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Small RNA, big defence: Early epigenetic responses to genetic invasion

Published online by Cambridge University Press:  27 October 2025

Seunghui Mun ,
Yang Jae Kang  and
Jungnam Cho Open the ORCID record for Jungnam Cho [Opens in a new window]
Seunghui Mun
Affiliation:
Durham University , UK
Yang Jae Kang
Affiliation:
Gyeongsang National University , Republic of Korea
Jungnam Cho*
Affiliation:
Durham University , UK
*
Corresponding author: Jungnam Cho; Email: jungnam.cho@durham.ac.uk

Abstract

Plants are under constant genetic siege. From viruses and bacteria to transposable elements within their genomes, cells must contend with foreign genetic material. Besides these natural threats, modern biotechnology adds complexity by introducing transgenes to plants. While the integration of such DNA can enhance genetic diversity and confer desirable traits, its foreign origin is typically recognised by the plant cell as a signal of invasion and therefore targeted by the repressive mechanisms. Epigenetic silencing is a central strategy and involves the methylation of DNA and histones. A critical trigger of this silencing is the generation of small interfering RNAs (siRNAs). Although the role of siRNAs in maintaining epigenetic silencing is well established, the initial steps that lead to their production remain incompletely understood. This review discusses the key discoveries on how plant cells recognise foreign nucleic acids and initiate epigenetic silencing, contributing to our broader understanding of genome integrity and defence.

Keywords

epigenetic silencingNo-go RNA decayRNA-directed DNA methylationRNA quality controlsmall RNA

Information

Type
Review
Information
Quantitative Plant Biology , Volume 6 , 2025 , e34
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2025. Published by Cambridge University Press in association with John Innes Centre

1. Introduction

Epigenetic silencing in plants has been primarily studied in repetitive sequences and transposable elements (TEs). RNA-directed DNA methylation (RdDM) is a key epigenetic regulatory mechanism in plants that reinforces and maintains the epigenetic silencing (Gallego-Bartolomé et al., Reference Gallego-Bartolomé, Liu, Kuo, Feng, Ghoshal, Gardiner, Zhao, Park, Chory and Jacobsen2019; Matzke et al., Reference Matzke, Kanno and Matzke2015; Matzke & Mosher, Reference Matzke and Mosher2014; Xie et al., Reference Xie, Du, Hu and Du2024). The RdDM pathway is initiated by RNA Polymerase IV (Pol IV), which generates single-stranded RNAs that are converted into double-stranded RNAs by RNA-DEPENDENT RNA POLYMERASE 2 (RDR2). These are then processed into 24-nucleotide (nt) small interfering RNAs (siRNAs) by DICER-LIKE 3 (DCL3) and loaded onto ARGONAUTE 4 (AGO4). In conjunction with transcripts produced by RNA polymerase V (Pol V), 24-nt siRNAs guide the methylation machinery to specific genomic locations. The de novo DNA methyltransferase DOMAINS REARRANGED METHYLTRANSFERASE 2 (DRM2) is then recruited to catalyse methylation at cytosines in all sequence contexts (CG, CHG and CHH; H refers to A, T or C).

RdDM must accurately distinguish its genomic targets from essential genes to avoid silencing those critical for plant survival, and this discrimination is mediated by specialised proteins that read epigenetic marks written in the chromatins. For example, Pol IV recruitment to target DNA is coordinated by CLASSY1–4 (CLSY1–4) chromatin remodelers and the SAWADEE HOMEODOMAIN HOMOLOG 1 (SHH1) protein, a histone methylation reader. CLASSY proteins act in a tissue- and locus-specific manner to remodel chromatin and facilitate Pol IV access (Zhou et al., Reference Zhou, Palanca and Law2018), while SHH1 specifically recognises histone H3 lysine 9 dimethylation (H3K9me2) marks, enriched in repetitive sequences and TEs, and helps stabilise Pol IV binding at these chromatin sites (Law et al., Reference Law, Vashisht, Wohlschlegel and Jacobsen2011, Reference Law, Du, Hale, Feng, Krajewski, Palanca, Strahl, Patel and Jacobsen2013). In parallel, SU(VAR)3-9 HOMOLOG 2 (SUVH2) and SUVH9, which contain SRA domains that specifically bind methylated DNA, contribute to targeting of Pol V to pre-methylated regions (Johnson et al., Reference Johnson, Law, Khattar, Henderson and Jacobsen2008, Reference Johnson, Du, Hale, Bischof, Feng, Chodavarapu, Zhong, Marson, Pellegrini, Segal, Patel and Jacobsen2014; Liu et al., Reference Liu, Shao, Zhang, Zhou, Zhang, Li, Chen, Huang, Cai and He2014). This preferential recruitment of Pol IV and Pol V to already methylated DNA and histones highlights the RdDM pathway’s primary role in sustaining and reinforcing pre-established silencing marks.

Pol IV-mediated or canonical RdDM is largely limited to heterochromatic regions, and is less effective at targeting DNAs that are unmarked by repressive epigenetic modifications. However, an alternative RdDM pathway, often referred to as RDR6-dependent RdDM, expands the silencing potential to new TEs or exogenous sequences, such as transgenes and viral RNAs (Cuerda-Gil & Slotkin, Reference Cuerda-Gil and Slotkin2016; Fultz et al., Reference Fultz, Choudury and Slotkin2015; Hung & Slotkin, Reference Hung and Slotkin2021). This pathway is initiated when RDR6 converts the Pol II-transcribed and invasive RNAs into double-stranded RNAs, which are then processed by DCL2 and DCL4 into 21/22-nt siRNAs. These siRNAs are loaded onto AGO1, AGO2 or AGO6, which can trigger de novo DNA methylation at homologous genomic loci (Creasey et al., Reference Creasey, Zhai, Borges, Van Ex, Regulski, Meyers and Martienssen2014; Garcia et al., Reference Garcia, Garcia, Pontier, Marchais, Renou, Lagrange and Voinnet2012; McCue et al., Reference McCue, Panda, Nuthikattu, Choudury, Thomas and Slotkin2015; Panda et al., Reference Panda, Ji, Neumann, Daron, Schmitz and Slotkin2016; Pontier et al., Reference Pontier, Picart, Roudier, Garcia, Lahmy, Azevedo, Alart, Laudié, Karlowski, Cooke, Colot, Voinnet and Lagrange2012). While less well-characterised than canonical RdDM, this RDR6-dependent pathway represents a flexible and adaptive silencing system capable of initiating epigenetic silencing at novel targets, even in the absence of pre-existing methylation or heterochrom atic marks (Figure 1).

Figure 1. RDR6-dependent RNA-directed DNA methylation pathway. Host cells recognise nonself RNAs by distinctive features such as reduced translational efficiency and ribosome stalling caused by various factors. These RNAs are subsequently directed to siRNA bodies through mechanisms that remain unclear. The assembly of siRNA bodies relies on SGS3-driven phase separation, which recruits RDR6 to these sites. The resulting siRNAs then trigger RNA interference (RNAi) and initiate de novo DNA methylation. In diagrams, closed circles attached to DNA represent methylation, while ribosomes are shown in blue aligned along RNAs.

Since alternative RdDM initiates at the RNA stage, it cannot rely on the epigenetic cues that guide canonical RdDM; instead, its target specificity depends on sequence or structural signatures encoded within the RNA itself. For example, it has been well documented that RDR6 preferentially targets incomplete, truncated or aberrant RNAs (Baeg et al., Reference Baeg, Iwakawa and Tomari2017; Luo & Chen, Reference Luo and Chen2007). One major cause is cleavage by 22-nt miRNAs, which are particularly effective at initiating secondary siRNA production (Cuperus et al., Reference Cuperus, Carbonell, Fahlgren, Garcia-Ruiz, Burke, Takeda, Sullivan, Gilbert, Montgomery and Carrington2010; de Felippes et al., Reference de Felippes, Marchais, Sarazin, Oberlin and Voinnet2017; Iwakawa et al., Reference Iwakawa, Lam, Mine, Fujita, Kiyokawa, Yoshikawa, Takeda, Iwasaki and Tomari2021; Song et al., Reference Song, Li, Zhai, Zhou, Ma, Liu, Jeong, Nakano, Cao, Liu, Chu, Wang, Green, Meyers and Cao2012; Yoshikawa et al., Reference Yoshikawa, Iki, Tsutsui, Miyashita, Poethig, Habu and Ishikawa2013, Reference Yoshikawa, Han, Fujii, Aizawa, Nishino and Ishikawa2021). Moreover, the so-called two-hit model further suggests that the action of two small RNAs on the same transcript, one of these sites being uncleavable, enhances RDR6 activity, likely by increasing access for double-stranded RNA synthesis (Axtell et al., Reference Axtell, Jan, Rajagopalan and Bartel2006). In addition to cleavage-based triggers, RNAs with strong secondary structures, such as those derived from inverted repeats, or transcripts formed through overlapping sense and antisense transcription can produce double-stranded regions that mimic RDR6 substrates (Wroblewski et al., Reference Wroblewski, Matvienko, Piskurewicz, Xu, Martineau, Wong, Govindarajulu, Kozik and Michelmore2014; Zhang et al., Reference Zhang, Zhong, Smith, de Feyter, Greaves, Swain, Zhang and Wang2022). Importantly, all of these known pathways depend on pre-existing sequence complementarity, whether through miRNAs, siRNAs, or antisense RNAs, meaning that it serves to act as an adaptive process, rather than an innate mechanism, against foreign genetic elements. In the following section, recent findings around the innate immunity-like recognition of alien RNAs preceding the epigenetic silencing will be discussed.

2. Main

2.1. Translation-associated RNA cleavage

RNA cleavage is an essential prerequisite for the activity of RDR6, the key initiator of alternative RdDM, and complete and normal transcripts are immune to this process. For example, Creasey et al. suggested that miRNA-mediated RNA cleavage can trigger the production of TE-associated siRNAs, termed epigenetically activated siRNAs (easiRNAs), generated in the DNA methylation-deficient Arabidopsis mutants (Creasey et al., Reference Creasey, Zhai, Borges, Van Ex, Regulski, Meyers and Martienssen2014). Although several miRNA-independent pathways, such as mRNA splicing (Dalakouras et al., Reference Dalakouras, Lauter, Bassler, Krczal and Wassenegger2019; Kanno et al., Reference Kanno, Chiou, Wu, Lin, Matzke and Matzke2023; Oberlin et al., Reference Oberlin, Sarazin, Chevalier, Voinnet and Marí-Ordóñez2017), RNA processing (Dadami et al., Reference Dadami, Moser, Zwiebel, Krczal, Wassenegger and Dalakouras2013; Elvira-Matelot et al., Reference Elvira-Matelot, Bardou, Ariel, Jauvion, Bouteiller, Le Masson, Cao, Crespi and Vaucheret2016) and RNA surveillance pathways (Martínez de Alba et al., Reference Martínez de Alba, Moreno, Gabriel, Mallory, Christ, Bounon, Balzergue, Aubourg, Gautheret, Crespi, Vaucheret and Maizel2015; Moreno et al., Reference Moreno, de Alba, Bardou, Crespi, Vaucheret, Maizel and Mallory2013; Szádeczky-Kardoss et al., Reference Szádeczky-Kardoss, Csorba, Auber, Schamberger, Nyikó, Taller, Orbán, Burgyán and Silhavy2018), have been proposed to initiate the RNA cleavage required for alternative RdDM, these mechanisms appear to act only on specific transcripts and do not broadly explain the targeting specificity of alternative RdDM.

Previous studies have identified GC content as a key factor in ensuring robust transgene expression and preventing entry to the alternative RdDM pathway (Brule & Grayhack, Reference Brule and Grayhack2017; Parret et al., Reference Parret, Besir and Meijers2016; Sidorenko et al., Reference Sidorenko, Lee, Woosley, Moskal, Bevan, Merlo, Walsh, Wang, Weaver, Glancy, Wang, Yang, Sriram and Meyers2017). This finding is further supported by evidence that TEs tend to use codons that are suboptimal for the host translational machinery, resulting in weaker translational activities compared to endogenous genes (Kim et al., Reference Kim, Wang, Lei, Li, Fan and Cho2021). A similar reduction of translational activity was observed in the transcripts of a retrotransposon, known as EVADE (Oberlin et al., Reference Oberlin, Rajeswaran, Trasser, Barragán-Borrero, Schon, Plotnikova, Loncsek, Nodine, Marí-Ordóñez and Voinnet2022). Kim et al. also reported significant differences in GC3 content (GC content at the 3rd nucleotide position of a codon) between genes and TEs across diverse eukaryotic organisms, suggesting that codon usage and the resulting translational efficiency may serve as a universal mechanism for host genomes to discriminate self from non-self RNAs (Kim et al., Reference Kim, Wang, Lei, Li, Fan and Cho2021). Given that viruses, as being foreign to their hosts, typically exhibit codon usage patterns distinct from that of host (Belalov & Lukashev, Reference Belalov and Lukashev2013; Gaunt & Digard, Reference Gaunt and Digard2022; Jitobaom et al., Reference Jitobaom, Phakaratsakul, Sirihongthong, Chotewutmontri, Suriyaphol, Suptawiwat and Auewarakul2020; Plant & Ye, Reference Plant and Ye2022), it is plausible that translational activity, determined by codon composition, contributes broadly to recognition and silencing of foreign genetic elements.

Translational inefficiency not only reduces protein output but also can trigger RNA quality control mechanisms that result in RNA cleavage, a critical prerequisite essential for RDR6 activity in alternative RdDM. One such mechanism is the no-go RNA decay (NGD) pathway, which targets transcripts where ribosomes stall during translation (Inada & Beckmann, Reference Inada and Beckmann2024; X. Li et al., Reference Li, Zhou and Li2025; Monaghan et al., Reference Monaghan, Longman and Cáceres2023; Müller et al., Reference Müller, Becker, Denk, Hashimoto, Inada and Beckmann2025). These stalls can be caused by strong secondary structures, rare codons, disome formation (ribosome collisions) or other features that impede ribosome progression. In response, the NGD machinery induces endonucleolytic cleavage near the stall site, generating RNA fragments that can potentially serve as substrates for RDR6. Consistent with this notion, Oberlin et al. was able to detect cleaved RNA ends at where ribosome is stalled in EVADE RNA (Oberlin et al., Reference Oberlin, Rajeswaran, Trasser, Barragán-Borrero, Schon, Plotnikova, Loncsek, Nodine, Marí-Ordóñez and Voinnet2022), and Kim et al. found signals for frequent RNA cleavage and stacked ribosomes enriched in TEs of Arabidopsis (Kim et al., Reference Kim, Wang, Lei, Li, Fan and Cho2021). This positions NGD as a potential contributor to the initiation of siRNA production and silencing via alternative RdDM.

Emerging evidence suggests that NGD operates in plants, particularly in controlling non-native RNAs like that of viruses. For example, recent studies have shown that NGD factors, such as PELOTA1 and HBS1, play a direct role in suppressing viral infection in plants (Ge et al., Reference Ge, Cao, Qiao, Cui, Li, Shan, Gong, Zhang, Li, Wang, Zhou and Li2023; Pouclet et al., Reference Pouclet, Gagliardi and Garcia2023). In Arabidopsis, these proteins recognise conserved A-rich motifs (G1 – 2 A6 – 7) in potyvirus genomes and trigger endonucleolytic cleavage of viral RNAs, limiting their accumulation. This mirrors the observation that TEs are typically AT-rich, a feature associated with suboptimal translational efficiency (Boissinot, Reference Boissinot2022; Kim et al., Reference Kim, Wang, Lei, Li, Fan and Cho2021). Moreover, a recent study suggests that aberrant RNAs arise from ribosome stalling prior to the full establishment of transgene silencing (Kramer et al., Reference Kramer, Ratnayake, Edwards, Lowrey, Klaas, Sidorenko, Rowan, Michelmore, Meyers and Slotkin2025). These findings together highlight NGD as a targeted antiviral mechanism, linking translational surveillance to gene silencing and reinforcing the idea that inefficient translation may mark transcripts as non-self or aberrant.

The siRNA pathway in plants offers a strategic advantage over simple RNA degradation by acting more like an adaptive immune system. It enables sequence-specific recognition of foreign or aberrant RNAs and converts these into heritable silencing signals through RdDM. Unlike transient RNA decay, siRNA-mediated silencing can be amplified, systemic and long-lasting, ensuring robust and persistent defence. While there is rich, albeit circumstantial, evidence suggesting that NGD may act as a trigger for the initial RNA cleavage required to initiate the alternative RdDM pathway, direct empirical evidence linking NGD to siRNA biogenesis remains to be established. Once siRNAs are produced and DNA methylation is established at target loci, the canonical RdDM machinery can further strengthen and maintain the silenced state.

2.2. Localisation to siRNA bodies

RDR6 has been shown to localise to stress granules (SGs), cytoplasmic compartments formed particularly under environmental stress conditions (Kim et al., Reference Kim, Wang, Lei, Li, Fan and Cho2021; Kumakura et al., Reference Kumakura, Takeda, Fujioka, Motose, Takano and Watanabe2009; Moreno et al., Reference Moreno, de Alba, Bardou, Crespi, Vaucheret, Maizel and Mallory2013; Tan et al., Reference Tan, Luo, Yan, Liu, Aizezi, Cui, Tian, Ma and Guo2023; Wen et al., Reference Wen, Hu, Pi, Zhang, Duan, Li, Li, Zhao, Yang, Zhao, Liu, Su, Li and Zhang2024). SGs themselves are dynamic cytoplasmic structures that temporarily store and sort untranslated mRNAs during stress, helping cells modulate gene expression and maintain homeostasis (Ren et al., Reference Ren, Zhao and Zou2025; Zhao & Li, Reference Zhao and Li2025). In Arabidopsis, RDR6-containing SGs, also known as siRNA bodies, appear to form through liquid–liquid phase separation (LLPS) mediated by SGS3. Deletion of the LLPS domain in SGS3 disrupts its ability to localise to these granules, which in turn prevents the recruitment of RDR6 and impairs siRNA biogenesis (Kim et al., Reference Kim, Wang, Lei, Li, Fan and Cho2021; Tan et al., Reference Tan, Luo, Yan, Liu, Aizezi, Cui, Tian, Ma and Guo2023) (Figure 2).

Figure 2. RNA pathways initiating siRNA biogenesis. RNA cleavage is a critical prerequisite for entry into the siRNA pathway and can be initiated through multiple mechanisms. Ribosome stalling, often caused by suboptimal codons, can induce RNA cleavage and promote RNA localisation to siRNA bodies. m6A-modified RNAs are commonly linked to RNA destabilisation and stress granule localisation, yet the contribution of m6A-binding ECT (EVOLUTIONARILY CONSERVED C-TERMINAL DOMAIN) family proteins to this process remains unclear. Additional RNA modifications, including 5 NADylation and 3 uridylation, catalysed by DXO1 (DECAPPING AND EXORIBONUCLEASE PROTEIN 1) and TUTases (TERMINAL URIDYLYLTRANSFERASES), respectively, are closely associated with RNA degradation and siRNA biogenesis. Blue circle, m7G cap; black circle, m6A RNA methylation; yellow circle, NAD+ cap.

The formation of siRNA bodies adds an additional layer of specificity and selectivity in the system as not all transcripts are equally guided to these compartments. Studies have shown that RNAs with reduced translational activity are more strongly enriched in SGs (Helton et al., Reference Helton, Dodd and Moon2025; Khong et al., Reference Khong, Matheny, Jain, Mitchell, Wheeler and Parker2017; Khong & Parker, Reference Khong and Parker2018; Kim et al., Reference Kim, Wang, Lei, Li, Fan and Cho2021; Matheny et al., Reference Matheny, Rao and Parker2019, Reference Matheny, Van Treeck, Huynh and Parker2021). This selective enrichment of poorly translating RNAs in SGs appears to be evolutionarily conserved as it has been observed across diverse eukaryotes, including yeast, humans and plants. Although the precise biochemical mechanisms guiding ribosome-depleted RNAs to SGs remain unclear, these findings support the model that translational inefficiency is a key determinant in directing transcripts to the alternative RdDM pathway by funnelling them into cellular compartments where essential silencing components are localised.

In addition to reduced translation, N6-methyladenosine (m6A) RNA modification has been shown to promote the localisation of specific transcripts to SGs (Di Timoteo et al., Reference Di Timoteo, Giuliani, Setti, Biagi, Lisi, Santini, Grandioso, Mariani, Castagnetti, Perego, Zappone, Lattante, Sabatelli, Rotili, Vicidomini and Bozzoni2024; Fan et al., Reference Fan, Wang, Lei, Li, Chu, Yan, Wang, Wang, Yang and Cho2023; Li et al., Reference Li, Liu, Guo, Zhang, Chen, Liu, Cheng, Deng, Qiu, Zhang, Goh, Wang and Peng2024; Song et al., Reference Song, Chen, Wang, Cheng and Shyh-Chang2024; Wu et al., Reference Wu, Su, Zhang, Zhang, Wong, Ma, Shao, Hua, Shen and Yu2024). A recent study in Arabidopsis demonstrated that m6A-marked RNAs are preferentially enriched in these compartments, and this localisation depends on m6A reader proteins that facilitate LLPS (Fan et al., Reference Fan, Wang, Lei, Li, Chu, Yan, Wang, Wang, Yang and Cho2023; Wu et al., Reference Wu, Su, Zhang, Zhang, Wong, Ma, Shao, Hua, Shen and Yu2024). This suggests that m6A may serve as a licensing mark, guiding transcripts into the silencing pathway. While a direct role of m6A in promoting siRNA biogenesis remains to be confirmed, these observations support a model in which m6A facilitates the selective targeting of transcripts for silencing through compartmentalisation.

TE RNAs in plants are marked with high levels of m6A, reflecting a strategic layer of post-transcriptional regulation by the host. For example, in Arabidopsis, the retrotransposon Onsen is methylated by m6A upon heat activation, and this methylation restricts its activity by retaining its RNA in SGs (Fan et al., Reference Fan, Wang, Lei, Li, Chu, Yan, Wang, Wang, Yang and Cho2023). Similarly, TEs from other eukaryotes, such as LINE-1 elements in humans, are also modified by m6A (Barter & Cho, Reference Barter and Cho2025; Hwang et al., Reference Hwang, Jung, Mun, Lee, Park, Baek, Moon, Kim, Kim, Choi, Go, Tang, Choi, Choi, Cha, Park, Liang, Kim, Han and Ahn2021; Wei et al., Reference Wei, Yu, Yang, Liu, Gao, Huang, Dou, Liu, Zou, Cui, Zhang, Zhao, Liu, He, Sepich-Poore, Zhong, Liu, Li, Kou and He2022; Xiong et al., Reference Xiong, Wang, Lee, Li, Chen, Liao, Hasani, Nguyen, Zhu, Krakowiak, Lee, Han, Tsai, Liu and Li2021). Beyond TEs, many studies have identified m6A RNA methylation on viral RNAs as well (Y. Li et al., Reference Li, Chen and Sun2025; Manners et al., Reference Manners, Baquero-Perez and Whitehouse2019; Zhang et al., Reference Zhang, Peng and Wang2023), suggesting that this epitranscriptomic mark broadly functions to label non-native RNAs. However, because the same RNA modification also regulates endogenous mRNAs, m6A-mediated differentiation may rely on additional molecular signatures. For instance, transposon RNAs are often methylated at multiple sites throughout their sequence, whereas typical mRNAs usually exhibit a single methylation peak near stop codons (Fan et al., Reference Fan, Wang, Lei, Li, Chu, Yan, Wang, Wang, Yang and Cho2023). Such differences in the number and position of m6A marks may help distinguish non-native RNAs. Altogether, m6A might act as a host-encoded marker to selectively flag foreign RNAs, guiding them into silencing pathways and reinforcing genomic defence at the RNA level.

The localisation of RNAs to siRNA bodies represents a crucial selective step in siRNA production. This selective guidance relies on key features including reduced translational activity and m6A RNA methylation, which together help funnel target RNAs into the alternative RdDM pathway. Despite growing evidence supporting the importance of SG formation in RNA silencing, major knowledge gaps still remain. Notably, the precise molecular mechanisms by which m6A modifications and translational repression coordinate to drive RNA partitioning into SGs are still unclear. Additionally, whether similar principles apply universally across different organisms and RNA types warrant further investigation. Addressing these questions will be critical to fully understanding how cells maintain genomic stability through epitranscriptomic and translational control.

2.3. RNA decay versus RNA silencing

So far, we have examined the functional impacts of translational inactivation on the initiation of siRNA biogenesis, focusing on RNA cleavage and localisation to siRNA bodies, both of which confer RNA specificity to the silencing pathway. We also discussed NGD as a potential mediator of translation-associated cleavage of non-native RNAs. However, as a host RNA quality control mechanism, NGD primarily promotes RNA degradation rather than siRNA production (Deragon & Merret, Reference Deragon and Merret2025; Szádeczky-Kardoss et al., Reference Szádeczky-Kardoss, Gál, Auber, Taller and Silhavy2018; Wu et al., Reference Wu, Fu, Ren, Liu, Zhang and Ruan2023; You et al., Reference You, He, Hang, Zhang, Cao, Guo, Chen, Cui and Mo2019; Zhang et al., Reference Zhang, Zhu, Liu, Hong, Xu, Zhu, Shen, Wu, Ji, Wen, Zhang, Zhao, Wang, Lu and Guo2015). In this section, we review current knowledge on the interplay between RNA decay and RNA silencing in plants.

The relationship between RNA decay and siRNA biogenesis in plants is often antagonistic, with RNA decay acting as a primary RNA quality control mechanism that can override RNAi (Christie et al., Reference Christie, Brosnan, Rothnagel and Carroll2011; Kim, Reference Kim2023). Both pathways target aberrant or excessive RNAs in processing (P) bodies and siRNA bodies, respectively, but RNA decay typically acts first to prevent the activation of silencing responses. This prioritisation is crucial because RNA silencing, once triggered, can lead to the unintended silencing of functional endogenous genes. Thus, RNA decay serves to suppress inappropriate RNA silencing activity by rapidly degrading faulty RNAs before they can be recognised by the siRNA machinery. For instance, studies in Arabidopsis have shown that mutants deficient in DECAPPING 2 (DCP2) or EXORIBONUCLEASE 4 (XRN4), the P body components, accumulate aberrant RNAs that are subsequently processed into siRNAs, triggering gene silencing (Elvira-Matelot et al., Reference Elvira-Matelot, Bardou, Ariel, Jauvion, Bouteiller, Le Masson, Cao, Crespi and Vaucheret2016; Gregory et al., Reference Gregory, O’Malley, Lister, Urich, Tonti-Filippini, Chen, Millar and Ecker2008; Gy et al., Reference Gy, Gasciolli, Lauressergues, Morel, Gombert, Proux, Proux, Vaucheret and Mallory2007; Li & Wang, Reference Li and Wang2018; Martínez de Alba et al., Reference Martínez de Alba, Moreno, Gabriel, Mallory, Christ, Bounon, Balzergue, Aubourg, Gautheret, Crespi, Vaucheret and Maizel2015; Sorenson et al., Reference Sorenson, Deshotel, Johnson, Adler and Sieburth2018; Souret et al., Reference Souret, Kastenmayer and Green2004; Thran et al., Reference Thran, Link and Sonnewald2012). These findings illustrate how RNA decay pathways act to suppress RNA silencing under normal conditions, ensuring that RNA silencing remains a specialised response reserved for transgenes, viruses or highly abnormal transcripts, rather than ordinary endogenous mRNAs.

Although structurally complete and intact, RNAs modified at the 5 and 3 ends, such as nicotinamide adenine dinucleotide (NAD+) capping and 3 uridylation, can be directed into RNA stability or silencing pathways. At the 5 end, some RNAs bear non-canonical caps like NAD+ instead of the typical m7G cap. In Arabidopsis, NAD+-capped RNAs are recognised as aberrant and are preferentially targeted for degradation, limiting their potential to engage in RNA silencing (Carpentier et al., Reference Carpentier, Receveur, Cadoudal and Merret2025; Kwasnik et al., Reference Kwasnik, Wang, Krzyszton, Gozdek, Zakrzewska-Placzek, Stepniak, Poznanski, Tong and Kufel2019; Wang et al., Reference Wang, Li, Zhao, You, Le, Gong, Mo, Xia and Chen2019). Conversely, other studies suggest that NAD+-capped RNAs can be recruited to RDR6 and processed to siRNAs (Pan et al., Reference Pan, Li, Huang, Zhong, Wu, Wang, Zhang, Cai, Guo, Chen and Xia2020; Yu et al., Reference Yu, Willmann, Vandivier, Trefely, Kramer, Shapiro, Guo, Lyons, Snyder and Gregory2021). At the 3 end, uridylation, the addition of uridines by terminal uridylyl transferases (TUTases), can similarly mark RNAs for degradation or processing into small RNAs. In plants, uridylation of viral RNAs or transgene-derived transcripts promotes their degradation and enhances silencing (de Almeida et al., Reference de Almeida, Scheer, Gobert, Fileccia, Martinelli, Zuber and Gagliardi2018; Joly et al., Reference Joly, Garcia, Hily, Koechler, Demangeat, Garcia, Vigne, Lemaire, Zuber and Gagliardi2023; Scheer et al., Reference Scheer, de Almeida, Ferrier, Simonnot, Poirier, Pflieger, Sement, Koechler, Piermaria, Krawczyk, Mroczek, Chicher, Kuhn, Dziembowski, Hammann, Zuber and Gagliardi2021; Wang et al., Reference Wang, Kong, Wang, Wang, Zhong, Lao, Dong, Zhang, Huang, Mo, Yu and Ren2022). These modifications act as molecular tags that distinguish normal RNAs from those targeted for silencing, thereby ensuring precise regulation of gene expression and defence. However, the mechanisms by which specific RNA modifications are selected to channel RNAs into either degradation or silencing pathways remain incompletely understood, and further research is needed to elucidate the determinants governing these RNA fates.

3. Conclusion and future perspectives

Despite significant advances in our understanding of RNA silencing in plants, critical questions remain regarding the earliest steps of pathway initiation. One major gap concerns the molecular signals that guide the recruitment of RDR6 to aberrant RNAs. Although translation stalling and RNA quality control mechanisms have been implicated, the precise criteria by which transcripts are selected for RDR6-mediated dsRNA synthesis remain unclear. The RNA-binding protein SGS3, which interacts with RDR6 and contributes to siRNA processing, is a potential determinant of target selection, but its exact role in this context is not fully understood. Insights from yeast offer additional clues. In yeast, NGD has been shown to generate 3 cleavage fragments with 5 hydroxyl (5OH) ends, in contrast to the 5 phosphorylated ends typically produced by other endoribonucleases (Navickas et al., Reference Navickas, Chamois, Saint-Fort, Henri, Torchet and Benard2020). Notably, RNA degradation pathways that follow ribosome-associated RNA cleavage generally require 5 phosphate groups, and the tRNA ligase Trl1 can phosphorylate 5OH termini, thereby licensing them for decay. This raises the intriguing possibility that a similar mechanism might exist in plants to regulate the fate of NGD-generated fragments. Mapping 5OH-RNAs in plants and identifying host enzymes analogous to Trl1 would be a compelling direction for future research. Additionally, the localisation of NGD-related events within siRNA bodies further suggests a spatial link between RNA decay and RNA silencing, warranting deeper investigation into their potential coordination.

RNA silencing is highly responsive to environmental cues, including pathogen attack, drought, UV exposure and nitrogen deprivation (Kallemi et al., Reference Kallemi, Verret, Andronis, Ioannidis, Glampedakis, Kotzabasis and Kalantidis2024; Li et al., Reference Li, Ma, Yang, Zhao, Li and Wan2023; Lopez-Gomollon & Baulcombe, Reference Lopez-Gomollon and Baulcombe2022; Pothof et al., Reference Pothof, Verkaik, van IJcken, Wiemer, Ta, van der Horst, Jaspers, van Gent, Hoeijmakers and Persengiev2009; Westwood et al., Reference Westwood, McCann, Naish, Dixon, Murphy, Stancombe, Bennett, Powell, Webb and Carr2013; Wu et al., Reference Wu, Li, Iwakawa, Pan, Tang, Ling-Hu, Liu, Sheng, Feng, Zhang, Zhang, Tang, Xia, Zhai and Guo2020). However, the molecular basis by which such stimuli selectively initiate silencing remains unresolved. Future studies should apply time-resolved transcriptomics and small RNA-seq after environmental stimuli to identify early-responding genes and siRNA populations. Once initiated, RNA silencing can amplify itself via secondary siRNA production, yet the mechanisms that constrain or fine-tune this amplification are not well characterised. Experiments that titrate dsRNA or trigger RNA levels using synthetic constructs or inducible promoters could be used to establish these thresholds in vivo.

Understanding how plants detect and epigenetically silence foreign genetic elements is crucial for unravelling the complexities of genome defence and stability. While much progress has been made in identifying the role of siRNAs in maintaining silencing, the early events that initiate this response are only beginning to be elucidated. Continued investigation into these upstream processes will not only deepen our fundamental knowledge of plant immunity but also inform the development of more stable and predictable transgenic technologies in agriculture and biotechnology.

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Competing interest

The authors declare none.

Author contributions

SM drafted the manuscript, and YJK and JC edited and revised the manuscript.

Funding statement

This work was supported by the National Research Foundation of Korea (RS-2024-00336161 to YJK) and UKRI-BBSRC (UKRI1915 to JC).

Footnotes

S.M. and Y.J.K. authors contributed equally.

Associate Editor: Dr. Yuan Wang

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Figure 0

Figure 1. RDR6-dependent RNA-directed DNA methylation pathway. Host cells recognise nonself RNAs by distinctive features such as reduced translational efficiency and ribosome stalling caused by various factors. These RNAs are subsequently directed to siRNA bodies through mechanisms that remain unclear. The assembly of siRNA bodies relies on SGS3-driven phase separation, which recruits RDR6 to these sites. The resulting siRNAs then trigger RNA interference (RNAi) and initiate de novo DNA methylation. In diagrams, closed circles attached to DNA represent methylation, while ribosomes are shown in blue aligned along RNAs.

Figure 1

Figure 2. RNA pathways initiating siRNA biogenesis. RNA cleavage is a critical prerequisite for entry into the siRNA pathway and can be initiated through multiple mechanisms. Ribosome stalling, often caused by suboptimal codons, can induce RNA cleavage and promote RNA localisation to siRNA bodies. m6A-modified RNAs are commonly linked to RNA destabilisation and stress granule localisation, yet the contribution of m6A-binding ECT (EVOLUTIONARILY CONSERVED C-TERMINAL DOMAIN) family proteins to this process remains unclear. Additional RNA modifications, including 5 NADylation and 3 uridylation, catalysed by DXO1 (DECAPPING AND EXORIBONUCLEASE PROTEIN 1) and TUTases (TERMINAL URIDYLYLTRANSFERASES), respectively, are closely associated with RNA degradation and siRNA biogenesis. Blue circle, m7G cap; black circle, m6A RNA methylation; yellow circle, NAD+ cap.

Author comment: Small RNA, big defence: Early epigenetic responses to genetic invasion — R0/PR1

Published online by Cambridge University Press:  27 October 2025
DOI: https://doi.org/10.1017/qpb.2025.10029.pr1 [Opens in a new window]
Jungnam Cho [Opens in a new window] Durham University, United Kingdom of Great Britain and Northern Ireland
Revision round: 0
Role: author

Comments

August 8th, 2025

Dear editor,

I would like to submit our review manuscript entitled “Small RNA, big defense: Early epigenetic responses to genetic invasion” to the < Sculpting plant identity through chromatin landscapes> Collection of Quantitative Plant Biology.

In this review, we examine the early events underlying small RNA biogenesis in plants. As part of the innate defence system, the small RNA pathway must discriminate between self and nonself genetic elements, a process whose molecular mechanisms are only beginning to be elucidated. Given the pathway’s central role in both plant biology and biotechnology, this review offers a timely and insightful synthesis of current knowledge. We believe that this review fits perfectly with the Collection and is of broad readership encompassing a wide range of plant research from immunity to epigenetics.

I confirm that this manuscript is not under consideration in any other journals and hope you will find it suitable for publication in Quantitative Plant Biology.

Sincerely,

Jungnam Cho, PhD

Associate Professor

Department of Biosciences

Durham University

jungnam.cho@durham.ac.uk

Review: Small RNA, big defence: Early epigenetic responses to genetic invasion — R0/PR2

Published online by Cambridge University Press:  27 October 2025
DOI: https://doi.org/10.1017/qpb.2025.10029.pr2 [Opens in a new window]
Reviewer_1
Date of review:  05 September 2025
Revision round: 0
Role: reviewer
Recommendation/decision: minor-revision

Conflict of interest statement

Reviewer declares none.

Comments

The manuscript entitled “Small RNA, big defense: Early epigenetic responses to genetic invasion” reviewed recent findings on how plant cells recognize foreign nucleic acids and initiate epigenetic silencing. The authors discussed these findings from three perspectives: translation-associated RNA cleavage, localization to siRNA bodies, and RNA decay versus RNA silencing. By integrating these emerging mechanisms with established pathways, such as RNA-directed DNA methylation (RdDM) and non-conanical RdDM pathways, primarily executors for silencing foreign nucleic acids, the manuscript advances our understanding of how plant cells distinguish foreign nucleic acids from their own. The authors, who themselves contributed significantly to this field, offer reasonable and insightful interpretation and perspective. Overall, the manuscript is well-written, concise, and accurate. I really enjoyed reading it.

Minor concerns:

1, Both figures are somewhat oversimplified. First, key symbols (for example, ribosomes and DNA methylation in Figure 1) should be clearly defined in the figures or figure legends. Second, figure 1 focuses on ribosome stalling and siRNA body. It would be better to add some details on why and how non-self RNAs are experiencing ribosome stalling and how these non-self RNAs are being processed to be delivered into the siRNA body. One solution is to combine figures 1 and 2 into a large figure with more mechanisms included.

2, On page 7, line 201, the authors stated that “m6A acts as a host-encoded marker to selectively flag foreign RNAs, guiding them into silencing pathways and reinforcing genomic defense at the RNA level.” I think the statement might not be accurate because the majority of the plant mRNAs have m6A modifications. Therefore, m6A modifications on foreign RNAs may not be necessary to label or distinguish non-native RNAs. There must be some other mechanisms together with m6A modifications to label non-native RNAs. I recommend the authors discuss the complexity and possibility of different mechanisms.

3, On page 7, line 214-237, when discussing RNA decay pathways act to suppress RNA silencing under normal conditions, the authors likely treat NGD and RNA decay as the same mechanism. I think the authors may need to add some details to distinguish these two RNA decay pathways. For example, normal RNA decay occurred in processing bodies. DCP2 and XRN4 are key components of processing bodies, and their deficiency leads to aberrant processing into siRNA in siRNA bodies. NGD, which targets transcripts with stalled ribosomes, may actively contribute to silencing initiation by generating cleavage RNA fragments. I hope the authors can explain more details to clarify the differences between these mechanisms.

Review: Small RNA, big defence: Early epigenetic responses to genetic invasion — R0/PR3

Published online by Cambridge University Press:  27 October 2025
DOI: https://doi.org/10.1017/qpb.2025.10029.pr3 [Opens in a new window]
Reviewer_2
Date of review:  24 September 2025
Revision round: 0
Role: reviewer
Recommendation/decision: minor-revision

Conflict of interest statement

Reviewer declares none.

Comments

This review focuses on the epigenetic defense mechanisms against “genetic invasion” from exogenous genetic elements (e.g., viruses, bacteria, transgenes) and endogenous threats (e.g., transposable elements, TEs) in plants. It emphasizes the central role of small interfering RNAs (siRNAs) and RNA-directed DNA methylation (RdDM) in these processes, while dissecting the understudied early steps of epigenetic silencing initiation. This manuscript was written well and covered major recent progresses in this area. Still, it needs some minor improvements to be accepted. My comments are:

1. Line 143, in this part on NGD, the most recent paper on aberrant RNA and transgene silencing (Kramer, et al., 2025) should be covered and cited.

2. Line 153, the disome from ribosome collision was reportedly related to NGD as well. The authors may discuss the role of the architecture of ribosomes and mRNA in NGD and RQC that result in aberrant RNA and siRNA biogenesis.

3. Line 219, recent papers on siRNA generated from insufficient mRNA degradation should also be cited, such as Zhang, et al. 2015, Science and You, et al. 2019, Nat. Commun.

4. Line 274, the Nature paper (Wu, et al. 2020) on 22-nt siRNA and nitrogen-depletion discussed the relationship between environmental cues and translational repression. Though RdDM-mediated gene silencing was not mentioned in this paper, the authors may also discussed environment-induced siRNAs playing roles in DNA methylation.

Recommendation: Small RNA, big defence: Early epigenetic responses to genetic invasion — R0/PR4

Published online by Cambridge University Press:  27 October 2025
DOI: https://doi.org/10.1017/qpb.2025.10029.pr4 [Opens in a new window]
Yuan Wang Chinese Academy of Sciences, China
Date of review:  24 September 2025
Revision round: 0
Role: Associate Editor
Recommendation/decision: minor-revision

Comments

No accompanying comment.

Decision: Small RNA, big defence: Early epigenetic responses to genetic invasion — R0/PR5

Published online by Cambridge University Press:  27 October 2025
DOI: https://doi.org/10.1017/qpb.2025.10029.pr5 [Opens in a new window]
Revision round: 0
Role: Editor in Chief
Recommendation/decision: minor-revision

Comments

No accompanying comment.

Author comment: Small RNA, big defence: Early epigenetic responses to genetic invasion — R1/PR6

Published online by Cambridge University Press:  27 October 2025
DOI: https://doi.org/10.1017/qpb.2025.10029.pr6 [Opens in a new window]
Jungnam Cho [Opens in a new window] Durham University, United Kingdom of Great Britain and Northern Ireland
Revision round: 1
Role: author

Comments

September 29th, 2025

Dear editor,

I would like to resubmit our review manuscript entitled “Small RNA, big defense: Early epigenetic responses to genetic invasion” to the < Sculpting plant identity through chromatin landscapes> Collection of Quantitative Plant Biology.

As you will find, the manuscript has been revised in accordance with the reviewers’ suggestions, which are detailed in our point-by-point response letter. I also confirm that the manuscript complies the journal’s formatting style and hope you will find it suitable for publication in Quantitative Plant Biology.

Sincerely,

Jungnam Cho, PhD

Associate Professor

Department of Biosciences

Durham University

jungnam.cho@durham.ac.uk

Recommendation: Small RNA, big defence: Early epigenetic responses to genetic invasion — R1/PR7

Published online by Cambridge University Press:  27 October 2025
DOI: https://doi.org/10.1017/qpb.2025.10029.pr7 [Opens in a new window]
Yuan Wang Chinese Academy of Sciences, China
Date of review:  19 October 2025
Revision round: 1
Role: Associate Editor
Recommendation/decision: accept

Comments

No accompanying comment.

Decision: Small RNA, big defence: Early epigenetic responses to genetic invasion — R1/PR8

Published online by Cambridge University Press:  27 October 2025
DOI: https://doi.org/10.1017/qpb.2025.10029.pr8 [Opens in a new window]
Revision round: 1
Role: Editor in Chief
Recommendation/decision: accept

Comments

No accompanying comment.