水稻高温感知及响应机制的研究进展

doi:10.3969/j.issn.0253-9608.2022.06.001

自然杂志 ›› 2022, Vol. 44 ›› Issue (6): 411-421.doi: 10.3969/j.issn.0253-9608.2022.06.001

• 特约专稿 • 下一篇

水稻高温感知及响应机制的研究进展

阚义^①②，林鸿宣^①②

①中国科学院分子植物科学卓越创新中心，植物分子遗传国家重点实验室，上海 200032；②岭南现代农业科学与技术广东省实验室，广州 511431

收稿日期:2022-11-09 出版日期:2022-12-25 发布日期:2022-12-19
通讯作者: 林鸿宣，中国科学院院士，研究方向：作物遗传与功能基因组学。
基金资助:
国家自然科学基金资助项目(31788103、32201705)、中国博士后科学基金资助项目(2022T150648)

A research progress of thermo-perception and thermo-responses in rice

KAN Yi^①②, LIN Hongxuan^①②

①National Key Laboratory of Plant Molecular Genetics, CAS Centre for Excellence in Molecular Plant Sciences and Collaborative Innovation Center of Genetics and Development, Shanghai 200032, China；②Guangdong Laboratory for Lingnan Modern Agriculture, Guangzhou 511431, China

Received:2022-11-09 Online:2022-12-25 Published:2022-12-19

摘要/Abstract

摘要： 全球气候变暖威胁粮食安全，水稻极易受到高温的影响而减产。植物通过不同层面感知高温并激活下游的高温响应，包括膜流动性、蛋白质内稳态和活性氧内稳态平衡的改变等。水稻在不同的亚细胞结构(细胞膜、内质网、叶绿体)和不同的生理生化过程(核酸、蛋白质、代谢)上响应高温。自然位点在生产应用上更为便捷，其中TT1(Thermotolerance 1)、TT2、TT3是三个重要的水稻耐高温自然位点，并分别通过参与毒性蛋白清除、钙信号介导的蜡质代谢以及细胞膜-叶绿体信号转导调控水稻抗热，因此挖掘耐高温自然位点，解析作物高温感知及响应机制，为培育抗高温作物新品种提供理论基础，具有重要意义。

关键词: 高温, 水稻, 热感知, 热响应, 自然位点

Abstract: Global warming threatens food security, and rice is vulnerable to high temperatures, especially at reproductive stage. Plants perceive high temperatures and activate downstream responses in different levels, including disruptions in membrane fluidity, protein homeostasis and reactive oxygen species homeostasis. Rice responds to high temperature in different subcellular structures (cell membrane, endoplasmic reticulum, chloroplast) and different physiological and biochemical processes (nucleic acid, protein, metabolism). Natural alleles are more convenient for agricultural production, among which TT1 (Thermotolerance 1), TT2 and TT3 are three indispensable natural alleles conferring rice thermotolerance respectively via cytotoxic protein elimination, calcium signaling-mediated wax metabolism and membrane-chloroplast signaling. Therefore, it is of great significance to mine natural alleles of thermotolerance and clarify the mechanism of thermo-perception and thermo-responses, providing a theoretical basis for breeding thermotolerant varieties in crops.

阚义, 林鸿宣. 水稻高温感知及响应机制的研究进展[J]. 自然杂志, 2022, 44(6): 411-421.

KAN Yi, LIN Hongxuan. A research progress of thermo-perception and thermo-responses in rice[J]. Chinese Journal of Nature, 2022, 44(6): 411-421.

参考文献

[1] ZHAO C, LIU B, PIAO S, et al. Temperature increase reduces global yields of major crops in four independent estimates [J]. Proc
Natl Acad Sci USA, 2017, 114: 9326-9331.
[2] NEVAME A Y M, EMON R M, MALEK M A, et al. Relationship between high temperature and formation of chalkiness and their
effects on quality of rice [J]. Biomed Res Int, 2018, 2018: 1653721.
[3] SHI W, LI X, SCHMIDT R C, et al. Pollen germination and in vivo fertilization in response to high-temperature during flowering in
hybrid and inbred rice [J]. Plant Cell Environ, 2018, 41: 1287-1297.
[4] ARSHAD M S, FAROOQ M, ASCH F, et al. Thermal stress impacts reproductive development and grain yield in rice [J]. Plant Physiol
Biochem, 2017, 115: 57-72. [5] JUNG J H, BARBOSA A D, HUTIN S, et al. A prion-like domain in ELF3 functions as a thermosensor in Arabidopsis [J]. Nature, 2020, 585: 256-260.
[6] CHUNG B Y W, BALCEROWICZ M, DI ANTONIO M, et al. An RNA thermoswitch regulates daytime growth in Arabidopsis [J].
Nature Plants, 2020, 6: 522-532.
[7] HE N Y, CHEN L S, SUN A Z, et al. A nitric oxide burst at the shoot apex triggers a heat-responsive pathway in Arabidopsis [J]. Nature Plants, 2022, 8: 434-450.
[8] ZHU J K. Abiotic stress signaling and responses in plants [J]. Cell, 2016, 167: 313-324.
[9] MITTLER R, FINKA A, GOLOUBINOFF P. How do plants feel the heat? [J]. Trends Biochem Sci, 2012, 37: 118-125.
[10] RAWAT N, SINGLA-PAREEK S L, PAREEK A. Membrane dynamics during individual and combined abiotic stresses in plants
and tools to study the same [J]. Physiol Plant, 2021, 171: 653-676.
[11] ZHAO X, WEI J, HE L, et al. Identification of fatty acid desaturases in maize and their differential responses to low and high temperature [J]. Genes, 2019, 10: 445.
[12] NARAYANAN S, ZOONG-LWE Z S, GANDHI N, et al. Comparative lipidomic analysis reveals heat stress responses of two
soybean genotypes differing in temperature sensitivity [J]. Plants, 2020, 9: 457.
[13] DING Y, SHI Y, YANG S. Molecular regulation of plant responses to environmental temperatures [J]. Mol Plant, 2020, 13: 544-564.
[14] DWIVEDI S K, BASU S, KUMAR S, et al. Enhanced antioxidant enzyme activities in developing anther contributes to heat stress
alleviation and sustains grain yield in wheat [J]. Funct Plant Biol, 2019, 46: 1090-1102.
[15] CUI Y, LU S, LI Z, et al. CYCLIC NUCLEOTIDE-GATED ION CHANNELs 14 and 16 promote tolerance to heat and chilling in
rice [J]. Plant Physiol, 2020, 183: 1794-1808.
[16] SHEN H, ZHONG X, ZHAO F, et al. Overexpression of receptorlike kinase ERECTA improves thermotolerance in rice and tomato
[J]. Nat Biotechnol, 2015, 33: 996-1003.
[17] CHEN C, CHEN H, LIN Y S, et al. A two-locus interaction causes interspecific hybrid weakness in rice [J]. Nat Commun, 2014, 5:
3357-3357.
[18] KAN Y, MU X R, ZHANG H, et al. TT2 controls rice thermotolerance through SCT1-dependent alteration of wax biosynthesis [J]. Nature Plants, 2022, 8: 53-67.
[19] ZHANG H, ZHOU J F, KAN Y, et al. A genetic module at one locus in rice protects chloroplasts to enhance thermotolerance [J]. Science, 2022, 376: 1293-1300.
[20] LIU X H, LYU Y-S, YANG W, et al. A membrane-associated NAC transcription factor OsNTL3 is involved in thermotolerance in rice
[J]. Plant Biotechnol J, 2020, 18: 1317-1329.
[21] CHEN J H, CHEN S T, HE N Y, et al. Nuclear-encoded synthesis of the D1 subunit of photosystem II increases photosynthetic efficiency and crop yield [J]. Nature Plants, 2020, 6: 570-580.
[22] YANG Y, XU J, HUANG L, et al. PGL, encoding chlorophyllide a oxygenase 1, impacts leaf senescence and indirectly affects grain
yield and quality in rice [J]. J Exp Bot, 2016, 67: 1297-1310.
[23] LV Y, SHAO G, QIU J, et al. White leaf and panicle 2, encoding a PEP-associated protein, is required for chloroplast biogenesis under heat stress in rice [J]. J Exp Bot, 2017, 68: 5147-5160.
[24] QIU Z, KANG S, HE L, et al. The newly identified heat-stress sensitive albino 1 gene affects chloroplast development in rice [J].
Plant Sci, 2018, 267: 168-179.
[25] QIU Z, ZHU L, HE L, et al. DNA damage and reactive oxygen species cause cell death in the rice local lesions 1 mutant under high
light and high temperature [J]. New Phytol, 2019, 222: 349-365.
[26] TANG Y, GAO C C, GAO Y, et al. OsNSUN2-mediated 5-methylcytosine mRNA modification enhances rice adaptation to
high temperature [J]. Dev Cell, 2020, 53: 272-286.e277.
[27] WANG D, QIN B, LI X, et al. Nucleolar DEAD-Box RNA helicase TOGR1 regulates thermotolerant growth as a pre-rRNA chaperone
in rice [J]. PLoS Genet, 2016, 12: e1005844.
[28] XU Y, ZHANG L, OU S, et al. Natural variations of SLG1 confer high-temperature tolerance in indica rice [J]. Nat Commun, 2020,
11: 5441.
[29] CHEN K, GUO T, LI X M, et al. Translational regulation of plant response to high temperature by a dual-function tRNAHis
guanylyltransferase in rice [J]. Mol Plant, 2019, 12: 1123-1142.
[30] LIN M Y, CHAI K H, KO S S, et al. A positive feedback loop between HEAT SHOCK PROTEIN101 and HEAT STRESSASSOCIATED
32-kD PROTEIN modulates long-term acquired thermotolerance illustrating diverse heat stress responses in rice varieties [J]. Plant Physiol, 2014, 164: 2045-2053.
[31] LI X M, CHAO D Y, WU Y, et al. Natural alleles of a proteasome α2 subunit gene contribute to thermotolerance and adaptation of
African rice [J]. Nat Genet, 2015, 47: 827-833.
[32] LIU J, ZHANG C, WEI C, et al. The RING finger ubiquitin E3 ligase OsHTAS enhances heat tolerance by promoting H2O2-induced
stomatal closure in rice [J]. Plant Physiol, 2016, 170: 429-443.
[33] QIAO B, ZHANG Q, LIU D, et al. A calcium-binding protein, rice annexin OsANN1, enhances heat stress tolerance by modulating the production of H₂O₂ [J]. J Exp Bot, 2015, 66: 5853-5866.
[34] HUANG X Y, CHAO D Y, GAO J P, et al. A previously unknown zinc finger protein, DST, regulates drought and salt tolerance in rice
via stomatal aperture control [J]. Genes Dev, 2009, 23: 1805-1817.
[35] FANG Y, LIAO K, DU H, et al. A stress-responsive NAC transcription factor SNAC3 confers heat and drought tolerance
through modulation of reactive oxygen species in rice [J]. J Exp Bot, 2015, 66: 6803-6817.
[36] MUHLEMANN J K, YOUNTS T L B, MUDAY G K. Flavonols control pollen tube growth and integrity by regulating ROS
homeostasis during high-temperature stress [J]. Proceedings of the National Academy of Sciences, 2018, 115: E11188-E11197.
[37] DONG N Q, SUN Y, GUO T, et al. UDP-glucosyltransferase regulates grain size and abiotic stress tolerance associated with
metabolic flux redirection in rice [J]. Nat Commun, 2020, 11: 2629.
[38] HOSSAIN M A, LI Z G, HOQUE T S, et al. Heat or cold priminginduced cross-tolerance to abiotic stresses in plants: key regulators
and possible mechanisms [J]. Protoplasma, 2018, 255: 399-412.

水稻高温感知及响应机制的研究进展

A research progress of thermo-perception and thermo-responses in rice

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