microRNA参与植物次生代谢与非生物胁迫的调控

作者：王韵壹、李英、熊慧卿

[1] Chuck G, O’Connor D. Small RNAs going the distance during plant development[J]. Curr Opin Plant Biol, 2010, 13(1): 40-45
[2] Iwakawa HO, Yukihide T. The functions of MicroRNAs: mRNA decay and translational repression[J]. Trends Cell Biol, 2015, 25(11): 651-665
[3] 陈思, 陈薇, 庞基良. miRNAs调控植物生长发育的研究进展[J]. 北方园艺 (Chen Si, Chen Wei, Pang Ji-Liang. Advances in the regulation of plant growth and development by miRNAs[J]. North Hortic), 2016, 5: 200-206
[4] Lenka M, Dominika J, Stefano D, et al. C-prenylated flavonoids with potential cytotoxic activity against solid tumor cell lines[J]. Phytochem Rev, 2019, 18 (4): 1051-1100
[5] Tiwari P, Mishra KP. Flavonoids sensitize tumor cells to radiation: molecular mechanisms and relevance to cancer radiotherapy[J]. Int J Radiat Biol, 2020, 96(3): 360-369
[6] Gupta OP, Karkute SG, Banerjee S, et al. Contemporary understanding of miRNA-Based regulation of secondary metabolites biosynthesis in plants[J]. Front Plant Sci, 2017, 8: 374
[7] Li Y, Cui W, Wang R, et al. MicroRNA858-mediated regulation of anthocyanin biosynthesis in kiwifruit (Actinidia arguta) based on small RNA sequencing[J]. PLoS One, 2019, 14(5): e0217480
[8] 陈林波, 夏丽飞, 刘悦, 等. 基于高通量测序筛选‘紫娟’花青素合成相关的miRNA[J]. 茶叶科学 (Chen Lin-Bo, Xia Li-Fei, Liu Yue, et al. Screening of miRNAs related to anthocyanin synthesis in ‘Zijuan’ based on high-throughput sequencing[J]. J Tea Sci), 2019, 39(6): 681-691
[9] Yang T, Ma H, Zhang J, et al. Systematic identification of long noncoding RNAs expressed during light-induced anthocyanin accumulation in apple fruit[J]. Plant J, 2019, 100(3): 572-590
[10] Wang Y, Liu W, Wang X, et al. MiR156 regulates anthocyanin biosynthesis through SPL targets and other microRNAs in poplar[J]. Hortic Res, 2020, 7(1): 118
[11] Khan S, Ali A, Saifi M, et al. Identification and the potential involvement of miRNAs in the regulation of artemisinin biosynthesis in A. annua[J]. Sci Rep, 2020, 10(1): 13614
[12] Saifi M, Yogindran S, Nasrullah N, et al. Co-expression of anti-miR319g and miRStv_11 lead to enhanced steviol glycosides content in Stevia rebaudiana[J]. BMC Plant Biol, 2019, 19(1): 274
[13] Boke H, Ozhuner E, Turktas M, et al. Regulation of the alkaloid biosynthesis by mi RNA in opium poppy[J]. Plant Biotechnol J, 2015, 13(3): 409-420
[14] 乔岩. 马铃薯光诱导糖苷生物碱代谢相关miRNAs的鉴定与功能分析[D]. 兰州: 甘肃农业大学 (Qiao Yan. Identification and functional analysis of light-induced miRNAs associated with glycoalkaloids metabolism in potato[D]. Lanzhou: Gansu Agricultural University), 2017
[15] Chen C, Xie F, Hua Q, et al. Integrated sRNAome and RNA-Seq analysis reveals miRNA effects on betalain biosynthesis in pitaya[J]. BMC Plant Biol, 2020, 20(1): 437
[16] Qiu C W, Liu L, Feng X, et al. Genome-wide identification and characterization of drought stress responsive microRNAs in Tibetan wild barley[J]. Int J Mol Sci, 2020, 21(8): 2795
[17] López-Galiano MJ, García-Robles I, González-Hernández AI, et al. Expression of miR159 is altered in tomato plants undergoing drought stress[J]. Plants (Basel), 2019, 8(7): 201
[18] Li R, Fan T, Wang T, et al. Characterization and functional analysis of miR166f in drought stress tolerance in mulberry (Morus multicaulis)[J]. Mol Breed, 2018, 38(11): 132
[19] Fan G, Liu Y, Du H, et al. Identification of drought-responsive miRNAs in Hippophae tibetana using high-throughput sequencing[J]. 3 Biotech, 2020, 10(2): 53
[20] Feyissa BA, Arshad M, Gruber MY, et al. The interplay between miR156/SPL13 and DFR/WD40-1 regulate drought tolerance in alfalfa[J]. BMC Plant Biol, 2019, 19(1): 434
[21] Lin JS, Kuo CC, Yang IC, et al. MicroRNA160 modulates plant development and heat shock protein gene expression to mediate heat tolerance in Arabidopsis[J]. Front Plant Sci, 2018, 9: 68
[22] Zhang M, An P, Li H, et al. The miRNA-mediated post-transcriptional regulation of maize in response to high temperature[J]. Int J Mol Sci, 2019, 20(7): 1754
[23] Ahmed W, Li R, Xia Y, et al. Comparative analysis of miRNA expression profiles between heat-tolerant and heat-sensitive genotypes of flowering Chinese cabbage under heat stress using high-throughput sequencing[J]. Genes (Basel), 2020, 11(3): 264
[24] Chen J, Pan A, He S, et al. Different microRNA families involved in regulating high temperature stress response during cotton (Gossypium hirsutum L.) anther development[J]. Int J Mol Sci, 2020, 21(4): 1280
[25] Tang W, Thompson WA. OsmiR528 enhances cold stress tolerance by repressing expression of stress response-related transcription factor genes in plant cells[J]. Curr Genomics, 2019, 20 (2): 100-114
[26] Zhu H, Zhang Y, Tang R, et al. Banana sRNAome and degradome identify microRNAs functioning in differential responses to temperature stress[J]. BMC Genomics, 2019, 20(1): 33
[27] Liu W, Cheng C, Chen F, et al. High-throughput sequencing of small RNAs revealed the diversified cold-responsive pathways during cold stress in the wild banana (Musa itinerans)[J]. BMC Plant Biol, 2018, 18(1): 308
[28] Abla M, Sun H, Li Z, et al. Identification of miRNAs and their response to cold stress in Astragalus Membranaceus[J]. Biomolecules, 2019, 9(5): 182
[29] Wang W, Liu D, Chen D, et al. MicroRNA414c affects salt tolerance of cotton by regulating reactive oxygen species metabolism under salinity stress[J]. RNA Biol, 2019, 16(3): 362-375
[30] Bai Q, Wang X, Chen X, et al. Wheat miRNA TaemiR408 acts as an essential mediator in plant tolerance to Pi deprivation and salt stress via modulating stress-associated physiological processes[J]. Front Plant Sci, 2018, 9: 499
[31] Ma Y, Xue H, Zhang F, et al. The miR156/SPL module regulates apple salt stress tolerance by activating MdWRKY100 expression[J]. Plant Biotechnol J, 2021, 19(2): 311
[32] Zhang H, Liu X, Yang X, et al. miRNA–mRNA integrated analysis reveals roles for miRNAs in a typical halophyte, Reaumuria soongorica, during seed germination under salt stress[J]. Plants (Basel), 2020, 9(3): 351
[33] Jiu S, Leng X, Haider MS, et al. Identification of copper (Cu) stress-responsive grapevine microRNAs and their target genes by high-throughput sequencing[J]. R Soc Open Sci, 2019, 6(1): 180735
[34] Sun Z, Shu L, Zhang W, et al. Cca-miR398 increases copper sulfate stress sensitivity via the regulation of CSD mRNA transcription levels in transgenic Arabidopsis thaliana[J]. PeerJ, 2020, 8: e9105
[35] Gao J, Luo M, Peng H, et al. Characterization of cadmium-responsive MicroRNAs and their target genes in maize (Zea mays) roots[J]. BMC Mol Biol, 2019, 20(1): 14
[36] Ding Y, Wang Y, Jiang Z, et al. MicroRNA268 overexpression affects rice seedling growth under cadmium stress[J]. J Agric Food Chem, 2017, 65(29): 5860-5867
[37] Šamec D, Karalija E, Šola I, et al. The role of polyphenols in abiotic stress response: The influence of molecular structure[J]. Plants, 2021, 10(1): 118
[38] 谢冬微, 孙健. 不同发育时期亚麻茎秆中木质素积累相关miRNA及其靶基因的挖掘分析[J]. 南方农业学报 (Xie Dong-Wei, Sun Jian. Mining and analysis of miRNAs and target genes related to lignin accumulation in flax stalks at different developmental stages[J]. J South Agric), 2020, 51(10): 2321-2330
[39] 石晓雯. 甘薯逆境胁迫和花青素合成相关microRNA及其靶基因的鉴定和分析[D]. 晋中: 山西农业大学(Shi Xiao-Wen. Identification and analysis of microRNA related to adversity stress and anthocyanin biosynthesis in sweet potato[D]. Jinzhong: Shanxi Agricultural University), 2018
[40] Cui L G, Shan J X, Shi M, et al. The miR156-SPL 9-DFR pathway coordinates the relationship between development and abiotic stress tolerance in plants[J]. Plant J, 2014, 80(6): 1108-1117
[41] Bustamante A, Marques M C, Sanz-Carbonell A, et al. Alternative processing of its precursor is related to miR319 decreasing in melon plants exposed to cold[J]. Sci Rep, 2018, 8(1): 15538
[42] Zheng X, Li H, Chen M, et al. Smi-miR396b targeted SmGRFs, SmHDT1, and SmMYB37/4 synergistically regulates cell growth and active ingredient accumulation in Salvia miltiorrhiza hairy roots[J]. Plant Cell Rep, 2020, 39(10): 1263-1283
[43] Sun X, Xu L, Wang Y, et al. Identification of novel and salt-responsive miRNAs to explore miRNA-mediated regulatory network of salt stress response in radish (Raphanus sativus L.)[J]. BMC Genomics, 2015, 16(1): 197
[44] Abla M, Sun H, Li Z, et al. Identification of miRNAs and their response to cold stress in Astragalus Membranaceus[J]. Biomolecules, 2019, 9(5): 182
[45] Fu L, Ding Z, Tan D, et al. Genome-wide discovery and functional prediction of salt-responsive lncRNAs in duckweed[J]. BMC Genomics, 2020, 21(1): 212