Interacting Impact of Adrenal and Ovarian Aging on the CNS

肾上腺和卵巢衰老对中枢神经系统的相互作用影响

基本信息

批准号：
7317131
负责人：
HENRYK F URBANSKI
金额：
$ 53.74万
依托单位：
OREGON HEALTH & SCIENCE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2007
资助国家：
美国
起止时间：
2007-09-01 至 2012-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7317131
关键词：
10 year old 21 year old Acetylcholine Activity Cycles Adrenal Glands Adult Age Age-associated memory impairment Aging Amygdaloid structure Animal Model Animals Area Attention Autopsy Behavior Behavior assessment Behavioral Biochemical Blood Circulation Brain Brain region Characteristics Circadian Rhythms Cognition Cognitive Cues Data Development Disease Dopamine Elderly Endocrine Enzymatic Biochemistry Enzymes Estradiol Estrogens Event Female Follicle Stimulating Hormone Foundations Functional disorder Future Genes Glutamates Goals Gonadal Steroid Hormones Health Hippocampus (Brain)Histocytochemistry Hormonal Change Hormone replacement therapy Hormones Human Immunoassay Immunohistochemistry Impaired cognition In Situ Hybridization Inorganic Sulfates Laboratories Learning Macaca mulatta Magnetic Resonance Imaging Memory Menopause Methodology Monitor Nervous System Physiology Neuraxis Neurosecretory Systems Neurotransmitters Norepinephrine Oregon Output Ovarian Ovarian Tissue Ovary Perimenopause Periodicity Physiological Physiological Processes Physiology Plasma Play Postmenopause Prefrontal Cortex Premenopause Primates Production Progesterone Radioimmunoassay Receptor Gene Research Research Personnel Reverse Transcriptase Polymerase Chain Reaction Risk Role Sampling Series Short-Term Memory Sleep Sleep Wake Cycle Solid Source Steroid Receptors Steroids System Testing Time Tissues Unspecified or Sulfate Ion Sulfates Visual attention Visuospatial Woman age related attenuation base behavior test brain morphology circadian pacemaker cognitive function dehydroepiandrosterone design falls gamma-Aminobutyric Acid in vivo Model inhibin B insight nonhuman primate programs protective effect response stem therapy development young adult

项目摘要

DESCRIPTION (provided by applicant): A characteristic feature of the menopause is a marked attenuation in the production and release of ovarian steroids, such as estradiol and progesterone. However, the impact of these changes on human physiology, especially within the central nervous system (CNS), is far from being clear. We have already shown that female rhesus macaques, like women, undergo menopause, and that a change in plasma FSH and inhibin B levels represents the first endocrine manifestation of this event. We have also shown that plasma levels of the adrenal steroid, dehydroepiandrosterone (DHEA), fall markedly around this time. DHEA is one of the most abundant steroids in the circulation; it is released into the circulation in a circadian manner and is readily converted to estradiol in many tissues. The overall aim of this proposal is to examine the interacting impact of adrenal and ovarian aging on the CNS of primates. Using the female rhesus macaque as a pragmatic animal model, we propose to test the hypothesis that the aging-related attenuation of DHEA release exacerbates the perimenopausal decline in estradiol, and thereby negatively impacts central physiological processes such as cognition, learning, and attention, and leads to perturbation of the circadian sleep-wake cycle. Specific Aim 1 will use a battery of behavioral tests to assess differences between young adults, old regularly-cycling and irregularly-cycling adults, and old ovariectomized adults; the old animals will be tested both as untreated controls and also after extended treatment with "young" physiological levels of DHEA. Cognitive and behavioral assessments will include: 1) delayed response test of spatial working memory, which is particularly sensitive to aging and prefrontal cortex dysfunction; 2) delayed non- matching-to-sample, a task probing primarily hippocampus-based memory; 3) a visuospatial cueing test of visual attention that is estrogen-sensitive; and 4) a test of behavioral reactivity sensitive to amygdala damage. In addition, sleep-wake cycles will be continuously monitored using Actiwatch recorders, and MRI will be performed before and after DHEA replacement to monitor morphological and biochemical changes in the key brain regions. Specific Aim 2 will use a series of biochemical and histochemical methodologies to elucidate the plasticity that occurs within the CNS during adrenal-ovarian aging. Gene microarrays and RT-PCR will be used to identify genes that are differentially expressed in the CNS between young and old animals, regular and irregular old cyclers, and DHEA-treated and untreated old animals. The focus will be on genes encoding enzymes involved in the conversion of DHEA to estradiol, steroid receptors, and genes associated with key neurotransmitters systems and circadian clocks. Immunohistochemistry, in situ hybridization histochemistry, RIA and biochemical enzymology will be used to corroborate the results. By elucidating the interacting impact of declining ovarian and adrenal steroids on CNS function, we expect to lay a foundation for the development of therapies for many aging-associated disorders in women.

描述（由申请人提供）：更年期的一个特征是卵巢类固醇（例如雌二醇和黄体酮）的产生和释放显着减弱。然而，这些变化对人类生理学的影响，特别是对中枢神经系统（CNS）的影响，目前还不清楚。我们已经证明，雌性恒河猴与女性一样，都会经历更年期，血浆 FSH 和抑制素 B 水平的变化代表了这一事件的第一个内分泌表现。我们还发现，肾上腺类固醇脱氢表雄酮 (DHEA) 的血浆水平在此时显着下降。 DHEA 是循环中最丰富的类固醇之一；它以昼夜节律的方式释放到循环中，并且很容易在许多组织中转化为雌二醇。该提案的总体目标是研究肾上腺和卵巢衰老对灵长类动物中枢神经系统的相互作用影响。使用雌性恒河猴作为实用动物模型，我们建议检验以下假设：与衰老相关的 DHEA 释放减弱会加剧围绝经期雌二醇的下降，从而对认知、学习和注意力等中枢生理过程产生负面影响。导致昼夜节律睡眠-觉醒周期的扰动。具体目标 1 将使用一系列行为测试来评估年轻人、定期骑车和不定期骑车的老年人以及切除卵巢的老年人之间的差异；年老的动物将作为未经治疗的对照以及经过“年轻”生理水平的 DHEA 长期治疗后进行测试。认知和行为评估将包括：1）空间工作记忆的延迟反应测试，该测试对衰老和前额皮质功能障碍特别敏感； 2）延迟样本不匹配，这是一项主要探测基于海马体的记忆的任务； 3）雌激素敏感的视觉注意力视觉空间提示测试； 4) 对杏仁核损伤敏感的行为反应性测试。此外，将使用 Actiwatch 记录仪持续监测睡眠-觉醒周期，并在 DHEA 替代前后进行 MRI，以监测关键大脑区域的形态和生化变化。具体目标 2 将使用一系列生化和组织化学方法来阐明肾上腺-卵巢衰老过程中中枢神经系统内发生的可塑性。基因微阵列和 RT-PCR 将用于识别年轻和年老动物、规则和不规则的老年循环者以及 DHEA 处理和未处理的老年动物之间中枢神经系统中差异表达的基因。重点是编码参与 DHEA 转化为雌二醇、类固醇受体的酶的基因，以及与关键神经递质系统和生物钟相关的基因。免疫组织化学、原位杂交组织化学、RIA和生化酶学将用于证实结果。通过阐明卵巢和肾上腺类固醇下降对中枢神经系统功能的相互作用影响，我们期望为开发治疗许多女性衰老相关疾病的疗法奠定基础。