Wenk G L, Stoehr J D, Quintana G, Mobley S, Wiley R G
Arizona Research Laboratories, Division of Neural Systems, Memory and Aging, University of Arizona, Tucson 85724.
J Neurosci. 1994 Oct;14(10):5986-95. doi: 10.1523/JNEUROSCI.14-10-05986.1994.
The behavioral, biochemical, histological, and electrophysiological effects of a basal forebrain injection of saporin, a ribosome-inactivating protein, coupled to a monoclonal antibody against the low-affinity NGF receptor (192 IgG) were investigated in adult rats. Within the basal forebrain region, the low-affinity NGF receptor is exclusively expressed by cholinergic neurons in the medial septal area, diagonal band, and nucleus basalis magnocellularis (NBM). The presence of this receptor upon these cells confers a degree of specificity to the 192 IgG-saporin that could not previously be achieved by previous lesioning techniques, such as excitatory amino acids. Rats with unilateral injections of different amounts of 192 IgG-saporin were prepared to determine the optimal conditions in order to produce a lesion restricted to the NBM that would not destroy cholinergic afferents to hippocampus or nearby regions. Electroencephalographic (EEG) recordings were taken from these lesioned rats before and during treatment with scopolamine (1 mg/kg, i.p.). Another group of rats received bilateral NBM injections of 192 IgG-saporin and were behaviorally tested using a rewarded, delayed-alternation task on a T-maze and a passive avoidance task. Finally, histological and biochemical investigations confirmed the effectiveness and specificity of the 192 IgG-saporin. The results showed that the 192 IgG-saporin did not destroy neurotensin, galanin, somatostatin, NADPH-diaphorase, or neuropeptide Y neurons within the NBM. Also, biomarkers of cholinergic function were significantly decreased throughout the neocortex and within the NBM, but not in the olfactory bulbs, hippocampus, or dorsal caudate nucleus. Intraperitoneal injections of scopolamine, but not NBM injections of 192 IgG-saporin, increased total power across all frequency bands; however, slow-wave frequencies showed a greater increase in power as compared to fast-wave frequencies. Acquisition, and performance of the delayed-alternation or passive avoidance tasks were not impaired by the lesions. These data confirm the effectiveness and specificity of this novel lesioning tool and suggest that selective loss of NBM cholinergic cells is not sufficient to impair performance in these behavioral tasks.
在成年大鼠中,研究了向基底前脑注射与抗低亲和力神经生长因子受体(192 IgG)单克隆抗体偶联的核糖体失活蛋白皂草素后的行为、生化、组织学和电生理效应。在基底前脑区域内,低亲和力神经生长因子受体仅由内侧隔区、斜角带和大细胞基底核(NBM)中的胆碱能神经元表达。这些细胞上该受体的存在赋予了192 IgG - 皂草素一定程度的特异性,这是先前诸如兴奋性氨基酸等损伤技术所无法实现的。制备单侧注射不同剂量192 IgG - 皂草素的大鼠,以确定产生局限于NBM且不会破坏海马或附近区域胆碱能传入纤维的损伤的最佳条件。在给予东莨菪碱(1 mg/kg,腹腔注射)治疗前和治疗期间,对这些损伤大鼠进行脑电图(EEG)记录。另一组大鼠接受双侧NBM注射192 IgG - 皂草素,并使用T迷宫上的奖励延迟交替任务和被动回避任务进行行为测试。最后,组织学和生化研究证实了192 IgG - 皂草素的有效性和特异性。结果表明,192 IgG - 皂草素并未破坏NBM内的神经降压素、甘丙肽、生长抑素、NADPH - 黄递酶或神经肽Y神经元。此外,胆碱能功能的生物标志物在整个新皮层和NBM内显著降低,但在嗅球、海马或背侧尾状核中未降低。腹腔注射东莨菪碱,而非NBM注射192 IgG - 皂草素,增加了所有频段的总功率;然而,与快波频率相比,慢波频率的功率增加更大。延迟交替或被动回避任务的习得和表现并未因损伤而受损。这些数据证实了这种新型损伤工具的有效性和特异性,并表明NBM胆碱能细胞的选择性丧失不足以损害这些行为任务的表现。