Histochemistry of nucleotidyl cyclases and cyclic nucleotide phosphodiesterases

Immunocytochemistry of cGMP in the Cerebellum of the Immature, Adult, and Aged Rat: the Involvement of Nitric Oxide. A Micropharmacological Study

In this study we describe the localization of formaldehyde-fixed cGMP-immunoreactivity (cGMP-IR) in rat cerebellar tissue slices incubated in vitro. In the absence of phosphodiesterase inhibition, cGMP-immunofluorescence was of low intensity in tissue slices prepared from immature cerebella. Addition of isobutylmethylxanthine (IBMX) to the incubation medium resulted in the appearance of cGMP-IR in clusters of astrocytes in the internal granular layer. Addition of N-methyl-d-aspartate (NMDA), kainic acid, atrial natriuretic factor (ANF), or sodium nitroprusside (SNP) gave an intense cGMP-IR in Bergmann fibres, Bergmann cell bodies, and astrocytes in the internal granular layer. Astrocytes in the white matter showed cGMP-IR after incubation of the slice in the presence of ANF or nitroprusside, but not after NMDA or kainic acid. In addition, after SNP stimulation of cGMP production, cGMP-IR was found in fibres which were not positive for glial fibrillary acidic protein (GFAP). In the adult cerebellar slice, intense basal cGMP-immunostaining was observed in Bergmann fibres, Bergmann cell bodies, and astrocytes in the granular layer. No cGMP-IR was observed in Purkinje cells. Stimulation of the cGMP-content in the glial structures by NMDA, ANF, or SNP, was suggested by the immunocytochemical results. However, when measured biochemically, only the effect of SNP was statistically significant, and immunocytochemistry showed that SNP clearly stimulated cGMP synthesis in neuronal cell structures. In the cerebellum of the aged rat a reduced cGMP-IR was found compared to the adult, in the same structures which showed cGMP-IR in the adult. Basal cGMP-immunostaining was reduced in the presence of haemoglobin, methylene blue, by inhibiting nitric oxide synthesis with NG-monomethyl-l-arginine (NGMAr), or by depletion of external Ca2+. Also the stimulatory effect of NMDA and of ANF (partly) on the cGMP-IR was inhibited by these compounds. cGMP-IR after stimulation of guanylate cyclase by SNP was reduced by the concomitant presence of haemoglobin or methylene blue, but not by NGMAr, or by omission of Ca2+. Our results point to an important role for cGMP in the functioning of glial tissue in the cerebellum and also suggest a role for nitric oxide as an intercellular mediator in the functioning of glutamate and ANF in the cerebellum.

Atrial natriuretic peptide and guanylin-activated guanylate cyclase isoforms in human sweat glands

The ultracytochemical localization of membrane-bound guanylate cyclases A and C, stimulated by atrial natriuretic peptide and guanylin respectively, has been studied in human sweat glands. The results showed that the peptides stimulated guanylate cyclases A and C in both eccrine and apocrine glands. In the secretory cells, enzymatic activity was present on the plasma membranes and on intracellular membranes involved in the secretory mechanism. In eccrine glands, the cells of the excretory duct also presented enzymatic activity on the plasma membranes. In both glands, myoepithelial cells, surrounding the secretory cells, exhibited only guanylate cyclase A activity. These localizations of enzymatic activity suggest a role for both atrial natriuretic peptide and guanylin in regulating glandular secretion.

Ultracytochemical detection of guanylate cyclase C activity in alimentary tract and associated glands of the rat. Influence of pH, ATP and the ions Mg2+ and Mn2+

Intestinal guanylate cyclase C is activated by guanylin, an endogenous peptide. This activity seems to be modulated by adenine nucleotides, the ions Mg2+ and Mn2+, and pH. In this study, we report an ultracytochemical method for the localization of guanylate cyclase C activity at the electron microscope level. We studied the enzymatic activity in the presence or absence of guanylin and/or ATP, in the presence of the ions Mg2+ or Mn2+, and at different pH levels. The greatest distribution of enzymatic activity was detected in samples incubated at pH 8 and 7.4 in the presence of guanylin, Mg2+ and ATP. Guanylate cyclase C activity was detected at the surface epithelium of stomach and intestine, and in liver, exocrine pancreas and parotid gland. In the intestine, enzymatic activity was more widely distributed in the duodenum than in the jejunum-ileum and colon. In the small intestine, activity was more evident in the upper portion than in the basal portion of the villus. In samples incubated at pH 8 and 7.4 in the absence of ATP, enzymatic activity was detected only in small intestine, liver and exocrine pancreas. Enzymatic activity was present in duodenum incubated at pH 8 and 7.4 in the presence of Mn2+ and in the presence or absence of ATP. No samples incubated in all these experimental conditions but at pH 5 or samples incubated in the presence of guanylin only or in the absence of guanylin, displayed guanylate cyclase C activity. Our results suggest that a complete ultracytochemical detection of guanylate cyclase C activity requires guanylin as stimulator, and incubation in the presence of Mg2+ and ATP at pH 8 and 7.4.

S100B and S100A1 proteins in bovine retina:their calcium-dependent stimulation of a membrane-bound guanylate cyclase activity as investigated by ultracytochemistry

The Ca2(+)-binding proteins of the EF-hand type, S100B and S100A1, were detected in the outer segment of bovine retina photoreceptors where they are localized to disc membranes, as investigated by immunofluorescence and immunogold cytochemistry. S100B and S100A1 stimulate a membrane-bound guanylate cyclase activity associated with photoreceptor disc membranes in dark-adapted retina in a Ca2(+)-dependent manner, although with different Ca2+ requirements, as investigated by an ultracytochemical approach. Other retinal cell types express S100B and S100A1 as well. S100B is detected in the outer limiting membrane, fine cell processes in the outer nuclear layer and the outer plexiform layer, cell bodies in the inner nuclear layer and the ganglion cell layer, and the inner limiting membrane, whereas S100A1 has a more discrete distribution. S100B and S100A1 also stimulate a membrane-bound guanylate cyclase activity in photoreceptor cell bodies and Muller cells, but their effect appears independent of the light- or dark-adapted state of the retina and is observed at relatively high Ca2+ concentrations. These data represent the ultrastructural counterpart of recent biochemical observations implicating S100B and, possibly, S100A1 in the Ca2(+)-dependent stimulation of a photoreceptor membrane-bound guanylate cyclase activity [T. Duda, R. M. Goraczniak and R. K. Sharma (1996) Molecular characterization of S100A1-S1000B protein in retina and its activation mechanism of bovine photoreceptor guanylate cyclast. Biochemistry 35, 6263-6266; A. Margulis, N. Pozdnyakov and A. Sitaramayya (1996) Activation of bovine photoreceptor guanylate cyclast by S100 proteins. Biochem. Biophys. Res. Commun. 218, 243-247]. Our data suggest that at least S100B may take part in the regulation of a membrane-bound guanylate cyclase-based signalling pathway in both photoreceptors and Muller cells.

Ultracytochemical study of guanylate cyclases A and B in light- and dark-adapted retinas

The ultracytochemical localization of guanylate cyclases A and B activity has been studied after stimulation with atrial natriuretic peptide and C-type natriuretic peptide in light- and dark-adapted retinas and pigmented epithelium. The results showed that both peptides stimulated guanylate cyclases A and B activity in light-adapted retinas only. Guanylate cyclases A and B activity was detected on plasma membrane of body of photoreceptors, bipolar, horizontal and ganglion cells, on plasma membranes of interneuronal connections at plexiform layers and on the plasma membrane of fibres at the nerve fibres layer. Independently of the light-or dark-adapted state, the pigmented epithelium also presented guanylate cyclases A and B activity on basal and lateral plasma membranes.

Cytochemical and biochemical studies on adenylate cyclase activity in preneoplastic and neoplastic liver tissue and cultured liver cells

The ATP-analogue adenylyl(beta,gamma-methylene)diphosphonate was chosen as substrate for the cytochemical localization of adenylate cyclase (AC) activity. The tissues investigated covered normal rat liver and liver from carcinogen-treated animals with preneoplastic lesions and hepatocellular neoplasms, as well as cultured liver cells. The AC reaction product methylene diphosphonate was precipitated with Pb2+ immediately at the place of production. This approach permitted a precise localization of AC activity by light and electron microscopy. The specificity of the AC reaction was demonstrated by control reactions, including inhibition of AC with 2'5'-dideoxyadenosine and activation with forskolin, glucagon, and cholera toxin. Endogenous phosphatases were inhibited with tetramisole and NAD. In normal liver, AC activity was mainly localized in the sinusoidal membrane of hepatocytes. A distinct gradient in activity was observed within the liver lobule. Hepatocytes localized around the terminal hepatic venule showed a significant higher AC activity compared to hepatocytes near the portal tract. AC was clearly decreased in focal preneoplastic liver lesions of the glycogenotic-basophilic cell lineage leading to hepatocellular carcinomas. Cytochemically detected intensity of AC activity corresponded to data obtained by microbiochemical assays in laser-dissected tissue samples. A remarkable interdependence of AC activity and degree of differentiation was also seen in epithelial rat liver cell lines: Highly differentiated cells show high enzyme activity and vice versa, as shown by both cytochemical and biochemical examinations. It is concluded that alterations in cellular signal transduction caused by alterations in AC activity play an important role in hepatocarcinogenesis.

Microscopical localization on adenylate cyclase: a historical review of methodologies

The histochemistry technique for localizing adenylate cyclase has been developed over the past two decades. Early efforts were directed at overcoming the criticism of the lead capture technique, the inhibition of the enzyme by fixation, and problems associated with the substrate. The introduction of alternative metal ions, strontium and cerium, offered solutions to the criticism of the lead capture technique. The inhibition of the enzyme by the various fixation methods used has been rarely overcome satisfactorily and the use of non-fixed material during incubation is one of the alternatives that has been suggested. The introduction of adenylate (beta-gamma-methylene) diphosphate as an alternative substrate offers a solution to the problems associated with commercially available adenylyl imidodiphosphate. Although no standard medium or method has been accepted by all researchers, the histochemical technique still has a place in the arsenal of the modern cell biologist. The technique localizes the active enzyme, as opposed to the protein, active and nonactive, by immunocytochemistry and the precursors of the protein by in situ hybridization methods.

Cytochemical localization of guanylate cyclase in photoreceptor cells of the mouse

BACKGROUND

Light-stimulated excitation causes a decrease of the cGMP concentration in vertebrate photoreceptor cells. The cGMP content is restored by the catalytic action of a guanylate cyclase (EC 4.6.1.2).

METHODS

The spatial distribution of guanylate cyclase was determined cytochemically in rod visual cells of the mouse.

RESULTS

In retinal tissue of the mouse guanylate cyclase was found throughout the photoreceptor cells, in the outer and the inner segments, and was especially prominent in the cilia and in elongations of cilia extending into the outer segments. A reaction product of adenylate cyclase (EC 4.6.1.1) could not be demonstrated in vertebrate rod outer segments.

CONCLUSION

The relatively high amount of guanylate cyclase in the inner segments and the cilia may contribute-at least in part-to the actual concentration and the time course of concentration changes of the cGMP concentration in rod outer segments.

Detection of guanylate cyclases A and B stimulated by natriuretic peptides in gastrointestinal tract of rat

The ultracytochemical localization of membrane-bound guanylate cyclases A and B has been studied after stimulation with atrial natriuretic peptide, C-type natriuretic peptide and brain natriuretic peptide in the gastrointestinal tract of rat. The two isoforms are stimulated differently by the three peptides. The results showed that the atrial and C-type natriuretic peptides stimulated guanylate cyclase activity, whereas the brain peptide seemed not to activate enough of the enzyme to detect. The guanylate cyclase activity had a wider distribution in stomach and small intestine than in large intestine; nevertheless, the reaction product of guanylate cyclase A activity had a wider localization in the stomach, whereas the reaction product of guanylate cyclase B activity had a wider distribution in the small intestine. In the small and large intestine, we detected mostly similar localizations of guanylate cyclase activity irrespective of the peptide used; in the stomach the reaction products of guanylate cyclase A and B were detected in different cell types or in different sites of the same cell. In all the gastrointestinal tract, guanylate cyclase activity was detected mainly in three types of cells: exocrine and endocrine cells; undifferentiated and mature epithelial cells; and smooth muscle cells. These localizations of guanylate cyclase activity suggest its role in regulating glandular secretion, cellular proliferation and muscular activity.

Detection of membrane-bound guanylate cyclase activity in rat C6 glioma cells at different growth states following activation by natriuretic peptides

We studied the activity and the ultracytochemical localization of membrane-bound guanylate cyclase (GC) after stimulation with rat atrial natriuretic peptide (rANP), porcine brain natriuretic peptide (pBNP), rat brain natriuretic peptide (rBNP), or porcine C-type natriuretic peptide (CNP) in rat C6 glioma cells during proliferation or following exposure of confluent cells to dibutyryl cyclic AMP (db-cAMP) or retinoic acid (RA). Under our experimental conditions all peptides were activators of GC as demonstrated by the accumulation of cGMP within cells. During proliferation of C6 cells, the amounts of cGMP remained approximately constant. However, at subconfluency, confluency and postconfluency, the GC reaction product was located at different sites in C6 cells. At subconfluency, GC reaction product was on membranes of protoplasmic extensions, at postconfluency, GC reaction product was in association with membranes of cell bodies, and at confluency, both localizations of GC reaction product were detected. Incubation of confluent cells in culture medium containing db-cAMP or RA induced the appearance of long and slender protoplasmic extensions. Under these conditions, the GC reaction product was localized exclusively to these processes. These data suggest that GC is differentially located depending on the state of growth of glial cells, and that in differentiating glial cells GC is preferentially located in cell processes.

Towards a standard method to demonstrate adenylate cyclase activity at the electron microscopical level

The ventral epidermis of the frog Rana fuscigula is a typical tight epithelium which acts as a functional syncytium in the active transepithelial transport of sodium ions. Transport across this epithelium is regulated by cyclic adenosine monophosphate (cAMP). This study was undertaken to formulate an optimal protocol for the localization, within this epithelium, of adenylate cyclase; the enzyme involved in cAMP synthesis. The ventral epithelium of R. fuscigula was collagenase treated and processed using five different fixation/incubation protocols. The components of a basal incubating medium were modified by changing the localizing agent, adding adenylate cyclase stimulators and inhibitors of other enzymes. Control incubations undertaken included a) leaving the substrate out, b) prior heat inactivation of the enzyme, c) specific blockers and d) incubation for alkaline phosphatase as an alternative enzyme. The samples were then processed for electron microscopy. Localization of adenylate cyclase was best obtained, when fixing the tissue after incubation for 30 min at 37 degrees C. The medium that gave the best and most consistent localization contained magnesium chloride; as a required ion, theophylline, dithiothreitol, ouabain, levamisole; as enzyme inhibitors, forskolin; as a stimulator of adenylate cyclase, lead nitrate; as the capture agent and column purified adenylyl imidodiphosphate; as the substrate.

Cytochemical localization of adenylate cyclase in the sodium-transporting epithelium isolated from frog skin

A modified cytochemical technique with 5'-adenylylimidodiphosphate as substrate, was used to examine the distribution of adenylate cyclase in cells comprising the transepithelial Na+ transport pathway in isolated frog skin epithelium. Particular attention was paid to the effects of fixation on the activity and localization of adenylate cyclase. Fixation in glutaraldehyde alone or in combination with paraformaldehyde reduced the amount of reaction product, while better results were obtained using unfixed tissues. Optimum results were obtained following stimulation of adenylate cyclase with forskolin and in the presence of specific metabolic inhibitors. Adenylate cyclase was localized in the basolateral membranes of the principal cells which constitute a functional syncytium for Na+ transport and was absent from the apical membranes of the outermost granulosum cells. This distribution is consistent with the transepithelial Na+ transport model and defines the functional morphology of the cells involved in Na+ transport across frog skin. The results are compatible with the process of Na+ re-absorption across other epithelial cells, verifying that frog skin is a convenient model-tissue to study Na+ transport mechanisms. Adenylate cyclase was also found in membranes of the mitochondria-rich cells, a minor and parallel Na+ transporting pathway.

Detection of particulate guanylate cyclase in rat neurohypophysis after stimulation with ANF and BNP: an ultracytochemical study

We investigated the ultracytochemical localization of particulate guanylate cyclase (GC) in the rat neurohypophysis after activation with rat atrial natriuretic factor (rANF) or porcine brain natriuretic peptide (pBNP). Under our experimental conditions, the presence of GC reaction product indicated that rANF and pBNP were strong activators of particulate GC since samples incubated in basal conditions without rANF or pBNP did not reveal any GC reaction product. The rANF-stimulated GC was localized both to pituicytes and to nerve fibers and endings whereas the pBNP-stimulated GC was present exclusively in nerve fibers and endings. Recently, two subtypes of receptors for natriuretic peptides have been identified as two isoforms of particulate GC [24,50]. Our data indicate that the receptors of the two hormones have a partially distinct distribution in the rat neurohypophysis. In pituicytes, GC reaction product was found on plasma membrane of finger-like processes and on the membranes surrounding the lipid droplets. In nerve fibers and endings, GC reaction product was associated with intracellular membranes. This finding suggests that the enzyme could mediate an internal inhibitory action of these hormones on the release of vasopressin and oxytocin.

Receptors for N-acetylated sugars may stimulate adenylate cyclase to sensitize and tune mechanoreceptors involved in triggering nematocyst discharge

In fishing tentacles of sea anemones, cnidocyte/supporting cell complexes (CSCCs) trigger the discharge of nematocysts following stimulation by swimming prey of specific mechanoreceptors and chemoreceptors located on the supporting cells. Two types of mechanoreceptors have been identified: a contact-sensitive mechanoreceptor (CSM), and a vibration-sensitive mechanoreceptor (VSM). The CSMs become predisposed to initiate nematocyst discharge into static (i.e., nonvibrating) test probes in the presence of submicromolar free and conjugated N-acetylated sugars, a process referred to as sensitization. In seawater, the VSMs cause maximal discharge in response to test probes vibrating at 30, 50-55, and 75 Hz, whereas in the presence of submicromolar N-acetylated sugars the VSMs cause maximal discharge into test probes vibrating at 5, 15, 30, and 40 Hz, a process referred to as tuning. Tuning of the VSMs is accompanied by elongation of the stereocilium bundles comprising the VSMs. We report that dibutyryl cyclic-AMP sensitizes CSMs and tunes VSMs to the lower frequencies of 5, 15, 30, and 40 Hz, while cyclic-AMP has no such effects. Endogenous adenylate cyclase activity at the apical plasma membrane of the supporting cells is detectable by cytochemical methods in the presence of N-acetylated sugars but not in seawater alone. By activating adenylate cyclase with L858051, an analogue of forskolin, or by activating the stimulatory form of G proteins (Gs) with cholera toxin, CSCCs are induced to sensitize CSMs and to tune VSMs to the lower frequencies of 5, 15, 30, and 40 Hz. Caged GTP-gamma S also sensitizes CSMs but tunes VSMs to 5, 15, 30, 40, 55, 65, and 75 Hz, suggesting that VSM tuning may be regulated both by Gs and inhibitory G-proteins. Together, these results implicate cAMP as the second messenger for activated supporting cell chemoreceptors involved in sensitizing the CSMs and tuning the VSMs to lower frequencies.

On the stimulation of soluble and particulate guanylate cyclase in the rat brain and the involvement of nitric oxide as studied by cGMP immunocytochemistry

The localization of the particulate and soluble guanylate cyclase in the rat brain was studied using cGMP-immunocytochemistry. The cGMP was fixed to tissue protein using a formaldehyde fixative, and an antibody against cGMP was used which was raised against a cGMP-formaldehyde-thyroglobulin conjugate. We used the atrial natriuretic factor (ANF) as a model compound to stimulate the particulate enzyme and sodium nitroprusside (SNP) to stimulate the soluble enzyme. Sequential immunostaining for cGMP and glial fibrillary acidic protein (GFAP) showed that the great majority of the ANF-responsive, cGMP-producing cells were astrocytes. These ANF-responsive cells were found in discrete parts of the CNS; not all astrocytes in these regions were responsive to ANF. SNP stimulated cGMP in abundantly present neuronal fibres throughout the CNS; few neuronal cell bodies showed increased cGMP production after SNP. Moreover, SNP also raised cGMP in astrocytes, however, not all astrocytes showed the response to SNP. These results suggest that cells might be present in the CNS which contain both the soluble and the particulate guanylate cyclase. It was demonstrated that in the immature cerebellum, the cGMP was raised in glial structures in response to N-methyl-D-aspartate (NMDA), ANF, SNP, and kainic acid. The response to NMDA and kainic acid was sensitive to inhibition of the nitric oxide synthesis from L-arginine by NG-methyl-L-arginine. Surprisingly the response to ANF localized in the molecular layer and the granular layer was also sensitive to inhibition by NG-methyl-L-arginine, whereas the response to ANF in the deep nuclei was not. A small depolarization induced by 10 to 20 mmol/l K+ induced an increase in cGMP in chopped hippocampus tissue which showed a biphasic temporal characteristic. The initial, fast (30 sec), peak was shown to be localized in varicose fibres throughout the hippocampus, whereas the slower response (10 min) was localized in astrocytes. These studies demonstrate that the different enzymes which synthesize cGMP are differently localized. However, there is also a time dependency in the activation of the guanylate cyclases, which becomes apparent in different structures at different times. The possible role of cGMP as a regulator of ion homeostase is discussed.

Re-evaluation of the specificity of adenylyl (beta,gamma-methylene)diphosphonate as a substrate for adenylate cyclase

The conversion of the ATP-analogue adenylyl(beta,gamma-methylene)diphosphonate (AMPPCP) to cyclic AMP by adenylate cyclase of rat liver membranes was demonstrated using a radioimmunoassay for cyclic AMP. The conversion was only insignificantly lower than with adenylylimidodiphosphate (AMPPNP), another ATP-analogue which is usually used in the histochemical adenylate cyclase assay. The unspecific phosphate production was lower with AMPPCP as compared to AMPPNP. Therefore AMPPCP is considered to be a more suitable substrate for the histochemical assay. Unspecific phosphate deposition in the histochemical assay was due to ATP:pyrophosphatase activity and could be significantly inhibited by 1 mM NAD. However, a residual phosphate deposition due to cleavage of NAD could not be suppressed. Adenylate cyclase activity could be markedly activated by 5 x 10(-5) M forskolin, an activator of the catalytic subunit of the enzyme, and inhibited by 1 mM 2'5'-dideoxyadenosine, a specific inhibitor of adenylate cyclase. Adenylate cyclase was localized predominantly in the sinusoidal part of the plasma membrane, while ATP-pyrophosphatase seemed to be restricted to the canalicular part. It is concluded that at least three parallel assays are necessary for routine histochemical demonstration of adenylate cyclase, namely (1) basal activity (2) activation by forskolin and (3) inhibition by 2'5'-dideoxyadenosine, to demonstrate a specific enzyme reaction.

Second messenger enzymes in glial cells: a cytochemical point of view

Knowledge about second messenger metabolizing enzymes in neuroglia is still rather fragmentary. Therefore, the aim of the present investigation was to localize adenylate cyclase, guanylate cyclase, cyclic nucleotide phosphodiesterase and protein kinase A in glial cells of the rat hippocampus and cerebellum. Enzyme histochemical and immunohistochemical methods were used to detect the enzymes at the light and electron microscopic level. Astroglial cells were found to contain all 4 enzymes. Especially the microvascular glial cell processes were reactive. Oligodendroglial cells were only stained for adenylate cyclase acticity. Intracellularly, microtubules and intracellular membranes were frequently stained. The results point to the regulation of glial cell metabolism and of transport processes by cyclic nucleotides.

Synaptic receptors and intracellular signal transduction in the cerebellum

Glutamate receptor subtypes mediating excitatory synaptic neurotransmission in the cerebellar cortex are briefly reviewed from molecular biological, electrophysiological and pharmacological points of view. In particular, molecular biological findings of a novel family of AMPA-selective glutamate receptors are introduced, and the pharmacological and electrophysiological properties and the identity of cerebellar N-methyl-D-aspartate-sensitive receptors probably existing on Purkinje cells are discussed in comparison with well-established cerebral NMDA receptors. As possible intracellular mechanisms of the long-term depression of parallel fiber-Purkinje cell neurotransmission, the perspective of the roles of novel messengers, nitric oxide and arachidonic acid, is particularly commented based on recent information about cerebral long-term events. The specificity and possible independence of cerebellar excitatory amino acid receptors and linked intracellular second messengers are also suggested, taking the highly active guanylate cyclase system in Purkinje cells and other cerebellum-specific proteins into consideration.

Immunocytology on microwave-fixed cells reveals rapid and agonist-specific changes in subcellular accumulation patterns for cAMP or cGMP

We developed a method for cAMP and cGMP immunocytology based upon fixation by microwave irradiation. Fixation by microwave irradiation prevented three problems found with other fixation methods: nucleotide loss from cells, nucleotide diffusion within cells, and chemical modification of immunologic epitopes. Six agonists (four that stimulate adenylate cyclase and two that stimulate guanylate cyclase) produced cAMP or cGMP accumulation patterns that were agonist-specific, dose-dependent, detectable at physiologic concentrations of hormone, and time-dependent within 15 sec to 30 min. cAMP accumulation after 1 mM forskolin was greatest in the nucleus. Isoproterenol, prostaglandin E2, or calcitonin caused initial accumulation of cAMP along the plasma membrane, but later accumulation was greater in the cytoplasm. With calcitonin the later accumulation of cAMP was selectively perinuclear and along the nuclear membrane. Sodium nitroprusside stimulated cGMP accumulation diffusely throughout the cytoplasm. Atrial natriuretic peptide initiated cGMP accumulation near the plasma membrane, and cGMP accumulation moved from there into the cytoplasm. In conclusion, microwave irradiation preserved cell structure and allowed visualization of expected as well as unsuspected changes in intracellular accumulation patterns of cAMP and cGMP.

A functional parameter to study heterogeneity of glial cells in rat brain slices: cyclic guanosine monophosphate production in atrial natriuretic factor (ANF)-responsive cells

Stimulation of guanylate cyclase in vitro by atrial natriuretic factor (ANF) or sodium nitroprusside was studied in rat brain tissue slices biochemically as well as by means of cyclic guanosine monophosphate (cGMP) immunocytochemistry. The ANF-responsive, cGMP-producing cells were studied in the olfactory bulb, the septal area, the hippocampus, the medial amygdala, and the medial preoptic area. These cells, having the ANF-stimulated particulate guanylate cyclase, were characterized as astroglial cells on the basis of their glial fibrillary acidic protein (GFAP) immunostaining, although not all astroglial cells in these areas could be identified as cGMP-immunoreactive cells. Sodium nitroprusside-stimulated soluble guanylate cyclase activity was demonstrated in neuronal cell bodies and varicose fibers and was associated with blood vessel walls. Upon maturation, a significant decrease in cGMP production was found after stimulation by 100 nM ANF-(103-126) in the olfactory bulb, the medial amygdala, and the hippocampus, but not in the septal area; no change was found in these areas in cGMP content after stimulation of cGMP production by 10 microM sodium nitroprusside. Via cGMP immunocytochemistry, no qualitative differences were seen in the ANF-responsive, cGMP-producing cells upon maturation.

Localization of cGMP in the cerebellum of the adult rat: an immunohistochemical study

The localization of cGMP in the cerebellum of the adult rat after fixation with formaldehyde was studied with an antibody raised against a cGMP-formaldehyde-thyroglobulin conjugate. Three different protocols were used: (1) in vitro incubation of 300 microns cerebellar slices followed by fixation and cryostat sectioning; (2) in vitro incubation of 100 microns cerebellar slices followed by fixation with no further sectioning; (3) perfusion fixation of the anesthetized rat followed by vibratome sectioning. All 3 protocols gave essentially the same results: cGMP-immunoreactivity was found predominantly in Bergmann fibers in the molecular layer, in Bergmann cell bodies in the Purkinje cell layer (but not in Purkinje cells), and in astroglial cells in the granular layer.