Identification of microRNA associated with flower organ development in <em>Rosa chinensis</em> ‘Viridiflora’

Sui Meng-Jie; Yan Hui-Jun; Wang Zhen-Zhen; Qiu Xian-Qin; Jian Hong-Ying; Wang Qi-Gang; Chen Min; Zhang Hao; Tang Kai-Xue

doi:10.11913/PSJ.2095-0837.2019.10037

Plant Science Journal > 2019 > 37(1): 37-46. > DOI: 10.11913/PSJ.2095-0837.2019.10037 CSTR: 32231.14.PSJ.2095-0837.2019.10037

Sui Meng-Jie, Yan Hui-Jun, Wang Zhen-Zhen, Qiu Xian-Qin, Jian Hong-Ying, Wang Qi-Gang, Chen Min, Zhang Hao, Tang Kai-Xue. Identification of microRNA associated with flower organ development in Rosa chinensis ‘Viridiflora’[J]. Plant Science Journal, 2019, 37(1): 37-46. DOI: 10.11913/PSJ.2095-0837.2019.10037

Citation:

PDF (7043 KB)

Identification of microRNA associated with flower organ development in Rosa chinensis ‘Viridiflora’

1.
College of Landscape and Horticulture, Yunnan Agricultural University, Kunming 650201, China
2. Flower Research Institute of Yunnan Academy of Agricultural Sciences, Kunming 650205, China
3. School of Agriculture, Yunnan University, Kunming 650091, China

Funds: This work was supported by grants from the National Natural Science Foundation of China (31660579, 31872144) and Academic and Technical Talents Training Project of Yunnan Province (2017HB067)

More Information

Received Date: July 31, 2018
Revised Date: September 26, 2018
Published Date: February 27, 2019

Graphical Abstract

Abstract

Abstract

In this study, two independent microRNA (miRNA) libraries of Rosa chinensis ‘Viridiflora’and ‘Old Blush’ at the flower bud development stage were constructed and sequenced with Illumina sequencing. In total, 39 known miRNAs and 42 known pre-miRNAs were discovered, and 56 novel miRNAs and 57 novel pre-miRNAs were predicted in the ‘Viridiflora’library. In total, 39 known miRNAs and 40 known pre-miRNAs were identified, and 53 novel miRNAs and 57 novel pre-miRNAs were predicted in the ‘Old Blush’ library. Compared with ‘Old Blush’, there were 31 differentially expressed miRNAs in ‘Viridiflora’, with 17 up-regulated and 14 down-regulated. The RT-qPCR results showed that the expressions of miR156, miR398, and miR535 were up-regulated, whereas those of miR167, miR172, and miR396 were down-regulated in ‘Viridiflora’, identical to those obtained by sequencing. The expressions of miR172 and miR156 in different floral organs of the two rose species were detected by RT-qPCR. We found that miR172 was down-regulated in the petals, pistils, and stamens of ‘Viridiflora’. Furthermore, RcAP2 was previously reported to be up-regulated in relative flower organs, suggesting that miR172 may negatively regulate the expression of its target gene RcAP2. Thus, miR172 may play an important role in the development of floral organs of ‘Viridiflora’.
- Rosa chinensis ‘Viridiflora’,
- Flower organ development,
- MiRNAs high-throughput sequencing,
- RT-qPCR

FullText(HTML)

References (38)

References

[1]	张佐双,朱秀珍. 中国月季[M]. 北京:中国林业出版社,2006.
[2]	刘永刚,刘青林. 月季遗传资源的评价与利用[J]. 植物遗传资源学报,2004,5(1):87-90. Liu YG,Liu QL. Evaluation and exploitation of genetic resources in roses[J]. Journal of Plant Genetic Resource,2004,5(1):87-90.
[3]	Yan HJ,Yang JK,Zhang H,Li SB,Zhang T,et al. Use of digital gene expression to discriminate gene expression in different developmental stages of Rosa chinenssis ‘Pallida’[J]. Acta Horticulturae,2015,1064:115-121.
[4]	Chmelmitsky I, Azizbekova N,Khayat E,Zieslin N. Morphological development of normal and phyllody expressing Rosa hybridacv. Motrea flowers[J]. Plant Growth Regul,2002,37:215-221.
[5]	Bendahmane M, Dubois A,Raymond O,Bris ML. Gene-tics and genomics of flower initiation and development in roses[J]. J Exp Biol,2013,64(4):847-857.
[6]	Krussman G. The complete book of roses[M]. Portland:Timber Press,1981.
[7]	丁正明. 月季绿辦病[J]. 上海师范学院学报,1983,1:90-97.Ding ZM. The rose phyllody[J].Journal of Shanghai Normal University,1983,1:90-97.
[8]	Chmelnitsky I,Khayat E,Zieslin N. Involvement of RAG,a rose homologue of AGAMOUS,in phyllody development of Rosa hybridacv. Motrea[J]. Plant Growth Regul,2003,39(1):63-66.
[9]	Yan H,Hao Z,Wang Q,Jian H,Qiu X, et al. The Rosa chinensiscv. Viridiflora phyllody phenotype is associated with misexpression of flower organ identity genes[J]. Front Plant Sci,2016,7(638):1-14.
[10]	Aukerman MJ,Sakai H. Regulation of flowering time and floral organ identity by a microRNA and its APETALA2-liketarget genes[J]. Plant Cell,2003,15(11):2730-2741.
[11]	Park W,Li J,Song R,Messing J,Chen X. CARPEL FACTORY,a Dicer homolog,and HEN1,a novel protein,act in microRNA metabolism in Arabidopsis thaliana[J]. Curr Biol,2002,12(17):1484-1495.
[12]	Lauter N,Kampani A,Carlson S,Goebel M,Moose SP. MicroRNA172 down-regulates glossy15 to promote vegetative phase change in maize[J]. Proc Natl Acad Sci USA,2005,102(26):9412-9417.
[13]	Wei Q,Ma C,Xu Y,Wang T,Chen Y,et al. Control of chrysanthemum flowering through integration with an aging pathway[J]. Nat Commun,2017,8(1):829.
[14]	Wang JW,Czech B,Weigel D. MiR156-regulated SPL transcription factors define an endogenous flowering pathway in Arabidopsis thaliana[J]. Cell,2009,138(4):738-749.
[15]	Chen X. A microRNA as a translational repressor of APETALA2 in Arabidopsisflower development[J]. Science,2004,303(5666):2022-2025.
[16]	Wen M,Shen Y,Shi S,Tang T. miREvo:an integrative microRNA evolutionary analysis platform for next-generation sequencing experiments[J]. BMC Bioinformatics,2012,13:140.
[17]	Friedlander MR,Mackowiak SD,Li N,Chen W,Rajewsky N. MiRDeep2 accurately identifies known and hundreds of novel microRNA genes in seven animal clades[J]. Nucleic Acids Res,2012,40:37-52.
[18]	Kanehisa M,Araki M,Goto S,Hattori1 M,Hirakawa M,et al. KEGG for linking genomes to life and the environment[J]. Nucleic Acids Res,2008,36:480-484.
[19]	't Hoen PA,Ariyurek Y,Thygesen HH,Vreugdenhil E,Vossen R H,et al. Deep sequencing-based expression analysis shows major advances in robustness,resolution and inter-lab portability over five microarray platforms[J]. Nucleic Acids Res,2008,36(21):e141.
[20]	Qiu DY,Pan XP,Wilson IW,Li FL,Liu M,et al. High throughput sequencing technology reveals that the taxoid elicitor methyl jasmonate regulates microRNA expression in Chinese yew (Taxus chinensis)[J].Gene,2009,436(1-2):37-44.
[21]	Xie ZX,Allen E,Fahlgren N,Calamar A,Givanand SA,et al. Expression of ArabidopsismiRNA genes[J]. Plant Physiol,2005,138(4):2145-2154.
[22]	Rajagopalan R,Vaucheret H,Trejo J,Bartel DP. Adiverse and evolutionarily fluid set of microRNAsinArabidopsis thaliana[J]. Genes Dev,2006,20(24):3407-3425.
[23]	Wei B,Cai T,Zhang RZ,Li AL,Huo NX,et al. Novel microRNAs uncovered by deep sequencing of small RNA transcriptomes in bread wheat (Triticum aestivumL.) and Brachypodium distachyon (L.) Beauv. [J].Funct Integr Genomics,2009,9(4):499-511.
[24]	黄儒,苍晶,于晶,卢宝伟,刘丽杰,等. 冬小麦小RNA高通量测序及生物信息学分析[J]. 植物学报,2014,49(1):8-18.Hang R,Cang J,Yu J,Lu BW,Liu LJ,et al. Solexa sequencing and bioinformatics analysis of small RNA in winter wheat[J]. Chinese Bulletin of Botany,2014,49(1):8-18.
[25]	Baksa I,Nagy T,Barta E,Havelda Z,Várallyay E,et al. Identification of Nicotiana benthamianamicroRNAs and their targets using high throughput sequencing and degradome analysis[J]. BMC Genomics,2015,16(1):1025.
[26]	Chen J,Yi Z,Li Q,Wang Y,Chen L,et al. Identification of miRNAs and their targets through high-throughput sequencing and degradome analysis in male and female Asparagus officinalis[J]. BMC Plant Biol,2016,16:80.
[27]	Wang L,Du H,Wuyun TN. Genome-wide identification of microRNAs and their targets in the leaves and fruits of Eucommia ulmoidesusing high-throughput sequencing[J]. Front Plant Sci,2016,7:1632.
[28]	Yokotani N,Nakano R,Imanishi S. Ripening-associated ethylene biosynthesis in tomato fruit is autocatalytically and developmentally regulated[J]. J Exp Biol,2009,60(12):3433-3442.
[29]	Jack T. Molecular and genetic mechanisms of floral control[J]. Plant Cell,2004,16:S1-S17.
[30]	Wang JW,Czech B,Weigel D. miR156-Regulated SPL transcription factors define an endogenous flowering pathway in Arabidopsis thaliana[J]. Cell,2009,138(4):738-749.
[31]	Wu G,Park MY,Conway SR,Wang JW,Weigel D,et al. The sequential action of miR156 and miR172 regulates developmental timing in Arabidopsis[J]. Cell,2009,138(4):750-759.
[32]	Horiguchi G,Kim G,Tsukaya H. The transcription factor AtGRF5 and the transcription coactivator AN3 regulate cell proliferation in leaf primordia of Arabidopsis thaliana[J]. Plant J,2005,43(1):68-78.
[33]	Liu H,Guo S,Xu Y,Li C,Zhang Z,et al. OsmiR396d-regulated OsGRFs function in floral organogenesis in rice through binding to their targets OsJMJ706 and OsCR4[J]. Plant Physiol,2014,165(1):160-174.
[34]	Jung JH,Seo YH,Seo PJ,Reyes JL,Yun J,et al. The GIGANTEA-regulated microRNA172 mediates photoperiodic flowering independent of CONSTANS in Arabidopsis[J].Plant Cell,2007,19(9):2736-2748.
[35]	侍婷,高志红,章镇,庄维兵. MicroRNA参与植物花发育调控的研究进展[J]. 中国农学通报,2010,26(13):267-271. Shi T,Gao ZH,Zhang Z,Zhuang WB,Advance of researchon microRNA in flower development regulation[J]. Chinese Agricultural Science Bulletin,2010,26(13):267-271.
[36]	Wang JW,Czech B,Weigel D. MiR156-regulated SPL transcription factors delne an endogenous flowering pathway in Arabidopsis thaliana[J]. Cell,2009,138(4):738-749.
[37]	陈罡. 植物MicroRNA对花发育调控研究进展[J]. 辽宁林业科技,2017,(2):55-58.
[38]	Grigorova B,Mara C,Hollender C,Sijacic P,Chen XM,et al. LEUNIG and SEUSS co-repressors regulate miR172 expression in Arabidopsisflowers[J]. Development,2011,138(12):2451-2456.

[1]	Peng Li-Ping, Cheng Fang-Yun, Zhong Yuan, Xu Xing-Xing, Xian Hong-Li. Phenotypic variation in cultivar populations of Paeonia ostii T. Hong et J. X. Zhang[J]. Plant Science Journal, 2018, 36(2): 170-180. DOI: 10.11913/PSJ.2095-0837.2018.20170
[2]	ZHANG Wen-Liu, GAO Jiang-Yun, LIU Qiang. Habenaria chlorina, a Newly Recorded Species of Orchidaceae from China(英文稿)[J]. Plant Science Journal, 2016, 34(1): 18-20. DOI: 10.11913/PSJ.2095-0837.2016.10018
[3]	LIAO Zhen-Ni, HUANG Qing, CHENG Qi-Ming, YU Xiao-Ying, LI Xiao-Peng, LIU En-Xue. Effect of Plant Age on Botanical Characteristics and Chemical Composition of Essential Oil from Lavandin[J]. Plant Science Journal, 2014, 32(5): 517-521. DOI: 10.11913/PSJ.2095-0837.2014.50517
[4]	LIU Wei, ZHANG Lin, ZHOU Jie, SHI Guo-Yu, LIU Jian-Hua, WANG Xiao. Comparison of Active Constituents at Different Growth Stages in Salvia miltiorrhiza Bge. and Salvia miltiorrhiza Bge. f. alba[J]. Plant Science Journal, 2013, 31(6): 596-602. DOI: 10.3724/SP.J.1142.2013.60596
[5]	WANG Yi, WANG Yan. Habenaria anomaliflora,a New Record of Orchidaceae from China[J]. Plant Science Journal, 2010, 28(6): 696-697.
[6]	DAI Xi-Ling, WANG Quan-Xi, ZHU Rui-Liang, CAO Jian-Guo. Structure and Development of the Sporoderm in Coniogramme japonica (Thunb.) Diels (Hemionitidaceae)[J]. Plant Science Journal, 2010, 28(2): 119-125.
[7]	MU Hong-Ping, YE Wan-Hui, CHEN Yi-Zhu, ZHU Jian-Ling, CAO Hong-Lin. Photosynthesis and Growth of Ardisia crenata and Ardisia punctata under Different Phosphorus Nutrition Levels[J]. Plant Science Journal, 2008, 26(5): 514-519.
[8]	CHEN Li-Jun, RAO Wen-Hui. The Occurrence of Habenaria leptoloba(Orchidaceae) in Guangdong[J]. Plant Science Journal, 2008, 26(3): 255-258.
[9]	LIU Shi-Biao, HU Zheng-Hai. Effects of Shading Treatment on the Leaf Morphology, Structure and Photosynthetic Characteristics of Gynostemma pentaphyllum[J]. Plant Science Journal, 2004, 22(4): 339-344.
[10]	LIU Zhong-Jian, CHEN Sing-Chi. Cymbidium aestivum,A New Species of Orchidaceae from Yunnan[J]. Plant Science Journal, 2004, 22(4): 323-325.

Cited By

Get Citation

PDF

XML

Article views (846) PDF downloads (470)

Turn off MathJax

Article Contents

Abstract

References

Identification of microRNA associated with flower organ development in Rosa chinensis ‘Viridiflora’

Abstract

References

Related Articles

Catalog

Identification of microRNA associated with flower organ development in Rosa chinensis ‘Viridiflora’

Abstract

References

Related Articles

Catalog

Export File

Citation

Format

Content