Abstract
Long non-coding RNAs (lncRNAs) have been shown in animals to play roles in a wide range of biological processes. In plant, light modulates the growth and development as a key external signal. However, little is known about the role of plant lncRNA in response to light. In this study, we sequenced the messenger RNAs (mRNAs), lncRNAs and microRNAs (miRNAs) in Arabidopsis seedlings under blue light for 2 h and 8 h. Compared to dark, we identified 4197 mRNAs, 375 miRNAs and 481 lncRNAs, or 5207 mRNAs, 286 miRNAs and 545 lncRNAs of differential expressions under blue light treatments for 2 h or 8 h respectively. Subsequently, a total of 407 competing endogenous RNA (ceRNA) pairs (lncRNA-mRNA-miRNA) were constructed. We identified a blue light-induced lncRNA which plays roles in blue light-directed plant photomorphogenesis and response to mannitol stress by serving as a ceRNA to sequester miR167 in a type of target mimicry. These results revealed previously unknown roles of the lncRNA in blue light signaling and mannitol stress, and provided useful resources of lncRNAs associated with miRNAs in response to blue light.
Similar content being viewed by others
Introduction
Long non-coding RNAs (lncRNAs) represent transcripts of more than 200 nucleotides in length without or with little protein-coding potential. Previous studies have shown that lncRNAs are involved in many biological processes, including chromatin structure regulation, stem cell fate determination, tumorgenesis, etc. LncRNAs affect gene expression by acting as cis-acting elements, trans-acting factors, scaffolding components of chromatin-modified protein complexes, or nuclear body maintenance factors1,2,3.
LncRNAs have been extensively studied in animals. In contrast, the number of plant lncRNAs that have been functionally characterized are limited4,5. Plant lncRNAs have been found to be involved in gene silencing6, flowering time regulation (COLD ASSISTED INTRONIC NONCODING RNA (COLDAIR and COOLAIR)7;8, biotic and abiotic stress responses9, male fertility (LONG-DAY-SPECIFIC MALE-FERTILITY-ASSOCIATED RNA, LDMAR)10, photomorphogenesis11, plant disease resistance12, and regulation of phosphate assimilation (INDUCED BY PHOSPHATE STARVATION1, IPS1/At4)13;14.
Interestingly, some lncRNAs can serve as signal molecules under different stimulation conditions15. In addition, the non-coding IPS1 (INDUCED BY PHOSPHATE STARVATION 1) RNA can serve as a molecular bait, which binds directly to ceRNA to block the role of the targets (Franco-Zorrilla et al., 2007), or to transcription factor/regulator to inhibit the related signal transduction. The ceRNA is the RNA component in a complex for transcriptional regulation through RNA-RNA interaction. CeRNAs include some of the protein-coding RNAs, lncRNAs, miRNAs, pseudogene RNAs, and circular RNAs (circRNAs)16. The function of the interaction between the lncRNA and its miRNA target was shown in the sequestration of miR399 by plant lncRNA IPS1/At4 to regulate phosphate homeostasis14. LncRNA can act as a directing factor: after binding to protein, it can locate the protein complexes on specific DNA sequences, and regulate the transcription of downstream factors. In addition, lncRNAs can serve as scaffold molecules to bind to multiple transcription factors to activate multiple signaling pathways at the same time, and achieve information integration between different signaling pathways17.
As one of the most important environmental factors, light regulates plant growth and development in many aspects, including germination, photomorphogenesis, phototropism, flowering, stem and leaf growth, clock regulation, stomatal opening, chloroplast movement and anthocyanin synthesis18. Plants use at least four types of photoreceptors to receive spectral signals of different wavelengths, including phytochromes (phys), cryptochromes (crys), phototropins (phots), and ultraviolet B receptors. PhyA to phyE are receptors of red and far red lights19,20,21,22. Three types of blue light receptors were identified: cryptochrome (including CRY1 and CRY2), phototropin (including PHOT1 and PHOT2) and LOV/F-box/Kelch-repeat protein (including ZTL, LKP2 and FKF1)21. The interactions between blue light receptors LKP2 and FKF1 and the transcription factor CDF2 play important roles in blue light signal transduction through ubiquitination-mediated protein degradation23. In previous works, we revealed that CDF2 is involved in miRNA transcription and processing24, and PIF4, which was known to interact with phyB and CRY125,26, plays a role in miRNA biogenesis to affect red light-directed plant photomorphogenesis27.
Here we found that blue light induced the expressions of Arabidopsis lncRNAs along with the changed expressions of a group of miRNAs under blue light. By screening the mutants of lncRNAs, we identified a blue light-induced lncRNA (NONATHG000085.1) (named BLIL1) which was able to inhibit hypocotyl elongation under blue light. Bioinformatics analysis showed a competitive relationship between BLIL1 and miRNA167. We characterized the ceRNA relationship between BLIL1 and miRNA167 by analyzing the levels of BLIL1, miRNA167 and the transcripts of miRNA167-targeted genes ARF6/8, as well as the phenotypes of their mutants under blue light or mannitol treatments. Our results demonstrated a previously unknown role of lncRNA in the blue light signaling and mannitol stress response.
Results
High-throughput sequencing of the transcripts from the Arabidopsis seedlings upon blue light treatments
To annotate the relationships between lncRNAs and miRNAs in Arabidopsis under blue light, we performed lncRNA sequencing of three biological replicates, each with three samples using 4 day dark-grown WT seedlings exposed to continuous blue light for 0 h, 2 h and 8 h (Fig. 1A). 1,095,370–1,100,180 M paired-end reads with 100 bp in length for the mRNAs and lncRNAs, and 11,600,936–12,413,799 single-end reads with 50 bp in length for the miRNAs were acquired from nine samples (Table S1 in Supporting Information). All the clean reads were aligned to Arabidopsis reference genome assembly (UMD3.1.80) for further analysis. We calculated the correlation coefficient (r2) of the sequencing data among the three individual samples of biological replicates in each period based on the FPKM and TPM values, and found that the r2 values were 0.8499–0.9958, 0.9774–0.9995 and 0.8955–0.9907 for the mRNAs, lncRNAs and miRNAs, respectively, indicating that the similarities of the mRNA, lncRNA or miRNA biological replicates were sufficiently high (Fig. S1).
Identification of lncRNAs inArabidopsisseedlings under blue light
To annotate lncRNAs, we extracted the total RNA from samples. Non-coding RNAs and mRNAs were enriched by removing the ribosomal RNAs (rRNAs) from the total RNA. Due to the instability of rRNA removing efficiency, we also removed rRNA-contained reads by alignment. We choose Coding Poteintial Calculator (CPC)28 and iSeeRNA29 which perform well compared to other softwares in both accuracy and efficiency for lncRNA prediction. Cuffmege was used to merge several assemblies together and filter the transfrags that are probably artifacts. A single annotation file was then generated for downstream differential analysis. We obtained the whole parsimonious set of transcripts to detect the novel transcripts from the initial assemblies, and compared the assembled transcripts to the reference annotation. HISAT reference annotation based assembly method was used to reconstruct the transcripts, and background noise was reduced by using FPKM and coverage threshold30,31. The novel transcripts were identified by calculating the coding potential of these transcripts (Fig. 1B).
We also calculated the distribution of lncRNA loci induced under blue light treatments for 2 h and 8 h in NONCODE v3.032 with Cuffcompare categories. We found that the majority of lncRNA loci (46.15%) are antisense, while 28.85% are intergenic, 10.58% divergent, 9.62% intronic and 4.81% sense (Fig. 1C).
Identification of DEmRNAs, DEmiRNAs, and DElncRNAs in Arabidopsis seedlings under blue light
To identify the regulatory networks of mRNAs, lncRNAs and miRNAs under blue light, we analyzed the differentially expressed mRNAs, lncRNAs and miRNAs (DEmRNAs, DElncRNAs, DEmiRNAs). Compared to the dark condition, 481 or 545 DElncRNAs were found in Arabidopsis seedlings under blue light treatment for 2 h or 8 h respectively, (Fig. 2A,B), of which 316 or 308 were up-regulated and 165 or 237 down-regulated. In addition, 4197 or 5207 DEmRNAs were identified in Arabidopsis seedlings under blue light treatment for 2 h or 8 h respectively, with 3222 or 3970 up-regulated and 975 or 1237 down-regulated more than two fold. In total, 375 or 286 DEmiRNAs were found in Arabidopsis seedlings under blue light treatments for 2 h or 8 h respectively, with 233 or 175 up-regulated and 142 or 111 down-regulated for more than two fold (Fig. 2C,D).
To validate the expression patterns of lncRNAs under the blue light treatment, we performed qRT-PCR analysis to examine the expressions and sequences of 6 lncRNAs (which include 4 transcripts present in the Arabidopsis database (http://www.noncode.org/) and 2 novel transcripts based on our assembly of RNA-seq data) (Fig. 3A–F). The expression patterns of all lncRNAs were found to be consistent with the RNA-seq data. In addition, we also performed Northern blots of 4 miRNAs to validate the results of miRNA sequencing. We found that the expression patterns of the 4 miRNAs were similar to those shown in the miRNA sequencing data (Fig. 3G).
Identification of the ceRNA pairs inArabidopsisseedlings under blue light
It was known that lncRNA can play a role in sequestering the specific miRNA by acting as a ceRNA in a type of target mimicry to protect the target mRNA in both plants and animals33,34,35,36. We measured the likelihood of the ceRNAs using StarBase v2.037,38. Using the hypergeometric test39, we calculated the p-value for each potential ceRNA pair (lncRNA-mRNA)38. Our bioinformatics analysis indicated that 180 of the identified lncRNAs have the potential to compete with miRNAs, including several conserved miRNAs such as miR160, miR164, miR167, miR169 and miR172 (Fig. 4A,B, Figs. S2 and S3). We then constructed lncRNA-miRNA-mRNA interaction networks (Figs. S2 and S3). We found that 744 DEGs (differentially expressed genes) and 183 DElncRNAs were targeted by 155 miRNAs (Figs. S2 and S3).
The role of BLIL1-miR167 pair in blue light-directed plant photomorphogenesis
We found that miR167 plays a role in modulating hypocotyl elongation27, therefore, we focused on the regulatory network of lncRNA-miRNA167-mRNA. The 14 complementary nucleotides of miR167 to BLIL1 are shown in Fig. 4, including 8 bases at the 5′ end of miR167 (Fig. 4B,C). To confirm the expression profiles of BLIL1 and miR167, we performed qRT-PCRs to examine the transcript levels of BLIL1 and miR167-targeted mRNAs under blue light treatments for 2 h, 8 h and 12 h. As shown in Fig. 5A–C, the transcript levels of BLIL1, ARF6 and ARF8 which are targets of miR16740, were induced under blue light treatments. Moreover, Northern blots confirmed that the transcript level of miR167 is opposite to those of BLIL1, ARF6 and ARF8 (Fig. 5A–C).
We then investigated the role of the BLIL1-ARF6/8-miR167 regulatory network in photomorphogenesis by examining the blue light-dependent inhibition of hypocotyl elongation. We analyzed the hypocotyl growth of 4-day-old Col and blil1-1, blil1-2, arf6/8 and miR167 mutant seedlings grown under continuous blue light at 10 µmol s−1m−2 intensity, or continuous darkness. The blil1-1, blil1-2, arf6/8 mutants display long hypocotyl phenotypes compared with wild type after treatment with continuous blue light, and miR167 mutant shows shorter hypocotyl than Col under blue light (Fig. 5D–F). The hypocotyl lengths of these mutants were similar to that of Col grown under dark condition (Fig. S4). These results revealed the competitive relationships between miR167 and BLIL1 or ARF6/8 in regulation of the blue light-dependent photomorphogenesis.
The role of BLIL1-miR167 pair in response to mannitol stress
As miR167 was reported to be involved in stress responses41, we validated the competitive relationship among BLIL1, ARF6/8 and miR167 under osmotic stresses. We performed qRT-PCRs to examine the induction profile of BLIL1, ARF6/8 and miR167 under 200 mM mannitol stress. When the seedlings were treated by 200 mM mannitol, the levels of BLIL1 and ARF6/8 transcripts increased slightly at 3 h, obviously at 6 h, and reached the maximum at 12 h (Fig. 6A,C), whereas the level of miR167 decreased obviously at 6 h with no significant difference at 3 h (Fig. 6B).
To further confirm the competitive relationship, we investigated the mannitol tolerances of blil1-1, blil1-2, arf6/8 and miR167 mutant seedlings. Five days after germination on normal MS medium, the seedlings were transferred to MS medium plates containing 200 mM mannitol, and the plates were stood-up. The amounts of lateral roots were measured at the 7th day after transferring. As shown in Fig. 6D–F, the results demonstrated that blil1-1, blil1-2, arf6/8 mutants displayed more lateral roots than Col, while miR167 mutant showed less lateral roots than Col under mannitol stress. As a control, no significant differences were observed among the mutants and Col seedlings under normal MS medium. These results indicated that the mutants of blil1-1, blil1-2, and arf6/8 showed reduced sensitivity to mannitol treatment, whereas miR167 displayed elevated sensitivity to mannitol treatment, suggesting that BLIL1 and ARF6/8 acts as positive factors, and miR167 as a negative factor in response to mannitol stress.
Discussion
Blue light plays an important role in plant growth and development42,43. Many genes have been known to be involved in blue light signal transduction44. The recent discovery of lncRNAs has shown that lncRNAs play roles in many regulatory pathways, such as the regulation of chromatin structure and determination of cell fate1,2,6,7,8,9,10,11,12,13,14. However, up to now, lncRNA has not been shown to be involved in blue light signal transduction. In this study, we identified differentially expressed lncRNAs under blue light compared to the dark condition. We confirmed that an lncRNA (BLIL1) functions as a ceRNA to compete with miRNA167. Further genetics and phenotype analysis of the related mutants supported that BLIL1 is antagonistic to miR167 under blue light and manitol stress.
In this study, we examined blue light-regulated lncRNA and miRNA expressions in 4 d seedlings grown in darkness and then exposed to blue light for 2 h and 8 h. Darkness was used as control instead of white light which is of full spectrum, and contains different wavelengths of lights including blue light. Jiao et al. used darkness as the control to analyze the expressions of transcription factors under blue and white light treatments45. Wang et al. identified long noncoding natural antisense transcripts (lncNATs) from the etiolated seedlings exposing to continuous white light for 1 h or 6 h, and the dark-grown seedlings were used as the control46. Darkness was also used as control to examine the transcriptome changes in cry1cry2 mutation and BLUE-LIGHT INHIBITOR OF CRYPTOCHROMES 1 (BIC1) overexpression lines in response to blue light47 and analyze the expression profiles of blue light-grown WT, cry1cry2, and CNT1 or CNT1-G283E overexpression seedlings48. In addition, we used darkness as control to study miRNA expressions induced under red light treatments for 2 h and 8h27.
CeRNAs play important roles in the regulation of miRNA or lncRNA functions. IPS1, a plant lncRNA, is a known functional ceRNA involved in regulation of phosphate assimilation14. MiR160 and miR166 for eTMs (endogenous miRNA target mimic) that interact with several lncRNAs were found in Arabidopsis and rice49. In this study, we constructed a blue light induced ceRNA network of Arabidopsis, providing useful resources for studying the blue light signaling. In addition, our ceRNA analysis showed that a single miRNA might target multiple lncRNAs or mRNA (Figs. S2 and S3 in Supporting Information). In animals, lncRNAs were shown to act as ceRNAs to regulate mRNA expression by sponging miRNA in bovine adipocyte differentiation50. Nine lncRNAs were proved to act as ceRNAs to affect the expression of lipid metabolic genes by sponging miRNAs in bovine liver51. In this work, we focused the intergenic and non-coding sequences of Arabidopsis thaliana to predict lncRNAs, and identified 407 ceRNA candidate pairs. Moreover, we verified the competitive function among miR167, BLIL1, and miRNA167 target genes. Many lncRNAs might be functional ceRNAs, which might be important for plant growth and development or stress responses.
LncRNA can regulate the biological activities of eukaryotes through different mechanisms52. LncRNA can function as a ceRNA by coordinating with miRNAs, in addition, lncRNAs may regulate gene expression in a cis- or trans-acting manner53. The regulatory roles of lncRNAs in gene expression could be achieved by acting on the adjacent target genes, which was known as the cis-acting process of lncRNAs54. Some lncRNAs can regulate the translation of mRNA through interfering with the binding of mRNA binding proteins to the mRNA53. Cis-Natural Antisense Transcripts (cis-NATs) were known to regulate cognate sense mRNA translation55. An example for trans-acting lncRNA is Arabidopsis hidden treasure 1 (HID1) which associates with the chromatin of the first intron of transcription factor PIF3 and inhibit PIF3 transcription56. Several studies also have reported that lncRNAs can regulate the activities of transcription factors57,58,59. It has been known that many regulatory factors involved in light signaling pathways21,22, further studies on the connection between lncRNAs and these regulatory factors will provide additional information regarding their detailed roles in light signaling pathway.
Methods
Plant materials and growth conditions
Arabidopsis thaliana (ecotype Col-0), miR167b (CS872594),arf6 (CS24606), arf8 (CS24608), arf6/8 (CS24632), blil1-1 (SALK_112856) and blil1-2 (CS65633) mutants were obtained from the Arabidopsis Biological Resource Center (Ohio State University). All plants were grown in soil or Murashige and Skoog (MS) medium at 16 hr light/8 hr dark photoperiod unless specifically indicated otherwise.
LncRNA and mRNA data analysis
The in-house Perl script was used to process the original reads in fastq format. Clean reads were obtained by removing the reads with adapters and poly-N, and low-quality reads. Q20 (base ratio > 20), q30 (base ratio > 30) and GC content of the obtained clean data were calculated. The high-quality clean data were used for all the subsequent analysis60. The Arabidopsis reference genome and gene model annotation files were downloaded from ftp://ftp.ensembl.org/pub/release-80. We built an index of the reference genome using Bowtie v2.0.680 and aligned paired-end clean reads to the reference genome using TopHat v2.0.981. The mapped reads of each sample were assembled by Stringtie61.
MiRNA data analysis
Fastx_uutoolkit-0.0.13.2 was used to pre-process the original data by removing low-quality reads, 5′ joint contaminated reads, 3′ spliced reads, and reads with length less than 18 nt or with poly-A. The clean reads were then compared with known ncRNAs by using blast (v2.2.26) in RFAM database (v10.1). Clean reads matching any sequence in the RFAM database was deleted. Then, the proportion of four bases (A/T/G/C) in the clean reads at each location was calculated. The Arabidopsis miRNA sequences were downloaded from miRBase (http://www.mirbase.org/), and used to search for the clean reads consistent with the Arabidopsis reference genome60.
Identification of the differentially expressed lncRNAs, mRNAs and miRNAs
We used CuffDiff (V2.1.1) to calculate the values of lncRNAs and coding mRNAs for FPKM (the number of fragments per kilo-base of exon per million mapped fragments), and TPM (transcripts per million) fractions of miRNAs. The differential expressions of miRNAs were analyzed by EdgeR. We analyzed differential expressions of lncRNAs, mRNAs and miRNAs by comparing blue light treatment with dark condition. In any pairwise comparisons, the expressions of lncRNAs and mRNAs with corrected p-values < 0.05 and absolute fold-change values>2.0, or miRNAs with p-values < 0.05, absolute fold-change values>2.0, and miRDeep2 score ≥1, were considered to be differentially expressed60.
Real-time quantitative PCR
The first strand of cDNA is synthesized from total RNA (1 μg) and M-MLV reverse transcriptase (Promega) using random primers and serves as a template for subsequent PCR amplification. Pri-miRNA levels were detected by qRT-PCRs using Bio-Rad CFX Real-Time System. Actin gene was used as the internal control for normalization of DNA templates. Each PCR was repeated at least three times. Data were analyzed by Bio-Rad iCycler iQ Real-Time Detection system. The transcript level was calculated by the relative 2–ΔΔCt method62. The primers used for qRT-PCRs are listed in Table S2 supplemental information.
Small RNA deep sequencing
Small RNAs were isolated from 4-day-old plant seedlings by using the mirVana miRNA Isolation Kit (Ambion, AM1561) and sequenced by high-throughput sequencing of Illumina HiSeq. 2000. Sequencing data of all known miRNAs were hierarchical clustered in an unsupervised manner to analyze the degree of differential expression of small RNA63.
LncRNA and mRNA deep sequencing
LncRNAs and mRNAs were isolated from 4-day-old plant seedlings. Ribosomal RNAs (rRNAs) were removed using TruSeq Stranded Total RNA with Ribo-Zero Plant kit (Illumina, 20020610) and the rRNA-free residue was obtained by ethanol precipitation. The first-strand cDNA was synthesized using a random Hexamer-primer and reverse transcriptase (Invitrogen). The second strand cDNA was synthesized using RNase H (Invitrogen) and DNA polymerase I (New England BioLabs). Subsequently, the sequencing libraries were generated using the rRNA-free RNA with a NEBNext Ultra Directional RNA Library Prep Kit for Illumina (New England Biolabs, MA, USA), and sequenced by high-throughput sequencing of Illumina Hiseq Xten pair-end 150 (PE150).
Hypocotyl growth analysis
The seedlings were treated with light as described64 with some modifications. The seedlings of each line were cultured in the same 100 mm Petri dish for each repeat. The seeds were soaked in 70% ethanol for 5 minutes, and then in 95% ethanol for 5 minutes. Seeds were vernalizated for 3 days in darkness at 4 °C. The culture dishes were placed in white light for 3 hours to induce germination and in the growth chamber at 21 °C for 21 hours. The dishes were then transferred to experimental light conditions. The seedlings were transplanted into blue light (0.1, 0.5, 1 and 10 µmol s−1m−2) in a growth chamber (Percival Scientific Inc., Perry, Iowa, USA) for 4 days at 21 °C, respectively. Dark control seedlings were kept in darkness. The hypocotyl lengths of at least 30 seedlings were measured after blue light or dark treatments.
Mannitol stress treatments
Five days after germination on normal MS medium, the wild type and blil1-1, blil1-2, arf6/8 and miR167 mutant seedlings were transferred to MS medium plates with or without 200 mM mannitol, and the plates were stood-up. The phenotypes of seedlings were visualized 7 days after transferring.
Small RNA gel blot
Small RNA gel blot was performed as previously described24. Small RNAs were isolated from 4-day-old plant seedlings by using mirVana miRNA Isolation Kit (Ambion, AM1561). Small RNAs of about three micrograms were fractionated on a 15% polyacrylamide gel containing 8 M urea and then transferred to a nylon transfer membrane (GE Healthcare). Antisense oligonucleotides (Table S2 Supplemental information) were synthesized and biotin probes were labeled at 3′ end. Hybridization was carried out overnight in Ambion (AM8663) at 42 °C. A probe complementary to U6 (5′CATCCTTGCGCAGGGGCCA 3′) was used as a loading control.
Data availability
All necessary data generated or analyzed during the present study are included in this published article, its Supplementary Information files and NCBI (the National Center for Biotechnology Information) with the number PRJNA596364.
Change history
07 July 2020
An amendment to this paper has been published and can be accessed via a link at the top of the paper.
References
Huarte, M. & Rinn, J. L. Large Non-Coding Rnas: Missing Links in Cancer? Hum. Mol. Genet. 19, R152–R161 (2010).
Guttman, M. & Rinn, J. L. Modular Regulatory Principles of Large Non-Coding Rnas. Nature. 482, 339–346 (2012).
Rinn, J. L. & Chang, H. Y. Genome Regulation by Long Noncoding Rnas. Annu. Rev. Biochem. 81, 145–166 (2012).
Kim, E. D. & Sung, S. Long Noncoding Rna: Unveiling Hidden Layer of Gene Regulatory Networks. Trends Plant. Sci. 17, 16–21 (2012).
Shafiq, S., Li, J. & Sun, Q. Functions of Plants Long Non-Coding Rnas. Biochim. Biophys. Acta. 1859, 155–162 (2016).
Franco-Zorrilla, J. M. et al. Target Mimicry Provides a New Mechanism for Regulation of Microrna Activity. Nat. Genet. 39, 1033–1037 (2007).
Liu, F., Marquardt, S., Lister, C., Swiezewski, S. & Dean, C. Targeted 3′ Processing of Antisense Transcripts Triggers Arabidopsis Flc Chromatin Silencing. Science. 327, 94–97 (2010).
Heo, J. B. & Sung, S. Vernalization-Mediated Epigenetic Silencing by a Long Intronic Noncoding Rna. Science. 331, 76–79 (2011).
Ben, A. B. et al. Novel Long Non-Protein Coding Rnas Involved in Arabidopsis Differentiation and Stress Responses. Genome Res. 19, 57–69 (2009).
Ding, J. et al. A Long Noncoding Rna Regulates Photoperiod-Sensitive Male Sterility, an Essential Component of Hybrid Rice. Proc. Natl Acad. Sci. USA 109, 2654–2659 (2012).
Wang, Y. et al. Arabidopsis Noncoding Rna Mediates Control of Photomorphogenesis by Red Light. Proc. Natl Acad. Sci. USA 111, 10359–10364 (2014).
Seo, J. S. et al. Elf18-Induced Long-Noncoding Rna Associates with Mediator to Enhance Expression of Innate Immune Response Genes in Arabidopsis. Plant. Cell. 29, 1024–1038 (2017).
Shin, H., Shin, H. S., Chen, R. & Harrison, M. J. Loss of at4 Function Impacts Phosphate Distribution Between the Roots and the Shoots During Phosphate Starvation. Plant. J. 45, 712–726 (2006).
Franco-Zorrilla, J. M. et al. Target Mimicry Provides a New Mechanism for Regulation of Microrna Activity. Nat. Genet. 39, 1033–1037 (2007).
Kumar, M. M. & Goyal, R. Lncrna as a Therapeutic Target for Angiogenesis. Curr. Top. Med. Chem. 17, 1750–1757 (2017).
Nigro, J. M. et al. Scrambled Exons. Cell. 64, 607–613 (1991).
Wierzbicki, A. T. The Role of Long Non-Coding Rna in Transcriptional Gene Silencing. Curr. Opin. Plant. Biol. 15, 517–522 (2012).
Mancinelli, A. L. Interaction Between Light Quality and Light Quantity in the Photoregulation of Anthocyanin Production. Plant. Physiol. 92, 1191–1195 (1990).
Kircher, S. et al. Light Quality-Dependent Nuclear Import of the Plant Photoreceptors Phytochrome a and B. Plant. Cell. 11, 1445–1456 (1999).
Kircher, S. et al. Nucleocytoplasmic Partitioning of the Plant Photoreceptors Phytochrome a, B, C, D, and E is Regulated Differentially by Light and Exhibits a Diurnal Rhythm. Plant. Cell. 14, 1541–1555 (2002).
Yu, X., Liu, H., Klejnot, J. & Lin, C. The Cryptochrome Blue Light Receptors. Arabidopsis Book. 8, e135 (2010).
Van Buskirk, E. K., Decker, P. V. & Chen, M. Photobodies in Light Signaling. Plant. Physiol. 158, 52–60 (2012).
Imaizumi, T., Schultz, T. F., Harmon, F. G., Ho, L. A. & Kay, S. A. Fkf1 F-Box Protein Mediates Cyclic Degradation of a Repressor of Constans in Arabidopsis. Science. 309, 293–297 (2005).
Sun, Z., Guo, T., Liu, Y., Liu, Q. & Fang, Y. The Roles of Arabidopsis Cdf2 in Transcriptional and Posttranscriptional Regulation of Primary Micrornas. PLoS Genet. 11, e1005598 (2015).
Pedmale, U. V. et al. Cryptochromes Interact Directly with Pifs to Control Plant Growth in Limiting Blue Light. Cell. 164, 233–245 (2016).
Khanna, R. et al. A Novel Molecular Recognition Motif Necessary for Targeting Photoactivated Phytochrome Signaling to Specific Basic Helix-Loop-Helix Transcription Factors. Plant. Cell. 16, 3033–3044 (2004).
Sun, Z. et al. Coordinated Regulation of Arabidopsis Microrna Biogenesis and Red Light Signaling through Dicer-Like 1 and Phytochrome-Interacting Factor 4. PLoS Genet. 14, e1007247 (2018).
Kim, D., Langmead, B. & Salzberg, S. L. Hisat: A Fast Spliced Aligner with Low Memory Requirements. Nat. Methods. 12, 357–360 (2015).
Pollier, J., Rombauts, S. & Goossens, A. Analysis of Rna-Seq Data with Tophat and Cufflinks for Genome-Wide Expression Analysis of Jasmonate-Treated Plants and Plant Cultures. Methods Mol. Biol. 1011, 305–315 (2013).
Kong, L. et al. Cpc: Assess the Protein-Coding Potential of Transcripts Using Sequence Features and Support Vector Machine. Nucleic Acids Res. 35, W345–W349 (2007).
Sun, K. et al. Iseerna: Identification of Long Intergenic Non-Coding Rna Transcripts From Transcriptome Sequencing Data. Bmc Genomics. 14(Suppl 2), S7 (2013).
Bu, D. et al. Noncode V3.0: Integrative Annotation of Long Noncoding Rnas. Nucleic Acids Res. 40, D210–D215 (2012).
Guil, S. & Esteller, M. Rna-Rna Interactions in Gene Regulation: The Coding and Noncoding Players. Trends Biochem. Sci. 40, 248–256 (2015).
Denzler, R., Agarwal, V., Stefano, J., Bartel, D. P. & Stoffel, M. Assessing the Cerna Hypothesis with Quantitative Measurements of Mirna and Target Abundance. Mol. Cell. 54, 766–776 (2014).
Salmena, L., Poliseno, L., Tay, Y., Kats, L. & Pandolfi, P. P. A Cerna Hypothesis: The Rosetta Stone of a Hidden Rna Language? Cell. 146, 353–358 (2011).
Franco-Zorrilla, J. M. et al. Target Mimicry Provides a New Mechanism for Regulation of Microrna Activity. Nat. Genet. 39, 1033–1037 (2007).
Yang, J. H. et al. Starbase: A Database for Exploring Microrna-Mrna Interaction Maps From Argonaute Clip-Seq and Degradome-Seq Data. Nucleic Acids Res. 39, D202–D209 (2011).
Li, J. H., Liu, S., Zhou, H., Qu, L. H. & Yang, J. H. Starbase V2.0: Decoding Mirna-Cerna, Mirna-Ncrna and Protein-Rna Interaction Networks From Large-Scale Clip-Seq Data. Nucleic Acids Res. 42, D92–D97 (2014).
Sumazin, P. et al. An Extensive Microrna-Mediated Network of Rna-Rna Interactions Regulates Established Oncogenic Pathways in Glioblastoma. Cell. 147, 370–381 (2011).
Liu, N. et al. Down-Regulation of Auxin Response Factors 6 and 8 by Microrna 167 Leads to Floral Development Defects and Female Sterility in Tomato. J. Exp. Bot. 65, 2507–2520 (2014).
Jodder, J., Das, R., Sarkar, D., Bhattacharjee, P. & Kundu, P. Distinct Transcriptional and Processing Regulations Control Mir167a Level in Tomato During Stress. Rna Biol. 15, 130–143 (2018).
Hoang, N., Bouly, J. P. & Ahmad, M. Evidence of a Light-Sensing Role for Folate in Arabidopsis Cryptochrome Blue-Light Receptors. Mol. Plant. 1, 68–74 (2008).
Yu, X., Liu, H., Klejnot, J. & Lin, C. The Cryptochrome Blue Light Receptors. Arabidopsis Book. 8, e135 (2010).
Gyula, P., Schafer, E. & Nagy, F. Light Perception and Signalling in Higher Plants. Curr. Opin. Plant. Biol. 6, 446–452 (2003).
Jiao, Y. et al. A Genome-Wide Analysis of Blue-Light Regulation of Arabidopsis Transcription Factor Gene Expression During Seedling Development. Plant. Physiol. 133, 1480–1493 (2003).
Wang, H. et al. Genome-Wide Identification of Long Noncoding Natural Antisense Transcripts and their Responses to Light in Arabidopsis. Genome Res. 24, 444–453 (2014).
Wang, Q. et al. Photoactivation and Inactivation of Arabidopsis Cryptochrome 2. Science. 354, 343–347 (2016).
He, S. B. et al. The Cnt1 Domain of Arabidopsis Cry1 Alone is Sufficient to Mediate Blue Light Inhibition of Hypocotyl Elongation. Mol. Plant. 8, 822–825 (2015).
Wu, H. J., Wang, Z. M., Wang, M. & Wang, X. J. Widespread Long Noncoding Rnas as Endogenous Target Mimics for Micrornas in Plants. Plant. Physiol. 161, 1875–1884 (2013).
Li, M. et al. Long Non-Coding Rna Adncr Suppresses Adipogenic Differentiation by Targeting Mir-204. Biochim. Biophys. Acta. 1859, 871–882 (2016).
Liang, R. et al. Using Rna Sequencing to Identify Putative Competing Endogenous Rnas (Cernas) Potentially Regulating Fat Metabolism in Bovine Liver. Sci. Rep. 7, 6396 (2017).
Marchese, F. P., Raimondi, I. & Huarte, M. The Multidimensional Mechanisms of Long Noncoding Rna Function. Genome Biol. 18, 206 (2017).
Fatica, A. & Bozzoni, I. Long Non-Coding Rnas: New Players in Cell Differentiation and Development. Nat. Rev. Genet. 15, 7–21 (2014).
Marquardt, S. et al. Functional Consequences of Splicing of the Antisense Transcript Coolair On Flc Transcription. Mol. Cell. 54, 156–165 (2014).
Deforges, J. et al. Control of Cognate Sense Mrna Translation by Cis-Natural Antisense Rnas. Plant. Physiol. 180, 305–322 (2019).
Wang, Y. et al. Arabidopsis Noncoding Rna Mediates Control of Photomorphogenesis by Red Light. Proc. Natl Acad. Sci. USA 111, 10359–10364 (2014).
Martianov, I., Ramadass, A., Serra, B. A., Chow, N. & Akoulitchev, A. Repression of the Human Dihydrofolate Reductase Gene by a Non-Coding Interfering Transcript. Nature. 445, 666–670 (2007).
Shamovsky, I., Ivannikov, M., Kandel, E. S., Gershon, D. & Nudler, E. Rna-Mediated Response to Heat Shock in Mammalian Cells. Nature. 440, 556–560 (2006).
Willingham, A. T. et al. A Strategy for Probing the Function of Noncoding Rnas Finds a Repressor of Nfat. Science. 309, 1570–1573 (2005).
Liang, R. et al. Using Rna Sequencing to Identify Putative Competing Endogenous Rnas (Cernas) Potentially Regulating Fat Metabolism in Bovine Liver. Sci. Rep.-Uk. 7, (2017).
Pertea, M. et al. Stringtie Enables Improved Reconstruction of a Transcriptome From Rna-Seq Reads. Nat. Biotechnol. 33, 290–295 (2015).
Livak, K. J. & Schmittgen, T. D. Analysis of Relative Gene Expression Data Using Real-Time Quantitative Pcr and the 2(-Delta Delta C(T)) Method. Methods. 25, 402–408 (2001).
Eisen, M. B., Spellman, P. T., Brown, P. O. & Botstein, D. Cluster Analysis and Display of Genome-Wide Expression Patterns. Proc. Natl Acad. Sci. USA 95, 14863–14868 (1998).
Monte, E. et al. Isolation and Characterization of Phyc Mutants in Arabidopsis Reveals Complex Crosstalk Between Phytochrome Signaling Pathways. Plant. Cell. 15, 1962–1980 (2003).
Acknowledgements
This work was supported by National Science Foundation of China (31971334 and 31871230).
Author information
Authors and Affiliations
Contributions
Z.S., Z.H., K.H., and Y.F. designed the experiments. Z.S. performed most of experiments, Z.S., Z.H. and K.H. analyzed data, PW assisted in experiments. Z.S. and Y.F. wrote the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Sun, Z., Huang, K., Han, Z. et al. Genome-wide identification of Arabidopsis long noncoding RNAs in response to the blue light. Sci Rep 10, 6229 (2020). https://doi.org/10.1038/s41598-020-63187-1
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-020-63187-1
- Springer Nature Limited
This article is cited by
-
lncRNAs involved in the Shade Avoidance Syndrome (SAS) in Arabidopsis thaliana
BMC Genomics (2024)
-
Emphasizing the role of wheat circular RNA in defense response against stripe rust disease
Journal of Plant Biochemistry and Biotechnology (2024)
-
Genomic survey of high-throughput RNA-Seq data implicates involvement of long intergenic non-coding RNAs (lincRNAs) in cytoplasmic male-sterility and fertility restoration in pigeon pea
Genes & Genomics (2023)
-
Integrated analysis of the lncRNA/circRNA-miRNA-mRNA expression profiles reveals novel insights into potential mechanisms in response to root-knot nematodes in peanut
BMC Genomics (2022)
-
Transcriptome-guided annotation and functional classification of long non-coding RNAs in Arabidopsis thaliana
Scientific Reports (2022)