CNS DEVELOPMENT UNDER HYPERGRAVITY : MODULATION BY TH?

超重力下中枢神经系统的发育：TH 的调节？

• 批准号: 6640159
• 负责人: Elizabeth M Sajdel-Sulkowska
• 金额: $ 40.93万
• 依托单位: BRIGHAM AND WOMEN'S HOSPITAL
• 依托单位国家: 美国
• 财政年份: 2002
• 资助国家: 美国
• 起止时间: 2002-08-01 至 2005-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6640159
• 关键词: brain morphology; central nervous system; cerebellar Purkinje cell; developmental neurobiology; environmental stressor; gene expression; granule cell; gravity; hormone regulation /control mechanism; hypothalamic pituitary axis; hypothyroidism; immunocytochemistry; laboratory rat; malnutrition; maternal behavior; newborn animals; northern blottings; stress; thyroid hormone binding protein; thyroid hormones; thyrotropin; thyroxine; triiodothyronine

DESCRIPTION (provided by applicant): To evaluate the potential risks associated with space exploration, the proposed studies will assess the impact of altered gravity on the developing CNS. Specifically, these studies will probe the hypothesis that changes in gravity affect cerebellar development and that this effect is mediated by altered thyroid status. This hypothesis is based on the following: (1) both the CNS and thyroid status are inhibited in astronauts and in adult animals exposed to micro- and hypergravity; (2) thyroid hormone (TH) is critical for normal CNS development; and (3) motor coordination, controlled by the cerebellum, is affected in both astronauts and animals under altered gravity. The experiments designed to test this hypothesis will utilize the hypergravity paradigm of a 24-ft centrifuge, since it provides the most adaptable system for studying the effect of altered gravity on developing mammals. Based on preliminary findings suggesting that exposure to centrifugation from gestation through weaning results in changes in the developing cerebellum and altered thyroid status in rat neonates, we predict that: (1) changes in cerebellar size and structure observed at 15G will become more pronounced at higher gravitational loading; (2) the mild hypothyroidism observed at 1.5 G will become more severe at higher gravitational loading. The effect of hypergravity on neonatal cerebellum will be evaluated primarily in terms of the celebellar size and number of Purkinje and granule cells; the thyroid status of dams and neonates will be assessed primarily in terms of plasma thyroid stimulating hormone (TSH), free T3 and T4, and neonatal cerebellar T3 and T4 at P6 to P21. These parameters will be compared between stationary controls (SC), rotational controls (RC) and hypergravity-exposed (HG, 1.5G. 1.65G. and 1.75G) dams and/or pups during one of the three developmental periods: (1) the second part of embryonic development through the neonatal period (Gil to P21); (2) the second part of embryonic development only (Gil-P 1); and (3) the neonatal period only (P1 to P21). To examine the possible contribution of other factors such as malnutrition, pair-fed controls will be included to evaluate the contribution of maternal-offspring interactions, HG neonates will be cross-fostered to SC dams. The status of the hypothalamic-pituitary-thyroid (HPT) axis will be examined by measuring neonatal serum thyroid-binding proteins (TBG, TTR) and thyroid size. Should these studies support the direct involvement of THin the neonatal response to hypergravity, a TI! supplement will be given to dams or pups to attempt to prevent the adverse effects of altered gravity. Additional molecular studies, including immuno-chemical immunohistological, and gene expression analyses (northern blots, RPA, and rat-specific cDNA arrays, focusing on TH-regulated genes) will probe the molecular mechanism(s) involved in gravity response. These studies will aid in developing an understanding of how altered gravity affects CNS development, what role the thyroid hormone plays in that response, and whether this response can be modulated by hormonal therapy.

描述（由申请人提供）：为了评估与太空探索相关的潜在风险，拟议的研究将评估重力变化对发展中的CNS的影响。具体来说，这些研究将探讨重力变化影响小脑发育的假设，这种影响是由甲状腺状态改变介导的。这一假设的依据如下：（1）宇航员和暴露于微重力和超重力的成年动物的中枢神经系统和甲状腺状态都受到抑制;（2）甲状腺激素对中枢神经系统的正常发育至关重要;（3）在重力改变的情况下，宇航员和动物的运动协调（由小脑控制）都受到影响。为检验这一假设而设计的实验将利用24英尺离心机的超重力范例，因为它为研究重力变化对哺乳动物发育的影响提供了最具适应性的系统。基于初步研究结果表明，从妊娠到断奶暴露于离心导致新生大鼠小脑发育和甲状腺状态改变，我们预测：（1）在15 G下观察到的小脑大小和结构变化在更高的重力负荷下将变得更加明显;（2）在1.5 G下观察到的轻度甲状腺功能减退症在更高的重力负荷下将变得更加严重。超重对新生儿小脑的影响将主要根据小脑的大小和浦肯野细胞和颗粒细胞的数量进行评价;母鼠和新生儿的甲状腺状态将主要根据血浆促甲状腺激素（TSH）、游离T3和T4以及P6至P21时新生儿小脑的T3和T4进行评估。这些参数将在静止对照（SC）、旋转对照（RC）和超重力暴露（HG，1.5G）之间进行比较。1.65G.和1.75G）母鼠和/或幼鼠在三个发育期之一：（1）胚胎发育的第二部分至新生儿期（Gil至P21）;（2）仅胚胎发育的第二部分（Gil至P1）;和（3）仅新生儿期（P1至P21）。为了检查营养不良等其他因素的可能贡献，将纳入成对喂养的对照组以评估母子相互作用的贡献，HG新生儿将与SC母鼠交叉寄养。通过测量新生儿血清甲状腺结合蛋白（TBG、TTR）和甲状腺大小检查下丘脑-垂体-甲状腺（HPT）轴的状态。如果这些研究支持TH直接参与新生儿对超重力的反应，TI！补充剂将给予母鼠或幼鼠，以试图防止重力改变的不利影响。其他分子研究，包括免疫化学免疫组织学和基因表达分析（北方印迹，RPA和大鼠特异性cDNA阵列，重点是TH调节基因）将探测重力反应的分子机制。这些研究将有助于了解重力改变如何影响CNS发育，甲状腺激素在这种反应中起什么作用，以及这种反应是否可以通过激素治疗来调节。