| [1] |
Song X, Li Y, Cao X, Qi Y. 2019. MicroRNAs and their regulatory roles in plant-environment interactions. |
| [2] |
Zhan J, Meyers BC. 2023. Plant small RNAs: their biogenesis, regulatory roles, and functions. |
| [3] |
Yu B, Yang Z, Li J, Minakhina S, Yang M, et al. 2005. Methylation as a crucial step in plant microRNA biogenesis. |
| [4] |
Bobadilla Ugarte P, Barendse P, Swarts DC. 2023. Argonaute proteins confer immunity in all domains of life. |
| [5] |
Yu Y, Ji L, Le BH, Zhai J, Chen J, et al. 2017. ARGONAUTE10 promotes the degradation of miR165/6 through the SDN1 and SDN2 exonucleases in Arabidopsis. |
| [6] |
Wang X, Wang Y, Dou Y, Chen L, Wang J, et al. 2018. Degradation of unmethylated miRNA/miRNA*s by a DEDDy-type 3' to 5' exoribonuclease Atrimmer 2 in Arabidopsis. |
| [7] |
Ren G, Chen X, Yu B. 2012. Uridylation of miRNAs by HEN1 SUPPRESSOR1 in Arabidopsis. |
| [8] |
Wang X, Zhang S, Dou Y, Zhang C, Chen X, et al. 2015. Synergistic and independent actions of multiple terminal nucleotidyl transferases in the 3' tailing of small RNAs in Arabidopsis. |
| [9] |
Chen J, Li X, Dong X, Wang X. 2024. Functions and mechanisms of RNA tailing by nucleotidyl transferase proteins in plants. |
| [10] |
Lang PLM, Christie MD, Dogan ES, Schwab R, Hagmann J, et al. 2018. A role for the F-box protein HAWAIIAN SKIRT in plant microRNA function. |
| [11] |
Mei J, Jiang N, Ren G. 2019. The F-box protein HAWAIIAN SKIRT is required for mimicry target-induced microRNA degradation in Arabidopsis. |
| [12] |
Martín-Merchán A, Moro B, Bouet A, Bologna NG. 2023. Domain organization, expression, subcellular localization, and biological roles of ARGONAUTE proteins in Arabidopsis. |
| [13] |
Sheu-Gruttadauria J, MacRae IJ. 2017. Structural foundations of RNA silencing by Argonaute. |
| [14] |
Fang Y, Li N, Fan Y, Zhang Z, Cai Y, et al. 2026. Characterization of the miRNA turnover landscape and its regulation in Arabidopsis. |
| [15] |
Vaucheret H, Vazquez F, Crété P, Bartel DP. 2004. The action of ARGONAUTE1 in the miRNA pathway and its regulation by the miRNA pathway are crucial for plant development. |
| [16] |
Giudicatti AJ, Tomassi AH, Manavella PA, Arce AL. 2021. Extensive analysis of miRNA trimming and tailing indicates that AGO1 has a complex role in miRNA turnover. |
| [17] |
Yifhar T, Pekker I, Peled D, Friedlander G, Pistunov A, et al. 2012. Failure of the tomato trans-acting short interfering RNA program to regulate AUXIN RESPONSE FACTOR3 and ARF4 underlies the wiry leaf syndrome. |
| [18] |
De N, Young L, Lau PW, Meisner NC, Morrissey DV, et al. 2013. Highly complementary target RNAs promote release of guide RNAs from human Argonaute2. |
| [19] |
Diederichs S, Haber DA. 2007. Dual role for argonautes in microRNA processing and posttranscriptional regulation of microRNA expression. |
| [20] |
Yang A, Shao TJ, Bofill-De Ros X, Lian C, Villanueva P, et al. 2020. AGO-bound mature miRNAs are oligouridylated by TUTs and subsequently degraded by DIS3L2. |
| [21] |
Derrien B, Baumberger N, Schepetilnikov M, Viotti C, De Cillia J, et al. 2012. Degradation of the antiviral component ARGONAUTE1 by the autophagy pathway. |
| [22] |
Bressendorff S, Sjøgaard IMZ, Prestel A, Voutsinos V, Jansson MD, et al. 2025. Importance of an N-terminal structural switch in the distinction between small RNA-bound and free ARGONAUTE. |
| [23] |
Kobayashi H, Shoji K, Kiyokawa K, Negishi L, Tomari Y. 2019. VCP machinery mediates autophagic degradation of empty Argonaute. |
| [24] |
Kobayashi H, Shoji K, Kiyokawa K, Negishi L, Tomari Y. 2019. Iruka eliminates dysfunctional Argonaute by selective ubiquitination of its empty state. |
| [25] |
Mi S, Cai T, Hu Y, Chen Y, Hodges E, et al. 2008. Sorting of small RNAs into Arabidopsis argonaute complexes is directed by the 5' terminal nucleotide. |
| [26] |
Frank F, Sonenberg N, Nagar B. 2010. Structural basis for 5'-nucleotide base-specific recognition of guide RNA by human AGO2. |
| [27] |
Zhou L, Lim MYT, Kaur P, Saj A, Bortolamiol-Becet D, et al. 2018. Importance of miRNA stability and alternative primary miRNA isoforms in gene regulation during Drosophila development. |
| [28] |
Guo Y, Liu J, Elfenbein SJ, Ma Y, Zhong M, et al. 2015. Characterization of the mammalian miRNA turnover landscape. |
| [29] |
Schwab R, Palatnik JF, Riester M, Schommer C, Schmid M, et al. 2005. Specific effects of microRNAs on the plant transcriptome. |
| [30] |
Sheu-Gruttadauria J, Pawlica P, Klum SM, Wang S, Yario TA, et al. 2019. Structural basis for target-directed microRNA degradation. |
| [31] |
Ren G, Xie M, Zhang S, Vinovskis C, Chen X, et al. 2014. Methylation protects microRNAs from an AGO1-associated activity that uridylates 5' RNA fragments generated by AGO1 cleavage. |
| [32] |
Zuber H, Scheer H, Joly AC, Gagliardi D. 2018. Respective contributions of URT1 and HESO1 to the uridylation of 5' fragments produced from RISC-cleaved mRNAs. |
| [33] |
Ibrahim F, Rymarquis LA, Kim EJ, Becker J, Balassa E, et al. 2010. Uridylation of mature miRNAs and siRNAs by the MUT68 nucleotidyltransferase promotes their degradation in Chlamydomonas. |
| [34] |
Kim H, Lee YY, Kim VN. 2025. The biogenesis and regulation of animal microRNAs. |
| [35] |
Svendsen JM, Reed KJ, Vijayasarathy T, Montgomery BE, Tucci RM, et al. 2019. henn-1/HEN1 promotes germline immortality in Caenorhabditis elegans. |
| [36] |
Franco-Zorrilla JM, Valli A, Todesco M, Mateos I, Puga MI, et al. 2007. Target mimicry provides a new mechanism for regulation of microRNA activity. |
| [37] |
Todesco M, Rubio-Somoza I, Paz-Ares J, Weigel D. 2010. A collection of target mimics for comprehensive analysis of microRNA function in Arabidopsis thaliana. |
| [38] |
Yan J, Gu Y, Jia X, Kang W, Pan S, et al. 2012. Effective small RNA destruction by the expression of a short tandem target mimic in Arabidopsis. |
| [39] |
Zhang H, Zhang J, Yan J, Gou F, Mao Y, et al. 2017. Short tandem target mimic rice lines uncover functions of miRNAs in regulating important agronomic traits. |
| [40] |
Ameres SL, Horwich MD, Hung JH, Xu J, Ghildiyal M, et al. 2010. Target RNA–directed trimming and tailing of small silencing RNAs. |
| [41] |
Haas G, Cetin S, Messmer M, Chane-Woon-Ming B, Terenzi O, et al. 2016. Identification of factors involved in target RNA-directed microRNA degradation. |
| [42] |
Xie J, Ameres SL, Friedline R, Hung JH, Zhang Y, et al. 2012. Long-term, efficient inhibition of microRNA function in mice using rAAV vectors. |
| [43] |
Cazalla D, Yario T, Steitz JA. 2010. Down-regulation of a host microRNA by a Herpesvirus saimiri noncoding RNA. |
| [44] |
de la Mata M, Gaidatzis D, Vitanescu M, Stadler MB, Wentzel C, et al. 2015. Potent degradation of neuronal miRNAs induced by highly complementary targets. |
| [45] |
Bitetti A, Mallory AC, Golini E, Carrieri C, Carreño Gutiérrez H, et al. 2018. microRNA degradation by a conserved target RNA regulates animal behavior. |
| [46] |
Shi CY, Kingston ER, Kleaveland B, Lin DH, Stubna MW, et al. 2020. The ZSWIM8 ubiquitin ligase mediates target-directed microRNA degradation. |
| [47] |
Han J, LaVigne CA, Jones BT, Zhang H, Gillett F, et al. 2020. A ubiquitin ligase mediates target-directed microRNA decay independently of tailing and trimming. |
| [48] |
Farnung J, Slobodyanyuk E, Wang PY, Blodgett LW, Lin DH, et al. 2026. The E3 ubiquitin ligase mechanism specifying targeted microRNA degradation. |
| [49] |
Zhang W, Murphy C, Sieburth LE. 2010. Conserved RNaseII domain protein functions in cytoplasmic mRNA decay and suppresses Arabidopsis decapping mutant phenotypes. |
| [50] |
Jiang S, Li H, Zhang L, Mu W, Zhang Y, et al. 2025. Generic Diagramming Platform (GDP): a comprehensive database of high-quality biomedical graphics. |