Screening and Validation of miRNA Reference Genes and Genes in Ilex asprella under Cadmium Stress

doi:10.11924/j.issn.1000-6850.casb2024-0543

Abstract

Abstract:

The objective of this study was to identify stably expressed internal reference miRNAs and genes under cadmium (Cd) stress in the roots of Ilex asprella, for the purpose of determining the expression levels of Cd stress-responsive miRNAs and their target genes. In this study, total RNA was extracted from Ilex asprella roots subjected to various Cd stress durations, followed by reverse transcription. Subsequently, the Ct values of 9 candidate internal reference miRNAs and 8 candidate internal reference genes were determined through RT-qPCR experiments. The optimal internal reference miRNAs and genes were subsequently identified through a comprehensive and systematic analysis using tools such as geNorm, NormFinder, BestKeeper, and RefFinder. After that, based on the best internal reference miRNAs and genes, this study further determined the expression of 6 miRNAs and their target genes in response to Cd stress in the roots of Ilex asprella. The results showed that although the results of various tools were different due to algorithm differences, in the comprehensive analysis of RefFinder, this study identified UBQ as the best internal reference gene, with the stability ranking of UBQ > Actin > 18S > GAPDH > UBC > EF1-α > 28S > α-TUB, the best internal reference miRNA was U6, and the stability ranking was U6 > 5S > MIR156ab > MIR396f > MIR159d > MIR390j > MIR171t > U4 > MIR166ab. The expression analysis results of 6 miRNAs and their target genes showed that under the Cd stress, the expression of MIR159c decreased gradually, while the expression of MIR171a and MIR393a increased significantly. In addition, the expression levels of MIR167m-5p, MIR399f-5p and MIR529d increased first and then decreased. There was a significant negative correlation between these miRNAs and their target genes, which indicated that under Cd stress environment, Ilex asprella could negatively regulate its target genes through miRNAs to adapt to Cd stress. In conclusion, this study successfully screened the best internal reference gene UBQ and internal reference miRNA U6 in the roots of Ilex asprella under Cd stress, and detected the expression of miRNAs and their target genes in response to Cd stress, which provided a theoretical basis for in-depth study of the regulation mechanism of Cd stress on the expression of miRNAs and their target genes in Ilex asprella.

Key words: Cd stress, Ilex asprella, real time quantitative PCR, internal reference gene, miRNA

ZHOU Xinyu, QIU Zijie, HUANG Jinheng, NIE Xiaofeng, YANG Quan, LIAO Peiran. Screening and Validation of miRNA Reference Genes and Genes in Ilex asprella under Cadmium Stress[J]. Chinese Agricultural Science Bulletin, 2025, 41(11): 31-39.

Figures/Tables 9

References 28

[1]	高晓玲, 陈丰连, 曾元儿, 等. 微波消解—原子吸收光谱法测定岗梅根茎中铅、镉的含量[J]. 广州中医药大学学报, 2011, 28(6):639-642.
[2]	李柯帆, 王枫, 丁雯, 等. 荧光定量PCR在药用植物基因表达及鉴别中的应用[J]. 世界中医药, 2022, 17(21):3101-3106,3111.
[3]	岳炜楠, 胥通玉, 苗佳敏, 等. 紫花苜蓿不同组织及不同激素处理下内参基因的筛选[J/OL]. 草原与草坪,1-16[2025-04-08]. http://kns.cnki.net/kcms/detail/62.1156.S.20240521.1243.002.html.
[4]	何长霞, 罗陈, 闫晋强, 等. 冬瓜实时荧光定量PCR内参基因的筛选与评价[J]. 园艺学报, 2024, 51(4):748-760.
[5]	张芷睿, 张耀华, 王秋实, 等. 大豆实时荧光定量PCR内参基因的筛选与验证[J]. 植物生理学报, 2020, 56(9):1963-1973.
[6]	ZHAN J P, MEYERS B C. Plant small rnas: their biogenesis, regulatory roles, and functions[J]. Annual review of plant biology, 2022,74:21-51.
[7]	JIN G, ZHANG X H, YU S Y, et al. Screening and validation of optimal mirna reference genes in different developing stages and tissues of Lilium henryi baker[J]. Scientific reports, 2024, 14(1):1545-1545.
[8]	郑夏生, 叶国兵, 纪晓宇, 等. 岗梅实时荧光定量PCR内参基因的筛选[J]. 热带作物学报, 2015, 36(6):1119-1124.
[9]	XIE F L, WANG J Y, ZHANG B H. Reffinder: a web-based tool for comprehensively analyzing and identifying reference genes[J]. Funct integr genomics, 2023, 23(2):125-125.
[10]	XIE F L, XIAO P, CHEN D L, et al. Mirdeepfinder: a mirna analysis tool for deep sequencing of plant small rnas[J]. Plant molecular biology, 2012,80:75-84.
[11]	李浩霞, 黄稳娥, 柳西宁, 等. 枸杞实时荧光定量RT-qPCR内参基因筛选与验证[J]. 江苏农业科学, 2023, 51(9):41-51.
[12]	巨秀婷, 何金娣, 张梦洁, 等. 郁金香不同组织内参基因筛选及稳定表达分析[J]. 南方农业学报, 2023, 54(11):3174-3185.
[13]	李红英, 陈萌笛, 王政博, 等. 镉胁迫下构树qRT-PCR内参基因筛选及验证[J]. 林业科学研究, 2023, 36(4):129-138.
[14]	李静宇, 孙铭阳, 徐世强, 等. 穿心莲茉莉酸甲酯及非生物胁迫下Real-time PCR内参基因的筛选[J]. 中国实验方剂学杂志, 2022, 28(5):133-140.
[15]	宋美玲, 黄胜和, 陈祖杰, 等. 斑地锦RT-qPCR内参基因的筛选[J]. 广西植物, 2022, 42(2):340-348.
[16]	李东昕, 常纯皓, 于放. 长春花CrU6 snRNA基因筛选及表达稳定性分析[J/OL]. 分子植物育种,1-8[2025-02-16]. http://kns.cnki.net/kcms/detail/46.1068.S.20220224.1353.012.html.
[17]	GRECO M, CHIAPPETTA A, BRUNO L, et al. In posidonia oceanica cadmium induces changes in dna methylation and chromatin patterning[J]. Journal of experimental botany, 2012, 63(2):695-709. doi: 10.1093/jxb/err313 pmid: 22058406
[18]	MENG J G, ZHANG X D, TAN S K, et al. Genome-wide identification of cd-responsive nramp transporter genes and analyzing expression of nramp 1 mediated by mir167 in Brassica napus[J]. Biometals, 2017, 30(6):917-931.
[19]	LIU X, HUANG S, XIE H T. Advances in the regulation of plant development and stress response by mir167[J]. Front biosci (Landmark Ed), 2021, 26(9):655-665. doi: 10.52586/4974 pmid: 34590474
[20]	DUBEY S, SAXENA S, CHAUHAN A S, et al. Identification and expression analysis of conserved micrornas during short and prolonged chromium stress in rice (Oryza sativa)[J]. Environmental science and pollution research, 2020, 27(1):380-390.
[21]	XUE T, LIU Z H, DAI X H, et al. Primary root growth in arabidopsis thaliana is inhibited by the mir159 mediated repression of myb33, myb65 and myb101[J]. Plant science, 2017,262:182-189.
[22]	GUTIERREZ L, BUSSELL J D, PACURAR D I, et al. Phenotypic plasticity of adventitious rooting in arabidopsis is controlled by complex regulation of auxin response factor transcripts and microrna abundance[J]. Plant cell, 2009, 21(10):3119-3132.
[23]	樊航, 宣磊, 胥猛. 杨树PeHAM1和PeHAM2基因的克隆、表达及亚细胞定位[J]. 分子植物育种, 2019, 17(8):2476-2485.
[24]	SHI W G, LIU W Z, MA C F, et al. Dissecting micrornas-mrnas regulatory networks underlying sulfur assimilation and cadmium accumulation in poplar leaves[J]. Plant cell physiol, 2020, 61(9):1614-1630.
[25]	MA H Z, LIU C, LI Z X, et al. Zmbzip4 contributes to stress resistance in maize by regulating aba synthesis and root development[J]. Plant physiol, 2018, 178(2):753-770. doi: 10.1104/pp.18.00436 pmid: 30126870
[26]	JIANG J J, ZHU H T, LI N, et al. The mir393-target module regulates plant development and responses to biotic and abiotic stresses[J]. International journal of molecular sciences, 2022, 23(16):9477-9477.
[27]	DING D, ZHANG L F, WANG H, et al. Differential expression of mirnas in response to salt stress in maize roots[J]. Annals of botany, 2009, 103(1):29-38. doi: 10.1093/aob/mcn205 pmid: 18952624
[28]	ZHU H, ZHOU Y Y, ZHAI H, et al. A novel sweetpotato wrky transcription factor, ibwrky2, positively regulates drought and salt tolerance in transgenic arabidopsis[J]. Biomolecules, 2020, 10(4):506.

基因	上游引物序列(5’-3’)	下游引物序列(5’-3’)
18S	ATGCCTTGTCTTTGGTGC	TGGGGTTGATGTTACTTGAT
GADPH	GAACTCGGAACGCCATAC	GCTGCTTCATTCAACATCAT
Actin	GTACTACTAACAGAAGCACCGC	GCATAAAGAGACAGAACAGCC
α-TUB	ACTAACCTGGTCCCGTACCC	AGCCGCATTGACATCCTT
EF-1α	GCATGTTGTCGCCGTTGAA	GCTGCCGGTACTGGTGAGTT
UBQ	ACCCCTAAGCCTCAGAACAAG	TCGCCGACTACAACATCCA
UBC	TTTTGGGGGGTGTATCTG	TGTCTGTCCCTCTCTCTGTGT
28S	TCACCTCCACCACTTCTCTCT	TGCTGTTCGCTTTGACTCC
MYB65	ACCCTTTCTGCCTCCTTTGT	TGTCAGGTGATTGATTCTTTGC
ARF8	GCCGTGAAGGGAGTGGTAAT	CCCAGGATATGGTGAAAGTGA
HAM3	TTCGTGTGTCTGAGAATGAGG	ATGGTTAGGAAATGGGAGGT
IAA9	GGAATATGGAAAACGGAGGA	CGCAGACTTGAATAAACAGAGAAG
ABF2	AGGGTA EMBED Excel.Sheet.8 EMBED Excel.Sheet.8 EMBED Excel.Sheet.8 EMBED Excel.Sheet.8 EMBED Word.Document.8 EMBED Word.Document.8 TTGGGTTGTTGTGTAA	GGAAAAATGGGCTGATGTTG
WRKY50	TTGGGGGTTATGCCACAA	TGCTTAGAACAGATGACAAGAGAGT

基因	上游引物序列(5’-3’)	下游引物序列(5’-3’)
18S	ATGCCTTGTCTTTGGTGC	TGGGGTTGATGTTACTTGAT
GADPH	GAACTCGGAACGCCATAC	GCTGCTTCATTCAACATCAT
Actin	GTACTACTAACAGAAGCACCGC	GCATAAAGAGACAGAACAGCC
α-TUB	ACTAACCTGGTCCCGTACCC	AGCCGCATTGACATCCTT
EF-1α	GCATGTTGTCGCCGTTGAA	GCTGCCGGTACTGGTGAGTT
UBQ	ACCCCTAAGCCTCAGAACAAG	TCGCCGACTACAACATCCA
UBC	TTTTGGGGGGTGTATCTG	TGTCTGTCCCTCTCTCTGTGT
28S	TCACCTCCACCACTTCTCTCT	TGCTGTTCGCTTTGACTCC
MYB65	ACCCTTTCTGCCTCCTTTGT	TGTCAGGTGATTGATTCTTTGC
ARF8	GCCGTGAAGGGAGTGGTAAT	CCCAGGATATGGTGAAAGTGA
HAM3	TTCGTGTGTCTGAGAATGAGG	ATGGTTAGGAAATGGGAGGT
IAA9	GGAATATGGAAAACGGAGGA	CGCAGACTTGAATAAACAGAGAAG
ABF2	AGGGTA EMBED Excel.Sheet.8 EMBED Excel.Sheet.8 EMBED Excel.Sheet.8 EMBED Excel.Sheet.8 EMBED Word.Document.8 EMBED Word.Document.8 TTGGGTTGTTGTGTAA	GGAAAAATGGGCTGATGTTG
WRKY50	TTGGGGGTTATGCCACAA	TGCTTAGAACAGATGACAAGAGAGT

基因	上游引物序列(5’-3’)	下游引物序列(5’-3’)
MIR171t	CCTTGAGCCGCGTCAATATCTCA	Reverse Primer(Kit)
MIR156ab	CCCCGACAGAAGAGAGTGAGCAC	Reverse Primer(Kit)
MIR159d	CCCCTTGGATTGAAGGGAGCTCT	Reverse Primer(Kit)
MIR396f	CCCCTTCCACAGCTTTCTTGAACTA	Reverse Primer(Kit)
MIR390j	GAGCTCAGGAGGGATAGCGCC	Reverse Primer(Kit)
MIR166ab	CGGACCAGGCTTCATTCCCC	Reverse Primer(Kit)
5S	GGCTATTCTGGTGTCCTAGGCGTAGA	Reverse Primer(Kit)
U4	GGCTCAATTGCTGGTTGAAAACTATTTCC	Reverse Primer(Kit)
U6	GCGGTTGGAACGATACAGAGAAGATT	Reverse Primer(Kit)
MIR156ac-5p	TTGACAGAAGATAGAGAGCAC	Reverse Primer(Kit)
MIR159c	TTGGATTGAAGGGAGCTCCA	Reverse Primer(Kit)
MIR167m-5p	TGAAGCTGCCAGCCTGATCTC	Reverse Primer(Kit)
MIR171a	TGATTGAGCCGCGCCAATATC	Reverse Primer(Kit)
MIR393a	TCCAAAGGGATCGCATTGATCC	Reverse Primer(Kit)
MIR399f-5p	GGGCTTCCCTCCCTTGGCAGC	Reverse Primer(Kit)
MIR529d	AGAAGAGAGAGAGTACAGCCC	Reverse Primer(Kit)

基因	上游引物序列(5’-3’)	下游引物序列(5’-3’)
MIR171t	CCTTGAGCCGCGTCAATATCTCA	Reverse Primer(Kit)
MIR156ab	CCCCGACAGAAGAGAGTGAGCAC	Reverse Primer(Kit)
MIR159d	CCCCTTGGATTGAAGGGAGCTCT	Reverse Primer(Kit)
MIR396f	CCCCTTCCACAGCTTTCTTGAACTA	Reverse Primer(Kit)
MIR390j	GAGCTCAGGAGGGATAGCGCC	Reverse Primer(Kit)
MIR166ab	CGGACCAGGCTTCATTCCCC	Reverse Primer(Kit)
5S	GGCTATTCTGGTGTCCTAGGCGTAGA	Reverse Primer(Kit)
U4	GGCTCAATTGCTGGTTGAAAACTATTTCC	Reverse Primer(Kit)
U6	GCGGTTGGAACGATACAGAGAAGATT	Reverse Primer(Kit)
MIR156ac-5p	TTGACAGAAGATAGAGAGCAC	Reverse Primer(Kit)
MIR159c	TTGGATTGAAGGGAGCTCCA	Reverse Primer(Kit)
MIR167m-5p	TGAAGCTGCCAGCCTGATCTC	Reverse Primer(Kit)
MIR171a	TGATTGAGCCGCGCCAATATC	Reverse Primer(Kit)
MIR393a	TCCAAAGGGATCGCATTGATCC	Reverse Primer(Kit)
MIR399f-5p	GGGCTTCCCTCCCTTGGCAGC	Reverse Primer(Kit)
MIR529d	AGAAGAGAGAGAGTACAGCCC	Reverse Primer(Kit)

内参基因	标准曲线方程	扩增效率/%	R²
UBC	y = -3.2755x + 30.579	101.97	0.9875
α-TUB	y = -3.3943x + 30.647	97.06	0.9853
28S	y = -3.3943x + 30.647	108.41	0.9889
18S	y = -3.1354x + 26.853	109.33	0.9956
GAPDH	y = -3.1596x + 25.041	107.25	0.9938
EF-1α	y = -3.0366x + 31.773	103.99	0.9985
Actin	y = -3.2298x + 28.573	100.14	0.9992
UBQ	y = -3.3185x + 24.461	113.45	0.9899
MIR171t	y = -3.0829x + 29.294	111.04	0.9858
MIR156ab	y = -3.4045x + 24.405	96.66	0.9915
MIR159d	y = -3.3429x + 19.851	99.13	0.9977
MIR396f	y = -3.4674x + 19.971	94.26	0.9965
MIR390j	y = -3.4946x + 23.815	93.26	0.9869
MIR166ab	y = -3.3186x + 24.069	100.13	0.9978
5S	y = -3.2527x + 18.429	102.97	0.9831
U4	y = -3.5304x + 15.669	91.97	0.9976
U6	y = -3.486x + 20.117	93.58	0.9996