新生大鼠啶虫脒亚慢性暴露致成年后神经系统毒性的研究
Sub-chronic Exposure to Acetamiprid in Neonatal Rats Leads to Neurotoxicity in Adulthood
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摘要: 观察新生大鼠啶虫脒(acetamiprid, ACE)慢暴露对成年后神经行为、大脑皮质与海马的影响。选择出生一周的雄性Sprague-Dawley (SD)大鼠18只,随机分为对照组(Control)、ACE-15组(15 mg·kg-1·d-1)、ACE-40组(40 mg·kg-1·d-1),每组6只。ACE暴露组灌胃干预9周,期间每周检测体质量。采用开放旷场实验(OFT)、Morris水迷宫(MWM)检测大鼠行为学变化;采用试剂盒检测大脑皮质和海马组织中丙二醛(MDA)和超氧化物歧化酶(SOD)水平;采用Western Blot法检测白细胞介素IL-1β、IL-10蛋白表达量;采用苏木精-伊红(H&E)染色法检测大脑皮质和海马组织病理学改变;采用Nissl染色法检测大脑海马DG、CA3区神经元变化。OFT结果显示,与对照组相比,ACE暴露组大鼠在中央区运动距离和时间均减少。MWM结果显示,定位巡航期间,暴露组逃逸潜伏期时间增加,目标象限停留时间减少。空间探索期间,ACE-40组跨平台次数减少,目标象限内游泳速度降低。暴露组大鼠脑皮质和海马组织中MDA浓度增高;暴露组大鼠脑皮质SOD活性降低,海马组织SOD活性增高。Western Blot结果显示,与对照组相比,暴露组大鼠皮质和海马组织中IL-1β表达量增高;IL-10表达量降低。H&E结果显示,ACE-40组海马DG、CA3区神经元出现排列紊乱、层数减少和轮廓模糊。Nissl染色结果显示,暴露组大鼠海马DG、CA3区神经元数量减少,尼氏小体减少。以上结果表明,新生大鼠ACE亚慢性暴露能够导致成年后神经行为变化,可能与脑皮质和海马组织的氧化应激与炎症有关。Abstract: To observe the effects of sub-chronic exposure to acetamiprid (ACE) in neonatal rats on neurobehavior, cerebral cortex, and hippocampus in adulthood. 18 one-week-old male Sprague-Dawley (SD) rats were randomly divided into control group, ACE-15 group (15 mg·kg-1·d-1) and ACE-40 group (40 mg·kg-1·d-1), with 6 rats in each group (n=6). The ACE-exposed groups were given gavage intervention for 9 weeks, during which body weight was measured weekly. Open field test (OFT) and Morris water maze (MWM) were used for neurobehavioral assessment in SD rats; malondialdehyde (MDA) and superoxide dismutase (SOD) levels in cerebral cortex and hippocampus were detected by ELISA kits; IL-1β and IL-10 expression were detected by Western Blot; hematoxylin and eosin (H&E) staining was used to detect histopathological changes in cerebral cortex and hippocampus; Nissl staining was used to detect neuronal changes in the DG and CA3 regions of the hippocampus. The OFT results showed that the movement distance and duration of movement in the central zone were reduced in the ACE-exposed groups rats compared to the control group. The MWM results showed that the escape latency was increased and the target quadrant residence was decreased in the ACE-exposed group compared with the control group; the target crossing was decreased and the swimming speed in the target quadrant was decreased in the ACE-40 group. The MDA level was increased in the cerebral cortex and hippocampus, whereas the SOD content was decreased in the cerebral cortex but increased in the hippocampus in ACE-exposed groups. Higher expression of IL-1β and lower expression of IL-10 in the cerebral cortex and hippocampus were also detected in ACE-exposed groups in contrast to the control rats. Disorders of neuronal arrangement, reduced cell layers, and reduced Nissl bodies in the DG and CA3 regions of the hippocampus were observed in ACE-exposed rats. The above results suggest that sub-chronic exposure to ACE in neonatal rats can lead to neurobehavioral changes in adulthood, which may be related to oxidative stress and inflammation in the cerebral cortex and hippocampus.
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Key words:
- acetamiprid /
- SD rats /
- sub-chronic exposure /
- neurobehavior /
- neurotoxicity
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Bass C, Denholm I, Williamson M S, et al. The global status of insect resistance to neonicotinoid insecticides[J]. Pesticide Biochemistry and Physiology, 2015, 121: 78-87 Taillebois E, Cartereau A, Jones A K, et al. Neonicotinoid insecticides mode of action on insect nicotinic acetylcholine receptors using binding studies[J]. Pesticide Biochemistry and Physiology, 2018, 151: 59-66 Katić A, Kašuba V, Kopjar N, et al. Effects of low-level imidacloprid oral exposure on cholinesterase activity, oxidative stress responses, and primary DNA damage in the blood and brain of male Wistar rats[J]. Chemico-Biological Interactions, 2021, 338: 109287 Chen M, Tao L, McLean J, et al. Quantitative analysis of neonicotinoid insecticide residues in foods: Implication for dietary exposures[J]. Journal of Agricultural and Food Chemistry, 2014, 62(26): 6082-6090 Menon M, Mohanraj R, Sujata W. Monitoring of neonicotinoid pesticides in water-soil systems along the agro-landscapes of the Cauvery delta region, South India[J]. Bulletin of Environmental Contamination and Toxicology, 2021, 106(6): 1065-1070 Cycoń M, Piotrowska-Seget Z. Biochemical and microbial soil functioning after application of the insecticide imidacloprid[J]. Journal of Environmental Sciences, 2015, 27: 147-158 Hladik M L, Kolpin D W, Kuivila K M. Widespread occurrence of neonicotinoid insecticides in streams in a high corn and soybean producing region, USA[J]. Environmental Pollution, 2014, 193: 189-196 Morrissey C A, Mineau P, Devries J H, et al. Neonicotinoid contamination of global surface waters and associated risk to aquatic invertebrates: A review[J]. Environment International, 2015, 74: 291-303 The Food and Agriculture Organization. 5.2 acetamiprid (246) toxicology[EB/OL]. (2019-03-28)[2022-09-14] http://www.fao.org/fileadmin/templates/agphome/documents/Pests_Pesticides/JMPR/Report11/Acetamiprid.pdf Zhao G P, Yang F W, Li J W, et al. Toxicities of neonicotinoid-containing pesticide mixtures on nontarget organisms[J]. Environmental Toxicology and Chemistry, 2020, 39(10): 1884-1893 Wang H X, Yang D J, Fang H J, et al. Predictors, sources, and health risk of exposure to neonicotinoids in Chinese school children: A biomonitoring-based study[J]. Environment International, 2020, 143: 105918 Hirai A, Sugio S, Nimako C, et al. Ca2+ imaging with two-photon microscopy to detect the disruption of brain function in mice administered neonicotinoid insecticides[J]. Scientific Reports, 2022, 12(1): 1-13 Brunet J L, Maresca M, Fantini J, et al. Intestinal absorption of the acetamiprid neonicotinoid by Caco-2 cells: Transepithelial transport, cellular uptake and efflux[J]. Journal of Environmental Science and Health Part B, Pesticides, Food Contaminants, and Agricultural Wastes, 2008, 43(3): 261-270 Kavvalakis M P, Tzatzarakis M N, Theodoropoulou E P, et al. Development and application of LC-APCI-MS method for biomonitoring of animal and human exposure to imidacloprid[J]. Chemosphere, 2013, 93(10): 2612-2620 Todani M, Kaneko T, Hayashida H, et al. Acute poisoning with neonicotinoid insecticide acetamiprid[J]. The Japanese Journal of Toxicology, 2008, 21(4): 387-390 Nakayama A, Yoshida M, Kagawa N, et al. The neonicotinoids acetamiprid and imidacloprid impair neurogenesis and alter the microglial profile in the hippocampal dentate gyrus of mouse neonates[J]. Journal of Applied Toxicology, 2019, 39(6): 877-887 EFSA Panel on Plant Protection Products and their Residues (PPR). Scientific Opinion on the developmental neurotoxicity potential of acetamiprid and imidacloprid[J]. EFSA Journal, 2013, 11(12): 3471 Simon-Delso N, Amaral-Rogers V, Belzunces L P, et al. Systemic insecticides (neonicotinoids and fipronil): Trends, uses, mode of action and metabolites[J]. Environmental Science and Pollution Research, 2015, 22(1): 5-34 Aseperi A K, Busquets R, Hooda P S, et al. Behaviour of neonicotinoids in contrasting soils[J]. Journal of Environmental Management, 2020, 276: 111329 Loser D, Hinojosa M G, Blum J, et al. Functional alterations by a subgroup of neonicotinoid pesticides in human dopaminergic neurons[J]. Archives of Toxicology, 2021, 95(6): 2081-2107 Gasmi S, Kebieche M, Rouabhi R, et al. Alteration of membrane integrity and respiratory function of brain mitochondria in the rats chronically exposed to a low dose of acetamiprid[J]. Environmental Science and Pollution Research, 2017, 24(28): 22258-22264 Karaca B U, Arican Y E, Boran T, et al. Toxic effects of subchronic oral acetamiprid exposure in rats[J]. Toxicology and Industrial Health, 2019, 35(11-12): 679-687 Kagawa N, Nagao T. Neurodevelopmental toxicity in the mouse neocortex following prenatal exposure to acetamiprid[J]. Journal of Applied Toxicology, 2018, 38(12): 1521-1528 Dhouib I B, Annabi A, Doghri R, et al. Neuroprotective effects of curcumin against acetamiprid-induced neurotoxicity and oxidative stress in the developing male rat cerebellum: Biochemical, histological, and behavioral changes[J]. Environmental Science and Pollution Research International, 2017, 24(35): 27515-27524 Shamsi M, Soodi M, Shahbazi S, et al. Effect of acetamiprid on spatial memory and hippocampal glutamatergic system[J]. Environmental Science and Pollution Research International, 2021, 28(22): 27933-27941 胡爱萍, 周红宇, 秦晓怡. 甲醛对小鼠的学习记忆及脑组织抗氧化酶的影响[J]. 环境与健康杂志, 2007, 24(9): 686-688 Hu A P, Zhou H Y, Qin X Y. Effects of formaldehyde on learning, memory and activity of antioxidase in cerebral tissues of mice[J]. Journal of Environment and Health, 2007, 24(9): 686-688(in Chinese)
Mandal P, Mondal S, Karnam S S, et al. A behavioral study on learning and memory in adult Sprague Dawley rat in induced acetamiprid toxicity[J]. Exploratory Animal and Medical Research, 2015, 5: 27-32 Ford K A, Casida J E. Chloropyridinyl neonicotinoid insecticides: Diverse molecular substituents contribute to facile metabolism in mice[J]. Chemical Research in Toxicology, 2006, 19(7): 944-951 Abd-Elhakim Y M, Mohammed H H, Mohamed W A M. Imidacloprid impacts on neurobehavioral performance, oxidative stress, and apoptotic events in the brain of adolescent and adult rats[J]. Journal of Agricultural and Food Chemistry, 2018, 66(51): 13513-13524 Bhardwaj S, Srivastava M K, Kapoor U, et al. A 90 days oral toxicity of imidacloprid in female rats: Morphological, biochemical and histopathological evaluations[J]. Food and Chemical Toxicology, 2010, 48(5): 1185-1190 Agrawal A, Sharma B. Pesticides induced oxidative stress in mammalian systems: A review[J]. International Journal of Biological & Medical Research, 2010, 1(3): 90-104 Salim S. Oxidative stress and the central nervous system[J]. Journal of Pharmacology and Experimental Therapeutics, 2016, 360(1): 201-205 Annabi E, Ben Salem I, Abid-Essefi S. Acetamiprid, a neonicotinoid insecticide, induced cytotoxicity and genotoxicity in PC12 cells[J]. Toxicology Mechanisms and Methods, 2019, 29(8): 580-586 Panemangalore M, Bebe F N. Dermal exposure to pesticides modifies antioxidant enzymes in tissues of rats[J]. Journal of Environmental Science and Health, Part B, 2000, 35(4): 399-416 Terayama H, Endo H, Tsukamoto H, et al. Acetamiprid accumulates in different amounts in murine brain regions[J]. International Journal of Environmental Research and Public Health, 2016, 13(10): 937 Taylor J M, Main B S, Crack P J. Neuroinflammation and oxidative stress: Co-conspirators in the pathology of Parkinson's disease[J]. Neurochemistry International, 2013, 62(5): 803-819 Lopez-Rodriguez A B, Hennessy E, Murray C L, et al. Acute systemic inflammation exacerbates neuroinflammation in Alzheimer's disease: IL-1β drives amplified responses in primed astrocytes and neuronal network dysfunction[J]. Alzheimer's & Dementia, 2021, 17(10): 1735-1755 Lee G H, Choi K C. Adverse effects of pesticides on the functions of immune system[J]. Comparative Biochemistry and Physiology Part C: Toxicology & Pharmacology, 2020, 235: 108789 Mendiola A S, Cardona A E. The IL-1β phenomena in neuroinflammatory diseases[J]. Journal of Neural Transmission, 2018, 125(5): 781-795 Santhanasabapathy R, Vasudevan S, Anupriya K, et al. Farnesol quells oxidative stress, reactive gliosis and inflammation during acrylamide-induced neurotoxicity: Behavioral and biochemical evidence[J]. Neuroscience, 2015, 308: 212-227 -
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