Kritzer M F, Cowey A, Somogyi P
MRC Anatomical Neuropharmacology Unit, Oxford, United Kingdom.
J Neurosci. 1992 Nov;12(11):4545-64. doi: 10.1523/JNEUROSCI.12-11-04545.1992.
Local GABAergic connections are undoubtedly important for the operation of cerebral cortex, including the tuning of receptive field properties of visual cortical neurons. In order to begin to correlate specific configurations of GABAergic networks with particular receptive field properties, we examined the arrangement of GABAergic neurons projecting to foci in compartments of known functional specialization in striate (area V1) and extrastriate (areas V2, V4) cortices of rhesus monkeys. GABAergic cells were detected autoradiographically following microinjections into supragranular, granular, or infragranular layers of 5, 10, or 50 nl of 3H-nipecotic acid, which selectively exploits the GABA reuptake mechanism. These injections produced complex inter- and intralaminar distributions of retrograde perikaryal labeling that was selective for GABA-immunopositive neurons and glia. The pattern of retrograde labeling depended on both the laminar and cytoarchitectonic location of injection sites. In all cases, a high density of labeled neurons was present in the immediate vicinity of injection sites, with the density of labeled neurons decreasing for the most part uniformly with horizontal distance. Injections in supragranular layers produced relatively widespread labeling (up to 1.5-1.7 mm from the center of injections) in upper layers, whereas in granular and infragranular layers, labeling was confined to a radius of 0.25-0.5 mm. Conversely, injections in infragranular layers produced labeling that was widest (up to 1 mm) in lower layers, but more laterally restricted in supragranular layers. Injections in granular layers, on the other hand, produced an even distribution of labeling, 0.6-1.0 mm in diameter, throughout all layers. Comparably placed injections in V1, V2, and V4 resulted in patterns of labeling that were distinguished by features including stepwise increases in the lateral extent of labeling from striate to extrastriate areas, and the circular versus markedly elongated intralaminar distribution of labeled neurons in V1 and V4 versus V2. Further, for superficial injections, labeling was present in all layers in V1 and V2, but did not extent below the top layer V in area V4. These findings offer clear examples of organizational differences in the intrinsic inhibitory connections of visual cortices. The results also demonstrate that the number of GABAergic neurons projecting to any spot in cortex decreases systematically with horizontal distance from the spot, and that radiolabeled cells do not coalesce to form slabs, columns, or clusters. This relatively even distribution of retrogradely labeled cells in the tangential plane is consistent with recent computer simulations (Worgotter and Koch, 1991) that suggest that inhibitory neurons broadly tuned as a population can produce the specific response properties of cortical neurons.(ABSTRACT TRUNCATED AT 400 WORDS)
局部γ-氨基丁酸能(GABAergic)连接对于大脑皮层的运作无疑至关重要,包括对视觉皮层神经元感受野特性的调节。为了开始将GABA能网络的特定构型与特定的感受野特性联系起来,我们研究了向恒河猴纹状皮层(V1区)和纹外皮层(V2、V4区)中已知功能特化分区的焦点投射的GABA能神经元的排列。在向颗粒上层、颗粒层或颗粒下层微量注射5、10或50 nl的3H-哌啶酸后,通过放射自显影检测GABA能细胞,3H-哌啶酸选择性利用GABA再摄取机制。这些注射产生了逆行性核周标记的复杂层间和层内分布,该分布对GABA免疫阳性神经元和神经胶质细胞具有选择性。逆行标记的模式取决于注射部位的层状和细胞构筑位置。在所有情况下,注射部位紧邻区域存在高密度的标记神经元,标记神经元的密度在很大程度上随水平距离均匀降低。在颗粒上层的注射在上层产生相对广泛的标记(距注射中心达1.5 - 1.7 mm),而在颗粒层和颗粒下层,标记局限于0.25 - 0.5 mm的半径范围内。相反,在颗粒下层的注射在下层产生最宽(达1 mm)的标记,但在颗粒上层的侧向范围受限。另一方面,在颗粒层的注射在所有层中产生直径为0.6 - 1.0 mm的均匀标记分布。在V1、V2和V4区进行的位置相当的注射产生的标记模式具有以下特征:从纹状区到纹外区标记的侧向范围逐步增加,以及V1和V4区与V2区中标记神经元的层内圆形与明显拉长分布的差异。此外,对于浅层注射,V1和V2区的所有层都有标记,但在V4区不延伸到顶层V以下。这些发现提供了视觉皮层内在抑制性连接组织差异的清晰例子。结果还表明,投射到皮层中任何一点的GABA能神经元数量随与该点的水平距离系统性减少,并且放射性标记细胞不会聚合并形成板层、柱状或簇状。在切向平面中逆行标记细胞的这种相对均匀分布与最近的计算机模拟(Worgotter和Koch,1991)一致,该模拟表明作为一个群体广泛调谐的抑制性神经元可以产生皮层神经元的特定反应特性。(摘要截短于400字)