Bachmann S, Bosse H M, Mundel P
Department of Anatomy and Cell Biology I, University of Heidelberg, Germany.
Am J Physiol. 1995 May;268(5 Pt 2):F885-98. doi: 10.1152/ajprenal.1995.268.5.F885.
Nitric oxide (NO) is generated from L-arginine by NO synthase (NOS). We have investigated the localization of constitutive NOS isoforms in rat, mouse, guinea pig, rabbit, pig, and human kidney. NADPH diaphorase (NADPH-d) reaction was used for histochemical detection of NOS enzyme activity, neuronal NOS (NOS I) and endothelial NOS (NOS III) were identified by specific antibody, and in situ hybridization was applied for NOS I mRNA detection. Strong presence of NOS I in macula densa (MD), previously detected in rat, was found in all species including humans. Additional NOS I-positive cells of the thick ascending limb (TALH) were defined. A clear-cut distinction between Tamm-Horsfall-protein-positive cells of the TALH and NOS I-positive cells of the TALH was shown. Ultrastructurally, NOS I was located in the cytosol. Intimate spatial relation between NOS I-positive cells and renin-containing preglomerular afferent arteriole suggests an effect of MD-derived NO on the juxtaglomerular granular cells. In the renal vasculature, both NADPH-d and NOS III were located in the endothelium of cortical and medullary vessels, whereas the muscle layer was unreactive. The glomerular arterioles showed stronger labeling in the efferent than in the afferent endothelium, and efferent endothelium selectively contained both NOS I and NOS III. The unique morphology of efferent endothelial cells indicates a particular role for NO in this vessel segment. At the capillary level, only the glomerular tuft showed NOS-positive endothelia. A subpopulation of renal nerves containing NADPH-d and NOS I was found in perivascular connective tissue and near pelvic epithelium. These results demonstrate a wide distribution of two constitutive NOS isoforms in the kidney of various animal species including humans. The distinct location of both isoforms in the cortex confirms that NO plays a crucial role in local glomerular signaling events.
一氧化氮(NO)由一氧化氮合酶(NOS)催化L-精氨酸生成。我们研究了组成型NOS亚型在大鼠、小鼠、豚鼠、兔、猪和人肾脏中的定位。采用NADPH黄递酶(NADPH-d)反应进行NOS酶活性的组织化学检测,用特异性抗体鉴定神经元型NOS(NOS I)和内皮型NOS(NOS III),并应用原位杂交检测NOS I mRNA。在包括人类在内的所有物种中均发现致密斑(MD)中存在大量的NOS I,这一现象先前已在大鼠中检测到。厚壁升支(TALH)中额外的NOS I阳性细胞也得到了明确。TALH中Tamm-Horsfall蛋白阳性细胞与NOS I阳性细胞之间存在明显区别。超微结构显示,NOS I位于细胞质中。NOS I阳性细胞与含肾素的球前传入小动脉之间存在紧密的空间关系,提示MD产生的NO对球旁颗粒细胞有影响。在肾血管系统中,NADPH-d和NOS III均位于皮质和髓质血管的内皮细胞中,而肌层无反应。肾小球小动脉在出球小动脉内皮中的标记比入球小动脉更强,且出球小动脉内皮选择性地同时含有NOS I和NOS III。出球小动脉内皮细胞独特的形态表明NO在该血管段具有特殊作用。在毛细血管水平,只有肾小球毛细血管襻显示NOS阳性内皮细胞。在血管周围结缔组织和肾盂上皮附近发现了一群含有NADPH-d和NOS I的肾神经。这些结果表明,两种组成型NOS亚型广泛分布于包括人类在内的多种动物的肾脏中。两种亚型在皮质中的不同定位证实了NO在局部肾小球信号传导事件中起关键作用。
