miRNA在调控植物种子发育及响应非生物胁迫中的研究进展

doi:10.11924/j.issn.1000-6850.casb2022-0660

中国农学通报 ›› 2023, Vol. 39 ›› Issue (12): 86-92.doi: 10.11924/j.issn.1000-6850.casb2022-0660

miRNA在调控植物种子发育及响应非生物胁迫中的研究进展

刘洋¹^,²(), 杨佳庆¹^,², 余徐润¹^,², 熊飞¹^,²()

¹ 江苏省作物遗传生理重点实验室/江苏省作物栽培生理重点实验室，扬州大学农学院
² 江苏省粮食作物现代产业技术协同创新中心，扬州大学，江苏扬州 225009

收稿日期:2022-08-28 修回日期:2022-11-27 出版日期:2023-04-25 发布日期:2023-04-21
通讯作者: 熊飞，男，1972年出生，江苏泰兴人，教授，博士，主要从事于小麦器官发育与品质形成的研究。通信地址：225009 江苏省扬州市邗江区文汇东路48号扬州大学生物科学与技术学院，E-mail：feixiong@yzu.edu.cn。
作者简介:
刘洋，女，1998年出生，河南郑州人，在读硕士，主要从事小麦颖果发育研究。通信地址：225009 江苏省扬州市邗江区文汇东路48号扬州大学生物科学与技术学院，Tel：19850505840，E-mail：2226399731@qq.com。
基金资助:
国家自然科学基金“小麦强弱势粒胚乳异步发育差异的机制及其调控途径研究”(31971810); “小麦顶小穗分化机制及其与穗粒数的关系”(31801269)

miRNA in Regulating Seed Development and the Response to Abiotic Stress in Plant: A Review

LIU Yang¹^,²(), YANG Jiaqing¹^,², YU Xurun¹^,², XIONG Fei¹^,²()

¹ Jiangsu Key Laboratory of Crop Genetics and Physiology/Jiangsu Key Laboratory of Crop Cultivation and Physiology, Agricultural College of Yangzhou University
² Jiangsu Co-Innovation Center for Modern Production Technology of Grain Crops, Yangzhou University, Yangzhou, Jiangsu 225009

Received:2022-08-28 Revised:2022-11-27 Online:2023-04-25 Published:2023-04-21

摘要/Abstract

摘要：

microRNA(miRNA)是一类内源性小分子非编码RNA，它通过引导mRNA的裂解或抑制翻译调控靶基因在植物种子发育和响应非生物胁迫过程中起着关键作用。为了进一步鉴定和明确与种子发育及响应非生物胁迫相关的miRNAs功能和调控机制，归纳了植物中参与种子胚和胚乳发育调控及响应低温、盐、干旱等非生物胁迫的miRNAs类型、靶基因及功能。miRNA在进化上高度保守，其表达在生物发育过程中具有明显的组织特异性和时间特异性，但在不同植物之间又有着相似性。然而，目前miRNAs生物发生和功能的调控因子是如何在转录或转录后被调控的以及miRNAs是如何利用转录裂解和翻译抑制机制来调控其靶点的还有待进一步阐明。未来对这些问题的研究不仅能为植物种子发育和植物响应非生物胁迫机制提供新的见解，而且能为基因的转录后调控研究提供更多的思路。

关键词: microRNA, 种子发育, 胚乳发育, 非生物胁迫, 温度胁迫, 水分胁迫, 盐胁迫, 矿质与氮素营养胁迫

Abstract:

microRNA (miRNA), an endogenous small non-coding RNA, regulates target genes by guiding mRNA cleavage or inhibiting translation. The role of miRNAs becomes extremely important in the regulation of plant seed development and the response to abiotic stress. In order to further identify and clarify the functions and regulatory mechanisms of miRNAs related to seed development and response to abiotic stress, the types, target genes and functions of miRNAs involved in the regulation of embryo and endosperm development in plant seed and in response to abiotic stress such as low temperature, salt and drought stress were summarized. miRNAs are highly conserved in evolution, and their expression is tissue-specific and time-specific during biological development, but they also have similarities among different plants. However, it remains to be further elucidated how regulators of miRNAs biogenesis and function are regulated during or after transcription, and how miRNAs use transcriptional cleavage and translation inhibition mechanisms to regulate their targets. Future research on these issues will not only provide new insights into plant seed development and plant response to abiotic stress, but also provide more ideas for post-transcriptional regulation of genes.

Key words: miRNA, seed development, endosperm development, abiotic stress, temperature stress, water stress, salt stress, mineral and nitrogen stress

刘洋, 杨佳庆, 余徐润, 熊飞. miRNA在调控植物种子发育及响应非生物胁迫中的研究进展[J]. 中国农学通报, 2023, 39(12): 86-92.

LIU Yang, YANG Jiaqing, YU Xurun, XIONG Fei. miRNA in Regulating Seed Development and the Response to Abiotic Stress in Plant: A Review[J]. Chinese Agricultural Science Bulletin, 2023, 39(12): 86-92.

图/表 1

参考文献 74

[1]	CAMBIAGNO D A, GIUDICATTI A J, ARCE A L, et al. HASTY modulates miRNA biogenesis by linking pri-miRNA transcription and processing[J]. Molecular plant, 2021, 14(3):426-439. doi: 10.1016/j.molp.2020.12.019 pmid: 33385584
[2]	MANAVELLA P A, YANG S W, PALATNIK J. Keep calm and carry on: miRNA biogenesis under stress[J]. The plant journal, 2019, 99(5):832-843. doi: 10.1111/tpj.14369 pmid: 31025462
[3]	XIE M, ZhANG S, YU B. MicroRNA biogenesis, degradation and activity in plants[J]. Cellular and molecular life sciences, 2015, 72(1):87-99. doi: 10.1007/s00018-014-1728-7 pmid: 25209320
[4]	ACHKAR N P, CAMBIAGNO D A, MANAVELLA P A. MiRNA biogenesis: a dynamic pathway[J]. Trends in plant science, 2016, 21(12):1034-1044. doi: S1360-1385(16)30157-1 pmid: 27793495
[5]	WANG S, QUAN L, LI S, et al. The PROTEIN PHOSPHATASE4 complex promotes transcription and processing of primary microRNAs in Arabidopsis[J]. The plant cell, 2019, 31(2):486-501. doi: 10.1105/tpc.18.00556 pmid: 30674692
[6]	JIA L, ZhANG D, QI X, et al. Identification of the conserved and novel miRNAs in mulberry by high-throughput sequencing[J]. PLoS one, 2014, 9(8):e104409. doi: 10.1371/journal.pone.0104409 URL
[7]	LI S, CASTILLO-GONZÁLEZ C, YU B, et al. The functions of plant small RNA s in development and in stress responses[J]. The plant journal, 2017, 90(4):654-670. doi: 10.1111/tpj.2017.90.issue-4 URL
[8]	REINHART B J, WEINSTEIN E G, RHOADES M W, et al. MicroRNAs in plants[J]. Genes & development, 2002, 16(13):1616-1626. doi: 10.1101/gad.1004402 URL
[9]	LI M, YU B. Recent advances in the regulation of plant miRNA biogenesis[J]. RNA biology, 2021, 18(12):2087-2096. doi: 10.1080/15476286.2021.1899491 URL
[10]	ALVES A, CORDEIRO D, CORREIA S, et al. Small non-coding RNAs at the crossroads of regulatory pathways controlling somatic embryogenesis in seed plants[J]. Plants, 2021, 10(3):504. doi: 10.3390/plants10030504 URL
[11]	SUN X, LIN L, SUI N. Regulation mechanism of microRNA in plant response to abiotic stress and breeding[J]. Molecular biology reports, 2019, 46(1):1447-1457. doi: 10.1007/s11033-018-4511-2 pmid: 30465132
[12]	TANG Q, LV H, LI Q, et al. Characteristics of microRNAs and target genes in maize root under drought stress[J]. International journal of molecular sciences, 2022, 23(9):4968. doi: 10.3390/ijms23094968 URL
[13]	MIYASHIMA S, ROSZAK P, SEVILEM I, et al. Mobile PEAR transcription factors integrate positional cues to prime cambial growth[J]. Nature, 2019, 565(7740):490-494. doi: 10.1038/s41586-018-0839-y
[14]	BERNARDI Y, PONSO M A, BELÉN F, et al. MicroRNA miR394 regulates flowering time in Arabidopsis thaliana[J]. Plant cell reports, 2022, 41(6):1375-1388. doi: 10.1007/s00299-022-02863-0
[15]	SMOLIKOVA G, STRYGINA K, KRYLOVA E, et al. Transition from seeds to seedlings: hormonal and epigenetic aspects[J]. Plants, 2021, 10(9):1884. doi: 10.3390/plants10091884 URL
[16]	DHAKA N, SHARMA R. MicroRNA-mediated regulation of agronomically important seed traits: a treasure trove with shades of grey![J]. Critical reviews in biotechnology, 2021, 41(4):594-608. doi: 10.1080/07388551.2021.1873238 URL
[17]	SINGH P, DUTTA P, CHAKRABARTY D. MiRNAs play critical roles in response to abiotic stress by modulating cross-talk of phytohormone signaling[J]. Plant cell reports, 2021, 40(9):1617-1630. doi: 10.1007/s00299-021-02736-y pmid: 34159416
[18]	PAGANO L, ROSSI R, PAESANO L, et al. MiRNA regulation and stress adaptation in plants[J]. Environmental and experimental botany, 2021, 184:104369. doi: 10.1016/j.envexpbot.2020.104369 URL
[19]	WEI S J, CHAI S, ZHU R M, et al. HUA ENHANCER1 mediates ovule development[J]. Frontiers in plant science, 2020, 11:397. doi: 10.3389/fpls.2020.00397 URL
[20]	NOWAK K, MOROŃCZYK J, GRZYB M, et al. MiR172 Regulates WUS during somatic embryogenesis in Arabidopsis via AP2[J]. Cells, 2022, 11(4):718. doi: 10.3390/cells11040718 URL
[21]	KAI H, YUN W, ZHANPIN Z, et al. MiR160: an indispensable regulator in plant[J]. Frontiers in plant science, 2022, 13: 833322. doi: 10.3389/fpls.2022.833322 URL
[22]	MEIJER A, DE MEYER T, VANDEPOELE K, et al. Spatiotemporal expression profile of novel and known small RNAs throughout rice plant development focussing on seed tissues[J]. BMC genomics, 2022, 23(1):1-17. doi: 10.1186/s12864-021-08243-4
[23]	ALVES A, CONFRARIA A, LOPES S, et al. MiR160 interacts in vivo with pinus pinaster AUXIN RESPONSE FACTOR 18 target site and negatively regulates its expression during conifer somatic embryo development[J]. Frontiers in plant science, 2022, 13:857611. doi: 10.3389/fpls.2022.857611 URL
[24]	HERNANDEZ-CASTELLANO S, ANDRADE-MARCIAL M, AGUILAR-MÉNDEZ E D, et al. MiRNA expression analysis during somatic embryogenesis in Coffea canephora[J]. Plant cell, tissue and organ culture (PCTOC), 2022:1-14.
[25]	CAI H, LIU L, ZHANG M, et al. Spatiotemporal control of miR398 biogenesis, via chromatin remodeling and kinase signaling, ensures proper ovule development[J]. The plant cell, 2021, 33(5):1530-1553. doi: 10.1093/plcell/koab056 pmid: 33570655
[26]	REDDITT T J, CHUNG E H, KARIMI H Z, et al. AvrRpm1 functions as an ADP-ribosyl transferase to modify NOI domain-containing proteins, including Arabidopsis and soybean RPM1-interacting protein4[J]. The plant cell, 2019, 31(11):2664-2681.
[27]	HAN Y, ZHANG Y, CAO G, et al. Dynamic expression of miRNAs and functional analysis of target genes involved in the response to male sterility of the wheat line YS3038[J]. Plant physiology and biochemistry, 2021, 162:363-377. doi: 10.1016/j.plaphy.2021.02.047 pmid: 33730621
[28]	YANG X F, ZHAO X L, DAI Z Y, et al. OsmiR396/growth regulating factor modulate rice grain size through direct regulation of embryo-specific miR408[J]. Plant physiology, 2021, 186(1):519-533. doi: 10.1093/plphys/kiab084 pmid: 33620493
[29]	HUANG K R, ZHOU S Q, SHEN K M, et al. Elucidation of the miR164c-guided gene/protein interaction network controlling seed vigor in rice[J]. Frontiers in plant science, 2020, 11:589005. doi: 10.3389/fpls.2020.589005 URL
[30]	LUJÁN-SOTO E, JUÁREZ-GONZÁLEZ V T, REYES J L, et al. MicroRNA Zma-miR528 versatile regulation on target mRNAs during maize somatic embryogenesis[J]. International journal of molecular sciences, 2021, 22(10):5310. doi: 10.3390/ijms22105310 URL
[31]	KONG C, SU H N, DENG S P, et al. Global DNA methylation and mRNA-miRNA variations activated by heat shock boost early microspore embryogenesis in cabbage (Brassica oleracea)[J]. International journal of molecular sciences, 2022, 23(9):5147. doi: 10.3390/ijms23095147 URL
[32]	OLSEN O A. The modular control of cereal endosperm development[J]. Trends in plant science, 2020, 25(3):279-290. doi: 10.1016/j.tplants.2019.12.003 URL
[33]	MIRAY R, KAZAZ S, TO A, et al. Molecular control of oil metabolism in the endosperm of seeds[J]. International journal of molecular sciences, 2021, 22(4):1621. doi: 10.3390/ijms22041621 URL
[34]	MISHRA P, SINGH A, VERMA A K, et al. MicroRNA775 targets a probable β-(1,3)-galactosyltransferase to regulate growth and development in Arabidopsis thaliana[J]. Journal of plant growth regulation, 2021:1-14.
[35]	SHARMA D, TIWARI M, PANDEY A, et al. MicroRNA858 is a potential regulator of phenylpropanoid pathway and plant development[J]. Plant physiology, 2016, 171(2):944-959. doi: 10.1104/pp.15.01831 pmid: 27208307
[36]	SHARMA A, BEJERANO P I A, MALDONADO I C, et al. Genome-wide computational prediction and experimental validation of quinoa (Chenopodium quinoa) microRNAs[J]. Canadian journal of plant science, 2019, 99(5):666-675. doi: 10.1139/cjps-2018-0296 URL
[37]	CHANDRA T, MISHRA S, PANDA B B, et al. Study of expressions of miRNAs in the spikelets based on their spatial location on panicle in rice cultivars provided insight into their influence on grain development[J]. Plant physiology and biochemistry, 2021, 159:244-256. doi: 10.1016/j.plaphy.2020.12.020 pmid: 33388659
[38]	HU Y F, LI Y P, WENG J F, et al. Coordinated regulation of starch synthesis in maize endosperm by microRNAs and DNA methylation[J]. The plant journal, 2021, 105(1):108-123. doi: 10.1111/tpj.15043 pmid: 33098697
[39]	ZHANG M, ZHENG H, JIN L, et al. MiR169o and ZmNF-YA13 act in concert to coordinate the expression of ZmYUC1 that determines seed size and weight in maize kernels[J]. New phytologist, 2022:1-15.
[40]	WANG K, WANG X, LI M, et al. Low genetic diversity and functional constraint of miRNA genes participating pollen-pistil interaction in rice[J]. Plant molecular biology, 2017, 95(1):89-98. doi: 10.1007/s11103-017-0638-0 URL
[41]	YUE E, CAO H, LIU B. OsmiR535, a potential genetic editing target for drought and salinity stress tolerance in Oryza sativa[J]. Plants, 2020, 9(10):1337. doi: 10.3390/plants9101337 URL
[42]	卢秋巍. 冬小麦抗寒lncRNA筛选及与tae-miR398应答低温胁迫的互作研究[D]. 哈尔滨: 东北农业大学, 2018:68-81.
[43]	孙明哲, 崔娜, 孙晓丽, 等. Os-miR1435基因对水稻的遗传转化及耐冷功能鉴定[J]. 基因组学与应用生物学, 2014, 33(6):1181-1189.
[44]	LUO Y, WANG T, YANG D, et al. Identification and characterization of heat-responsive microRNAs at the booting stage in two rice varieties, 9311 and Nagina 22[J]. Genome, 2021, 64(11):969-984. doi: 10.1139/gen-2020-0175 URL
[45]	AYDINOGLU F. Elucidating the regulatory roles of microRNAs in maize (Zea mays L.) leaf growth response to chilling stress[J]. Planta, 2020, 251(2):1-15. doi: 10.1007/s00425-019-03297-x
[46]	FU J E, WAN L Y, SONG L S, et al. Identification of microRNAs in Taxillus chinensis (DC.) Danser seeds under cold stress[J]. BioMed research international, 2021, 2021:1-12.
[47]	SUN M Y, JING Y, WANG X S, et al. Gma-miR1508a confers dwarfing, cold tolerance, and drought sensitivity in soybean[J]. Molecular breeding, 2020, 40(4):1-13. doi: 10.1007/s11032-019-1080-6
[48]	KUMAR M, KUMAR R R, GOSWAMI S, et al. MiR430: the novel heat-responsive microRNA identified from miRNome analysis in wheat (Triticum aestivum L.)[J]. Indian journal of plant physiology, 2017, 22(4):566-576. doi: 10.1007/s40502-017-0341-9 URL
[49]	MANGRAUTHIA S K, SAILAJA B, PUSULURI M, et al. Deep sequencing of small RNAs reveals ribosomal origin of microRNAs in Oryza sativa and their regulatory role in high temperature[J]. Gene reports, 2018, 11:270-278. doi: 10.1016/j.genrep.2018.05.002 URL
[50]	ZHANG M B, AN P P, LI H P, et al. The miRNA-mediated post-transcriptional regulation of maize in response to high temperature[J]. International journal of molecular sciences, 2019, 20(7):1754. doi: 10.3390/ijms20071754 URL
[51]	CHAI W B, SONG N N, SU A Q, et al. ZmmiR190 and its target regulate plant responses to drought stress through an ABA-dependent pathway[J]. Plant science, 2021, 312:111034. doi: 10.1016/j.plantsci.2021.111034 URL
[52]	JIANG Y, WU X, SHI M, et al. The miR159-MYB33-ABI5 module regulates seed germination in Arabidopsis[J]. Physiologia plantarum, 2022, 174(2):e13659.
[53]	GENG Z, LIU J G, LI D, et al. A conserved miR394-targeted F-box gene positively regulates drought resistance in foxtail millet[J]. Journal of plant biology, 2021, 64(3):243-252. doi: 10.1007/s12374-021-09303-8
[54]	GAO W W, LI M K, YANG S G, et al. MiR 2105 and the kinase OsSAPK10 co-regulate OsbZIP86 to mediate drought-induced ABA biosynthesis in rice[J]. Plant physiology, 2022, 189(2):889-905. doi: 10.1093/plphys/kiac071 URL
[55]	CAO L R, LU X M, WANG G R, et al. Transcriptional regulatory networks in response to drought stress and rewatering in maize (Zea mays L.)[J]. Molecular genetics and genomics, 2021, 296(6):1203-1219. doi: 10.1007/s00438-021-01820-y
[56]	UM T, CHOI J, PARK T, et al. Rice microRNA171f/SCL6 module enhances drought tolerance by regulation of flavonoid biosynthesis genes[J]. Plant direct, 2022, 6(1):e374.
[57]	CHEN X Y, YANG Y, RAN L P, et al. Novel insights into miRNA regulation of storage protein biosynthesis during wheat caryopsis development under drought stress[J]. Frontiers in plant science, 2017, 8:1707. doi: 10.3389/fpls.2017.01707 URL
[58]	KATIYAR A, SMITA S, MUTHUSAMY S K, et al. Identification of novel drought-responsive microRNAs and trans-acting siRNAs from Sorghum bicolor (L.) Moench by high-throughput sequencing analysis[J]. Frontiers in plant science, 2015, 6:506.
[59]	WANG G, 余道乾, 杜雄明. 陆地棉种子发育过程中microRNA的挖掘与功能研究[J]. 棉花学报, 2014, 26(1):81-86.
[60]	XU T, ZHANG L, YANG Z M, et al. Identification and functional characterization of plant miRNA under salt stress shed light on salinity resistance improvement through miRNA manipulation in crops[J]. Frontiers in plant science, 2021, 12:972.
[61]	MAKKAR H, ARORA S, KHUMAN A K, et al. Target-mimicry-based miR167 diminution confers salt-stress tolerance during in vitro organogenesis of tobacco (Nicotiana tabacum L.)[J]. Journal of plant growth regulation, 2022, 41(4):1462-1480. doi: 10.1007/s00344-021-10376-5
[62]	ZHANG X P, SHEN J, XU Q J, et al. Long noncoding RNA lncRNA354 functions as a competing endogenous RNA of miR160b to regulate ARF genes in response to salt stress in upland cotton[J]. Plant, cell & environment, 2021, 44(10):3302-3321.
[63]	WANG R, FANG Y N, WU X M, et al. The miR399-CsUBC24 module regulates reproductive development and male fertility in citrus[J]. Plant physiology, 2020, 183(4): 1681-1695. doi: 10.1104/pp.20.00129 URL
[64]	PARMAR S, GHARAT S A, TAGIRASA R, et al. Identification and expression analysis of miRNAs and elucidation of their role in salt tolerance in rice varieties susceptible and tolerant to salinity[J]. PLoS one, 2020, 15(4):e0230958. doi: 10.1371/journal.pone.0230958 URL
[65]	AI B, CHEN Y, ZHAO M M, et al. Overexpression of miR1861h increases tolerance to salt stress in rice (Oryza sativa L.)[J]. Genetic resources and crop Evolution, 2021, 68(1):87-92. doi: 10.1007/s10722-020-01045-9
[66]	KANG T, YU C Y, LIU Y, et al. Subtly manipulated expression of ZmmiR156 in tobacco improves drought and salt tolerance without changing the architecture of transgenic plants[J]. Frontiers in plant science, 2020, 10:1664. doi: 10.3389/fpls.2019.01664 URL
[67]	常亚南, 王瀑童, 吴玉杰, 等. 小麦microRNA167e的特征及表达模式分析[J]. 麦类作物学报, 2019, 39(8):887-894.
[68]	王越, 周婷, 岳彩鹏, 等. 油菜盐胁迫响应miRNA及其靶基因鉴定[J]. 中国油料作物学报, 2022, 44(1):103-115.
[69]	YOUSUF P Y, SHABIR P A, HAKEEM K R. MiRNAomic approach to plant nitrogen starvation[J]. International journal of genomics, 2021, 2021:1-14.
[70]	ZHAO Y P, XU Z H, MO Q C, et al. Combined small RNA and degradome sequencing reveals novel miRNAs and their targets in response to low nitrate availability in maize[J]. Annals of botany, 2013, 112(3):633-642. doi: 10.1093/aob/mct133 pmid: 23788746
[71]	HOU G G, DU C Y, GAO H H, et al. Identification of microRNAs in developing wheat grain that are potentially involved in regulating grain characteristics and the response to nitrogen levels[J]. BMC plant biology, 2020, 20(1):1-21. doi: 10.1186/s12870-019-2170-7
[72]	ZULUAGA D L, DE PAOLA D, JANNI M, et al. Durum wheat miRNAs in response to nitrogen starvation at the grain filling stage[J]. PLoS one, 2017, 12(8):e0183253. doi: 10.1371/journal.pone.0183253 URL
[73]	高思. 小麦耐逆因子MIR444a, NF-YB2;3, TaRRM, TaRACK1和TaARR分子特征和功能研究[D]. 保定: 河北农业大学, 2016:33-42.
[74]	ZHAO Y, XU K, LIU G R, et al. Global identification and characterization of miRNA family members responsive to potassium deprivation in wheat (Triticum aestivum L.)[J]. Scientific reports, 2020, 10(1):1-13. doi: 10.1038/s41598-019-56847-4

miRNA在调控植物种子发育及响应非生物胁迫中的研究进展

miRNA in Regulating Seed Development and the Response to Abiotic Stress in Plant: A Review

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