NADPH-diaphorase Technique Research Articles

THYROID STATUS MODIFIES CARDIAC NITRIC OXIDE SYNTHASES DURING HEMORRHAGIC SHOCK: PP.22.400

The regulation of cardiac function is a complex process in which nitric oxide (NO) is a mediator and the thyroid status has a role. Objectives: To study the involvement of thyroid status and NO synthases (NOS) on hemodynamic changes induced by acute hemorragic shock. Animals euthyroid (E), hyperthyroid (H) and hypothyroid (h), are divided into two groups, control (C), and hemorrhaged rats (H) (withdrawal of 20 % of blood volume). Right atrium (A) and left ventricule (V) were removed at 120 min of hemorrhage. Histochemical NOS activity (NADPH-diaphorase technique), NOS, caveolin 1 and 3 (cav 1 and 3) protein levels (western blot) were evaluated. The results are expresed as X ± ES, n = 9/ group. Analysis of variance (ANOVA) followed by the ad hoc Bonferroni test was used for multiple comparisons. The 5% probability level was used as a criterion for biological significance. Results: Blood loss did not change neither eNOS and nNOS protein levels in A and V nor cav-3 protein levels in V. Conclusions: Acute blood loss increased NOS activity in A and V of euthyroid rats that correlated with changes in i-NOS protein levels. Hypovolemic state induced by acute hemorrhage induced changes in the cav-1 protein levels in A of hyperthyroid rats and in V of hyper and hypothyroid animals. The production of NO and its involvement in the cardiac adaptation to hemorrhage depend on the thyroid status. The coordinated expressional changes in NOS isoforms and their allosteric regulators, such as caveolin, may be viewed as a compensatory mechanism to maintain the production of bioactive NO.

Development of nitrergic neurons in the nervous system of the locust embryo

AbstractWe followed the development of the nitric oxide‐cyclic guanosine monophosphate (NO‐cGMP) system during locust embryogenesis in whole mount nervous systems and brain sections by using various cytochemical techniques. We visualized NO‐sensitive neurons by cGMP immunofluorescence after incubation with an NO donor in the presence of the soluble guanylyl cyclase (sGC) activator YC‐1 and the phosphodiesterase‐inhibitor isobutyl‐methyl‐xanthine (IBMX). Central nervous system (CNS) cells respond to NO as early as 38% embryogenesis. By using the NADPH‐diaphorase technique, we identified somata and neurites of possible NO‐synthesizing cells in the CNS. The first NADPH‐diaphorase‐positive cell bodies appear around 40% embryogenesis in the brain and at 47% in the ventral nerve cord. The number of positive cells reaches the full complement of adult cells at 80%. In the brain, some structures, e.g., the mushroom bodies acquire NADPH‐diaphorase staining only postembryonically. Immunolocalization of L‐citrulline confirmed the presence of NOS in NADPH‐diaphorase‐stained neurons and, in addition, indicated enzymatic activity in vivo. In whole mount ventral nerve cords, citrulline immunolabeling was present in varying subsets of NADPH‐diaphorase‐positive cells, but staining was very variable and often weak. However, in a regeneration paradigm in which one of the two connectives between ganglia had been crushed, strong, reliable staining was observed as early as 60% embryogenesis. Thus, citrulline immunolabeling appears to reflect specific activity of NOS. However, in younger embryos, NOS may not always be constitutively active or may be so at a very low level, below the citrulline antibody detection threshold. For the CNS, histochemical markers for NOS do not provide conclusive evidence for a developmental role of this enzyme. J. Comp. Neurol. 518:1157–1175, 2010. © 2010 Wiley‐Liss, Inc.

Development of nitrergic neurons in the nervous system of the locust embryo

We followed the development of the nitric oxide-cyclic guanosine monophosphate (NO-cGMP) system during locust embryogenesis in whole mount nervous systems and brain sections by using various cytochemical techniques. We visualized NO-sensitive neurons by cGMP immunofluorescence after incubation with an NO donor in the presence of the soluble guanylyl cyclase (sGC) activator YC-1 and the phosphodiesterase-inhibitor isobutyl-methyl-xanthine (IBMX). Central nervous system (CNS) cells respond to NO as early as 38% embryogenesis. By using the NADPH-diaphorase technique, we identified somata and neurites of possible NO-synthesizing cells in the CNS. The first NADPH-diaphorase-positive cell bodies appear around 40% embryogenesis in the brain and at 47% in the ventral nerve cord. The number of positive cells reaches the full complement of adult cells at 80%. In the brain, some structures, e.g., the mushroom bodies acquire NADPH-diaphorase staining only postembryonically. Immunolocalization of L-citrulline confirmed the presence of NOS in NADPH-diaphorase-stained neurons and, in addition, indicated enzymatic activity in vivo. In whole mount ventral nerve cords, citrulline immunolabeling was present in varying subsets of NADPH-diaphorase-positive cells, but staining was very variable and often weak. However, in a regeneration paradigm in which one of the two connectives between ganglia had been crushed, strong, reliable staining was observed as early as 60% embryogenesis. Thus, citrulline immunolabeling appears to reflect specific activity of NOS. However, in younger embryos, NOS may not always be constitutively active or may be so at a very low level, below the citrulline antibody detection threshold. For the CNS, histochemical markers for NOS do not provide conclusive evidence for a developmental role of this enzyme.

Effects of ascorbic acid supplementation in ileum myenteric neurons of streptozotocin-induced diabetic rats

The exacerbation of the oxidative stress and of the polyol pathway which impair damage myenteric plexus are metabolic characteristics of diabetes. The ascorbic acid (AA) is an antioxidant and an aldose reductase inhibitor, which may act as neuroprotector. The effects of AA supplementation on the density and cellular body profile area (CP) of myenteric neurons in STZ-induced diabetes in rats were assessed. Four groups with five animals each were formed: normoglycemic (C); diabetic (D); AA-treated diabetic (DS) and AA-treated normoglycemic (CS). Dosagen of 50mg of AA were given, three times a week, for each animal (group DS and CS). Ninety days later and after euthanasia, the ileum was collected and processed for the NADPH-diaphorase technique. There were no differences (P>0.05) in the neuronal density among the groups. The CP area was lower (P<0.05) in the DS and CS groups, with a higher incidence of neurons with a CP area exceeding 200µm² for groups C and D. The AA had no influence on the neuronal density in the ileum but had a neuroprotective effect, preventing the increase in the CP area and allowing a higher number of neurons with a CP area with less than 200µm².

Quantitative analysis of the neurons from the myenteric plexus in the ileum of rats submitted to severe protein deficiency

The effects of protein malnutrition on the quantitative aspects of the myenteric plexus in the ileum of adult Rattus norvegicus were assessed. Thirty 90-day-old rats were divided into two groups: Control Group (CG, n=15) and Experimental Group (EG, n=15). The CG received 26% protein chow and the EG received 4% protein chow for 90 days. At the end of the experiment, the animals from the CG weighed 369.63+/-26.33, and the ones from the EG 215.34+/-56.31. The ileum was submitted to Giemsa, NADH- and NADPH-diaphorase technique in order to evidence nervous cells in the whole-mount preparations. Animals from the EG presented a 41.75% body weight loss in relation to the CG as well as 17.6% length reduction for the ileum-jejunum. Moreover, the organ was 41% lighter for the EG. Giemsa-stained neurons were 17.02% more concentrated in the EG (p>0.05). NADH-diaphorase-stained neurons were 26.6% more concentrated in the EG (p<0.05), while the NADPH-diaphorase were 26.28% more concentrated in this group (p<0.05).

Assessment of NADPH-diaphorase stained myenteric neurons of the jejunum of diabetic rats supplemented with ascorbic acid

The relation between hyperglycemia and diabetic neuropathy has already been demonstrated in some studies. Among the theories proposed for its etiology the oxidative stress stands out. The performance of nitric oxide as a link between the metabolic and vascular neuropathogenic factors that triggers the diabetic neuropathy has already been put forward. This study aimed to assess the quantification and measurements of the cell body profile area (CBPA) of NADPH-diaphorase reactive (NADPH-dp) myenteric neurons of the jejunum of diabetic rats (induced by streptozotocin) supplemented with Ascorbic Acid (AA). These changes in the myenteric neurons seem to be related to the gastrointestinal disturbances observed in diabetes mellitus (DM). Twenty male Wistar rats (Rattus norvegicus) were distributed in 4 groups (n=5): controls (C), control supplemented (CS), diabetic (D), and diabetic suplemented (DS). DM was induced by estreptozotocin (50mg/kg body wt). One week after the induction and confirmation of the DM (glycemia exam), animals of the groups CS and DS received 50mg of AA three times a week by gavage. After 90 days of experiment, the animals were anesthetized with lethal thiopental dose (40mg/kg) and the collected jejunum processed for the histochemistry NADPH-diaphorase technique. Whole-mount preparations were obtained for quantitative and morphometric analysis of the myenteric neurons. A quantity of jejunum neurons in the Group D (96±7.5) was not different (P&gt;0.05) from Group DS (116±8.08), C (92±9.7), and CS (81±5.4), but in Group DS the quantity was higher (P&lt;0.05) than in Group C and CS. The CBPA of neurons from Group D (189.50±2.68µm²) and DS (195.92±3.75µm²) were lower (P&lt;0.05) than from Group C (225.13±4.37µm²) and CS (210.23±3.15µm²). The streptozotocin-induced DM did not change the jejunum-ileum area, the jejunum myenteric plexus space organization and the density of NADPH-dp neurons. The 50g AA-supplementation, three times a week, during 90 days, did not decrease hyperglycemia; however, it had a neuroprotective effect on the myenteric neurons, minimizing the increase on the CBPA of NADPH-dp neurons and increasing the amount of NADPD-dp neurons.

Nitric oxide regulates axonal regeneration in an insect embryonic CNS

In higher vertebrates, the central nervous system (CNS) is unable to regenerate after injury, at least partially because of growth-inhibiting factors. Invertebrates lack many of these negative regulators, allowing us to study the positive factors in isolation. One possible molecular player in neuronal regeneration is the nitric oxide (NO)-cyclic guanosine-monophosphate (cGMP) transduction pathway which is known to regulate axonal growth and neural migration. Here, we present an experimental model in which we study the effect of NO on CNS regeneration in flat-fillet locust embryo preparations in culture after crushing the connectives between abdominal ganglia. Using whole-mount immunofluorescence, we examine the morphology of identified serotonergic neurons, which send a total of four axons through these connectives. After injury, these axons grow out again and reach the neighboring ganglion within 4 days in culture. We quantify the number of regenerating axons within this period and test the effect of drugs that interfere with NO action. Application of exogenous NO or cGMP promotes axonal regeneration, whereas scavenging NO or inhibition of soluble guanylyl cyclase delays regeneration, an effect that can be rescued by application of external cGMP. NO-induced cGMP immunostaining confirms the serotonergic neurons as direct targets for NO. Putative sources of NO are resolved using the NADPH-diaphorase technique. We conclude that NO/cGMP promotes outgrowth of regenerating axons in an insect embryo, and that such embryo-culture systems are useful tools for studying CNS regeneration.

NADPH diaphorase reactive neurons in temporal lobe cortex of patients with intractable epilepsy and hippocampal sclerosis

Several studies have demonstrated a controversial involvement of NO in epileptogenesis. The aim of this study is to compare the NADPH diaphorase (NADPH-d) reactivity in the temporal cortex between surgical specimens of patients with intractable epilepsy and hippocampal sclerosis and autopsy controls. Brain samples of patients and postmortem controls were stained with the NADPH-d technique. Sprouting and larger areas of NADPH-d reactive neurons were found in the temporal cortex of epileptic patients.

Nitric oxide synthase activity in tissues of the blowfly Chrysomya megacephala (Fabricius, 1794)

Although insects lack the adaptive immune response of the mammalians, they manifest effective innate immune responses, which include both cellular and humoral components. Cellular responses are mediated by hemocytes, and humoral responses include the activation of proteolytic cascades that initiate many events, including NO production. In mammals, nitric oxide synthases (NOSs) are also present in the endothelium, the brain, the adrenal glands, and the platelets. Studies on the distribution of NO-producing systems in invertebrates have revealed functional similarities between NOS in this group and vertebrates. We attempted to localize NOS activity in tissues of naïve (UIL), yeast-injected (YIL), and saline-injected (SIL) larvae of the blowfly Chrysomya megacephala, using the NADPH diaphorase technique. Our findings revealed similar levels of NOS activity in muscle, fat body, Malpighian tubule, gut, and brain, suggesting that NO synthesis may not be involved in the immune response of these larval systems. These results were compared to many studies that recorded the involvement of NO in various physiological functions of insects.

Nitric oxide synthesis is blocked in the enteral nervous system during dormant periods of the snail Helix lucorum.

During dormancy of terrestrial snails, the whole neuromodulation of the nervous system is deeply modified. In this work we studied the adaptation of a previously described, putatively nitric oxide (NO) forming enteral network to the long-term resting periods of the snail Helix lucorum. The standard NADPH diaphorase (NADPHd) technique, which is an accepted method for histochemical NO synthase (NOS) detection, labeled the same enteric neurons of the midintestine in active or hibernated snails. Quantification of the NO-derived nitrite by the Griess reaction established that the nitrite formation is confined to the NADPHd-reactive network containing the midintestinal segment. In active snails, the nitrite formation could be enhanced by the NOS substrate L-arginine (10 microM-1 mM), but decreased by the known NOS inhibitors 1 mM N(omega)-nitro-L-arginine (NOARG) and 10 mM aminoguanidine (AG). Application of 1 mM L-arginine and 1 mM NOARG decreased the amplitude of the midintestinal muscle contractile activity, but did not affect the rectal motility. In dormancy, the nitrite formation was reduced in the NADPHd-reactive midintestinal network. Application of l-arginine could not provoke nitrite production and did not influence the midintestinal motility. Our findings indicate that NO is involved in the neural transmission to intestinal muscles of gastropods, but enteric release of NO is blocked during dormancy. The decreased NO synthesis is possibly due to an as yet undefined mechanism, by which the L-arginine/NO conversion ability of NOS could temporarily be inhibited in the long-term resting period of H. lucorum.

Ontogeny of NADPH diaphorase/nitric oxide synthase reactivity in the brain of Xenopus laevis

The development of nitric oxide synthase (NOS) expression in the brain of Xenopus laevis tadpoles was studied by means of immunohistochemistry using specific antibodies against NOS and enzyme histochemistry for nicotinamide adenine dinucleotide phosphate (NADPH)-diaphorase. Both techniques yielded identical results and were equally suitable for demonstrating the nitrergic system in the brain. The only mismatches were observed in the olfactory nerve and glomeruli and in the terminal nerve; they were intensely labeled with the NADPH-diaphorase technique but failed to stain with NOS immunohistochemistry. As early as stage 33, nitrergic cells were observed in the caudal rhombencephalon within the developing inferior reticular nucleus. At later embryonic stages, different sets of reticular and tegmental neurons were labeled in the middle reticular nucleus and, more conspicuously, in the laterodorsal and pedunculopontine tegmental nuclei. As development proceeded, new nitrergic cell groups gradually appeared in the mesencephalon, diencephalon, and telencephalon. A general caudorostral temporal sequence was observed, both in the whole brain and within each main brain subdivision. The premetamorphic period was mainly characterized by the maturation of the cell populations developed in the embryonic period. During prometamorphosis, the nitrergic system reached an enormous development, and many new cell groups were observed for the first time, in particular in the telencephalon. By the climax of metamorphosis, the pattern of organization of nitrergic cells and fibers observed in the brain was similar to that present in the adult brain. Transient expression of NOS was not detected in any brain region. Our data suggest that nitric oxide plays an important role during brain development of Xenopus. Comparison with the developmental pattern of nitrergic systems in other vertebrates shows that amphibians possess more common features with amniotes than with anamniotes.

Photoendocrine signal transduction in pineal photoreceptors of the trout. Role of cGMP and nitric oxide.

This study describes the presence and distribution of cGMP-immunoreactivity and of the nitric oxide (NO) synthesizing enzyme, NO synthase (NOS), as demonstrated by use of the NADPH-diaphorase technique in directly light sensitive pineal organ of the trout. Cyclic GMP immunohistochemistry revealed immunoreactivity in pineal photoreceptor cells that were identified by double-labeling with S-antigen, whereas NADPH-positive structures were located adjacent to these photoreceptor cells. Since NO is known to stimulate synthesis of cGMP, these results indicate a role for NO in pineal function, e.g. in cGMP related events in the phototransduction process as well as in the light-dark control of melatonin synthesis.

Selective upregulation of inducible nitric oxide synthase (iNOS) by lipopolysaccharide (LPS) and cytokines in microglia: in vitro and in vivo studies.

A role for free radicals has been proposed in infectious brain disease, where resident microglia cells upregulate the inducible nitric oxide synthase isoform (iNOS), and thus are capable of producing nitric oxide at enhanced rates. Using the constitutively expressed NADPH oxidase, microglial cells can generate superoxide, which reacts with nitric oxide to form the powerful oxidant peroxynitrite. In a mixed cell culture system of astrocytes and microglial cells, nitrite levels, used as an indicator of nitric oxide production, were elevated after the addition of lipopolysaccharide (LPS) and cytokines. Immunohistochemistry and the NADPH diaphorase technique demonstrated selective localization of the iNOS protein in microglial cells, whereas no iNOS protein or NADPH diaphorase activity was detected in astrocytes. A similar cellular distribution was observed in vivo following injection of LPS and cytokines into the rat striatum. By contrast, LPS and interferon-gamma led to translocation of NF-kappaB in microglia and in astrocytes, demonstrating that both cell types are responsive to the stimulus. Therefore, downstream control in iNOS expression is cell type-specific.

Whole-mount NADPH-diaphorase histochemistry is a reliable technique for the intraoperative evaluation of extent of aganglionosis.

Multiple seromuscular biopsies at three levels (narrow segment, transitional zone, and dilated segment) were taken and investigated intraoperatively to determine the extent of aganglionosis. Using the whole-mount preparation technique, circular muscle fibers were separated from the specimens. After a short prefixation, the muscle fibers were stained by the NADPH-diaphorase technique and were examined within 20-25 min. A fine and dense neuronal meshwork was observed between circular muscle fibers in the normal and ganglionic part of the bowel. In contrast, there was a complete lack of NADPH-diaphorase-positive fibers in the circular muscle of aganglionic colon. In the transitional zone, NADPH-diaphorase-positive fibers were markedly reduced compared to the ganglionic region. The density of these fibers increased and attained normal levels in the proximal bowel above the transition zone. These results suggest that whole-mount NADPH-diaphorase histochemistry is a three-dimensional technique suitable for the intraoperative evaluation of extend of aganglionosis. The technique is sufficiently rapid to be used in conjunction with routine frozen sections to assist in the diagnosis and in selecting the optimal level of resection at the time of pull-through operation.

Nitric oxide synthase in learning-relevant nuclei of the chick brain: morphology, distribution, and relation to transmitter phenotypes.

Nitric oxide (NO) has been implicated in learning in the hatchling chicken. To examine morphological and neurochemical properties of neurons that contain NO synthase (NOS) in brain regions known to be involved in learning and memory, the NADPH-diaphorase technique was used in conjunction with immunocytochemistry and tract tracing. A distinct cell type was NOS-labeled in the lobus parolfactorius (LPO) in the telencephalon, and neurons were labeled in the area ventralis of Tsai (AVT), the substantia nigra (nucleus tegmenti pedunculo-pontinus, pars compacta, TPc), and the locus coeruleus in the brainstem. Thus, NO may influence processes of learning and memory in the forebrain after release from intrinsic neurons and/or from extrinsic NOS-projections originating from the brainstem. DiI-tracing revealed that most of the NOS-positive neurons in the AVT/TPc project to the basal forebrain. The majority of tyrosine hydroxylase-positive (presumptive dopaminergic) neurons in the AVT and TPc expressed NOS. Double-labeling with antibodies to tyrosine hydroxylase, choline acetyltransferase, somatostatin, and the neurotrophin receptor as a marker for noradrenergic coeruleus neurons showed that NOS was not colocalized with noradrenergic or somatostatinergic neurons, and that less than a third of the cholinergic neurons were double-labeled for NOS. Injections of 6-hydroxydopamine into the brainstem did not reduce the density of NOS-labeled fibers in the LPO, indicating that most of the NO in the LPO originates from intrinsic neurons in the basal forebrain. Thus, NOS-containing presumptive local circuit neurons in the LPO are the most likely source of NO involved in learning of passive avoidance tasks in hatchling chicks.

Nitric oxide synthase in learning-relevant nuclei of the chick brain: Morphology, distribution, and relation to transmitter phenotypes

Nitric oxide (NO) has been implicated in learning in the hatchling chicken. To examine morphological and neurochemical properties of neurons that contain NO synthase (NOS) in brain regions known to be involved in learning and memory, the NADPH-diaphorase technique was used in conjunction with immunocytochemistry and tract tracing. A distinct cell type was NOS-labeled in the lobus parolfactorius (LPO) in the telencephalon, and neurons were labeled in the area ventralis of Tsai (AVT), the substantia nigra (nucleus tegmenti pedunculo-pontinus, pars compacta, TPc), and the locus coeruleus in the brainstem. Thus, NO may influence processes of learning and memory in the forebrain after release from intrinsic neurons and/or from extrinsic NOS-projections originating from the brainstem. DiI-tracing revealed that most of the NOS-positive neurons in the AVT/TPc project to the basal forebrain. The majority of tyrosine hydroxylase-positive (presumptive dopaminergic) neurons in the AVT and TPc expressed NOS. Double-labeling with antibodies to tyrosine hydroxylase, choline acetyltransferase, somatostatin, and the neurotrophin receptor as a marker for noradrenergic coeruleus neurons showed that NOS was not colocalized with noradrenergic or somatostatinergic neurons, and that less than a third of the cholinergic neurons were double-labeled for NOS. Injections of 6-hydroxydopamine into the brainstem did not reduce the density of NOS-labeled fibers in the LPO, indicating that most of the NO in the LPO originates from intrinsic neurons in the basal forebrain. Thus, NOS-containing presumptive local circuit neurons in the LPO are the most likely source of NO involved in learning of passive avoidance tasks in hatchling chicks.

Electrophysiological and Immunocytochemical Evidence for a cGMP-Mediated Inhibition of Subfornical Organ Neurons by Nitric Oxide

The activation of neurons in the subfornical organ (SFO) by angiotensin II (AngII) is well established and is widely regarded as the basis for the AngII-induced increase in water intake. Application of the nitric oxide (NO) donor sodium nitroprusside (SNP) led to an inhibition of the spontaneous electrical activity in 96% of the neurons sensitive for SNP (n = 50). In addition, the firing rate in 60% of the neurons inhibited by SNP decreased in response to superfusion with the natural substrate of the NO synthase (NOS) L-arginine whereas 70% increased their frequency after application of the NOS blocker NG-monomethyl-L-arginine (L-NMMA; n = 10). The inhibitory effect of SNP could be mimicked by application of membrane-permeable 8-Br-cGMP. The presence of nNOS, the neuronal isoform of NOS, was demonstrated immunocytochemically and using the NADPH-diaphorase technique on SFO slices. Using a highly selective antibody against cGMP in formaldehyde-fixed tissue, the NO donors SNP, 3-morpholinosydnonimine (SIN-1), and S-nitroso-N-acetyl-DL-penicillamine (SNAP) caused a strong increase in cGMP formation when applied under the same conditions as used for the electrophysiological recordings. These electrophysiological results suggest an important role for NO in SFO-mediated responses and offer a plausible explanation for the in vivo-observed opposite effects of AngII and NO on water intake.

Nitric oxide synthase in neurons and nerve fibers of lower airways and in vagal sensory ganglia of man. Correlation with neuropeptides.

The mediator accounting for the major relaxant responses to electrical field stimulation of human airways was previously identified as nitric oxide (NO). In the present study, we examined the distribution of the neuronal isoform of the NO-generating enzyme, nitric oxide synthase (bNOS, type I NOS) in nerve fibers of the human airways (trachea, large and small bronchi, bronchioli) as well as in human intrinsic and sensory ganglia of airway innervation by means of quantitative histochemistry (NADPH-diaphorase technique) and immunohistochemistry. Correlation with substance P (SP) and vasoactive intestinal peptide (VIP) was performed by double-labeling immunohistochemistry. NOS-containing nerve fibers were found to be present in the airway smooth muscle, around submucosal glands, around blood vessels and, very rarely, in the lamina propria. The innervation density of airway smooth muscle by NOS-containing nerve fibers decreased significantly from trachea to large-diameter bronchi to small-diameter bronchi, whereas NOS-containing nerve fibers were completely absent from bronchioli. Colocalization of NOS with VIP but not with SP was frequent in these nerve fibers. In airway intrinsic ganglia, the number of NOS-containing neuronal cell bodies increased from 57% in the trachea up to 83% in small bronchi. Around these perikarya, many nerve fibers displaying VIP-immunoreactive (VIP-IR) or SP-IR were found. In the superior vagal sensory (i.e., jugular) ganglion most of the neuronal cell bodies contained either NOS-IR or SP-IR; a colocalization of both was not as frequent. These data contribute to the understanding of the morphologic basis underlying the functional differences of the neural relaxant responses mediated by NO at different levels of the airway tree.

INTRARENAL LOCALIZATION OF NITRIC OXIDE SYNTHASE IN THE DEVELOPING PIGLET.† 2204

Nitric oxide (NO) may play a more important vasoactive role in the developing kidney than the adult, perhaps related to a different developmental intrarenal distribution of the NO synthesizing enzyme, nitric oxide synthase(NOS). These experiments determined the intrarenal histochemical localization of NOS in developing piglets ages 2 days, 1 week, 3 weeks and adult pigs. Kidneys were fixed by in-vivo perfusion, and placed in increasing sucrose concentrations for 72 hr. 15 micron cryostat sections were stained with the NADPH-diaphorase technique, which demonstrates the catalytic activity of NOS by the enzymatic reduction of nitro blue tetrazolium, NBT, in the presence of NADPH. Localization of NOS in the immature kidney differed from the adult in three major patterns: 1. NOS was present in the macula densa at all stages of nephron development, identifying the morphologic formation of this segment. 2. NOS localized to glomerular resistance arterioles in the developing kidney, most intensely in the 1 and 3 week old piglets. 3. All developing age groups intensely demonstrated NOS in segments of the thick ascending limb. In the adult, NOS was confined primarily to the macula densa, with faint staining of resistance arterioles and thick ascending limb. Summary: Intrarenal histochemical localization of NOS reveals distinct developmental localization patterns for the macula densa, glomerular resistance arterioles and tubular segments in the immature kidney that differ from the adult.Conclusion: The identification of NOS in these locations supports the role of NO as an important participant in developing renal function.

Developmental expression of NOS isoforms in fetal rat lung: implications for transitional circulation and pulmonary angiogenesis.

To better understand the role of nitric oxide (NO) in fetal lung development, specifically in the transition of the fetal circulation at birth, we studied the timing of cell-specific expression of NO synthase (NOS) isoforms from formation of lung buds (13th day of gestation) to 7 days postnatal. Expression of NOS was studied using immunohistochemical labeling with antibodies against the three known NOS isoforms and the NADPH diaphorase technique (NADPH-d). Endothelial NOS (eNOS) immunoreactivity was found in the cells of the 14-day fetal lung. As gestation proceeded, the quantity of these immunopositive cells increased, and they coalesced to form an inner (endothelial) layer of pulmonary vessels. This process of angiogenesis marked by eNOS-positive cells was seen from 15 days of gestation to at least 7 days postnatal. A majority of the eNOS immunoreactivity appeared densely in one focal spot in the cytoplasm, indicating that during development the eNOS may be primarily located in a cytoplasmic organelle. Epithelial cells of the rat airway from the same developmental period were positively stained with both brain NOS antibody (bNOS) and NADPH-d at the beginning of 13 days of gestation. Then the intensity of stainings began to decrease and reached the lowest level in the 16-day fetal lung. However, the NOS stainings of the epithelium, especially in small canalicular structures of the airways, began to increase at 18 days of gestation and was dramatically elevated at 20 days of gestation (term is 22 days). Postnatally, NOS in epithelium was decreased in distal airways in conjunction with the formation of alveolar structure. Inducible NOS (iNOS) immunoreactivity was also found in the epithelium of rat lung airways after 16 days of gestation. Unlike the bNOS staining, iNOS immunoreactivity exhibited a pattern of a small dot-like staining within epithelial cytoplasm during gestation and the first day postnatal, then changed to a pattern of diffuse cytoplasmic staining by the 7th postnatal day. This study concludes that 1) expression of three isoforms of NOS is present and regulated during lung development; 2) markedly increased NOS in epithelium near term supports a role for NO in mediating the pulmonary transition from fetal to neonatal life; and 3) eNOS immunohistochemistry serves as an effective marker to follow the process of pulmonary angiogenesis and suggests the concept of in situ formation of endothelial vesicles in developing mesenchyme.