Unlocking the dual power of Charybdis natator shell: antiviral and larvicidal activities

Karnan Ramachandran , Senthil Bakthavatchalam , Shunmuga Vadivu Ramalingam , Ramachandran Vinayagam , Mukeshwaran Ramesh , Sukumaran Marimuthu , Zhi-Hong Wen , Chandramohan Govindasamy , Khalid M. Almutairi , Yi-Hao Lo

Bioresources and Bioprocessing ›› 2025, Vol. 12 ›› Issue (1) : 29

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Bioresources and Bioprocessing ›› 2025, Vol. 12 ›› Issue (1) : 29 DOI: 10.1186/s40643-025-00868-7
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Unlocking the dual power of Charybdis natator shell: antiviral and larvicidal activities

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Abstract

This study investigates the in silico anti-arboviral potential of zoochemicals derived from the methanolic extract of Charybdis natator shell, alongside their larvicidal efficacy against Aedes aegypti 4th instar larvae. Through GC–MS analysis, 27 zoochemicals were identified, demonstrating promising in silico activity against molecular antiviral targets: DENV2 protease (PDB: 6MO1) for anti-dengue, RNA polymerase (PDB: 5U04) for anti-Zika, and nsP2 protease (PDB: 3TRK) for anti-chikungunya. A strong positive correlation (r = 0.726–0.889) in binding affinities (kcal/mol) suggests a consistent inhibitory mechanism across these targets. Furthermore, PASS analysis indicates higher probabilities of activity (Pa) for insecticidal properties compared to antiviral efficacy, highlighting their dual potential as larvicidal agents and antiviral candidates. The methanolic extract of Charybdis natator shell exhibited potent larvicidal activity against Aedes aegypti (LC₅₀ = 81.001 µg/mL) in a dose-dependent manner (R2 = 0.968). In silico analysis further elucidated its inhibitory action on key growth regulators of A. aegypti, underscoring its potential to disrupt larval development. These findings highlight the dual utility of C. natator shell extract in vector management and in mitigating the transmission of arboviral diseases such as Dengue, Zika, and Chikungunya. The extract's promise as an eco-friendly, cost-effective source for developing novel insecticidal and antiviral agents merits further exploration.

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Keywords

Antiviral / Arbovirus vector / Charybdis natator / Zoo-virucide / Crab zoochemicals

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Karnan Ramachandran, Senthil Bakthavatchalam, Shunmuga Vadivu Ramalingam, Ramachandran Vinayagam, Mukeshwaran Ramesh, Sukumaran Marimuthu, Zhi-Hong Wen, Chandramohan Govindasamy, Khalid M. Almutairi, Yi-Hao Lo. Unlocking the dual power of Charybdis natator shell: antiviral and larvicidal activities. Bioresources and Bioprocessing, 2025, 12(1): 29 DOI:10.1186/s40643-025-00868-7

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References

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[1]

Abdul-HammedM, AdedotunIO, FaladeVA, et al. . Target-based drug discovery, ADMET profiling and bioactivity studies of antibiotics as potential inhibitors of SARS-CoV-2 main protease (Mpro). Virusdisease, 2021, 32: 642-656.

[2]

AdawaraSN, MamzaP, GideonSA, et al. . Anti-dengue potential, molecular docking study of some chemical constituents in the leaves of Isatis tinctoria. Chem Rev Lett, 2020, 3: 104-109
[3]

AdawaraSN, GideonSA, MamzaP, et al. . Molecular docking and in-silico pharmacokinetic investigations towards designing multi-target potent dengue virus inhibitors with enhanced pharmacokinetic profile. Chem Rev Lett, 2021, 4: 200-205
[4]

AhmedSR, BanikA, AnniSM, et al. . Inhibitory potential of plant-derived metabolites against Zika virus: a computational-aided approach. Phytomed Plus, 2021, 1: 100129.

[5]

AlagarasuK, PatilP, KaushikM, et al. . In vitro antiviral activity of potential medicinal plant extracts against dengue and chikungunya viruses. Front Cell Infect Microbiol, 2022, 12: 866452.

[6]

AnandM, MaruthupandyM, KalaivaniR, et al. . Larvicidal activity of chitosan nanoparticles synthesized from crab and squilla species against Aedes aegypti. J Colloid Sci Biotechnol, 2014, 3: 188-193.

[7]

AragãoCF, PinheiroVCS, Nunes NetoJP, et al. . Natural infection of Aedes aegypti by chikungunya and dengue type 2 virus in a transition area of north-northeast Brazil. Viruses, 2019, 11: 1126.

[8]

Buendia-AtencioC, PieffetGP, Montoya-VargasS, et al. . Inverse molecular docking study of NS3-helicase and NS5-RNA polymerase of Zika virus as possible therapeutic targets of ligands derived from Marcetia taxifolia and its implications to Dengue virus. ACS Omega, 2021, 6: 6134-6143.

[9]

ChenR, MukhopadhyayS, MeritsA, et al. . ICTV virus taxonomy profile: Togaviridae. J Gen Virol, 2018, 99: 761-762.

[10]

ChenY, ChiX, ZhangH, et al. . Identification of potent Zika virus NS5 RNA-dependent RNA polymerase inhibitors combining virtual screening and biological assays. Int J Mol Sci, 2023, 24: 1900.

[11]

DantasWM, de OliveiraVN, SantosDA, et al. . Searching Anti-Zika virus activity in 1 H-1, 2, 3-triazole based compounds. Molecules, 2021, 26: 5869.

[12]

DongS, DimopoulosG. Antiviral compounds for blocking arboviral transmission in mosquitoes. Viruses, 2021, 13: 108.

[13]

Eiken BB (2024) Secondary Metabolites from Marine Invertebrate Extracts (Master's thesis, UiT The Arctic University of Norway).
[14]

ElshaarawyR, AboaliE, AlianA. Preliminary assessment of bioactive ingredients and antioxidant activity of some Red Sea invertebrates' extracts. Egypt J Aquat Biol Fish, 2023.

[15]

FilimonovDA, LaguninAA, GloriozovaTA, et al. . Prediction of the biological activity spectra of organic compounds using the PASS online web resource. Chem Heterocycl Compd, 2014, 50: 444-457.

[16]

Galal-Khallaf A, Al-Awthan YS, Al-Duais MA et al (2022) Nile crab Potamonautes niloticus shell extract: Chromatographic and molecular elucidation of potent antioxidant and anti-inflammatory capabilities. Bioorgan Chem 127:106023
[17]

Galal-KhallafA, Samir AboaliE, El-Sayed Hassab El-NabiS, et al. . As healthy as invasive: Charybdis natator shell extract reveals beneficial metabolites with promising antioxidant and anti-inflammatory potentials. Front Mar Sci, 2024, 11: 1376768.

[18]

GodoyAS, LimaGM, Oliveira, , et al. . Crystal structure of Zika virus NS5 RNA-dependent RNA polymerase. Nat Commun, 2017, 8: 14764.

[19]

GohVSL, MokCK, ChuJJH. Antiviral natural products for arbovirus infections. Molecules, 2020, 25: 2796.

[20]

GomathiD, KalaiselviM, RavikumarG, et al. . GC-MS analysis of bioactive compounds from the whole plant ethanolic extract of Evolvulus alsinoides (L.) L. J Food Sci Technol, 2015, 52: 1212-1217.

[21]

GuanL, YangH, CaiY, et al. . ADMET-score-a comprehensive scoring function for evaluation of chemical drug-likeness. Med Chem Commun, 2018, 10: 148-157.

[22]

HasanMK, KamruzzamanM, ManjurOHB, et al. . Structural analogues of existing anti-viral drugs inhibit SARS-CoV-2 RNA dependent RNA polymerase: a computational hierarchical investigation. Heliyon, 2021, 7: 06435.

[23]

HemaR, KumaravelS, AlagusundaramK. GC/MS determination of bioactive components of Murraya koenigii. J Am Sci, 2011, 7: 80-83
[24]

HoTH, ThiUTN, QuanQD, et al. . In silico screening for anti-Zika Virus compounds from Eclipta prostrata by molecular docking: English. Vietnam J Biotechnol, 2023, 21: 197-217
[25]

InduP, ArunagirinathanN, RameshkumarMR, et al. . Exploring potential anti-chikungunya virus activity of phytocompounds: computational docking and in vitro studies. J King Saud Univ Sci, 2022, 34: 102157.

[26]

IzzatiF, WarsitoMF, BayuA, et al. . Chemical diversity and biological activity of secondary metabolites isolated from Indonesian marine invertebrates. Molecules, 2021, 26: 1898.

[27]

JamkhandePG, WattamwarAS, PekamwarSS, et al. . Antioxidant, antimicrobial activity and in silico PASS prediction of Annona reticulata Linn. root extract. Beni-Suef Univ J Basic Appl Sci, 2014, 3: 140-148
[28]

JamkhandeP, GhanteM, KshirsagarR. In Silico PASS predictions and exploration of antioxidant and anti-inflammatory activity of Citrus karna Raf. Fruit Medeniyet Med J, 2024, 39: 49-58
[29]

KarnanR, SukumaranM, MariappanP, et al. . Insecticidal effect of zoochemicals mediated copper oxide nanoparticle using marine sponge Hyattella intestinalis (Lamarck, 1814) and molecular docking. Uttar Pradesh J Zool, 2023, 44: 64-72.

[30]

KarnanR, SukumaranM, MariappanP, et al. . Zoo-mediated CuO nanoparticles synthesis using sea urchin Salmacis virgulata (L. Agassiz & Desor, 1846) test as a novel reducing agent and evaluated the in silico antifungal activity. Uttar Pradesh J Zool, 2023, 44: 154-167.

[31]

KarnanR, SukumaranM, VelavanS. Zoochemical-mediated nanoparticle synthesis using marine sponge Hyattella intestinalis (Lamarck, 1814) as a reducing agents. Uttar Pradesh J Zool, 2023, 44: 35-41.

[32]

KarnanR, VelavanS, Mariappan, et al. . Evaluation of Insecticidal Activity of Zoochemical-Assisted Zinc Oxide Nanoparticle Using Marine Invertebrate Hyattella intestinalis (Lamarck, 1814). Uttar Pradesh J Zool, 2023, 44: 31-39.

[33]

KarnilaR, RamadhaniNR. Antioxidant activity of astaxanthin flour extract of mud crab (Scylla Serrata) with different acetone concentrations. In IOP Conf Ser Earth Environ Sci, 2021, 695: 012047.

[34]

Khurana N, Ishar MPS, Gajbhiye A et al (2011) PASS assisted prediction and pharmacological evaluation of novel nicotinic analogs for nootropic activity in mice. Eur J Pharmacol 662:22–30
[35]

KronenbergerT, Sa Magalhaes SerafimM, TonduruK, et al. . Ligand accessibility insights to the dengue virus NS3-NS2B protease assessed by long-timescale molecular dynamics simulations. ChemMedChem, 2021, 16: 2524-2534.

[36]

KühlN, LeutholdMM, BehnamMA, et al. . Beyond basicity: discovery of nonbasic DENV-2 protease inhibitors with potent activity in cell culture. J Med Chem, 2021, 64: 4567-4587.

[37]

LaithAA, AmbakM, Abol-MunafiAB, et al. . Metabolomic analysis of marine and mud crabs based on antibacterial activity. Aquac Rep, 2017, 7: 7-15.

[38]

LimH, LeeSY, HoLY, et al. . Mosquito larvicidal activity and cytotoxicity of the extracts of aromatic plants from Malaysia. Insects, 2023, 14: 512.

[39]

Loaiza-CanoV, Monsalve-EscuderoLM, RestrepoMP, et al. . In vitro and in silico anti-arboviral activities of Dihalogenated phenolic derivates of L-tyrosine. Molecules, 2021, 26: 3430.

[40]

LvYN, ZengM, YanZY, et al. . Juvenile hormone signaling is indispensable for late embryogenesis in ametabolous and hemimetabolous insects. BMC Biol, 2024, 22: 232.

[41]

MalhotraP, BasuS. The intricate role of ecdysis triggering hormone signaling in insect development and reproductive regulation. Insects, 2023, 14: 711.

[42]

MertenEM, SearsJD, LeisnerTM, et al. . Identification of a cell-active chikungunya virus nsP2 protease inhibitor using a covalent fragment-based screening approach. Proc Natl Acad Sci, 2024, 121: e2409166121.

[43]

NatarajanP, SinghS, BalamuruganK. Gas chromatography-mass spectrometry (GC-MS) analysis of bio active compounds presents in Oeophylla smaragdina. Res J Pharm Technol, 2019, 12: 2736-2741.

[44]

NguyenPT, YuH, KellerPA. Identification of chikungunya virus nsP2 protease inhibitors using structure-base approaches. J Mol Graph Model, 2015, 57: 1-8.

[45]

OliveiraAP, LopesAC, SilvaM, et al. . Exploring Montagu’s crab: primary and secondary metabolites and enzyme inhibition. Arab J Chem, 2019, 12: 4017-4025.

[46]

OoA, HassandarvishP, ChinSP, et al. . In silico study on anti-Chikungunya virus activity of hesperetin. PeerJ, 2016, 4: 2602.

[47]

Pecor D (2022) Mosquito Identification Guide: Guam. Walter Reed Biosystematics Unit (WRBU). May 3. https://vectormap.si.edu/downloads/VHazardReports/Mosquito%20Vector%20Identification%20Guide%20Guam.pdf
[48]

PengS, WangH, WangZ, et al. . Progression of antiviral agents targeting viral polymerases. Molecules, 2022, 27: 7370.

[49]

Puig-TorrentsM, DíezJ. Controlling arbovirus infection: high-throughput transcriptome and proteome insights. Front Microbiol, 2024, 15: 1330303.

[50]

RehmanG, GulN, KhanGN, et al. . Ethanolic extract of Allacanthos crab inhibits cancer cell proliferation, posses anti-inflammatory and antioxidant potentials. Gene Reports, 2020, 21: 100907.

[51]

SahaA, AcharyaBN, Priya, et al. . Development of nsP2 protease based cell free high throughput screening assay for evaluation of inhibitors against emerging Chikungunya virus. Sci Rep, 2018, 8: 10831.

[52]

SaisawangC, SillapeeP, SinsirimongkolK, et al. . Full length and protease domain activity of chikungunya virus nsP2 differ from other alphavirus nsP2 proteases in recognition of small peptide substrates. Biosci Rep, 2015, 35: e00196.

[53]

SimmondsP, BecherP, BukhJ, et al. . ICTV virus taxonomy profile: Flaviviridae. J Gen Virol, 2017, 98: 2-3.

[54]

SomaiaMZ, RababMA, SamyaHM, et al. . Antiproliferative and antioxidant activities of the edible crab Callinectes sapidus hepatopancreas and hemolymph extracts. Egypt J Aquat Biol Fish, 2021, 25: 531-550.

[55]

SoniN, DhimanRC. Larvicidal and antibacterial activity of aqueous leaf extract of Peepal (Ficus religiosa) synthesized nanoparticles. Parasite Epidemiol Control, 2020, 11: e00166.

[56]

TrottO, OlsonAJ. AutoDock Vina: improving the speed and accuracy of docking with a new scoring function, efficient optimization, and multithreading. J Comput Chem, 2010, 31: 455-461.

[57]

Veerabahu S, Janakiraman A, Ramamurthy VV et al (2024) Phytochemical profiling and molecular docking studies of orange and pomegranate fruit peel against cervical cancer. Lett Appl NanoBioSci 13:1–12
[58]

WeaverSCPetersCJ, CalisherCH. Host range, amplification and arboviral disease emergence. Infectious diseases from nature: mechanisms of viral emergence and persistence, 2005ViennaSpringer33-44.

[59]

World Health Organization (2005) Guidelines for Laboratory and Field Testing of Mosquito Larvicides. WHO/CDS/WHOPES/GCDPP/13
[60]

XuX, ChenY, LuX, et al. . An update on inhibitors targeting RNA-dependent RNA polymerase for COVID-19 treatment: promises and challenges. Biochem Pharmacol, 2022, 205: 115279.

[61]

YaoY, HuoT, LinYL, et al. . Discovery, X-ray crystallography and antiviral activity of allosteric inhibitors of flavivirus NS2B-NS3 protease. J Am Chem Soc, 2019, 141: 6832-6836.

Funding

Ministry of Science and Technology, Taiwan(NSTC-113-2314-B-283-001)

Zuoying Armed forces GENERAL Hospital(KAFGH-ZY-A-114013)

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