Co-localization of nitric oxide synthase immunoreactivity and NADPH diaphorase staining in neurons of the guinea-pig intestine

Summary Neuronal nitric oxide synthase (NOS), an enzyme capable of synthesizing nitric oxide, appears to be identical to neuronal NADPH diaphorase. The correlation was examined between NOS immunoreactivity and NADPH diaphorase staining in neurons of the ileum and colon of the guinea-pig. There was a one-to-one correlation between NOS immunoreactivity and NADPH diaphorase staining in all neurons examined; even the relative staining intensities obtained were similar with each technique. To determine whether pharmacological methods could be employed to demonstrate that NADPH diaphorase staining was due to the presence of NOS, tissue was pre-treated with N^G-nitro-l-arginine, a NOS inhibitor, or l-arginine, a natural substrate of NOS. In these experiments on unfixed tissue, it was necessary to use dimethyl thiazolyl tetrazolium instead of nitroblue tetrazolium as the substrate for the NADPH diaphorase histochemical reaction. Neither treatment caused a significant decrease in the level of NADPH diaphorase staining, implying that arginine and NADPH interact at different sites on the enzyme.     

Co-localization of nitric oxide synthase immunoreactivity and NADPH diaphorase staining in neurons of the guinea-pig intestine.

Neuronal nitric oxide synthase (NOS), an enzyme capable of synthesizing nitric oxide, appears to be identical to neuronal NADPH diaphorase. The correlation was examined between NOS immunoreactivity and NADPH diaphorase staining in neurons of the ileum and colon of the guinea-pig. There was a one-to-one correlation between NOS immunoreactivity and NADPH diaphorase staining in all neurons examined; even the relative staining intensities obtained were similar with each technique. To determine whether pharmacological methods could be employed to demonstrate that NADPH diaphorase staining was due to the presence of NOS, tissue was pre-treated with NG-nitro-L-arginine, a NOS inhibitor, or L-arginine, a natural substrate of NOS. In these experiments on unfixed tissue, it was necessary to use dimethyl thiazolyl tetrazolium instead of nitroblue tetrazolium as the substrate for the NADPH diaphorase histochemical reaction. Neither treatment caused a significant decrease in the level of NADPH diaphorase staining, implying that arginine and NADPH interact at different sites on the enzyme.     

Brugia malayi: localization of nitric oxide synthase in a lymphatic filariid

Nitric oxide synthase converts L-arginine to citrulline and nitric oxide, a gaseous signaling molecule critical to multiple physiological responses. Nitric oxide synthase was detected by Western blot analysis of Brugia malayi extracts using an antibody raised against a peptide from murine brain nitric oxide synthase. Using NADPH diaphorase staining and immunohistochemistry, nitric oxide synthase was localized in the parasitic nematode B. malayi. As in Ascaris suum, nitric oxide synthase was detected in the body wall muscles of adult B. malayi. This localization pattern is in agreement with the role of nitric oxide in the control of muscle tone in other invertebrates and in vertebrates. A novel finding was the localization of nitric oxide synthase in the oocytes, in developing embryos, and in spermatozoa. B. malayi nitric oxide synthase may play a role in developmental signaling, as has been suggested for Drosophila and Ilyanassa, a marine mud snail.     

Cytochemical localisation of the NADPH diaphorase activity in the Leydig cells of the mouse

 The distribution of the NADPH diaphorase activity was studied in mouse Leydig cells by means of light and electron microscopy. When observed by the light microscope, most Leydig cells appeared intensely stained; a few cells (about 10%) showed a slightly positive or apparently negative reaction. The inhibitory effects of N^G-nitro-l-arginine and iodonium diphenyl on frozen sections suggest the colocalisation of NADPH diaphorase reaction with nitric oxide synthase. The ultrastructural study revealed that all the Leydig cells were positively stained for NADPH diaphorase; however, a small number of cells displayed weak enzymatic activity. The reaction product was located in the mitochondria, smooth endoplasmic reticulum and lipidic vacuoles, and the nuclear envelope was also stained. The possible meaning of the NADPH diaphorase activity in the Leydig cells of mice was discussed. Accepted: 5 September 1997     

Histochemistry of nitric oxide synthase in the nervous system

Summary Nitric oxide synthase, which generates the physiological messenger molecule nitric oxide, and its associated NADPH diaphorase (NADPHd) activity are distributed throughout selective neuronal populations of the central and peripheral nervous system. Considerable evidence has been accumulated to indicate that NADPHd activity labels cells lacking neuronal nitric oxide synthase, i.e., the specificity of the reaction has to be considered for the reliable detection of the enzyme in neuronal but also non-neuronal tissue. In the present review, critical aspects of nitric oxide synthase visualization in neurones, using its NADPHd activity, are discussed. Furthermore, the organization of the central and peripheral nitric oxide synthase-containing neuronal systems is described. Nitric oxide synthase is present in local cortical and striatal neurones, hypothalamic magnocellular neurones, mesopontine cholinergic neurones, cerebellar interneurones, preganglionic sympathetic and parasympathetic neurones, neurones in parasympathetic autonomic and enteric ganglia and primary viscero-afferent neurones. Finally, injury-related alterations in nitric oxide synthase activity are briefly outlined. In this respect, the histochemistry of nitric oxide synthase may represent a valuable marker for neurochemical, if not structural, alterations observed in neural diseases, regeneration and transplantation.     

Histochemical Method for Detecting Nitric Oxide Synthase Activity in Cell Cultures

NADPH diaphorase histochemistry has been used extensively for detecting nitric oxide synthase (NOS) activity in various cell types including neuronal cell bodies, vascular endothelium, cells of the immune system and epithelial cells. The use of the diaphorase technique in cell cultures to study the induction of NOS has not been investigated. In this paper we report the use of diaphorase histochemistry as a good marker for the detection of NOS activity in cultured cells. This technique can be used in conjunction with other established techniques to determine the presence and activity of NOS in cultured cells.     

Stimulation of NO synthase activity in the immune-competent lepidopteran Estigmene acraea hemocyte line.

In contrast to the vertebrate immune system, nearly nothing is known about the immunological role of nitric oxide (NO) in invertebrates. This study provides evidence of the presence of a NO synthase (NOS) activity in an immune-competent, macrophage-like insect hemocyte line, previously established from larvae of the lepidopteran insect Estigmene acraea. As proven by photometric determination of nitroblue tetrazolium reduction after cell fixation, the E. acraea cells possess NADPH diaphorase (NADPHd) activity. This NADPH diaphorase activity was NADPH dependent, not inhibitable by superoxide dismutase, influenced by extracellular addition of L-arginine, and inhibited in a dose-dependent manner by the specific NOS inhibitor Nomega-monomethyl-L-arginine. Furthermore, the NADPH diaphorase activity was stimulated within 30 min by the addition of insect pathogenic bacteria (Bacillus thuringiensis var. kurstaki, Photorhabdus luminescens), bacterial lipopolysaccharide, and silica beads. In activated E. acraea cell suspensions strongly increased amounts of L-citrulline and enhanced levels of total nitrite/nitrate (as NO derivates) can be determined. This is the first report on stimulable NOS activity in insect hemocytes.     

Nitric oxide synthase protein and mRNA are discretely localized in neuronal populations of the mammalian CNS together with NADPH diaphorase.

Nitric oxide is a free radical that has been recently recognized as a neural messenger molecule. Nitric oxide synthase has now been purified and molecularly cloned from brain. Using specific antibodies and oligonucleotide probes, we have localized brain nitric oxide synthase to discrete neuronal populations in the rat and primate brain. Nitric oxide synthase is exclusively neuronal, and its localization is absolutely coincident with NADPH diaphorase staining in both rat and primate.     

Nitric oxide signaling in invertebrates

Nitric oxide (NO) is an unconventional neurotransmitter and neuromodulator molecule that is increasingly found to have important signaling functions in animals from nematodes to mammals. NO signaling mechanisms in the past were identified largely through experiments on mammals, after the discovery of NO's vasodilatory functions. The use of gene knock out mice has been particularly important in revealing the functions of the several isoforms of nitric oxide synthase (NOS), the enzyme that produces NO. Recent studies have revealed rich diversity in NO signaling. In addition to the well-established pathway in which NO activates guanylyl cyclase and cGMP production, redox mechanisms involving protein nitrosylation are important contributors to modulation of neurotransmitter release and reception. NO signaling studies in invertebrates are now generating a wealth of comparative information. Invertebrate NOS isoforms have been identified in insects and molluscs, and the conserved and variable amino acid sequences evaluated. Calcium-calmodulin dependence and cofactor requirements are conserved. NADPH diaphorase studies show that NOS is found in echinoderms, coelenterates, nematodes, annelids, insects, crustaceans and molluscs. Accumulating evidence reveals that NO is used as an orthograde transmitter and cotransmitter, and as a modulator of conventional transmitter release. NO appears to be used in diverse animals for certain neuronal functions, such as chemosensory signalin, learning, and development, suggesting that these NO functions have been conserved during evolution. The discovery of NO's diverse and unconventional signaling functions has stimulated a plethora of enthusiastic investigations into its uses. We can anticipate the discovery of many more interesting and some surprising NO signaling functions.     

Skeletal muscle fibres show NADPH diaphorase activity associated with mitochondria, the sarcoplasmic reticulum and the NOS-1-containing sarcolemma

The subcellular appearance of NADPH diaphorase activity in different rat skeletal muscles has been analyzed. Both a sarcolemma-associated as well as a non-sarcolemma-associated NADPH diaphorase-dependent generation of formazan was observed. The sarcolemma-associated NADPH diaphorase staining appeared regularly in two manifestations: one observed in longitudinal sections as dotted costameres at the cell surface which accordingly appeared in transversal sections as rings surrounding the myofibre surface. At this site, nitric oxide synthase (NOS)-1 was located. The second sarcolemma-associated site of NADPH diaphorase staining was found as bundles of longitudinal-orientated stripes of hitherto unidentified origin. The non-sarcolemma-associated production of formazan was likewise manifested at two sites: the first was found regularly in longitudinal sections as intense sarcomere-like striations occurring parallel to the I-bands and indicating mitochondria. The second non-sarcolemma-associated NADPH diaphorase staining was realized as fine longitudinal filaments of variable occurrence connecting the mitochondria and presumably belonging to the sarcoplasmic reticulum. Attempts to identify single NADPH diaphorase(s) existing in skeletal muscles by incubation with specific inhibitors failed but showed the presence of two different subpopulations of NADPH diaphorases in myofibres: a urea-resistant fraction in the sarcolemma region containing NOS-1 and a non-sarcolemma-associated, urea-sensitive fraction depleted of NOS-1.     

The distribution of NADPH diaphorase activity and immunoreactivity to nitric oxide synthase in the nervous system of the pulmonate mollusc Helix aspersa

Enzyme histochemistry and immunocytochemistry were used to determine the distribution of neurons in the snail Helix aspersa which exhibited nicotinamide adenine dinucleotide phosphate (NADPH) diaphorase activity and/or immunoreactivity to nitric oxide synthase (NOS). NADPH diaphorase-positive cells and fibres were distributed extensively throughout the central and peripheral nervous system. NADPH diaphorase-positive fibres were present in all neuropil regions of the central and peripheral ganglia, in the major interganglionic connectives and in peripheral nerve roots. NADPH diaphorase-positive cell bodies were found consistently in the eyes, the lips, the tentacular ganglia and the procerebral lobes of the cerebral ganglia; staining of cell bodies elsewhere in the nervous system was capricious. The distribution of NOS-like immunoreactivity differed markedly from that of NADPH diaphorase activity. Small clusters of cells which exhibited NOS-like immunoreactivity were present in the cerebral and pedal ganglia; fibres which exhibited NOS-like immunoreactivity were present in restricted regions of the neuropil of the central ganglia. The disjunct distributions of NADPH diaphorase activity and NOS-like immunoreactivity in the neurvous system of Helix suggest that the properties of neuronal NOS in molluscs may differ sigificantly from those described previously for vertebrate animals.     

Ca2+/calmodulin-dependent NO synthase type I: a biopteroflavoprotein with Ca2+/calmodulin-independent diaphorase and reductase activities.

NO synthase (NOS; EC 1.14.23) catalyzes the conversion of L-arginine into L-citrulline and a guanylyl cyclase-activating factor (GAF) that is chemically identical with nitric oxide or a nitric oxide-releasing compound (NO). Similar to the other isozymes of NOS that have been characterized to date, the soluble and Ca2+/calmodulin-regulated type I from rat cerebellum (homodimer of 160-kDa subunits) is dependent on NADPH for catalytic activity. The enzyme also possesses NADPH diaphorase activity in the presence of the electron acceptor nitroblue tetrazolium (NBT). We investigated the requirements of NOS and its content of the proposed additional cofactors tetrahydrobiopterin (H4biopterin) and flavins, further characterized the NADPH diaphorase activity, and quantified the NADPH binding site(s). Purified NOS type I Ca2+/calmodulin-independently bound the [32P]2',3'-dialdehyde analogue of NADPH (dNADPH), which, at near Km concentrations during 3-min incubations was utilized as a substrate and at higher concentrations or after prolonged incubations and cross-linking inhibited NOS activity. The NADPH diaphorase activity was Ca2+/calmodulin-independent, required higher NADPH concentrations than NOS activity, and was affected by dNADPH to a lesser degree. Divalent cations interfered with the diaphorase assay. Per dimer, native NOS contained about 1 mol each of H4biopterin, FAD, and FMN, classifying it as a biopteroflavoprotein, and incorporated 1 mol of dNADPH. No dihydrobiopterin (H2biopterin), biopterin, or riboflavin was detected. These findings suggest that NOS may share cofactors between two identical subunits via high-affinity binding sites.(ABSTRACT TRUNCATED AT 250 WORDS)     

大鼠中缝背核内一氧化氮合酶阳性原位触液神经元的观察

通过研究大鼠中缝背核内远位触液神经元与一氧化氮合酶（NOS）阳性神经元的关系。以探讨一氧化氮（NO）是否是触液神经元在脑-脑脊液之间的信息传递有关,选用霍乱毒素亚单位B标记的辣根过氧化物酶（CB-HRP）逆行追踪与还原型尼可酰胺腺嘌呤二核苷磷酸（NADPH）黄递酶反应,CB-HRP标记的神经元密集分布于中缝背核,可见CB-HRP/NADPH-d双重标记的神经元,中缝背核内一部分远位触液神经元存在NOS,这些神经元在脑-脑脊液之间的信息传递中起着很重要的作用。     

Nitric oxide biosynthesis by Leishmania amazonensis promastigotes containing a high percentage of metacyclic forms

Due to the diversity of its physiological and pathophysiological functions and general ubiquity, the study of nitric oxide (NO) has become of great interest. In this work, it was demonstrated that Leishmania amazonensis promastigotes produces NO, a free radical synthesized from l-arginine by nitric oxide synthase (NOS). A soluble NOS was purified from L. amazonensis promastigotes by affinity chromatography (2′, 5′-ADP-agarose) and on SDS-PAGE the enzyme migrates as a single protein band of 116.2 (±6) kDa. Furthermore, the presence of a constitutive NOS was detected through indirect immunofluorescence using anti-cNOS and in NADPH consumption assays. The present work show that NO production, detected as nitrite in culture supernatant, is prominent in promastigotes preparations with high number of metacyclic forms, suggesting an association with the differentiation and the infectivity of the parasite.     

Testosterone induction of male‐typical sexual behavior is associated with increased preoptic NADPH diaphorase and citrulline production in female whiptail lizards

In rodents, male‐typical copulatory behavior is generally dependent on gonadal sex steroids such as testosterone, and it is thought that the mechanism by which the hormone gates the behavior involves the gaseous neurotransmitter nitric oxide. According to one model, testosterone induces an up‐regulation of nitric oxide synthase (NOS) in the preoptic area, increasing nitric oxide synthesis following exposure to a sexual stimulus. Nitric oxide in turn, possibly through its effect on catecholamine turnover, influences the way the stimulus is processed and enables the appropriate copulatory behavioral response. In whiptail lizards (genus Cnemidophorus), administration of male‐typical levels of testosterone to females induces the display of male‐like copulatory responses to receptive females, and we hypothesized that this radical change in behavioral phenotype would be accompanied by a large change in the expression of NOS in the preoptic area. As well as comparing NOS expression using NADPH diaphorase histochemistry between testosterone‐treated females and controls, we examined citrulline immunoreactivity (a marker of recent nitric oxide production) in the two groups, following a sexual stimulus and following a nonsexual stimulus. Substantially more NADPH diaphorase‐stained cells were observed in the testosterone‐treated animals. Citrulline immunoreactivity was greater in testosterone‐implanted animals than in blank‐implanted animals, but only following exposure to a sexual stimulus. This is the first demonstration that not only is NOS up‐regulated by testosterone, but NOS thus up‐regulated is activated during male‐typical copulatory behavior. © 2006 Wiley Periodicals, Inc. J Neurobiol, 2006     

The dynamic distribution of NO and NADPH–diaphorase activity during IBA-induced adventitious root formation

Nitric oxide (NO) is a multifunctional molecule involved in numerous physiological processes in plants. In this study, we investigate the spatiotemporal changes in NO levels and endogenous NO‐generating system in auxin‐induced adventitious root formation. We demonstrate that NO mediates the auxin response, leading to adventitious root formation. Treatment of explants with the auxin indole‐3‐butyric acid (IBA) plus the NO donor sodium nitroprusside (SNP) together resulted in an increased number of adventitious roots compared with explants treated with SNP or IBA alone. The action of IBA was significantly reduced by the specific NO scavenger, 2‐(4‐carboxyphenyl)‐4,4,5,5‐tetramethylimidazoline‐1‐oxyl‐3‐oxide (c‐PTIO), and the nitric oxide synthase (NOS, enzyme commission 1.14.13.39) inhibitor, N^G‐nitro‐l ‐arg‐methyl ester (l ‐NAME). Detection of endogenous NO by the specific probe 4,5‐diaminofluorescein diacetate and survey of NADPH–diaphorase activity (commonly employed as a marker for NOS activity) by histochemical staining revealed that during adventitious root formation, NO and NADPH–diaphorase signals were specifically located in the adventitious root primordia in the basal 2‐mm region (as zone I) of both control and IBA‐treated explants. With the development of root primordia, NO and NADPH–diaphorase signals increased gradually and were mainly distributed in the root meristem. Endogenous NO and NADPH–diaphorase activity showed overall similarities in their tissue localization. Distribution of NO and NADPH–diaphorase activity similar to that in zone I were also observed in the basal 2–4‐mm region (zone II) of IBA‐treated explants, but neither NO nor NADPH–diaphorase signals were detected in this region of the control explants. l ‐NAME and c‐PTIO inhibited the formation of adventitious roots induced by IBA and reduced both NADPH–diaphorase staining and NO fluorescence. These results show the dynamic distribution of endogenous NO in the developing root primordia and demonstrate that NO plays a vital role in IBA‐induced adventitious rooting. Also, the production of NO in this process may be catalyzed by a NOS‐like enzyme.     

Nitric oxide synthase is localized predominantly in the Golgi apparatus and cytoplasmic vesicles of vascular endothelial cells

The localization of nitric oxide synthase (NOS) in vascular endothelial cells of submucosal blood vessels from the guinea-pig ileum was examined using NADPH diaphorase histochemistry at the light microscopic level, and endothelial NOS immunohistochemistry at the light and electron microscopic level. The pattern of staining observed following NADPH diaphorase histochemistry and endothelial NOS immunohistochemistry was identical. Endothelial cells of the arterioles, capillaries and venules showed small patches of intense, perinuclear staining. Under the electron microscope, endothelial NOS immunoreactivity was found predominantly in association with the Golgi apparatus and with the membranes of some vesicles. Small regions of the plasma membrane and the rough endoplasmic reticulum also showed some immunoreactivity. The presence of NOS in the Golgi apparatus and in vesicles raises the possibility that NOS may be exteriorized by endothelial cells, and hence that nitric oxide is synthesized extracellularly.     

Relationships between NADPH diaphorase staining and neuronal, endothelial, and inducible nitric oxide synthase and cytochrome P450 reductase immunoreactivities in guinea-pig tissues

 The presence of NADPH diaphorase staining was compared with the immunohistochemical localization of four NADPH-dependent enzymes – neuronal (type I), inducible (type II), and endothelial (type III) nitric oxide synthase (NOS) and cytochrome P450 reductase. Cell types that were immunoreactive for the NADPH-dependent enzymes were also stained for NADPH diaphorase, suggesting that endothelial and neuronal NOS and cytochrome P450 reductase all show NADPH diaphorase activity in formaldehyde-fixed tissue. However, in some tissues, the presence of NADPH diaphorase staining did not coincide with the presence of any of the NADPH-dependent enzymes we examined. In vascular endothelial cells, the punctate pattern of staining observed with NADPH diaphorase histochemistry was identical to that seen following immunohistochemistry using antibodies to endothelial NOS. In enteric and pancreatic neurons and in skeletal muscle, the presence of NADPH diaphorase staining correlated with the presence of neuronal NOS. In the liver, sebaceous glands of the skin, ciliated epithelium, and a subpopulation of the cells in the subserosal glands of the trachea, zona glomerulosa of the adrenal cortex, and epithelial cells of the lacrimal and salivary glands, the presence of NADPH diaphorase staining coincided with the presence of cytochrome P450 reductase immunoreactivity. In epithelial cells of the renal tubules and zona fasciculata and zona reticularis of the adrenal cortex, NADPH diaphorase staining was observed that did not coincide with the presence of any of the enzymes. Inducible NOS was not observed in any tissue. Thus, while tissues that demonstrate immunoreactivity for neuronal and endothelial NOS also stain positively for NADPH diaphorase activity, the presence of NADPH diaphorase staining does not reliably or specifically indicate the presence of one or more NOS isoforms. Accepted: 2 September 1996     

Comparison of dark- and light-adapted carp retinas with NADPH diaphorase staining

The carp retina was examined by NADPH diaphorase histochemistry to determine if the staining pattern of retinal cells was changed depending on the adaptation state of the retina. When dark-adapted for 5 h, ellipsoids of inner segments of both rods and cones and some horizontal cells were heavily stained. Staining was also found in subpopulations of amacrine cells and ganglion cells. In addition, Muller cells were strongly positive for NADPH diaphorase. When light-adapted for 5h, ellipsoids of photoreceptors and ganglion cells were less intensely stained, whereas Muller cells and horizontal cells became negative for NADPH diaphorase. Furthermore, rod ON-center bipolar cells were clearly stained. The difference of staining of amacrine cells between dark- and light-adapted retinas was not significant. The differences in diaphorase-staining pattern between dark- and light-adapted retinas suggest that Muller cells, some horizontal cells and rod ON-center bipolar cells contain inducible nitric oxide synthase,     

Histochemical differentiation between nitric oxide synthase-related and -unrelated diaphorase activity in the rat olfactory bulb

The widely used NADPH-diaphorase reaction for demonstrating neuronal nitric oxide synthase is not as specific as previously thought, as it visualizes both a nitric oxide synthase-related activity and a nitric oxide synthase-unrelated diaphorase. In the present study, we used the rat olfactory bulb as a model to characterize the NADPH-diaphorase activity of neuronal nitric oxide synthase histochemically in comparison with neuronal nitric oxide-unrelated diaphorase activity. The NADPH-diaphorase activity of nitric oxide synthase peaked at pH 8 and at Triton X-100 concentrations of 1--2.5%. It was stable in an acidic environment but was reduced in the presence of Triton X-100 and was inactivated by the flavoprotein inhibitor, diphenyleneiodonium. It preferred beta-NADPH as the co-substrate to alpha-NADPH and alpha-NADH. In contrast, nitric oxide synthase-unrelated diaphorase peaked at pH 10, displayed a Triton X-100 optimum at a concentration of 1%, was unstable in an acidic environment and used beta-NADPH, alpha-NADPH and alpha-NADH to similar extents. Differences in the characteristics between neuronal nitric oxide synthase-related and nitric oxide synthase-unrelated NADPH-diaphorase can be used to increase the specificity of the histochemical nitric oxide synthase marker reaction. © Chapman & Hall