The Histochemical Journal最新文献

Three isozymes of nitric oxide synthase (NOS) have been identified, cDNAs isolated and sequenced, and antibodies produced against each isozyme. Isozyme I (found primarily in central and peripheral neuronal cells), II (in cytokine-induced cells), and III (in endothelial cells) show less than 58% identity in the deduced amino acid sequences from humans. Many investigators have produced isozyme-specific antibodies and used these antibodies to locate these proteins in various cells and tissues. NOS-I is constitutively expressed, and the enzymatic activity is regulated by Ca2+ and calmodulin. The anti-NOS-I antibodies have allowed investigators to characterize non-adrenergic non-cholinergic neurons as nitrergic neurons, revealed NOS-I immunoreactivity in neurons and macula densa cells of the kidney and pancreatic islet cells, human skeletal muscle, and to demonstrate that various structures within the brain and spinal cord contain NOS-I. NOS-II is not regulated by Ca2+ and has been implicated in the pathophysiology of sepsis and autoimmune diseases. The anti-NOS-II antibodies have localized this isoform to infiltrating macrophages in pancreatic islets of diabetic rats, infiltrating macrophages and myocytes of a transplant heart model in rats, various cell types in bacterially and endotoxin-treated rats, alveolar macrophages in areas of inflammation in humans, and vascular smooth muscle cells of human atherosclerotic aneurysm. Isoform III is similar to NOS-I in that it is constitutively expressed and regulated by Ca2+ and calmodulin. Anti-NOS-III antibodies have found that this isoform is relatively specific for endothelial cells.

The gas nitric oxide is now recognized as an important signalling molecule that is synthesized from L-arginine by the enzyme nitric oxide synthase. This enzyme can be localized by different methods, including immunocytochemistry and the histochemical reaction for NADPH diaphorase. It has been demonstrated in various vertebrate cells and tissues, and recently several studies dealing with the production of nitric oxide in invertebrates have been published. Diploblastic animals, flatworms and nematodes seem to lack NADPH diaphorase activity but it has been found in the rest of the phyla studied. The most frequently reported sites for the production of nitric oxide are the central and peripheral nervous systems and, in primitive molluscs, the muscle cells. In insects, it has also been described in the Malpighian tubules. The roles of nitric oxide in invertebrates are closely related to the physiological actions described in vertebrates, namely, neurotransmission, defence, and salt and water balance. The recent cloning of the first nitric oxide synthase from an invertebrate source could open interesting avenues for further studies.

The three isoforms of nitric oxide synthase (NOS), neuronal (nNOS), endothelial (eNOS), and inducible (iNOS), can be visualized in cells and tissues by NADPH-diaphorase (NADPH-d) histochemistry, immunocytochemistry and in situ hybridization. Histochemical demonstration of NADPH-d shows the formazan final reaction product as a solid blue deposit. The ultrastructural localization of NADPH-d in the rat hippocampus showed an electron-dense deposit on membranes predominantly of the endoplasmic reticulum. The immunohistochemical demonstration of nNOS, using the nickel enhancement technique, shows positive reaction product over the dendrites and the soma of the nerve cell in the rat brain. Ultrastructural localization of nNOS in whole mount preparations of myenteric plexus and circular smooth muscle from guinea-pig ileum shows that NOS immunoreactivity was patchily distributed in myenteric neurones and was not specifically associated with any intracellular organelles or with plasma membranes. In situ hybridization, using radio-labelled probes, was used to study nNOS mRNA in lumbar dorsal root ganglia after peripheral transection of the sciatic nerve in rats. Labelling of the NOS mRNA-positive neurones is observed as a series of dense granules over the entire cell. NADPH-d histochemistry, immunocytochemistry and in situ hybridization each have a significant role to play in the localization of NOS. NADPH-d detects an enzyme associated with the NOS molecule, immunocytochemistry detects the NOS molecule, and in situ hybridization detects mRNA for NOS. Therefore, if each of these techniques is applied in carefully controlled experiments, consideration of the accumulated data should be valuable in revealing insights into the biology of NOS.

Physiological and histochemical studies have recently supported the notion that nitric oxide (NO) is the transduction signal responsible for the non-adrenergic, non-cholinergic relaxation of the vasculature as well as the airways of the mammalian lung. We report the presence of immunoreactivity to NO synthase (NOS) in nerve cell bodies and nerve fibres in the neural plexus of the buccal cavity and lungs of the frog, Rana temporaria, using the indirect immunocytochemical technique of avidin-biotin and the NADPH-diaphorase technique. The neural ganglia located next to the muscle layer and within the connective tissue of the buccal cavity were partially immunoreactive for NOS. In the lungs, NOS immunoreactivity occurred in nerve cell bodies, as well as in both myelinated and unmyelinated nerve fibres. Fine nerve fibres immunoreactive to NOS were observed within the muscle fibre bundles and next to the respiratory epithelium. Both the presence of NOS immunoreactivity and the positive histochemical reaction for NADPH-diaphorase in the neural plexus of amphibian respiratory tract suggests a broad evolutionary role for NO as a peripheral neurotransmitter.

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.

In rats, the distribution of nerve structures staining for NADPH-diaphorase, and showing immunoreactivities for nitric oxide synthase (NOS), tyrosine hydroxylase and various neuropeptides was studied in sensory ganglia (dorsal root, nodose and trigeminal ganglia), in sympathetic ganglia (superior cervical, stellate, coeliac-superior and inferior mesenteric ganglia), parasympathetic ganglia (sphenopalatine, submandibular, sublingual and otic ganglia), and in the mixed parasympathetic/sympathetic ganglia (major pelvic ganglia). The coincidence of neuronal cell bodies with strong NOS-immunoreactivity and strong NADPH diaphorase reactivity was almost total. The relative proportions of NOS-immunoreactive nerve cell bodies were largest in parasympathetic ganglia and major pelvic ganglia followed by sensory ganglia. In sympathetic ganglia no NOS-immunoreactive neuronal cell bodies could be detected. In parasympathetic and major pelvic ganglia, there was a very significant neuronal co-localization of immunoreactivities for NOS and vasoactive intestinal polypeptide (VIP). This was almost total in major pelvic ganglia, in which NOS-/VIP-immunoreactive nerve cell bodies were separate from sympathetic (tyrosine hydroxylase-/neuropeptide Y-immunoreactive), suggesting that NOS-/VIP-immuno-reactive neurons might also be parasympathetic.

Nitric oxide (NO) can exert a multitude of biological actions. NO, formed from L-arginine by a calcium-dependent enzyme (NO synthase) plays a key physiological role in regulating vascular tone and integrity. NO, formed by a constitutive neuronal isoform of NO synthase, likewise plays an important neuromodulator role. By contrast, high levels of NO can be generated following induction of a calcium-independent isoform of NO synthase. This excessive production of NO can provoke hypotension such as that observed in septic shock, and can exert cytotoxic actions leading to tissue injury and inflammation. Selective inhibitors of this inducible isoform thus have therapeutic potential in a number of disease states.

This review provides an update on the variety of histochemical techniques available for the cellular localization and expression of nitric oxide synthase in formalin-fixed tissue sections. The techniques of immunohistochemistry and NADPH-diaphorase histochemistry are discussed and the suitability of various types of probes and reporters which are useful for in situ detection of nitric oxide synthase mRNA expression are assessed. Figures are also included which illustrate the techniques described and protocols for in situ hybridization and NADPH-diaphorase histochemistry.

This report describes the development of a histochemical method for the demonstration of sarcoplasmic reticulum Ca-ATPase activity in cross-sections of skeletal muscle. The demonstration of sarcoplasmic reticulum Ca-ATPase activity is complicated by the fact that capturing reagents for phosphate inhibit the enzyme. We present a minimal model for heavy-metal-phosphate precipitation reactions which gives a theoretical description of the effect of enzyme inhibition on the rate of phosphate precipitation in the section. The model indicates that the choice of capturing reagent is crucial: whether or not ATPase activity can be demonstrated depends mainly on the inhibition constant and the solubility product of the phosphate salt of the capturing reagent (but also on a fairly large number of other factors). All lanthanides tested can be used to demonstrate sarcoplasmic reticulum Ca-ATPase activity, but dysprosium results in the highest staining intensity. This suggests that dysprosium inhibits sarcoplasmic reticulum Ca-ATPase to a lesser degree than the other lanthanides and/or the solubility product of its phosphate salt is smaller. As an example, the method is used to investigate the effect of thyroid hormone on sarcoplasmic reticulum Ca-ATPase activity in individual fibres of the rat soleus muscle.