Life stage-dependent RNA interference in the tropical rock lobster Panulirus ornatus: mechanistic insights from RNA-seq and functional studies

Thomas M. Banks; Susan Glendinning; Avani Bhojwani; Quinn P. Fitzgibbon; Gregory G. Smith; Tomer Ventura

doi:10.1007/s42995-025-00336-3

Marine Life Science & Technology ›› :1 -15. DOI: 10.1007/s42995-025-00336-3

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Life stage-dependent RNA interference in the tropical rock lobster Panulirus ornatus: mechanistic insights from RNA-seq and functional studies

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Abstract

RNA interference (RNAi) has emerged as a key molecular tool in various commercially important decapod crustaceans, offering potential biotechnological applications in aquaculture. However, in the tropical rock lobster Panulirus ornatus, gene silencing through RNAi has proven difficult to achieve despite the availability of extensive omics data. This study investigates the RNAi response across life stages in P. ornatus, focusing on larvae and juveniles to determine when the species is most receptive to RNAi. Late-stage phyllosoma larvae and early juveniles were microinjected with dsRNA for the insulin-like growth factor binding protein encoding gene to determine silencing efficiency. Our results show that while juveniles exhibit an efficient systemic RNAi response with robust silencing across tissues, larvae display limited silencing capacity. A key finding is the differential expression of RNAi pathway components, including SID1, which facilitates dsRNA uptake in juveniles but is less active in larvae. Fluorescent microscopy revealed that dsRNA is rapidly sequestered and expelled by the antennal gland in larvae, potentially limiting RNAi efficacy. To further explore the mechanisms underlying RNAi in P. ornatus, RNA-seq analysis was conducted on pleopods collected across time points after dsRNA exposure in juvenile lobsters. Transcriptomic analysis identified significant upregulation of RNAi machinery, including Dicer-2, Argonaute-2, and SID1, which are critical for silencing. Additionally, several genes associated with antiviral responses were differentially expressed, suggesting broader involvement of RNAi in immune regulation. These findings highlight the potential to enhance RNAi strategies in P. ornatus juveniles, advancing the development of RNAi-based tools for disease resistance and productivity in aquaculture.

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RNA Interference / Spiny lobsters / siRNA pathway / Transcriptomic analysis / Decapod crustaceans / Gene silencing mechanism / Aquaculture biotechnology

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Thomas M. Banks, Susan Glendinning, Avani Bhojwani, Quinn P. Fitzgibbon, Gregory G. Smith, Tomer Ventura. Life stage-dependent RNA interference in the tropical rock lobster Panulirus ornatus: mechanistic insights from RNA-seq and functional studies. Marine Life Science & Technology 1-15 DOI:10.1007/s42995-025-00336-3

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References

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[1]	Aung KM, Boldbaatar D, Umemiya-Shirafuji R, Liao M, Xuenan X, Suzuki H, Galay RL, Tanaka T, Fujisaki K. Scavenger receptor mediates systemic RNA interference in ticks. PLoS ONE, 2011, 6 e28407

[2]	Baldaccini M, Pfeffer S. Untangling the roles of RNA helicases in antiviral innate immunity. PLoS Pathog, 2021, 17 e1010072

[3]	Banks TM, Wang T, Fitzgibbon QP, Smith GG, Ventura T. Double-stranded RNA binding proteins in serum contribute to systemic RNAi across phyla—towards finding the missing link in Achelata. Int J Mol Sci, 2020, 21: 6967

[4]	Banks TM, Wang T, Fitzgibbon QP, Smith GG, Ventura T. A tale of two lobsters-transcriptomic analysis reveals a potential gap in the RNA interference pathway in the tropical rock lobster Panulirus ornatus. Int J Mol Sci, 2022, 23: 11752

[5]	Bernstein E, Caudy AA, Hammond SM, Hannon GJ. Role for a bidentate ribonuclease in the initiation step of RNA interference. Nature, 2001, 409: 363-366

[6]	Black N, Banks TM, Ventura T. Assessing transgenerational gene editing capacity for enhancing aquaculture productivity in decapod crustaceans. Rev Aquac, 2024, 16: 2077-2089

[7]	Blasi G, Bortoletto E, Gasparotto M, Filippini F, Bai CM, Rosani U, Venier P. A glimpse on metazoan ZNFX1 helicases, ancient players of antiviral innate immunity. Fish Shellfish Immunol, 2022, 121: 456-466

[8]

Chandler JC, Gandhi NS, Mancera RL, Smith G, Elizur A, Ventura T. Understanding insulin endocrinology in decapod crustacea: molecular modelling characterization of an insulin-binding protein and insulin-like peptides in the eastern spiny lobster, Sagmariasus verreauxi. Int J Mol Sci, 2017, 18 1832

[9]	Chen YG, Hur S. Cellular origins of dsRNA, their recognition and consequences. Nat Rev Mol Cell Biol, 2022, 23: 286-301

[10]	Chen HY, Toullec JY, Lee CY. The crustacean hyperglycemic hormone superfamily: progress made in the past decade. Front Endocrinol, 2020, 11 578958

[11]	Chen NX, Jin JJ, Chen YB, Hu YC, Shen YC, Li SD. The transcriptome of Litopenaeus vannamei in zoea larvae and adults infected by Vibrio parahaemolyticus. Front Mar Sci, 2023, 10: 1174176

[12]

Christiaens O, Delbare D, Van Neste C, Cappelle K, Yu N, De Wilde R, Van Nieuwerburgh F, Deforce D, Cooreman K, Smagghe G. Differential transcriptome analysis of the common shrimp Crangon crangon: special focus on the nuclear receptors and RNAi-related genes. Gen Comp Endocrinol, 2015, 212: 163-177

[13]	Chu E, Allegra CJ. The role of thymidylate synthase in cellular regulation. Adv Enzyme Regul, 1996, 36: 143-163

[14]	Ciechanowska K, Pokornowska M, Kurzynska-Kokorniak A. Genetic insight into the domain structure and functions of dicer-type ribonucleases. Int J Mol Sci, 2021, 22: 616

[15]	Claycomb JM. Ancient endo-siRNA pathways reveal new tricks. Curr Biol, 2014, 24: R703-715

[16]	Cooper AM, Silver K, Zhang J, Park Y, Zhu KY. Molecular mechanisms influencing efficiency of RNA interference in insects. Pest Manag Sci, 2019, 75: 18-28

[17]	Dennis DM, Pitcher CR, Skewes TD. Distribution and transport pathways of Panulirus ornatus(Fabricius, 1776) and Panulirus spp. larvae in the Coral Sea, Australia. Mar Freshwater Res, 2002, 52: 1175-1185

[18]	Dennis DM, Skewes TD, Pitcher CR. Habitat use and growth of juvenile ornate rock lobsters, Panulirus ornatus (Fabricius, 1798), in Torres Strait, Australia. Mar Freshwater Res, 1998, 48: 663-670

[19]	Deymier S, Louvat C, Fiorini F, Cimarelli A. ISG20: an enigmatic antiviral RNase targeting multiple viruses. FEBS Open Bio, 2022, 12: 1096-1111

[20]	Duchaine TF, Wohlschlegel JA, Kennedy S, Bei Y, Conte DJr, Pang K, Brownell DR, Harding S, Mitani S, Ruvkun G, Yates JR3rd, Mello CC. Functional proteomics reveals the biochemical niche of C. elegans DCR-1 in multiple small-RNA-mediated pathways. Cell, 2006, 124: 343-354

[21]	Espert L, Degols G, Gongora C, Blondel D, Williams BR, Silverman RH, Mechti N. ISG20, a new interferon-induced RNase specific for single-stranded RNA, defines an alternative antiviral pathway against RNA genomic viruses. J Biol Chem, 2003, 278: 16151-16158

[22]	Feinberg EH, Hunter CP. Transport of dsRNA into cells by the transmembrane protein SID-1. Science, 2003, 301: 1545-1547

[23]	Fessler JH, Kramerova I, Kramerov A, Chen Y, Fessler LI. Papilin, a novel component of basement membranes, in relation to ADAMTS metalloproteases and ECM development. Int J Biochem Cell Biol, 2004, 36: 1079-1084

[24]	Fitzgibbon QP, Battaglene SC. Effect of water temperature on the development and energetics of early, mid and late-stage phyllosoma larvae of spiny lobster. Aquaculture, 2012, 344: 153-160

[25]	Garbutt JS, Belles X, Richards EH, Reynolds SE. Persistence of double-stranded RNA in insect hemolymph as a potential determiner of RNA interference success: evidence from Manduca sexta and Blattella germanica. J Insect Physiol, 2013, 59: 171-178

[26]	Ge HL, Tan K, Shi LL, Sun R, Wang WM, Li YH. Comparison of effects of dsRNA and siRNA RNA interference on insulin-like androgenic gland gene (IAG) in red swamp crayfish Procambarus clarkii. Gene, 2020, 752 144783

[27]	Glendinning S, Fitzgibbon QP, Smith GG, Ventura T. Unravelling the neuropeptidome of the ornate spiny lobster Panulirus ornatus: a focus on peptide hormones and their processing enzymes expressed in the reproductive tissues. Gen Comp Endocrinol, 2023, 332 114183

[28]	Godwin ARF, Singh M, Lockhart-Cairns MP, Alanazi YF, Cain SA, Baldock C. The role of fibrillin and microfibril binding proteins in elastin and elastic fibre assembly. Matrix Biol, 2019, 84: 17-30

[29]	Goto A, Blandin S, Royet J, Reichhart JM, Levashina EA. Silencing of toll pathway components by direct injection of double-stranded RNA into Drosophila adult flies. Nucleic Acids Res, 2003, 31: 6619-6623

[30]

Goto A, Okado K, Martins N, Cai H, Barbier V, Lamiable O, Troxler L, Santiago E, Kuhn L, Paik D, Silverman N, Holleufer A, Hartmann R, Liu J, Peng T, Hoffmann JA, Meignin C, Daeffler L, Imler JL. The kinase IKKbeta regulates a STING- and NF-kappaB-dependent antiviral response pathway in Drosophila. Immunity, 2018, 49225–234e224

[31]

Gu W, Shirayama M, Conte DJr., Vasale J, Batista PJ, Claycomb JM, Moresco JJ, Youngman EM, Keys J, Stoltz MJ, Chen CC, Chaves DA, Duan S, Kasschau KD, Fahlgren N, Yates JR, Mitani S, Carrington JC, Mello CC. Distinct argonaute-mediated 22G-RNA pathways direct genome surveillance in the C. elegans germline. Mol Cell, 2009, 36: 231-244

[32]	Guan RB, Li HC, Fan YJ, Hu SR, Christiaens O, Smagghe G, Miao XX. A nuclease specific to lepidopteran insects suppresses RNAi. J Biol Chem, 2018, 293: 6011-6021

[33]	Guo WC, Fu KY, Yang S, Li XX, Li GQ. Instar-dependent systemic RNA interference response in Leptinotarsa decemlineata larvae. Pestic Biochem Physiol, 2015, 123: 64-73

[34]	Hong SJ, Kim KH. RNA interference targeting WSSV ribonucleotide reductase 2 provides long-term protection against infection in Litopenaeus vannamei. Dis Aquat Organ, 2024, 159: 71-78

[35]	Horwich MD, Li C, Matranga C, Vagin V, Farley G, Wang P, Zamore PD. The Drosophila RNA methyltransferase, DmHen1, modifies germline piRNAs and single-stranded siRNAs in RISC. Curr Biol, 2007, 17: 1265-1272

[36]	Hwa V, Oh Y, Rosenfeld RG. The insulin-like growth factor-binding protein (IGFBP) superfamily. Endocr Rev, 1999, 20: 761-787

[37]	Hyde CJ, Fitzgibbon QP, Elizur A, Smith GG, Ventura T. Transcriptional profiling of spiny lobster metamorphosis reveals three new additions to the nuclear receptor superfamily. BMC Genomics, 2019, 20: 531

[38]	Idrees S, Paudel KR, Sadaf T, Hansbro PM. How different viruses perturb host cellular machinery via short linear motifs. EXCLI J, 2023, 22: 1113-1128

[39]	Jiravanichpaisal P, Puanglarp N, Petkon S, Donnuea S, Soderhall I, Soderhall K. Expression of immune-related genes in larval stages of the giant tiger shrimp, Penaeus monodon. Fish Shellfish Immunol, 2007, 23: 815-824

[40]	Joga MR, Zotti MJ, Smagghe G, Christiaens O. RNAi efficiency, systemic properties, and novel delivery methods for pest insect control: what we know so far. Front Physiol, 2016, 7: 553

[41]	Judith HW. Cuticular proteins in insects and crustaceans. Am Zool, 1999, 39: 600-609

[42]	Kanciruk P. Cobb JS, Phillips BF. Ecology of juvenile and adult Palinuridae (spiny lobsters). The biology and management of lobsters, 1980, San Diego, Academic Press5996

[43]	Kelly TR, Fitzgibbon QP, Smith GG, Banks TM, Ventura T. Tropical rock lobster (Panulirus ornatus) uses chemoreception via the antennular lateral flagellum to identify conspecific ecdysis. Sci Rep, 2023, 13: 12409

[44]	Kelman Z. PCNA: structure, functions and interactions. Oncogene, 1997, 14: 629-640

[45]	Ketting RF. The many faces of RNAi. Dev Cell, 2011, 20: 148-161

[46]	Kingsolver MB, Huang Z, Hardy RW. Insect antiviral innate immunity: pathways, effectors, and connections. J Mol Biol, 2013, 425: 4921-4936

[47]	Kough AS, Paris CB, Behringer DC, Butler MJ. Modelling the spread and connectivity of waterborne marine pathogens: the case of PaV1 in the Caribbean. ICES J Mar Sci, 2015, 72: i139-i146

[48]	Lewis CL, Fitzgibbon QP, Smith GG, Elizur A, Ventura T. Transcriptomic analysis and time to hatch visual prediction of embryo development in the ornate spiny lobster (Panulirus ornatus). Front Mar Sci, 2022, 9 889317

[49]	Lewis CL, Fitzgibbon QP, Smith GG, Elizur A, Ventura T. Ontogeny of the cytochrome P450 superfamily in the ornate spiny lobster (Panulirus ornatus). Int J Mol Sci, 2024, 25 1070

[50]	Li H, Yin B, Wang S, Fu Q, Xiao B, Lu K, He J, Li C. RNAi screening identifies a new Toll from shrimp Litopenaeus vannamei that restricts WSSV infection through activating dorsal to induce antimicrobial peptides. PLoS Pathog, 2018, 14 e1007109

[51]	Li Y, Liu D, Wang Y, Su W, Liu G, Dong W. The importance of glycans of viral and host proteins in enveloped virus infection. Front Immunol, 2021, 12 638573

[52]	Liu Q, Rand TA, Kalidas S, Du F, Kim HE, Smith DP, Wang X. R2D2, a bridge between the initiation and effector steps of the Drosophila RNAi pathway. Science, 2003, 301: 1921-1925

[53]	Lozano J, Gomez-Orte E, Lee HJ, Belles X. Super-induction of Dicer-2 expression by alien double-stranded RNAs: an evolutionary ancient response to viral infection?. Dev Genes Evol, 2012, 222: 229-235

[54]	Maruekawong K, Tirasophon W, Panyim S, Attasart P. Involvement of Lv SID-1 in dsRNA uptake in Litopenaeus vannamei. Aquaculture, 2018, 482: 65-72

[55]	Maruekawong K, Panyim S, Attasart P. Involvement of endocytosis in cellular uptake of injected dsRNA into hepatopancreas but not in gill of Litopenaeus vannamei. Aquaculture, 2019, 500: 393-397

[56]	Maruekawong K, Namlamoon O, Attasart P. Systemic gene silencing from oral uptake of dsRNA in Litopenaeus vannamei requires both clathrin-mediated endocytosis and LvSID-1. Aquaculture, 2022, 548 737557

[57]	McEwan DL, Weisman AS, Hunter CP. Uptake of extracellular double-stranded RNA by SID-2. Mol Cell, 2012, 47: 746-754

[58]	Melnyk CW, Molnar A, Baulcombe DC. Intercellular and systemic movement of RNA silencing signals. EMBO J, 2011, 30: 3553-3563

[59]	Miller SC, Brown SJ, Tomoyasu Y. Larval RNAi in Drosophila?. Dev Genes Evol, 2008, 218: 505-510

[60]	Mongelli V, Saleh MC. Bugs are not to be silenced: small RNA pathways and antiviral responses in insects. Annu Rev Virol, 2016, 3: 573-589

[61]	Muzi-Falconi M, Giannattasio M, Foiani M, Plevani P. The DNA polymerase alpha-primase complex: multiple functions and interactions. Sci World J, 2003, 3: 21-33

[62]	Nakanishi K. Anatomy of RISC: how do small RNAs and chaperones activate Argonaute proteins?. Wiley Interdiscip Rev RNA, 2016, 7: 637-660

[63]	Nguyen DV, Christiaens O, Bossier P, Smagghe G. RNA interference in shrimp and potential applications in aquaculture. Rev Aquac, 2018, 10: 573-584

[64]	Nguyen AT, Glendinning S, Ventura T. A refined roadmap to decapod sexual manipulation. Rev Aquac, 2023, 15: 1654-1663

[65]	Nie L, Cai SY, Shao JZ, Chen J. Toll-like receptors, associated biological roles, and signaling networks in non-mammals. Front Immunol, 2018, 9: 1523

[66]	Nilsen P, Karlsen M, Sritunyalucksana K, Thitamadee S. White spot syndrome virus VP28 specific double-stranded RNA provides protection through a highly focused siRNA population. Sci Rep, 2017, 7: 1028

[67]	O'Brien J, Hayder H, Zayed Y, Peng C. Overview of microRNA biogenesis, mechanisms of actions, and circulation. Front Endocrinol, 2018, 9 402

[68]	Orban TI, Izaurralde E. Decay of mRNAs targeted by RISC requires XRN1, the Ski complex, and the exosome. RNA, 2005, 11: 459-469

[69]	Phillips BF, Sastry AN. Cobb JS, Phillips BF. Chapter 1 - larval ecology. The biology and management of lobsters, 1980, San Diego, Academic Press1157

[70]	Ponprateep S, Tharntada S, Somboonwiwat K, Tassanakajon A. Gene silencing reveals a crucial role for anti-lipopolysaccharide factors from Penaeus monodon in the protection against microbial infections. Fish Shellfish Immunol, 2012, 32: 26-34

[71]	Qiu L, Guo XM, Feng YH, Xing JY, Ren XY, Huang J. Susceptibility of kuruma shrimp to the infection with decapod iridescent virus 1. Front Mar Sci, 2023, 10: 1114123

[72]	Quispe RL, Justino EB, Vieira FN, Jaramillo ML, Rosa RD, Perazzolo LM. Transcriptional profiling of immune-related genes in Pacific white shrimp (Litopenaeus vannamei) during ontogenesis. Fish Shellfish Immunol, 2016, 58: 103-107

[73]	Ramirez F, Sakai LY. Biogenesis and function of fibrillin assemblies. Cell Tissue Res, 2010, 339: 71-82

[74]	Rivera-Vicens RE, Garcia-Escudero CA, Conci N, Eitel M, Worheide G. TransPi-a comprehensive transcriptome analysis PIpeline for de novo transcriptome assembly. Mol Ecol Resour, 2022, 22: 2070-2086

[75]	Rojas-Rios P, Simonelig M. piRNAs and PIWI proteins: regulators of gene expression in development and stem cells. Development, 2018, 145 dev161786

[76]	Rosen O, Weil S, Manor R, Roth Z, Khalaila I, Sagi A. A crayfish insulin-like-binding protein: another piece in the androgenic gland insulin-like hormone puzzle is revealed. J Biol Chem, 2013, 288: 22289-22298

[77]	Sagi A, Manor R, Ventura T. Gene silencing in crustaceans: from basic research to biotechnologies. Genes, 2013, 4: 620-645

[78]	Saleh MC, van Rij RP, Hekele A, Gillis A, Foley E, O'Farrell PH, Andino R. The endocytic pathway mediates cell entry of dsRNA to induce RNAi silencing. Nat Cell Biol, 2006, 8: 793-802

[79]	Sanchez-Paz A. White spot syndrome virus: an overview on an emergent concern. Vet Res, 2010, 41: 43

[80]	Schuster S, Miesen P, van Rij RP. Antiviral RNAi in insects and mammals: parallels and differences. Viruses, 2019, 11: 448

[81]	Shan T, Wang Y, Bhattarai K, Jiang H. An evolutionarily conserved serine protease network mediates melanization and toll activation in Drosophila. Sci Adv, 2023, 9 eadk2756

[82]	Shih JD, Hunter CP. SID-1 is a dsRNA-selective dsRNA-gated channel. RNA, 2011, 17: 1057-1065

[83]	Shih JD, Fitzgerald MC, Sutherlin M, Hunter CP. The SID-1 double-stranded RNA transporter is not selective for dsRNA length. RNA, 2009, 15: 384-390

[84]	Shpak N, Manor R, Abilevich LK, Mantal O, Shavit K, Aflalo ED, Toiber D, Sagi A. Short versus long double-stranded RNA activation of a post-transcriptional gene knockdown pathway. RNA Biol, 2017, 14: 1766-1775

[85]	Singh IK, Singh S, Mogilicherla K, Shukla JN, Palli SR. Comparative analysis of double-stranded RNA degradation and processing in insects. Sci Rep, 2017, 7: 17059

[86]	Smith G, Salmon M, Kenway M, Hall M. Description of the larval morphology of captive reared spiny lobsters, benchmarked against wild-caught specimens. Aquaculture, 2009, 295: 76-88

[87]	Smith G, Glendinning S, Ventura T. Transcriptomic changes following induced de-masculinisation of Australian red claw crayfish Cherax quadricarinatus. Int J Mol Sci, 2023, 24: 3292

[88]	Song S, Wang Y, Liu P. DNA replication licensing factors: novel targets for cancer therapy via inhibiting the stemness of cancer cells. Int J Biol Sci, 2022, 18: 1211-1219

[89]	Stephens M. False discovery rates: a new deal. Biostatistics, 2017, 18: 275-294

[90]	Stiles B. Cuticle proteins of the boll-weevil, Anthonomus grandis, abdomen—structural similarities and glycosylation. Insect Biochem, 1991, 21: 249-258

[91]	Tabara H, Sarkissian M, Kelly WG, Fleenor J, Grishok A, Timmons L, Fire A, Mello CC. The rde-1 gene, RNA interference, and transposon silencing in C. elegans. Cell, 1999, 99: 123-132

[92]	Tada S, Blow JJ. The replication licensing system. Biol Chem, 1998, 379: 941-949

[93]	Taning CNT, Christiaens O, Berkvens N, Casteels H, Maes M, Smagghe G. Oral RNAi to control Drosophila suzukii: laboratory testing against larval and adult stages. J Pest Sci, 2016, 89: 803-814

[94]	Thammasorn T, Sangsuriya P, Meemetta W, Senapin S, Jitrakorn S, Rattanarojpong T, Saksmerprome V. Large-scale production and antiviral efficacy of multi-target double-stranded RNA for the prevention of white spot syndrome virus (WSSV) in shrimp. BMC Biotechnol, 2015, 15: 110

[95]	Uy T, Fitzgibbon QP, Codabaccus BM, Smith GG. Thermal physiology of tropical rock lobster (Panulirus ornatus); defining physiological constraints to high temperature tolerance. Aquaculture, 2023, 569 739357

[96]	van Cleef KW, van Mierlo JT, Miesen P, Overheul GJ, Fros JJ, Schuster S, Marklewitz M, Pijlman GP, Junglen S, van Rij RP. Mosquito and Drosophila entomobirnaviruses suppress dsRNA- and siRNA-induced RNAi. Nucleic Acids Res, 2014, 42: 8732-8744

[97]	Ventura T, Manor R, Aflalo ED, Weil S, Rosen O, Sagi A. Timing sexual differentiation: full functional sex reversal achieved through silencing of a single insulin-like gene in the prawn, Macrobrachium rosenbergii. Biol Reprod, 2012, 86 90

[98]	Ventura T, Chandler JC, Nguyen TV, Hyde CJ, Elizur A, Fitzgibbon QP, Smith GG. Multi-tissue transcriptome analysis identifies key sexual development-related genes of the ornate spiny lobster (Panulirus ornatus). Genes, 2020, 11 1150

[99]	Wang P-H, He J-G. Vanpouille-Box C, Galluzzi L. Chapter Six-Nucleic acid sensing in invertebrate antiviral immunity. International review of cell and molecular biology, 2019Academic Press287360345

[100]

Wang QC, Nie QH, Feng ZH. RNA interference: antiviral weapon and beyond. World J Gastroenterol, 2003, 9: 1657-1661

[101]

Willis JH. Cuticular proteins in insects and crustaceans. Am Zool, 1999, 39: 600-609

[102]

Winston WM, Molodowitch C, Hunter CP. Systemic RNAi in C. elegans requires the putative transmembrane protein SID-1. Science, 2002, 295: 2456-2459

[103]

Winston WM, Sutherlin M, Wright AJ, Feinberg EH, Hunter CP. Caenorhabditis elegans SID-2 is required for environmental RNA interference. Proc Natl Acad Sci USA, 2007, 104: 10565-10570

[104]

Wu J, Yang J, Cho WC, Zheng Y. Argonaute proteins: structural features, functions and emerging roles. J Adv Res, 2020, 24: 317-324

[105]

Wynant N, Santos D, Van Wielendaele P, Vanden Broeck J. Scavenger receptor-mediated endocytosis facilitates RNA interference in the desert locust, Schistocerca gregaria. Insect Mol Biol, 2014, 23: 320-329

[106]

Yamaguchi S, Naganuma M, Nishizawa T, Kusakizako T, Tomari Y, Nishimasu H, Nureki O. Structure of the dicer-2-R2D2 heterodimer bound to a small RNA duplex. Nature, 2022, 607: 393-398

[107]

Yang L, Tian Y, Peng YY, Niu J, Wang JJ. Expression dynamics of core RNAi machinery genes in pea aphids upon exposure to artificially synthesized dsRNA and miRNAs. Insects, 2020, 11: 70

[108]

Ye C, An X, Jiang YD, Ding BY, Shang F, Christiaens O, Taning CNT, Smagghe G, Niu J, Wang JJ. Induction of RNAi core machinery's gene expression by exogenous dsRNA and the effects of pre-exposure to dsRNA on the gene silencing efficiency in the pea aphid (Acyrthosiphon pisum). Front Physiol, 2018, 9: 1906

[109]

Ye C, Hu XS, Wang ZW, Wei D, Smagghe G, Christiaens O, Niu J, Wang JJ. Involvement of clathrin-dependent endocytosis in cellular dsRNA uptake in aphids. Insect Biochem Mol Biol, 2021, 132 103557

[110]

Zhai X, Yuan Y, He WT, Wu Y, Shi Y, Su S, Du Q, Mao Y. Evolving roles of glycosylation in the tug-of-war between virus and host. Natl Sci Rev, 2024, 11 nwae086

[111]

Zhang R, Jing Y, Zhang H, Niu Y, Liu C, Wang J, Zen K, Zhang CY, Li D. Comprehensive evolutionary analysis of the major RNA-induced silencing complex members. Sci Rep, 2018, 8: 14189

[112]

Zimmer-Faust RK, Spanier E. Gregariousness and sociality in spiny lobsters: implications for den habitation. J Exp Mar Biol Ecol, 1987, 105: 57-71

[113]

Zhang X, Zhang J, Zhu KY. Chitosan/double-stranded RNA nanoparticle-mediated RNA interference to silence chitin synthase genes through larval feeding in the African malaria mosquito (Anopheles gambiae). Insect Mol Biol, 2010, 19: 683-693