Dopamine-containing small intensely fluorescent cells and sympathetic ganglion function

This article reviews some of the neuropharmacology of the dopamine (DA)-containing small intensely fluorescent cells of sympathetic ganglia. The major metabolite of DA found in the ganglia is 3,4-dihydroxyphenylacetic acid (DOPAC). DOPAC content appears to be a direct reflection of DA synthesis. DA synthesis can be enhanced by muscarinic agonists and diminished by muscarinic antagonists. Neuroleptic drugs stimulate DA synthesis in the ganglion, which suggests that a local negative neuronal feedback loop might operate within the ganglion. There may be a correlation between deficient DA synthesis in spontaneous hypertensive rats and the development of hypertension. It is possible that some of the peripheral side effects of drugs that act on dopaminergic neurons in the brain might originate from the drugs' action on peripheral dopaminergic neuronal systems such as the sympathetic ganglion.     

A comparative and quantitative study of small intensely fluorescent (SIF) cells in the sympathetic ganglia of some small mammals

This comparative study of the number of SIF cells in the ganglions of the rat, cat, rabbit, mouse and hamster has confirmed that the mean number of SIF cells in the same ganglion of different species varies greatly, for instance in the superior cervical ganglion (SCG) of the rat and the cat, in the stellate ganglion of the cat and the mouse, or in the inferior mesenteric ganglion of the hamster and the other species. There is also considerable variability among individuals of the same animal species. In the SCG, the only ganglion for which there are data on the number of neurons, the ratio of SIF cells to neurons is around 1% in the rat, 0.2% in the rabbit, 0.3% in the mouse and 0.05% in the cat, i.e. a twenty-fold difference between the cat and the rat. Williams et al. (1975) distinguished type 1 SIF cells, corresponding to interneurons, from type 2, which are purely endocrine cells. Type 2 appears to be predominant in all ganglia, except the rabbit SCG where type 1 is highly predominant, and in all species, except the rat, in which this distinction is not applicable. The possible implications of these data on ganglionic functioning are discussed.     

Effect of hydrocortisone on the ultrastructure of the small,intensely fluorescent,granule-containing cells in cultures of sympathetic ganglia of newborn rats

Summary Sympathetic chain ganglia of newborn rats were cultured in Rose chambers with or without hydrocortisone. After one week, the cultures were examined by light microscopy for formaldehyde-induced catecholamine fluorescence and by electron microscopy after fixation in 5% glutaraldehyde solution and thereafter in 1% osmium tetroxide. Hydrocortisone (10 mg/l) caused a great increase in the number of the small, intensely fluorescent (SIF) cells in the ganglion explants, and the fluorescence intensity of these cells was also increased. The SIF cells corresponded to small, granule-containing (SGC) cells in the electronmicros copic preparations, and in addition to an increase in their number there was also an increase in the size and number of granular vesicles in the presence of hydrocortisone. In control cultures the granular vesicles were round (about 100 nm in diameter) or elongated (40–150 nm in cross section and 150–250 nm in length); both types of vesicles contained electron dense cores. In hydrocortisone-containing cultures round granular vesicles up to 200 nm in diameter were also observed; the cores of these vesicles were of variable electron density. It is concluded that in tissue culture, hydrocortisone causes an increased formation of catecholamine-containing granular vesicles in SIF-SGC cells and their precursors and an increase in the number of these cells.This work was supported by grants from the National Heart Foundation, the Australian Research Grants Committee and the Sigrid Juselius Foundation.University of Melbourne Senior Research Fellow, September, 1971 – August, 1972; present address: Department of Anatomy, University of Helsinki, Siltavuorenpenger, Helsinki, Finland, 00170.Holder of a grant from the National Health and Medical Research Council of Australia.Sunshine Foundation and Rowden White Research Fellow in the University of Melbourne, September, 1971 – August, 1972; present address: Department of Anatomy, University of Helsinki, Siltavuorenpenger, Helsinki, Finland, 00170.     

Hydrocortisone-induced increase in the number of small intensely fluorescent cells and their histochemically demonstrable catecholamine content in cultures of sympathetic ganglia of the newborn rat

Synopsis It is known that hydrocortisone causes a great increase in the number of small intensely fluorescent (SIF) cells in the sympathetic ganglia when injected into newborn rats. The effect of hydrocortisone on nervous tissuein vitro has not been studied previously.Pieces of newborn rat sympathetic ganglia were cultivated in Rose chambers. Hydrocortisone was dissolved in the medium in concentrations of 1–9 mg/l. Both control and hydrocortisone-containing cultures were examined daily by phase-contrast microscopy, and the catecholamines were demonstrated histochemically by formaldehyde-induced fluorescence after 7 days in culture.All cultures showed outgrowths of axons and supporting cells elements, although these were less extensive in the groups of cultures with hydrocortisone. After a week, SIF cells with a green fluorescence were observed in the control explants. In all cultures with hydrocortisone, a concentration-dependent increase was observed in the fluorescence intensity and the number of the SIF cells in the explant; numerous SIF cells were also seen in the outgrowth. Some SIF cells showed processes and the longest processes were seen in cultures with the highest concentration of hydrocortisone.It is concluded that hydrocortisone causes an increased synthesis of catecholamines in the SIF cellsin vitro, and an increase in their number by affecting either their division or their differentiation from a more immature form, or both. This effect was a direct one and not mediated by any system other than the ganglion itself. Induction of enzyme synthesis by hydrocortisone is proposed as an explanation of the increase in catecholamine concentration.University of Melbourne Senior Research Fellow, September 1971-August 1972Sunshine Foundation and Rowden White Trust Overseas Research Fellow in the University on Melbourne, September 1971-August 1972     

Quantitative fluorescence studies of the effects of catecholamines and hydrocortisone on endogenous amine levels in neurones and small intensely fluorescent cells of embryonic chick sympathetic ganglia in vivo and in vitro

Summary Chick embryo lumbar sympathetic ganglia (11 day) cultured for three days and uncultured (in vivo) ganglia of comparable age were freeze-dried and processed by the formaldehyde-induced fluorescence technique for the demonstration of biogenic monoamines. The catecholamine levels within principal neurone cell bodies and small intensely fluorescent (SIF) cells were then examined in plastic sections of the in vivo and in vitro ganglia by a quantitative fluorescence method under various experimental conditions. Culture of ganglia for three days in the presence of hydrocortisone acetate (10g/ml) resulted in an increased SIF cell fluorescence (P<0.001 compared to control) and a green to yellow colour shift in the fluorophore of SIF cells. No detectable alteration in the fluorescence level of neurones was observed. When neurones after three days in culture were incubated for 1 h in exogenous catecholamines, a significant increase in fluorescence levels (interpreted as an increase in catecholamine content) occurred with noradrenaline (2×10^–6 M; 2×10^–5 M). SIF cells in ganglia removed directly from 14-day old chicks similarly took up noradrenaline and dopamine, and also adrenaline (2×10^–5 M). Morphological results are presented which indicate that the cellular appearances and architecture of cultured ganglion explants are very similar to those in comparable ganglia in vivo.This work was supported by a grant from the Medical Research Council. We thank Mrs. G. O'Shea, Mr. T.T. Lee and Mr. P.F. Hire for their valuable technical assistance     

Histofluorescence and ultrastructural observations of small intensely fluorescent (SIF) cells in the superior sympathetic ganglion of the guinea pig

Summary Amine-containing small intensely fluorescent (SIF) cells are ubiquitous in vertebrate sympathetic ganglia and, in some species, SIF cells have been identified as interneurons. The hypothesis proposed in this study is that SIF cells in superior sympathetic ganglia of the guinea pig function as interneurons, with efferent connections characteristic for the species. Fluorescence (catecholamine) microscopy and 5-hydroxydopamine marker for electron microscopy were used to study SIF cells, their processes and connections in this ganglion.Brightly fluorescent fibers were seen attached to virtually all SIF cells, and were of two types. The first type, single or arranged in cords, interconnected elements of the SIF-cell system; these apparent linkages joined individual SIF cells as well as adjacent clusters. The electron-microscopic evidence for synaptic contacts between SIF cells warrants the claim that integrated action is a presumed function of these elements. The second type of SIF-cell process was generally of greater length. These individual, branching fibers made presumed connections with dendrites of most principal ganglionic neurons. This arrangement suggested by histofluorescence preparations was confirmed by electron microscopy to involve synaptic connections, and the postsynaptic element was shown to be continuous with the perikaryon of the principal ganglionic neuron. Ultrastructural evidence that collections of dense-cored vesicles occur within processes of both principal ganglionic neurons and SIF cells, in proximity to unsheathed portions of plasma membrane, leads to the conclusion that interstitial diffusion of catecholamine from both may occur; the finding of SIF cell processes adjacent to fenestrated blood vessels suggests that catecholamine may also be transported through capillaries.     

Relationship of blood vessels to small intensely fluorescent cells in the autonomic ganglion.

In our experiments we observed the relationship of the blood vessels to the small, intensely fluorescent cells (SIF cells) in the lower mesenteric ganglion of the cat. We injected the solution of Evan's blue into the ganglia and processed them with the fluorescent histochemical method by Falck and Hillarp. We observed that the SIF cells are placed in the ganglia closely to the blood vessels or closely round them. When observing lager groups of SIF cells placed at the edge of the ganglia a dense network of the blood vessels was observed among these cells.     

Sympathetic and sensory innervation of small intensely fluorescent (SIF) cells in rat superior cervical ganglion

The sympathetic ganglion contains small intensely fluorescent (SIF) cells derived from the neural crest. We morphologically characterize SIF cells and focus on their relationship with ganglionic cells, preganglionic nerve fibers and sensory nerve endings. SIF cells stained intensely for tyrosine hydroxylase (TH), with a few cells also being immunoreactive for dopamine β-hydroxylase (DBH). Vesicular acetylcholine transporter (VAChT)-immunoreactive puncta were distributed around some clusters of SIF cells, whereas some SIF cells closely abutted DBH-immunoreactive ganglionic cells. SIF cells contained bassoon-immunoreactive products beneath the cell membrane at the attachments and on opposite sites to the ganglionic cells. Ganglion neurons and SIF cells were immunoreactive to dopamine D2 receptors. Immunohistochemistry for P2X3 revealed ramified nerve endings with P2X3 immunoreactivity around SIF cells. Triple-labeling for P2X3, TH and VAChT allowed the classification of SIF cells into three types based on their innervation: (1) with only VAChT-immunoreactive puncta, (2) with only P2X3-immunoreactive nerve endings, (3) with both P2X3-immunoreactive nerve endings and VAChT-immunoreactive puncta. The results of retrograde tracing with fast blue dye indicated that most of these nerve endings originated from the petrosal ganglion. Thus, SIF cells in the superior cervical ganglion are innervated by preganglionic fibers and glossopharyngeal sensory nerve endings and can be classified into three types. SIF cells might modulate sympathetic activity in the superior cervical ganglion.     

A ratiometric and two-photon fluorescent probe for imaging hydrogen peroxide in living cells

As an important reactive oxygen species (ROS), hydrogen peroxide plays a significant role in the life activity system, and its abnormal levels are closely related to many diseases. Developing effective fluorescent probes for detecting hydrogen peroxide is very urgent. Therefore, we constructed a probe Z that can detect hydrogen peroxide in ratio. It has naphthimide as the fluorophore and phenylboronic acid pinacol esters as the recognition group. It shows higher sensitivity, lower detection limit, higher selectivity, and broad pH applicability. Moreover, probe Z has low cytotoxicity that can be used to detect exogenous hydrogen peroxide in HeLa cells and might be a potential tool for studying hydrogen peroxide in physiological activities.     

Small intensely fluorescent (SIF) cells and sympathetic nerves in the adult rabbit portal vein and during perinatal development

Summary The ontogenesis of small intensely fluorescent (SIF) cells and the adrenergic nerve plexus is described in stretch preparations of the rabbit portal vein. On the 25 to 26th days of gestation there was a predominance of SIF cells (8 to 30 m in diameter), but a few nerve fibres in bundles were also present. Each portal vein preparation contained 6 to 9 groups of cells. The distribution and number of SIF cells and nerve bundles remained constant until the 31st day of gestation at which stage the number of SIF cells had decreased, while the density of the nerve plexus had increased approximately 4-fold. The adult portal vein exhibited a dense adrenergic plexus, but SIF cells were absent from nine out of ten preparations.     

Cytochrome C is a hydrogen peroxide scavenger in mitochondria

The ability of succinate cytochrome c reductase (SCR) reduced cytochrome c to scavenge H(2)O(2) was investigated. H(2)O(2), whether added or produced by SCR, was efficiently removed when cytochrome c was reduced by SCR. On the other hand, ferrocytochrome c underwent re-oxidization when H(2)O(2) was added. Thus, these results indicate that cytochrome c reduced by succinate cytochrome c reductase has the ability to regulate H(2)O(max) in mitochondria.     

The distribution of noradrenergic nerves and small,intensely fluorescent (SIF) cells in the cat urinary bladder

Summary Fluorescence and electron microscopy have been used to study the distribution of noradrenergic nerves in the smooth muscle of the cat urinary bladder. Using the former technique, relatively few fluorescent noradrenergic nerves were observed in the body and fundus, while a rich plexus occurred adjacent to muscle cells of the bladder neck. The trigone could not be distinguished neuromorphologically from detrusor muscle in this region. Electron microscopy showed that the majority of noradrenergic terminals in the body and fundus were associated with presumptive cholinergic axons, while in the bladder neck noradrenergic terminals formed typical neuroeffector relationships with individual smooth muscle cells.Numerous ganglia occurred both in the adventitia and among the smooth muscle bundles, particularly in the bladder neck. The majority of the nerve cell bodies were non-fluorescent, although many contained bright orange autofluorescent granules, believed to be lysosomes. A small minority of ganglion cells were associated with fluorescent noradrenergic nerve terminals, thereby providing structural evidence for limited intraganglionic inhibition. In addition, occasional groups of small intensely fluorescent (SIF) cells were observed in some intramural ganglia and these were subsequently identified in the electron microscope. The possibility that these cells may provide a second inhibitory influence on bladder activity was considered.     

A red-emitting naphthofluorescein-based fluorescent probe for selective detection of hydrogen peroxide in living cells

We report the synthesis, properties, and cellular application of Naphtho-Peroxyfluor-1 (NPF1), a new fluorescent indicator for hydrogen peroxide based on a red-emitting naphthofluorescein platform. Owing to its boronate cages, NPF1 features high selectivity for hydrogen peroxide over a panel of biologically relevant reactive oxygen species (ROS), including superoxide and nitric oxide, as well as excitation and emission profiles in the far-red region of the visible spectrum (>600nm). Flow cytometry experiments in RAW264.7 macrophages establish that NPF1 can report changes in peroxide levels in living cells.     

Insulin-stimulated intracellular hydrogen peroxide production in rat epididymal fat cells.

Insulin stimulation of hydrogen peroxide production by rat epididymal fat cells was investigated by studying the oxidation of formate to CO2 by endogenous catalase. Under optimal concentrations of formate (0.1 to 1 mM) and glucose (0.275 mM), insulin stimulated formate oxidation 1.5- to 2.0-fold. Inhibitors of catalase activity, including nitrite and azide, inhibited both basal and insulin-stimulated formate oxidation at concentrations that did not interfere with insulin effects on glucose C-1 oxidation or glucose H-3 incorporation into lipids. The addition of exogenous catalase increased formate oxidation only slightly, while exogenous H2O2 (0.5 mM) stimulated formate oxidation by endogenous catalase strongly. These data indicate that the insulin-stimulated H2O2 production was intracellular. Insulin dose-response curves for formate oxidation were identical with those for glucose H-3 incorporation into lipids. The dependence of relative insulin effects on the logarithm of the glucose concentration was bell-shaped for formate oxidation and correlated highly with the coresponding dependences of glucose C-1 oxidation and glucose H-3 incorporation into lipids. This suggests that insulin stimulation of intracellular H2O2 production is linked to glucose metabolism. Since it is known that extracellular H2O2 can mimic insulin in several respects, these observations suggest that H2O2 may act as a "second messenger" for the observed effects of insulin.     

Age-related changes in the amount and intensity of the fluorescence of small, intensely fluorescing cells in the autonomic ganglia of rats

The number and intensity of fluorescence of small, intensely fluorescent cells were measured on serial slices of main pelvic (MPG) ganglion and lumbar ganglia of sympathetic trunk (LG), treated by modified Falck method, on days 1, 7, 14, 28, and 26-30 months of age. The content of paraform-induced fluorescence increased with age of two weeks and later in SIF cells of MPG and LG. The number of SIF cells in LG decreased with age, while that of MPG increased. The growth of a number of SIF cells in MPG was detected in large clusters.