Research progress on the interference effects of plasticizers on maternal behavior and its potential mechanisms.

doi:10.13287/j.1001-9332.202311.028

Abstract

Abstract: Environmental endocrine disrupting chemicals (EDCs), known as environmental hormones, are exogenous chemicals that can disrupt hormone levels and cause dysfunction of the secretory system in humans and animals. Plasticizers, which are widely used EDCs, are commonly used to enhance the flexibility of plastic products. As plastics age and wear, however, they can leach into the environment and enter the bodies of animals through various pathways such as the digestive tract and skin. They can lead to estrogen-like effects and have substantial reproductive toxicity. Residual plasticizer concentrations in the environment are typically low. Unlike high doses that induce acute damage to the reproductive system, low doses of plasticizers do not cause macroscopic harm and thus its reproductive toxicity is often overlooked for extended periods. An increasing number of studies conducted on humans and mice in recent years have demonstrated that low doses of plasticizers can induce reproductive toxicity by interfering with maternal behavior. Prenatal exposure to plasticizers can result in abnormal postnatal maternal behavior. Female offspring also exhibit significantly low maternal care, lactation, and other behaviors in adulthood, which may persist for multiple generations, significantly disrupting the animal breeding process and impacting the health and well-being of newborn pups. The underlying mechanisms have not been systematically summarized. The risk of continuous exposure to low-dose plasticizers in humans and animals has increased due to the extensive utilization of plastic and rubber products in modern production and lifestyle patterns. It is thus crucial to conduct a systematic review on the effects of low-dose plasticizers on maternal behavior. We reviewed the research progress on the disruptive effects of plasticizers on animals’ maternal behavior and concluded that these effects are primarily caused by inducing oxidative stress damage and DNA methylation reprogramming in the hypothalamic-pituitary-ovarian axis, as well as disrupting the balance of the thyroid system and causing intestinal microbial disorders. It would offer a novel perspective for future studies about the influence of plasticizers and other environmental hormones on maternal behavior in domesticated animals.

Key words: plasticizer, environmental endocrine disrupting chemicals, maternal behavior, interference effect, potential mechanism

HAN Chengquan, WANG Hui, WANG Jianwei, LI Fukuan, WANG Zhennan, HU Xiyi, YANG Yan, LYU Shenjin. Research progress on the interference effects of plasticizers on maternal behavior and its potential mechanisms.[J]. Chinese Journal of Applied Ecology, 2023, 34(11): 3157-3168.

References

[1] Carson R. Silent Spring. New York: Penguin Books Ltd, 1962
[2] Chen YX, Yang J, Yao B, et al. Endocrine disrupting chemicals in the environment: Environmental sources, biological effects, remediation techniques, and perspective. Environmental Pollution, 2022, 310: 119918
[3] Koch CA, Diamanti-Kandarakis E. Introduction to Endocrine Disrupting Chemicals: IS it time to act? Reviews in Endocrine and Metabolic Disorders, 2015, 16: 269-270
[4] Annamalai J, Namasivayam V. Endocrine disrupting chemicals in the atmosphere: Their effects on humans and wildlife. Environment International, 2015, 76: 78-97
[5] Ismanto A, Hadibarata T, Kristanti RA, et al. Endocrine disrupting chemicals (EDCs) in environmental matrices: Occurrence, fate, health impact, physio-chemical and bioremediation technology. Environmental Pollution, 2022, 302: 119061
[6] Saha S, Narayanan N, Singh N, et al. Occurrence of endocrine disrupting chemicals (EDCs) in river water, ground water and agricultural soils of India. International Journal of Environmental Science and Technology, 2022, 19: 11459-11474
[7] Kumawat M, Sharma P, Pal N, et al. Occurrence and seasonal disparity of emerging endocrine disrupting chemicals in a drinking water supply system and associa-ted health risk. Scientific Reports, 2022, 12: 9252
[8] Kim J, Yang S, Kim N. Effect of plasticizer dosage on properties of multiple recycled aggregate concrete. Journal of Material Cycles and Waste Management, 2023, 25: 1457-1469
[9] Lu ZZ, Zhang CT, Han CQ, et al. Plasticizer bis(2-ethylhexyl) phthalate causes meiosis defects and decreases fertilization ability of mouse oocytes in vivo. Journal of Agricultural and Food Chemistry, 2019, 67: 3459-3468
[10] Basak S, Das MK, Duttaroy AK. Plastics derived endocrine-disrupting compounds and their effects on early development. Birth Defects Research, 2020, 112: 1308-1325
[11] Adam N, Lachayze MA, Parmentier C, et al. Exposure to environmentally relevant doses of plasticizers alters maternal behavior and related neuroendocrine processes in primiparous and multiparous female mice. Environmental Pollution, 2022, 315: 120487
[12] Della SD, Minder I, Dessi-Fulgheri F, et al. Bisphenol-A exposure during pregnancy and lactation affects maternal behavior in rats. Brain Research Bulletin, 2005, 65: 255-260
[13] Palanza PL, Howdeshell KL, Parmigiani S, et al. Exposure to a low dose of bisphenol A during fetal life or in adulthood alters maternal behavior in mice. Environmental Health Perspectives, 2002, 110: 415-422
[14] López-Rodríguez D, Aylwin CF, Delli V, et al. Multi-and transgenerational outcomes of an exposure to a mixture of endocrine-disrupting chemicals (edcs) on puberty and maternal behavior in the female rat. Environmental Health Perspectives, 2021, 129: 087003
[15] Hou PF, Dai WT, Jin YS, et al. Maternal exposure to di-2-ethylhexyl phthalate (DEHP) depresses lactation capacity in mice. Science of the Total Environment, 2022, 837: 155813
[16] Li XN, Li HX, Yang TN, et al. Di-(2-ethylhexyl) phthalate induced developmental abnormalities of the ovary in quail (Coturnix japonica) via disruption of the hypothalamic-pituitary-ovarian axis. Science of the Total Environment, 2020, 741: 140293
[17] Bereketoglu C, Pradhan A. Plasticizers: Negative impacts on the thyroid hormone system. Environmental Science and Pollution Research, 2022, 29: 38912-38927
[18] Zhang XT, Qi W, Xu Q, et al. Di(2-ethylhexyl) phthalate (DEHP) and thyroid: Biological mechanisms of interference and possible clinical implications. Environmental Science and Pollution Research, 2022, 29: 1634-1644
[19] Liu YJ, Zhou CB, Li F, et al. Stocks and flows of polyvinyl chloride (PVC) in China: 1980-2050. Resources, Conservation and Recycling, 2020, 154: 104584
[20] Rahman M, Brazel CS. The plasticizer market: An assessment of traditional plasticizers and research trends to meet new challenges. Progress in Polymer Science, 2004, 29: 1223-1248
[21] Godwin AD. 24-Plasticizers// Kutz M, ed. Applied Plastics Engineering Handbook. 2nd Ed. New York: William Andrew Publishing, 2017: 533-553
[22] Sun FX, Kang LC, Xiang XL, et al. Recent advances and progress in the detection of bisphenol A. Analytical and Bioanalytical Chemistry, 2016, 408: 6913-6927
[23] Wei XF, Linde E, Hedenqvist MS. Plasticiser loss from plastic or rubber products through diffusion and evaporation. Npj Materials Degradation, 2019, 3: 18
[24] Geyer R, Jambeck JR, Law KL. Production, use, and fate of all plastics ever made. Science Advances, 2017, 3: e1700782
[25] Horn O, Nalli S, Cooper D, et al. Plasticizer metabolites in the environment. Water Research, 2004, 38: 3693-3698
[26] 王佳, 董四君. 邻苯二甲酸二乙基己酯(DEHP)毒理与健康效应研究. 生态毒理学报, 2012, 7(1): 25-34
[27] Nagrockiene D, Pundien I, Kicaite A. The effect of cement type and plasticizer addition on concrete properties. Construction and Building Materials, 2013, 45: 324-331
[28] Aldaher R, Khazaly A, Almahbobi S, et al. Reducing the effect of air pollution due to cement production by using low cement content concrete with same or more efficiency with normal concrete. Key Engineering Materials, 2021, 895: 50-58
[29] Zhang QQ, Ma ZR, Cai YY, et al. Agricultural plastic pollution in China: Generation of plastic debris and emission of phthalic acid esters from agricultural films. Environmental Science & Technology, 2021, 55: 12459-12470
[30] 杨博磊, 张晨曦, 王刚, 等. 花生及花生油中危害物污染调查. 花生学报, 2020, 49(2): 49-53
[31] Kavlock R, Boekelheide K, Chapin R, et al. NTP center for the evaluation of risks to human reproduction: Phthalates expert panel report on the reproductive and developmental toxicity of di-n-butyl phthalate. Reproductive Toxicology, 2002, 16: 489-527
[32] Fromme H, Gruber L, Schlummer M, et al. Intake of phthalates and di(2-ethylhexyl)adipate: Results of the integrated exposure assessment survey based on duplicate diet samples and biomonitoring data. Environment International, 2007, 33: 1012-1020
[33] Shea KM. Pediatric exposure and potential toxicity of phthalate plasticizers. Pediatrics, 2003, 111: 1467-1474
[34] Bosnir J, Puntarić D, Skes I, et al. Migration of phthalates from plastic products to model solutions. Collegium Antropologicum, 2003, 27: 23-30
[35] Rhind SM. Are endocrine disrupting compounds a threat to farm animal health, welfare and productivity? Reproduction in Domestic Animals, 2005, 40: 282-290
[36] Hagmar L, Kesson B, Nielsen J, et al. Mortality and cancer morbidity in workers exposed to low levels of vinyl chloride monomer at a polyvinyl chloride processing plant. American Journal of Industrial Medicine, 1990, 17: 553-565
[37] Maqbool F, Mostafalou S, Bahadar H, et al. Review of endocrine disorders associated with environmental toxicants and possible involved mechanisms. Life Sciences, 2016, 145: 265-273
[38] Eales J, Bethel A, Galloway T, et al. Human health impacts of exposure to phthalate plasticizers: An overview of reviews. Environment International, 2022, 158: 106903
[39] Moral R, Wang R, Russo IH, et al. Effect of prenatal exposure to the endocrine disruptor bisphenol A on mammary gland morphology and gene expression signature. Journal of Endocrinology, 2008, 196: 101-112
[40] Mortensen AS, Arukwe A. The persistent DDT metabolite, 1,1-dichloro-2,2-bis (p-chlorophenyl) ethylene, alters thyroid hormone-dependent genes, hepatic cytochrome P4503A, and pregnane× receptor gene expressions in Atlantic salmon (Salmo salar) parr. Environmental Toxicology and Chemistry, 2006, 25: 1607-1615
[41] Buras A, Battle L, Landers E, et al. Thyroid hormones regulate anxiety in the male mouse. Hormones and Behavior, 2014, 65: 88-96
[42] Quinnies KM, Doyle TJ, Kim KH, et al. Transgenerational effects of di-(2-ethylhexyl) phthalate (DEHP) on stress hormones and behavior. Endocrinology, 2015, 156: 3077-3083
[43] Di Fiore C, De Cristofaro A, Nuzzo A, et al. Biomonitoring of polycyclic aromatic hydrocarbons, heavy metals, and plasticizers residues: Role of bees and honey as bioindicators of environmental contamination. Environmental Science and Pollution Research, 2023, 30: 44234-44250
[44] Guo Y, Zhang ZF, Liu LY, et al. Occurrence and profiles of phthalates in foodstuffs from China and their implications for human exposure. Journal of Agricultural and Food Chemistry, 2012, 60: 6913-6919
[45] 谢婧. 辣椒及其种植环境中邻苯二甲酸酯类检测新方法研究. 硕士论文. 长沙: 中南林业科技大学, 2021
[46] Rilling JK, Young LJ. The biology of mammalian parenting and its effect on offspring social development. Science, 2014, 345: 771-776
[47] Nowak R, Porter RH, Levy F, et al. Role of mother-young interactions in the survival of offspring in domestic mammals. Reviews of Reproduction, 2000, 5: 153-163
[48] 包军. 家畜行为学. 北京: 高等教育出版社, 2008: 116-124
[49] Dwyer CM. Maternal behaviour and lamb survival: From neuroendocrinology to practical application. Animal, 2014, 8: 102-112
[50] Lv SJ, Yang Y, Dwyer CM, et al. Pen size and parity effects on maternal behaviour of small-tail Han sheep. Animal, 2015, 9: 1195-1202
[51] Lv SJ, Yang Y, Li FK. Parity and litter size effects on maternal behavior of small-tail Han sheep in China. Animal Science Journal, 2016, 87: 361-369
[52] Wang H, Han CQ, Li M, et al. Effects of parity, litter size and lamb sex on maternal behavior of small-tail Han sheep and their neuroendocrine mechanisms. Small Ruminant Research, 2021, 202: 106451
[53] Zhou R, Chen F, Feng XJ, et al. Perinatal exposure to low-dose of bisphenol A causes anxiety-like alteration in adrenal axis regulation and behaviors of rat offspring: A potential role for metabotropic glutamate 2/3 receptors. Journal of Psychiatric Research, 2015, 64: 121-129
[54] Lee YJ, Lin HT, Chaudhary MA, et al. Effects of prenatal phthalate exposure and childhood exercise on maternal behaviors in female rats at Postpartum: A role of oxtr methylation in the hypothalamus. International Journal of Molecular Sciences, 2021, 22: 9847
[55] Krishnan K, Rahman S, Hasbum A, et al. Maternal care modulates transgenerational effects of endocrine-disrupting chemicals on offspring pup vocalizations and adult behaviors. Hormones and Behavior, 2019, 107: 96-109
[56] Catanese MC, Vandenberg LN. Bisphenol S (BPS) alters maternal behavior and brain in mice exposed during pregnancy/lactation and their daughters. Endocrinology, 2017, 158: 516-530
[57] 周佩, 蒋子奇, 钏茂巧, 等. DEHP暴露对小鼠神经行为学及脑脂质过氧化物的影响. 环境科学学报, 2012, 32(9): 2339-2345
[58] Quinnies KM, Harris EP, Snyder RW, et al. Direct and transgenerational effects of low doses of perinatal di-(2-ethylhexyl) phthalate (DEHP) on social behaviors in mice. PLoS One, 2017, 12(2): e0171977
[59] Perera F, Nolte ELR, Wang Y, et al. Bisphenol A exposure and symptoms of anxiety and depression among inner city children at 10-12 years of age. Environmental Research, 2016, 151: 195-202
[60] Nadeem A, Al-Harbi NO, Ahmad SF, et al. Exposure to the plasticizer, di-(2-ethylhexyl) phthalate during juvenile period exacerbates autism-like behavior in adult BTBR T+tf/J mice due to DNA hypomethylation and enhanced inflammation in brain and systemic immune cells. Progress in Neuro-Psychopharmacology and Biolo-gical Psychiatry, 2021, 109: 110249
[61] Braun JM, Kalkbrenner AE, Calafat AM, et al. Impact of early-life bisphenol A exposure on behavior and exe-cutive function in children. Pediatrics, 2011, 128: 873-882
[62] Ohtani N, Iwano H, Suda K, et al. Adverse effects of maternal exposure to bisphenol F on the anxiety- and depression-like behavior of offspring. Journal of Veterinary Medical Science, 2017, 79: 432-439
[63] Kawai K, Nozaki T, Nishikata H, et al. Aggressive behavior and serum testosterone concentration during the maturation process of male mice: The effects of fetal exposure to bisphenol A. Environmental Health Perspectives, 2003, 111: 175-178
[64] Braun JM, Yolton K, Dietrich KN, et al. Prenatal bisphenol A exposure and early childhood behavior. Environmental Health Perspectives, 2009, 117: 1945-1952
[65] Perera F, Vishnevetsky J, Herbstman JB, et al. Prenatal bisphenol A exposure and child behavior in an inner-city cohort. Environmental Health Perspectives, 2012, 120: 1190-1194
[66] 王冲. 胚胎期双酚A暴露致雄性仔鼠学习记忆降低的分子机制研究. 博士论文. 太原: 山西农业大学, 2014
[67] Miyagawa K, Narita M, Narita M, et al. Memory impairment associated with a dysfunction of the hippo-campal cholinergic system induced by prenatal and neonatal exposures to bisphenol-A. Neuroscience Letters, 2007, 418: 236-241
[68] 楼张琪, 张雄. 孕鼠DEHP暴露对子代神经行为的影响及其机制. 吉林大学学报: 医学版, 2021, 47(2): 323-329
[69] Wang R, Xu XH, Weng HF, et al. Effects of early pubertal exposure to di-(2-ethylhexyl) phthalate on social behavior of mice. Hormones and Behavior, 2016, 80: 117-124
[70] Lovejoy MC, Graczyk PA, O’hare E, et al. Maternal depression and parenting behavior: A meta-analytic review. Clinical Psychology Review, 2000, 20: 561-592
[71] Moore PS, Whaley SE, Sigman M. Interactions between mothers and children: Impacts of maternal and child anxiety. Journal of Abnormal Psychology, 2004, 113: 471
[72] Nasu M, Abe Y, Matsushima A, et al. Deficient maternal behavior in multiparous Pou3f2 mice is associated with an impaired exploratory activity. Behavioural Brain Research, 2022, 427: 113846
[73] Lévy F, Keller M. Neurobiology of maternal behavior in sheep. Advances in the Study of Behavior, 2008, 38: 399-437
[74] Erhard HW, Rhind SM. Prenatal and postnatal exposure to environmental pollutants in sewage sludge alters emotional reactivity and exploratory behaviour in sheep. Science of the Total Environment, 2004, 332: 101-108
[75] Herreros MA, Gonzalez-Bulnes A, Ligo-Nuez S, et al. Toxicokinetics of di(2-ethylhexyl) phthalate (DEHP) and its effects on luteal function in sheep. Reproductive Biology, 2013, 13: 66-74
[76] Herreros MA, Encinas T, Torres-Rovira L, et al. Exposure to the endocrine disruptor di(2-ethylhexyl) phthalate affects female reproductive features by altering pulsatile LH secretion. Environmental Toxicology and Pharmacology, 2013, 36: 1141-1149
[77] Ellis BJ. The hypothalamic-pituitary-gonadal axis: A switch-controlled, condition-sensitive system in the regu-lation of life history strategies. Hormones and Behavior, 2013, 64: 215-225
[78] Rhind SM, Evans NP, Bellingham M, et al. Effects of environmental pollutants on the reproduction and welfare of ruminants. Animal, 2010, 4: 1227-1239
[79] Herreros MA, Gonzalez-Bulnes A, Iñigo-Nuñez S, et al. Pregnancy-associated changes in plasma concentration of the endocrine disruptor di-(2-ethylhexyl) phthalate in a sheep model. Theriogenology, 2010, 73: 141-146
[80] Berni M, Gigante P, Bussolati S, et al. Bisphenol S, a Bisphenol A alternative, impairs swine ovarian and adipose cell functions. Domestic Animal Endocrinology, 2019, 66: 48-56
[81] Liu T, Li N, Zhu J, et al. Effects of di-(2-ethylhexyl) phthalate on the hypothalamus-pituitary-ovarian axis in adult female rats. Reproductive Toxicology, 2014, 46: 141-147
[82] Hirosawa N, Yano K, Suzuki Y, et al. Endocrine disrupting effect of di-(2-ethylhexyl) phthalate on female rats and proteome analyses of their pituitaries. Proteomics, 2006, 6: 958-971
[83] Panagiotou EM, Ojasalo V, Damdimopoulou P. Phtha-lates, ovarian function and fertility in adulthood. Best Practice & Research Clinical Endocrinology & Metabolism, 2021, 35: 101552
[84] Davis BJ, Maronpot RR, Heindel JJ. Di-(2-ethylhexyl) phthalate suppresses estradiol and ovulation in cycling rats. Toxicology and Applied Pharmacology, 1994, 128: 216-223
[85] Riddle O, Lahr EL, Bates RW. The role of hormones in the initiation of maternal behavior in rats. American Journal of Physiology-Legacy Content, 1942, 137: 299-317
[86] Chen YB, Chen XT, Li XY, et al. Effects of bisphenol AF on growth, behavior, histology and gene expression in marine medaka (Oryzias melastigma). Chemosphere, 2022, 308: 136424
[87] Rebuli ME, Cao J, Sluzas E, et al. Investigation of the effects of subchronic low dose oral exposure to bisphenol A (BPA) and ethinyl estradiol (EE) on estrogen receptor expression in the juvenile and adult female rat hypothalamus. Toxicological Sciences, 2014, 140: 190-203
[88] Shi M, Sekulovski N, Maclean JA, et al. Prenatal exposure to bisphenol a analogues on female reproductive functions in mice. Toxicological Sciences, 2019, 168: 561-571
[89] Hill CE, Sapouckey SA, Suvorov A, et al. Developmental exposures to bisphenol S, a BPA replacement, alter estrogen-responsiveness of the female reproductive tract: A pilot study. Cogent Medicine, 2017, 4: 1317690
[90] Wang Y, Zhu QL, Dang X, et al. Local effect of bisphenol A on the estradiol synthesis of ovarian granulosa cells from PCOS. Gynecological Endocrinology, 2017, 33: 21-25
[91] Özel ş, Tokmak A, Aykut O, et al. Serum levels of phthalates and bisphenol-A in patients with primary ovarian insufficiency. Gynecological Endocrinology, 2019, 35: 364-367
[92] Akgül S, Sur Ü, Düzçeker Y, et al. Bisphenol A and phthalate levels in adolescents with polycystic ovary syndrome. Gynecological Endocrinology, 2019, 35: 1084-1087
[93] Li L, Zhang T, Qin XS, et al. Exposure to diethylhexyl phthalate (DEHP) results in a heritable modification of imprint genes DNA methylation in mouse oocytes. Molecular Biology Reports, 2014, 41: 1227-1235
[94] Barker DJ. The fetal and infant origins of adult disease. British Medical Journal, 1990, 301: 1111
[95] Yang C, Song G, Lim W. A mechanism for the effect of endocrine disrupting chemicals on placentation. Chemosphere, 2019, 231: 326-336
[96] Tang ZR, Xu XL, Deng SL, et al. Oestrogenic endocrine disruptors in the placenta and the fetus. International Journal of Molecular Sciences, 2020, 21: 1519
[97] Bigsby RM, Caperell-Grant A, Madhukar BV. Xenobio-tics released from fat during fasting produce estrogenic effects in ovariectomized mice. Cancer Research, 1997, 57: 865-869
[98] Mcdonough CM, Xu HS, Guo TL. Toxicity of bisphenol analogues on the reproductive, nervous, and immune systems, and their relationships to gut micro-biome and metabolism: Insights from a multi-species comparison. Critical Reviews in Toxicology, 2021, 51: 283-300
[99] Grabrucker S, Pagano J, Schweizer J, et al. Activation of the medial preoptic area (MPOA) ameliorates loss of maternal behavior in a Shank2 mouse model for autism. The EMBO Journal, 2021, 40: e104267
[100] Santos K, Mazzola T, Carvalho H. The prima donna of epigenetics: The regulation of gene expression by DNA methylation. Brazilian Journal of Medical Biological Research, 2005, 38: 1531-1541
[101] Kim M, Costello J. DNA methylation: An epigenetic mark of cellular memory. Experimental & Molecular Medicine, 2017, 49: e322
[102] Carcea I, Caraballo NL, Marlin BJ, et al. Oxytocin neurons enable social transmission of maternal beha-viour. Nature, 2021, 596: 553-557
[103] Fahrbach SE, Morrell JI, Pfaff DW. Oxytocin induction of short-latency maternal behavior in nulliparous, estrogen-primed female rats. Hormones and Behavior, 1984, 18: 267-286
[104] Numan M. Progesterone inhibition of maternal behavior in the rat. Hormones and Behavior, 1978, 11: 209-231
[105] Mann PE, Kinsley CH, Bridges RS. Opioid receptor subtype involvement in maternal behavior in lactating rats. Neuroendocrinology, 1991, 53: 487-492
[106] Bosch OJ, Neumann ID. Brain vasopressin is an important regulator of maternal behavior independent of dams’ trait anxiety. Proceedings of the National Academy of Sciences of the United States of America, 2008, 105: 17139-17144
[107] Davies P, Cicchetti D, Hentges RF. Maternal unresponsiveness and child disruptive problems: The interplay of uninhibited temperament and dopamine transpor-ter genes. Child Development, 2015, 86: 63-79
[108] Bridges RS. Neuroendocrine regulation of maternal behavior. Frontiers in Neuroendocrinology, 2015, 36: 178-196
[109] Keller SM, Doherty TS, Roth TL. Pharmacological manipulation of DNA methylation normalizes maternal behavior, DNA methylation, and gene expression in dams with a history of maltreatment. Scientific Reports, 2019, 9: 10253
[110] Numan M, Rosenblatt JS, Komisaruk BR. Medial preoptic area and onset of maternal behavior in the rat. Journal of Comparative and Physiological Psychology, 1977, 91: 146
[111] Fahrbach SE, Pfaff DW. Effect of preoptic region implants of dilute estradiol on the maternal behavior of ovariectomized, nulliparous rats. Hormones and Beha-vior, 1986, 20: 354-363
[112] Giordano AL, Siegel HI, Rosenblatt JS. Nuclear estrogen receptor binding in microdissected brain regions of female rats during pregnancy: Implications for maternal and sexual behavior. Physiology & Behavior, 1991, 50: 1263-1267
[113] Champagne FA, Weaver ICG, Diorio J, et al. Maternal care associated with methylation of the estrogen receptor-α1b promoter and estrogen receptor-α expression in the medial preoptic area of female offspring. Endocrinology, 2006, 147: 2909-2915
[114] Yaoi T, Itoh K, Nakamura K, et al. Genome-wide analysis of epigenomic alterations in fetal mouse forebrain after exposure to low doses of bisphenol A. Biochemical and Biophysical Research Communications, 2008, 376: 563-567
[115] Doshi T, Mehta SS, Dighe V, et al. Hypermethylation of estrogen receptor promoter region in adult testis of rats exposed neonatally to bisphenol A. Toxicology, 2011, 289: 74-82
[116] Chan KS, Mu LB. DNA Methylation of estrogen receptor α gene by phthalates. Journal of Toxicology and Environmental Health Part A, 2005, 68: 1995-2003
[117] Chen CH, Jiang SS, Chang IS, et al. Association between fetal exposure to phthalate endocrine disruptor and genome-wide DNA methylation at birth. Environmental Research, 2018, 162: 261-270
[118] Kang ER, Iqbal K, Tran DA, et al. Effects of endocrine disruptors on imprinted gene expression in the mouse embryo. Epigenetics, 2011, 6: 937-950
[119] Li LL, Keverne E, Aparicio S, et al. Regulation of maternal behavior and offspring growth by paternally expressed Peg3. Science, 1999, 284: 330-334
[120] Tindula G, Murphy SK, Grenier C, et al. DNA methylation of imprinted genes in Mexican-American newborn children with prenatal phthalate exposure. Epigeno-mics, 2018, 10: 1011-1026
[121] Okano M, Bell DW, Haber DA, et al. DNA Methyltransferases Dnmt3a and Dnmt3b are essential for De Novo methylation and mammalian development. Cell, 1999, 99: 247-257
[122] Kohli RM, Zhang Y. TET enzymes, TDG and the dynamics of DNA demethylation. Nature, 2013, 502: 472-479
[123] Rattan S, Beers HK, Kannan A, et al. Prenatal and ancestral exposure to di(2-ethylhexyl) phthalate alters gene expression and DNA methylation in mouse ovaries. Toxicology and Applied Pharmacology, 2019, 379: 114629
[124] Yuan C, Zhang Y, Liu Y, et al. DNA demethylation mediated by down-regulated TETs in the testes of rare minnow Gobiocypris rarus under bisphenol A exposure. Chemosphere, 2017, 171: 355-361
[125] Zhang XF, Zhang LJ, Li L, et al. Diethylhexyl phthalate exposure impairs follicular development and affects oocyte maturation in the mouse. Environmental & Molecular Mutagenesis, 2013, 54: 354-361
[126] Evans MD, Griffiths HR, Lunec J. Reactive Oxygen Species and their Cytotoxic Mechanisms// Bittar EE, ed. Advances in Molecular and Cell Biology. Emostertan: Elsevier, 1997: 25-73
[127] D’autréaux B, Toledano MB. ROS as signalling molecules: Mechanisms that generate specificity in ROS homeostasis. Nature Reviews Molecular Cell Biology, 2007, 8: 813-824
[128] Ray PD, Huang BW, Tsuji Y. Reactive oxygen species (ROS) homeostasis and redox regulation in cellular signaling. Cellular Signalling, 2012, 24: 981-990
[129] Betteridge DJ. What is oxidative stress? Metabolism, 2000, 49: 3-8
[130] Liu M, Jia SL, Dong T, et al. The occurrence of bisphenol plasticizers in paired dust and urine samples and its association with oxidative stress. Chemosphere, 2019, 216: 472-478
[131] Schaffert A, Karkossa I, Ueberham E, et al. Di-(2-ethylhexyl) phthalate substitutes accelerate human adipogenesis through PPARγ activation and cause oxidative stress and impaired metabolic homeostasis in mature adipocytes. Environment International, 2022, 164: 107279
[132] Tu ZH, Mu XY, Chen XM, et al. Dibutyl phthalate exposure disrupts the progression of meiotic prophase Ⅰ by interfering with homologous recombination in fetal mouse oocytes. Environmental Pollution, 2019, 252: 388-398
[133] Jia ZZ, Wang HY, Feng ZY, et al. Fluorene-9-bisphenol exposure induces cytotoxicity in mouse oocytes and causes ovarian damage. Ecotoxicology and Environmental Safety, 2019, 180: 168-178
[134] Huang MQ, Liu S, Fu L, et al. Bisphenol A and its analogues bisphenol S, bisphenol F and bisphenol AF induce oxidative stress and biomacromolecular damage in human granulosa KGN cells. Chemosphere, 2020, 253: 126707
[135] Ugwor EI, Dosumu OA, Eteng OE, et al. Morin atte-nuates neurobehavioural deficits, hippocampal oxidative stress, inflammation, and apoptosis in rats co-exposed to bisphenol S and diethyl phthalate. Brain Research, 2022, 1794: 148068
[136] Doufas AG, Mastorakos G. The hypothalamic-pituitary-thyroid axis and the female reproductive system. Annals of the New York Academy of Sciences, 2000, 900: 65-76
[137] Gy H, Kulcszr M, Rudas P. Clinical endocrinology of thyroid gland function in ruminants. Veterinarni medi-cina, 2002, 47: 199-210
[138] Liu CJ, Zhao LT, Wei L, et al. DEHP reduces thyroid hormones via interacting with hormone synthesis-related proteins, deiodinases, transthyretin, receptors, and hepatic enzymes in rats. Environmental Science and Pollution Research, 2015, 22: 12711-12719
[139] Cryan JF, Dinan TG. Mind-altering microorganisms: The impact of the gut microbiota on brain and beha-viour. Nature Reviews Neuroscience, 2012, 13: 701-712
[140] Mayer EA, Tillisch K, Gupta A. Gut/brain axis and the microbiota. The Journal of Clinical Investigation, 2015, 125: 926-938
[141] Labus JS, Osadchiy V, Hsiao EY, et al. Evidence for an association of gut microbial Clostridia with brain functional connectivity and gastrointestinal sensorimotor function in patients with irritable bowel syndrome, based on tripartite network analysis. Microbiome, 2019, 7: 45
[142] 沈馨, 孙志宏. 微生物-肠-脑轴与神经系统疾病的研究进展. 生物工程学报, 2021, 37: 3781-3788
[143] Hattori N, Yamashiro Y. The gut-brain axis. Annals of Nutrition and Metabolism, 2021, 77: 1-3
[144] Zheng P, Wu J, Zhang H, et al. The gut microbiome modulates gut-brain axis glycerophospholipid metabolism in a region-specific manner in a nonhuman primate model of depression. Molecular Psychiatry, 2021, 26: 2380-2392
[145] Li Q, Korzan WJ, Ferrero DM, et al. Synchronous evolution of an odor biosynthesis pathway and behavioral response. Current Biology, 2013, 23: 11-20
[146] Francis AP, Dominguez-Bello MG. Early-life microbiota perturbations and behavioral effects. Trends in Micro-biology, 2019, 27: 567-569
[147] Tang JQ, Yuan Y, Wei CX, et al. Neurobehavioral changes induced by di(2-ethylhexyl) phthalate and the protective effects of vitamin E in Kunming mice. Toxi-cology Research, 2015, 4: 1006-1015
[148] Sun GC, Lee YJ, Lee YC, et al. Exercise prevents the impairment of learning and memory in prenatally phthalate-exposed male rats by improving the expression of plasticity-related proteins. Behavioural Brain Research, 2021, 413: 113444
[149] Sun SW, Tan YZ, Wang LY, et al. Improving the activity and expression level of a phthalate-degrading enzyme by a combination of mutagenesis strategies and strong promoter replacement. Environmental Science and Pollution Research, 2023, 30: 41107-41119