Arnerić S P, Honig M A, Milner T A, Greco S, Iadecola C, Reis D J
Department of Neurology, Cornell University Medical College, New York, NY 10021.
Brain Res. 1988 Jun 28;454(1-2):11-30. doi: 10.1016/0006-8993(88)90799-8.
We sought to establish what proportion of the cholinergic innervation of the cerebral cortex (CX) is associated with intraparenchymal blood vessels by using immunocytochemical and neurochemical techniques, and whether [3H]acetylcholine ([3H]ACh) is synthesized and released by elements associated with cortical microvessels (MV). MVs and, for comparison, tissue homogenates were prepared using sucrose gradient/differential ultracentrifugation methods. Efficacy of the separation technique was indicated by the activity of gamma-glutamyltranspeptidase (up to 29.2-fold enrichment), an endothelial cell marker enzyme, in the MV fraction and microscopy. The size of isolated microvessels ranged from 5 to 40 micron (o.d.) with 67.7% of the vessels less than 10 micron and 32.2% between 11 and 40 micron (690 vessels measured from 4 animals). By electron microscopy immunoreactive choline acetyltransferase (ChAT), the biosynthetic enzyme for ACh, was localized to: (a) axons and axon terminals opposed to the basal laminae of capillaries and small arterioles, and (b) capillary endothelial cells. ChAT-labeled elements associated with MVs were most prominent in layers I, III and V of the CX consistent with the local pattern of cholinergic innervation. The absolute amount of ACh synthesized (pmol Ach/100 mg wet wt.) by elements associated with cortical MVs was relatively small (2.3% total cortical homogenate activity). Inhibition of MV ChAT activity to 5% of control by the specific ChAT inhibitor, 4-naphthylvinylpyridine, and HPLC analysis of the product, indicated that authentic ACh was measured. Other tissues similarly synthesized small amounts of ACh relative to the CX, caudate nucleus (CN, 2.4%), cerebellum (CRB, 1.4%) and liver (LIV, 3.9%). Consistent with the known extent of the cholinergic innervation of the tissues examined, the rank order of ChAT associated for both MVs and homogenate were: CN greater than CX much greater than CRB greater than LIV. However, based on the specific activities of ChAT, cortical MVs have the remarkable capacity to synthesize ACh at rates 95% greater than cortical (S1 fraction) homogenate (59.0 +/- 3.5 nmol/mg protein/40 min; n = 7), which is enriched in nerve terminals. Except for LV (+11%), other tissues also had remarkably high ChAT activity in MV (% above corresponding homogenate; P less than 0.05, n = 5): CN (+269) and CRB (+313). Release of [3H]ACh from MVs and, for comparison, nerve terminals were graded to K+ depolarization stimulus (5-55 mM), maximal with 55 mM K+ and Ca2+ dependent.(ABSTRACT TRUNCATED AT 400 WORDS)
我们试图运用免疫细胞化学和神经化学技术来确定大脑皮质(CX)胆碱能神经支配中与脑实质内血管相关的比例,以及[³H]乙酰胆碱([³H]ACh)是否由与皮质微血管(MV)相关的成分合成和释放。采用蔗糖梯度/差速超速离心法制备MV,作为对照,同时制备组织匀浆。通过γ-谷氨酰转肽酶(富集倍数高达29.2倍)的活性以及显微镜观察来表明分离技术的有效性,γ-谷氨酰转肽酶是一种内皮细胞标记酶,存在于MV组分中。分离出的微血管直径范围为5至40微米(外径),其中67.7%的血管直径小于10微米,32.2%的血管直径在11至40微米之间(从4只动物中测量了690根血管)。通过电子显微镜观察,乙酰胆碱生物合成酶免疫反应性胆碱乙酰转移酶(ChAT)定位于:(a)与毛细血管和小动脉基底层相对的轴突和轴突终末,以及(b)毛细血管内皮细胞。与MV相关的ChAT标记成分在CX的I、III和V层最为显著,这与胆碱能神经支配的局部模式一致。与皮质MV相关的成分合成的ACh绝对量(每100毫克湿重中ACh的皮摩尔数)相对较少(占皮质匀浆总活性的2.3%)。特异性ChAT抑制剂4-萘基乙烯基吡啶将MV的ChAT活性抑制至对照的5%,并对产物进行高效液相色谱分析,表明测量到的是真实的ACh。相对于CX,其他组织同样合成少量的ACh,尾状核(CN,2.4%)、小脑(CRB,1.4%)和肝脏(LIV,3.9%)。与所检查组织中已知的胆碱能神经支配程度一致,MV和匀浆中ChAT相关程度的排序为:CN>CX>>CRB>LIV。然而,基于ChAT的比活性,皮质MV合成ACh的能力显著,速率比富含神经终末的皮质(S1组分)匀浆高95%(59.0±3.5纳摩尔/毫克蛋白质/40分钟;n = 7)。除肝脏(增加11%)外,其他组织的MV中ChAT活性也显著高于相应的匀浆(高于相应匀浆的百分比;P<0.05,n = 5):CN(增加269)和CRB(增加313)。将MV以及作为对照的神经终末对[³H]ACh的释放分级给予K⁺去极化刺激(5 - 55毫摩尔),在55毫摩尔K⁺时释放最大且依赖于Ca²⁺。(摘要截断于400字)
