Cohn J, Cory-Slechta D A
Environmental Health Sciences Center, University of Rochester, School of Medicine and Dentistry, NY 14642.
Brain Res. 1993 Jan 15;600(2):208-18. doi: 10.1016/0006-8993(93)91375-3.
Exposure to lead (Pb) has been reported to inhibit MK-801 binding and to alter other NMDA receptor complex-associated functions. These reported changes are provocative since both NMDA receptor antagonism and Pb exposure are know to impair learning processes. Whether the Pb-induced changes in NMDA function relate to the learning impairments associated with Pb exposure, however, has not been explored. The contention of this study was that if changes in NMDA function produced by Pb serve as the basis of Pb-associated learning impairments, then such changes should be of sufficient biological magnitude and clinical relevance to induce alterations in sensitivity at the level of the whole animal, i.e., changes in behavioral sensitivity to glutamatergic compounds. Thus, in this study, dose-effect curves of control and Pb-treated rats working on a multiple schedule of repeated learning (repeated acquisition, RA) and performance (P) were compared following acute administration of MK-801, the non-competitive NMDA antagonist. Based on the nature of the reported effects of Pb on NMDA systems, it was expected that the curves of Pb-exposed rats would be right-shifted relative to controls, if differential behavioral sensitivity was evident. Rats were chronically exposed to 0, 50 or 250 ppm Pb acetate in drinking water from weaning and trained on the multiple RA and P schedule beginning at 55 days old. The RA component required the rat to learn a new 3-member sequence of responses during each experimental session (center right left, RLC, CLR, RCL, or LRC), while the correct sequence of responses for the P component was constant across sessions (LCR), requiring performance of an already learned response. Acute administration of MK-801 (0.05-0.3 mg/k, i.p.) resulted in decrements in accuracy in both the RA and P components of the schedule, indicative of non-specific effects on behavior rather than selective effects on learning. The declines in accuracy during the RA component of the schedule were primarily the result of increased perseverative responding, i.e., repetitive responding on a single lever. Both the decline in RA accuracy and the increases in perseverative responding produced by MK-801 were attenuated by Pb exposure. Moreover, dose-effect curves relating MK-801 dose to changes in rates of responding were significantly shifted to the right in Pb-exposed rats relative to controls. Taken together, these data demonstrate a subsensitivity of Pb-exposed rats to both the accuracy-impairing and response rate-altering properties of MK-801.(ABSTRACT TRUNCATED AT 400 WORDS)
据报道,接触铅(Pb)会抑制MK-801结合,并改变其他与NMDA受体复合物相关的功能。这些报道的变化具有启发性,因为已知NMDA受体拮抗作用和铅暴露都会损害学习过程。然而,铅诱导的NMDA功能变化是否与铅暴露相关的学习障碍有关,尚未得到探讨。本研究的论点是,如果铅引起的NMDA功能变化是铅相关学习障碍的基础,那么这种变化应该具有足够的生物学强度和临床相关性,以在整个动物水平上引起敏感性改变,即对谷氨酸能化合物的行为敏感性变化。因此,在本研究中,在急性给予非竞争性NMDA拮抗剂MK-801后,比较了在重复学习(重复习得,RA)和表现(P)的多重时间表上工作的对照大鼠和铅处理大鼠的剂量-效应曲线。基于所报道的铅对NMDA系统的影响性质,如果明显存在行为敏感性差异,预计铅暴露大鼠的曲线相对于对照会向右移动。大鼠从断奶开始长期饮用含0、50或250 ppm醋酸铅的水,并在55日龄开始接受多重RA和P时间表的训练。RA部分要求大鼠在每个实验阶段学习一个新的由三个反应组成的序列(中右左,RLC、CLR、RCL或LRC),而P部分的正确反应序列在各阶段保持不变(LCR),需要执行已经学会的反应。急性给予MK-801(0.05 - 0.3 mg/k,腹腔注射)导致时间表的RA和P部分的准确性下降,表明对行为有非特异性影响而非对学习有选择性影响。时间表RA部分准确性的下降主要是持续性反应增加的结果,即在单个杠杆上的重复反应。铅暴露减弱了MK-801引起的RA准确性下降和持续性反应增加。此外,与MK-801剂量相关的反应率变化的剂量-效应曲线在铅暴露大鼠中相对于对照明显向右移动。综上所述,这些数据表明铅暴露大鼠对MK-801的准确性损害和反应率改变特性存在亚敏感性。(摘要截断于400字)
