Geiman E J, Knox M C, Alvarez F J
Department of Anatomy, Wright State University, Dayton, Ohio 45435, USA.
J Comp Neurol. 2000 Oct 9;426(1):130-42. doi: 10.1002/1096-9861(20001009)426:1<130::aid-cne9>3.0.co;2-7.
Adult mammalian Renshaw cells express large and complex postsynaptic gephyrin/glycine receptor clusters on their surface. Larger gephyrin clusters correlate with more "efficacious" inhibitory synapses, in terms of larger postsynaptic quantal size amplitudes, in part because they likely contain more postsynaptic receptors (Lim et al. [1999] J. Physiol. (Lond.) 516:505-512; Oleskevich et al. [1999] J. Neurophysiology 82:312-319). Here, we studied the postnatal development of the gephyrin/glycine receptor cluster size on Renshaw cells. Renshaw cells were identified by their calbindin immunoreactivity, location and morphology, and presence of cholinergic input. The populations of clusters over developing Renshaw cells immunoreactive to gephyrin or glycine receptor alpha1 subunits were comparable in number, size, and complexity and displayed a high degree of colocalization (>90%) at all ages. Quantitative morphologic analysis was performed on gephyrin-immunoreactive clusters. In neonatal animals, Renshaw cells expressed small punctate gephyrin-immunoreactive clusters (mean cluster size +/- SD = 0.19 +/- 0.19 microm(2)at 2 days; 0.22 +/- 0. 19 microm(2)at 5 days). By 10 and 15 days of age, Renshaw cells exhibited gephyrin-immunoreactive clusters that were larger and more complex (0.32 +/- 0.19 microm(2) at 10 days; 0.41 +/- 0.32 microm(2) at 15 days). Cluster growth reached a plateau in 25- and 60-day-old Renshaw cells (0.45 +/- 0.43 microm(2); 0.56 +/- 0.55 microm(2), respectively). By using electron microscopy, we confirmed that gephyrin-immunoreactive clusters were located at postsynaptic sites at both early and late postnatal ages on Renshaw cells. The potential significance of this gephyrin/glycine receptor cluster size maturation that sets Renshaw cells apart from other interneurons is discussed.
成年哺乳动物的闰绍细胞在其表面表达大而复杂的突触后桥连蛋白/甘氨酸受体簇。就更大的突触后量子大小振幅而言,更大的桥连蛋白簇与更“有效”的抑制性突触相关,部分原因是它们可能包含更多的突触后受体(Lim等人[1999]《生理学杂志》(伦敦)516:505 - 512;Oleskevich等人[1999]《神经生理学杂志》82:312 - 319)。在此,我们研究了闰绍细胞上桥连蛋白/甘氨酸受体簇大小的出生后发育情况。闰绍细胞通过其钙结合蛋白免疫反应性、位置和形态以及胆碱能输入的存在来鉴定。发育中的闰绍细胞上对桥连蛋白或甘氨酸受体α1亚基免疫反应的簇群在数量、大小和复杂性方面相当,并且在所有年龄段都显示出高度的共定位(>90%)。对桥连蛋白免疫反应性簇进行了定量形态学分析。在新生动物中,闰绍细胞表达小的点状桥连蛋白免疫反应性簇(2天时平均簇大小±标准差 = 0.19±0.19平方微米;5天时为0.22±0.19平方微米)。到10天和15天时,闰绍细胞表现出更大且更复杂的桥连蛋白免疫反应性簇(10天时为0.32±0.19平方微米;15天时为0.41±0.32平方微米)。在25天和60天龄的闰绍细胞中,簇的生长达到平台期(分别为0.45±0.43平方微米;0.56±0.55平方微米)。通过电子显微镜,我们证实桥连蛋白免疫反应性簇在出生后早期和晚期都位于闰绍细胞的突触后部位。讨论了这种使闰绍细胞与其他中间神经元不同的桥连蛋白/甘氨酸受体簇大小成熟的潜在意义。
