Influence of Indian snake (Naja naja) venom on cognition and biochemical functions in N- Nitrosodiethylamine treated Drosophila melanogaster
Article Sidebar
-
Behavioural assay, Drosophila melanogaster, Naja naja, Peptides, Redox homeostasis, Snake venom
Abstract
The flies (Drosophila melanogaster) were segregated into four groups. 1st Group is normal-control, 2nd group is wild type flies administered with 0.01% NDEA, 3rd group is wild type flies administered with 0.01% NDEA + 0.01% Naja naja snake venom (NNV) and 4th group is flies administered with 0.01% NNV alone were administered via food medium for 21 days. After the experimental period, the behavioural changes were analyzed. The behavioural assays include negative geotaxis, phototaxis, smell chemotaxis, taste chemotaxis, thermotaxis, and hygrotaxis were carried out in all groups of flies. The behavioural changes were found to be deteriorated in NDEA administered flies when related to the control but the behaviour is likely to regularise in NDEA+NNV administered flies. The protein carbonyl levels and levels of thiobarbuturic acid reactive substance (TBARS), protein thiol and lipid peroxides were noticeably elevated in NDEA administered flies as matched to control flies and similarly be likely to regularize in the NDEA+NNV group. Likewise, the levels of superoxide dismutase (SOD), catalase (CAT), glutathione peroxidase (GPX), glutathione-S-transferase (GST) and reduced glutathione (GSH) were diminished in the group of NDEA administered and were noticeably more in the group of NDEA+NNV administered group. NNV has been stated to possess pharmacologically active components such as disintegrins, cobratoxin, hannalgesin, cytotoxin II, etc. which could possess antioxidant, antibacterial, hypotensive, cancer suppressive, anticoagulant, and analgesic activities. Our present study provides evidences that these components could normalize cognitive behaviour and attenuate oxidative stress in a genetically important model organism D. melanogaster.
Full text article
References
N Tolwinski. Introduction: Drosophila- A Model System for Developmental Biology. Journal of Developmental Biology, 5(3):9, 2017.
Z Mirzoyan, M Sollazzo, M Allocca, A M Valenza, D Grifoni, and P Bellosta. Drosophila melanogaster: A Model Organism to Study Cancer. Frontiers in Genetics, 10, 2019.
M Coll-Tané, A Krebbers, A Castells-Nobau, C Zweier, and A Schenck. Intellectual disability and autism spectrum disorders “on the fly”: insights from Drosophila. Disease Models & Mechanisms, 12(5), 2019.
J C Pendergrass, S D Targum, and J E Harrison. Cognitive Impairment Associated with Cancer: A Brief Review. Innovations in Clinical Neuro- science, 15(1-2):36–44, 2018.
Y Zhang, P Zanos, I L Jackson, X Zhang, X Zhu, T Gould, and Z Vujaskovic. Psychological stress enhances tumor growth and diminishes radiation response in the preclinical model of lung cancer. Radiotherapy and Oncology: Journal of the European Society for Therapeutic Radiology and Oncology, 146:126–135, 2020.
C Donohoe, M O Senge, L G Arnaut, and L C Gomes-Da-Silva. Cell death in photodynamic therapy: From oxidative stress to anti-tumor immunity. Biochimica et Biophysica Acta. Reviews on Cancer, 1872(2):188308–188308, 2019.
N K Badr El-Din, D A Ali, R Othman, S W French, and M Ghoneum. Chemopreventive role of arabinoxylan rice bran, MGN-3/Biobran, on liver carcinogenesis in rats. Biomedicine & Pharma- cotherapy = Biomedicine & Pharmacotherapie, 126, 2020.
C A Cañas, S Castaño-Valencia, F Castro- Herrera, F Cañas, and G J Tobón. Biomedical applications of snake venom: from basic science to autoimmunity and rheumatology. Journal of Translational Autoimmunity, 4:100076, 2021.
B Kalita, A J Saviola, S P Samuel, and A K Mukherjee. State-of-the-art review - A review on snake venom-derived antithrombotics: Potential therapeutics for COVID-19- associated thrombosis? International Journal of Biological Macromolecules, 192:1040–1057, 2021.
D D Nikodijević, J V Jovankić, D M Cvetković, M Z Anđelković, A G Nikezić, and M G Miluti- nović. L-amino acid oxidase from snake venom: Biotransformation and induction of apoptosis in human colon cancer cells. European Journal of Pharmacology, 910:174466– 174466, 2021.
R J Lewis and M L Garcia. Therapeutic potential of venom peptides. Nature Reviews. Drug Discovery, 2(10):790–802, 2003.
L L Vang, A V Medvedev, and J Adler. Simple ways to measure behavioral responses of Drosophila to stimuli and use of these methods to characterize a novel mutant. PloS One, 7(5):e37495, 2012.
W S Neckameyer and P Bhatt. Protocols to Study Behavior in Drosophila. Methods in Molecular Biology (Clifton, N.J.), 1478:303– 320, 2016.
W G Niehaus and B Samuelsson. Formation of malondialdehyde from phospholipid arachidonate during microsomal lipid peroxidation. European Journal of Biochemistry, 6(1):126– 130, 1968.
V M Hill, R M Connor, G B Sissoko, I S Irobunda, S Leong, J C Canman, N Stavropoulos, and M Shirasu-Hiza. A bidirectional relation- ship between sleep and oxidative stress in Drosophila. PLoS Biology, 16(7):e2005206, 2018.
L Li, J Huang, and Y Lin. Snake Venoms in Cancer Therapy: Past, Present, and Future. Toxins, 10(9), 2018.
Y Yang, G Zhang, F Guo, Q Li, H Luo, Y Shu, Y Shen, J Gan, L Xu, and H Yang. Mitochondrial UQCC3 Modulates Hypoxia Adaptation by Orchestrating OXPHOS and Glycoly- sis in Hepatocellular Carcinoma. Cell Reports, 33(5):108340–108340, 2020.
C. L Kuo, H. Y Chou, Y. C Chiu, A N Cheng, C. C Fan, Y. N Chang, C. H Chen, S S Jiang, N. J Chen, and A Y.-L Lee. Mitochondrial oxidative stress by Lon-PYCR1 maintains an immunosuppressive tumor microenvironment that promotes cancer progression and metastasis. Cancer Letters, 474:138–150, 2020.
A Gaya-Bover, R Hernández-López, M Alorda- Clara, J M Ibarra De La Rosa, E Falcó, T Fer- nández, M M Company, M Torrens-Mas, P Roca, J Oliver, J SastreSerra, and D G Pons. Antioxidant enzymes change in different non-metastatic stages in tumoral and peritumoral tissues of colorectal cancer. The International Journal of Biochemistry & Cell Biology, 120:105698, 2020.
K. C Wong, S Sankaran, J J Jayapalan, P Subramanian, and P S Abdul-Rahman. Melatonin improves cognitive behavior, oxidative stress, and metabolism in tumor-prone lethal giant larvae mutant of Drosophila melanogaster. Archives of Insect Biochemistry and Physiology, 107(1):e21785, 2021.
Authors
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Article Details
