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Abstract
Phase separation (PS) plays a fundamental role in organizing aggregates during the viral lifecycle, providing significant opportunities for in viral disease treatment by inhibiting PS. Intrinsically disordered regions (IDRs) have been extensively studied and found to be critical for PS. However, the discovery of small molecules that target residues within IDRs remains underexplored, particularly in the field of pesticides. Herein, we report a novel phytovirucide compound 29, which was screened from a series of vanillin derivatives designed with sulfonylpiperazine motifs. The inactivation efficacy of compound 29 against tomato spotted wilt virus (TSWV) was significantly superior to that of the control agents vanisulfane and ribavirin. Mechanistically, compound 29 binds to the TSWV nucleocapsid protein (NP) at residues Lys68 (K68), Thr92 (T92), and Arg94 (R94), with T92 and R94 located in the IDRs of NP. Mutations at these sites impair the ability to form aggregates. Furthermore, a host factor, GTP (Guanosine Triphosphate)-binding nuclear protein Ran-like (Niben101scf08341g01001, NbRANL), which interacts with NP and promotes its aggregation, was identified. Compound 29 also suppresses the expression of NbRANL, resulting in the dual inhibition of ribonucleoprotein complexes (RNPs) formation. This unique mechanism of action provides insights into IDRs-based virucide discovery.
Keywords
aggregate
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agrochemical
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intrinsically disordered region
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mechanism of action
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tomato spotted wilt virus
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Yanju Wang, Yuqin Luo, Xin Li, Feifei Chen, Xingjie Zhang, Lu Yu, Runjiang Song, Baoan Song.
A Vanillin-Derived Inhibitor of Aggregates via Targeting Intrinsically Disordered Regions of Phytoviral Nucleocapsid Protein.
Aggregate, 2025, 6(3): e725 DOI:10.1002/agt2.725
| [1] |
C. T. Walter and J. N. Barr, “Recent Advances in the Molecular and Cellular Biology of Bunyaviruses,” Journal of General Virology 92, (2011): 2467.
|
| [2] |
H. R. Pappu, R. A. Jones, and R. K. Jain, “Global Status of Tospovirus Epidemics in Diverse Cropping Systems: Successes Achieved and Challenges Ahead,” Virus Research 141 (2009): 219.
|
| [3] |
M. Prins and R. Goldbach, “The Emerging Problem of Tospovirus Infection and Nonconventional Methods of Control,” Trends in Microbiology 6 (1998): 31.
|
| [4] |
K. B. G. Scholthof, S. Adkins, H. Czosnek, et al., “Top 10 Plant Viruses in Molecular Plant Pathology,” Molecular Plant Pathology 12 (2011): 938.
|
| [5] |
M. J. Adams, E. J. Lefkowitz, A. M. Q. King, et al., “Changes to Taxonomy and the International Code of Virus Classification and Nomenclature Ratified by the International Committee on Taxonomy of Viruses (2017),” Archives of Virology 162 (2017): 2505.
|
| [6] |
T. Pergande, “Observations on Certain Thripidae,” Insect Life 7 (1895): 390-395.
|
| [7] |
A. J. M. Loomans and J. C. Van Lenteren, “Biological Control of Thrips Pests: A Review on Thrips Parasitoids,” Wageningen Agricultural University Papers 95 (1995): 89-201.
|
| [8] |
D. R. Jones, “Plant Viruses Transmitted by Thrips,” Plant Pathology 113 (2005): 119.
|
| [9] |
Y. L. Gao, Z. R. Lei, and S. R. Reitz, “Western Flower Thrips Resistance to Insecticides: Detection, Mechanisms and Management Strategies,” Pest Management Science 68 (2012): 1111.
|
| [10] |
D. Li, X. Shang, S. Reitz, et al., “Field Resistance to Spinosad in Western Flower Thrips Frankliniella occidentalis (Thysanoptera: Thripidae),” Journal of Integrative Agriculture 15 (2016): 2803.
|
| [11] |
B. A. Coutts, M. L. Thomas-Carroll, and R. A. C. Jones, “Patterns of Spread of Tomato Spotted Wilt Virus in Field Crops of Lettuce and Pepper: Spatial Dynamics and Validation of Control Measures,” Annals of Applied Biology 145 (2004): 231.
|
| [12] |
A. Nilon, K. Robinson, H. R. Pappu, and N. Mitter, “Current Status and Potential of RNA Interference for the Management of Tomato Spotted Wilt Virus and Thrips Vectors,” Pathogens 10 (2021): 320.
|
| [13] |
A. A. Hyman, C. A. Weber, and F. Jülicher, “Liquid-Liquid Phase Separation in Biology,” Annual Review of Cell and Developmental Biology 30 (2014): 39.
|
| [14] |
S. F. Banani, H. O. Lee, A. A. Hyman, and M. K. Rosen, “Biomolecular Condensates: Organizers of Cellular Biochemistry,” Nature Reviews Molecular Cell Biology 18 (2017): 285.
|
| [15] |
R. J. Emenecker, A. S. Holehouse, and L. C. Strader, “Emerging Roles for Phase Separation in Plants,” Developmental Cell 55 (2020): 69.
|
| [16] |
S. Alberti and A. A. Hyman, “Biomolecular Condensates at the Nexus of Cellular Stress, Protein Aggregation Disease and Ageing,” Nature Reviews Molecular Cell Biology 22 (2021): 196.
|
| [17] |
C. Wu, A. S. Holehouse, D. W. Leung, G. K. Amarasinghe, and R. E. Dutch, “Liquid Phase Partitioning in Virus Replication: Observations and Opportunities,” Annual Review of Virology 9 (2022): 285.
|
| [18] |
J. R. Fang, G. Castillon, S. Phan, et al., “Spatial and Functional Arrangement of Ebola Virus Polymerase inside Phase-Separated Viral Factories,” Nature Communications 14 (2023): 4159.
|
| [19] |
M. Charman, N. Grams, N. Kumar, et al., “A Viral Biomolecular Condensate Coordinates Assembly of Progeny Particles,” Nature 616 (2023): 332.
|
| [20] |
P. R. Banerjee, A. N. Milin, M. Muhammad Moosa, P. L. Onuchic, and A. A. Deniz, “Reentrant Phase Transition Drives Dynamic Substructure Formation in Ribonucleoprotein Droplets,” Angewandte Chemie International Edition 56 (2017): 11354.
|
| [21] |
Y. Liang, X. Y. Zhang, B. Y. Wu, et al., “Actomyosin-Driven Motility and Coalescence of Phase-Separated Viral Inclusion Bodies Are Required for Efficient Replication of a Plant Rhabdovirus,” New Phytologist 240 (2023): 1990.
|
| [22] |
W. Lin and P. D. Nagy, “Co-Opted Cytosolic Proteins Form Condensate Substructures Within Membranous Replication Organelles of a Positive-Strand RNA Virus,” New Phytologist 243 (2024): 1917.
|
| [23] |
X. D. Fang, Q. Gao, Y. Zang, et al., “Host Casein Kinase 1-Mediated Phosphorylation Modulates Phase Separation of a Rhabdovirus Phosphoprotein and Virus Infection,” Elife 11 (2022): e74884.
|
| [24] |
S. Nepal and E. Holmstrom, “Single-molecule-binding studies of antivirals targeting the hepatitis C virus core protein,” Journal of Virology 91 (2017): e00892.
|
| [25] |
J. Li, Z. K. Feng, J. Y. Wu, et al., “Structure and Function Analysis of Nucleocapsid Protein of Tomato Spotted Wilt Virus Interacting With RNA Using Homology Modeling,” Journal of Biological Chemistry 290 (2015): 3950.
|
| [26] |
S. Y. Li, Y. W. Wang, and L. H. Lai, “Small Molecules in Regulating Protein Phase Separation,” Acta Biochimica ET Biophysica Sinica 55 (2023): 1075.
|
| [27] |
D. Zhao, W. F. Xu, X. F. Zhang, et al., “Understanding the Phase Separation Characteristics of Nucleocapsid Protein Provides a New Therapeutic Opportunity Against SARS-CoV-2,” Protein Cell 12 (2021): 734.
|
| [28] |
A. Jack, L. S. Ferro, M. J. Trnka, et al., “SARS-CoV-2 Nucleocapsid Protein Forms Condensates With Viral Genomic RNA,” PLOS Biology 19 (2021): e3001425.
|
| [29] |
W. M. Babinchak, B. K. Dumm, S. Venus, et al., “Small Molecules as Potent Biphasic Modulators of Protein Liquid-Liquid Phase Separation,” Nature Communications 11 (2020): 5574.
|
| [30] |
J. Shi, H. F. He, Z. J. Liu, and D. Y. Hu, “Pepper Mild Mottle Virus Coat Protein as a Novel Target to Screen Antiviral Drugs,” Journal of Agricultural and Food Chemistry 70 (2022): 8233.
|
| [31] |
C. L. Wei, X. Yang, S. J. Shi, et al., “3-Hydroxy-2-oxindole Derivatives Containing Sulfonamide Motif: Synthesis, Antiviral Activity, and Modes of Action,” Journal of Agricultural and Food Chemistry 71 (2023): 267.
|
| [32] |
C. L. Wei, C. N. Zhao, J. Li, C. Y. Li, B. A. Song, and R. J. Song, “Innovative Arylimidazole-Fused Phytovirucides via Carbene-Catalyzed [3+4] Cycloaddition: Locking Viral Cell-to-Cell Movement by Out-Competing Virus Capsid-Host Interactions,” Advancement of Science 11 (2024): 2309343.
|
| [33] |
M. S. Lou, S. Li, F. R. Jin, T. B. Yang, R. J. Song, and B. A. Song, “Pesticide Engineering From Natural Vanillin: Recent Advances and a Perspective,” Engineering (2024), https://doi.org/10.1016/j.eng.2024.06.015.
|
| [34] |
M. Biesaga, M. Frigolé-Vivas, and X. Salvtella, “Intrinsically Disordered Proteins and Biomolecular Condensates as Drug Targets,” Current Opinion in Chemical Biology 62 (2021): 90.
|
| [35] |
T. Mittag and R. Parker, “Multiple Modes of Protein-Protein Interactions Promote RNP Granule Assembly,” Journal of Molecular Biology 430 (2018): 4636.
|
| [36] |
B. R. Sabari, A. Dall'Agnese, A. Boija, et al., “Coactivator Condensation at Super-Enhancers Links Phase Separation and Gene Control,” Science 361 (2018): eaar3958.
|
| [37] |
M. Saito, D. Hess, J. Eglinger, et al., “Acetylation of Intrinsically Disordered Regions Regulates Phase Separation,” Nature Chemical Biology 15 (2019): 51.
|
| [38] |
M. Zachrdla, A. Savastano, A. I. de Opakua, M.-S. Cima-Omori, and M. Zweckstetter, “Contributions of the N-Terminal Intrinsically Disordered Region of the Severe Acute Respiratory Syndrome Coronavirus 2 Nucleocapsid Protein to RNA-Induced Phase Separation,” Protein Science 31 (2022): e4409.
|
| [39] |
N. N. Zan, J. Li, H. F. He, D. Y. Hu, and B. A. Song, “Discovery of Novel Chromone Derivatives as Potential Anti-TSWV Agents,” Journal of Agricultural and Food Chemistry 69 (2021): 10819.
|
| [40] |
Y. W. Liu, J. X. Chen, D. D. Xie, B. A. Song, and D. Y. Hu, “First Report on Anti-TSWV Activities of Quinazolinone Derivatives Containing a Dithioacetal Moiety,” Journal of Agricultural and Food Chemistry 69 (2021): 12135.
|
| [41] |
Y. J. Wang, Y. Q. Luo, D. Y. Hu, and B. A. Song, “Design, Synthesis, Anti-Tomato Spotted Wilt Virus Activity, and Mechanism of Action of Thienopyrimidine-Containing Dithioacetal Derivatives,” Journal of Agricultural and Food Chemistry 70 (2022): 6015.
|
| [42] |
B. A. Song, H. P. Zhang, H. Wang, et al., “Synthesis and Antiviral Activity of Novel Chiral Cyanoacrylate Derivatives,” Journal of Agricultural and Food Chemistry 53 (2005): 7886.
|
| [43] |
X. H. Gan, D. Y. Hu, Y. J. Wang, L. Yu, and B. A. Song, “Novel Trans-Ferulic Acid Derivatives Containing a Chalcone Moiety as Potential Activator for Plant Resistance Induction,” Journal of Agricultural and Food Chemistry 65 (2017): 4367.
|
| [44] |
J. Zhang, L. Zhao, C. Zhu, et al., “Facile Synthesis of Novel Vanillin Derivatives Incorporating a Bis(2-Hydroxyethyl)Dithhioacetal Moiety as Antiviral Agents,” Journal of Agricultural and Food Chemistry 65 (2017): 4582.
|
| [45] |
J. Shi, L. Yu, and B. A. Song, “Proteomics Analysis of Xiangcaoliusuobingmi-Treated Capsicum annuum L. Infected With Cucumber Mosaic Virus,” Pesticide Biochemistry Physiology 149 (2018): 113.
|
| [46] |
J. Chen, J. Shi, L. Yu, et al., “Design, Synthesis, Antiviral Bioactivity, and Defense Mechanisms of Novel Dithioacetal Derivatives Bearing a Strobilurin Moiety,” Journal of Agricultural and Food Chemistry 66 (2018): 5335.
|
| [47] |
I. van Knippenberg, R. Goldbach, and R. Kormelink, “Purified Tomato Spotted Wilt Virus Particles Support Both Genome Replication and Transcription In Vitro,” Virology 303 (2002): 278-286.
|
| [48] |
T. Soellick, J. F. Uhrig, G. L. Bucher, J. W. Kellmann, and P. H. Schreier, “The Movement Protein NSm of Tomato Spotted Wilt Tospovirus (TSWV): RNA Binding, Interaction With the TSWV N Protein, and Identification of Interacting Plant Proteins,” Proceedings of the National Academic Sciences 97 (2000): 2373.
|
| [49] |
Z. K. Feng, X. J. Chen, Y. Q. Bao, J. H. Dong, Z. K. Zhang, and X. R. Tao, “Nucleocapsid of Tomato Spotted Wilt Tospovirus Forms Mobile Particles That Traffic on an Actin/Endoplasmic Reticulum Network Driven by Myosin XI-K,” New Phytologist 200 (2013): 1212.
|
| [50] |
K. Komoda, M. Narita, K. Yamashita, I. Tanaka, and M. Yao, “The Asymmetric Trimeric Ring Structure of the Nucleocapsid Protein of Tospovirus,” Journal of Virology 91 (2017): e01002.
|
| [51] |
M. F. Feng, R. X. Cheng, M. L. Chen, et al., “Rescue of Tomato Spotted Wilt Virus Entirely From Complementary DNA Clones,” Proceedings of the National Academic Sciences 117 (2019): 1181.
|
| [52] |
M. L. Chen, “Establishment of Mini-Replicon based Reverse-Genetics Systems of Orthotospovirus and Functional Analysis of N Interacting Host Factors”. (master's thesis, Nanjing Agricultural University (China), 2021).
|
| [53] |
X. Wang, Y. Xu, Y. Han, et al., “Overexpression of RAN1 in Rice and Arabidopsis Alters Primordial Meristem, Mitotic Progress, and Sensitivity to Auxin,” Plant Physiology 140 (2006): 91.
|
| [54] |
P. Xu and W. Cai, “RAN1 is Involved in Plant Cold Resistance and Development in Rice (Oryza sativa),” Journal of Experimental Botany 65 (2014): 3277.
|
| [55] |
A. Zang, X. Xu, S. Neill, and W. Cai, “Overexpression of OsRAN2 in Rice and Arabidopsis Renders Transgenic Plants Hypersensitive to Salinity and Osmotic Stress,” Journal of Experimental Botany 61 (2010): 777.
|
| [56] |
S. Schütz, E. R. Nöldeke, and R. Sprangers, “A Synergistic Network of Interactions Promotes the Formation of In Vitro Processing Bodies and Protects mRNA Against Decapping,” Nucleic Acids Research 45 (2017): 6911.
|
| [57] |
Y. Luo, Z. Na and S. A. Slavoff, “P-Bodies: Composition, Properties, and Functions,” Biochemistry 57 (2018): 2424.
|
| [58] |
J. Solis-Miranda, M. Chodasiewicz, A. Skirycz, et al., “Stress-Related Biomolecular Condensates in Plants,” The Plant Cell 35 (2023): 3187.
|
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