Neuroendocrine targets of endocrine disruptors

被引:0
作者
Andrea C. Gore
机构
[1] University of Texas,Center for Molecular and Cellular Toxicology, Division of Pharmacology & Toxicology, College of Pharmacy; Institute for Cellular and Molecular Biology; and Institute for Neuroscience
来源
Hormones | 2010年 / 9卷
关键词
Endocrine disruption; Epigenetic; Fetal basis of adult disease; GnRH; Hypothalamus; Sex differences; Thyroid; Transgenerational;
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学科分类号
摘要
The central neuroendocrine systems are responsible for the control of homeostatic processes in the body, including reproduction, growth, metabolism and energy balance, as well as stress responsiveness. These processes are initiated by signals in the central nervous system, specifically the hypothalamus, and are conveyed first by neural and then by endocrine effectors. The neuroendocrine systems, as the links between the brain and peripheral endocrine organs, play critical roles in the ability of an organism to respond to its environment under normal circumstances. When neuroendocrine homeostasis is disrupted by environmental endocrine-disrupting chemicals, a variety of perturbations can ensue, particularly when endocrine disruption occurs during critical developmental time periods. This article will discuss the evidence for environmental endocrine disruption of neuroendocrine systems and the effects on endocrine and reproductive functions.
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页码:16 / 27
页数:11
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共 239 条
[1]  
Bateman HL(2008)Disrupted female reproductive physiology following neonatal exposure to phytoestrogens or estrogen specific ligands is associated with decreased GnRH activation and kisspeptin fiber density in the hypothalamus Neurotoxicol 29 988-997
[2]  
Patisaul HB(2007)Estrogenic environmental endocrine-disrupting chemical effects on reproductive neuroendocrine function and dysfunction across the life cycle Rev Endocrine Metab Disorders 8 143-159
[3]  
Dickerson SM(1997)Hydroxylated polychlorinated biphenyls (PCBs) as estrogens and antiestrogens: Structure-activity relationships Toxicol Appl Pharmacol 145 111-123
[4]  
Gore AC(1998)Interaction of estrogenic chemicals and phytoestrogens with estrogen receptor beta Endocrinology 139 4252-4263
[5]  
Connor K(2007)Neonatal exposure to bisphenol A modifies the abundance of estrogen receptor a transcripts with alternative 50-untranslated regions in the female rat preoptic area J Endocrinol 194 201-212
[6]  
Ramamoorthy K(2002)Computational studies on biphenyl derivatives. Analysis of the conformational mobility, molecular electrostatic potential, and dipole moment of chlorinated biphenyl: searching for the rationalization of the selective toxicity of polychlorinated biphenyls (PCBs) Chem Res Toxicol 15 1514-1526
[7]  
Moore M(2000)Distribution of mRNAs encoding the arylhydrocarbon receptor, arylhydrocarbon receptor nuclear translocator, and arylhydrocarbon receptor nuclear translocator-2 in the rat brain and brainstem J Comp Neurol 427 428-439
[8]  
Kuiper GG(1959)Organizing action of prenatally administered testosterone propionate on the tissues mediating mating behavior in the female guinea pig Endocrinology 65 369-392
[9]  
Lemmen JG(2008)Steroid-induced sexual differentiation of the developing brain: multiple pathways, one goal J Neurochem 105 1561-1572
[10]  
Carlsson B(2008)Developmental exposures and imprinting on reproductive neuroendocrine systems Front Neuroendocrinol 29 358-374
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