Small granulated cell types in rat superior cervical and coeliac-mesenteric ganglia

Summary In the rat superior cervical and coeliac-mesenteric ganglia we have observed three types of small granulated (SG) cell: Type I cells are characterised by membrane-bounded cytoplasmic granules with a core of variable, moderate to low electron-density, whose limiting membranes are rounded in profile ranging from 50–150 nm in diameter. Type II SG cells contain numerous highly electron-dense, polymorphic cytoplasmic granules ranging from 100–300 nm in diameter. The haloes of Type II cell granules are variable in shape, and the core is often eccentrically located or fragmented. Type III SG cells contain membrane-bounded granules with a core of variable moderate to low electron-density. In profile these granules appear oblong or circular with average dimensions of 170 × 50 nm. All three SG cell types receive cholinergic-type pre-ganglionic terminals whose afferent nature is confirmed by their degeneration following pre-ganglionic neurectomy. Only Type I cells have been observed to donate efferent synapses to dendrites of principal ganglionic neurones and are thus interneuronal.This work was in part supported by a grant from the Medical Research Council. We wish to thank Mr. T.T. Lee for valuable technical assistance and Mr. P.F. Hire and Mr. K. Twohigg for illustrative help     

A comparison of the changes in the non-neuronal cell populations of the superior cervical ganglia following decentralization and axotomy

Transecting the axons of neurons in the adult superior cervical ganglion (SCG; axotomy) results in the survival of most postganglionic neurons, the influx of circulating monocytes, proliferation of satellite cells, and changes in neuronal gene expression. In contrast, transecting the afferent input to the SCG (decentralization) results in nerve terminal degeneration and elicits a different pattern of gene expression. We examined the effects of decentralization on macrophages in the SCG and compared the results to those previously obtained after axotomy. Monoclonal antibodies were used to identify infiltrating (ED1+) and resident (ED2+) macrophages, as well as macrophages expressing MHC class II molecules (OX6+). Normal ganglia contained ED2+ cells and OX6+ cells, but few infiltrating macrophages. After decentralization, the number of infiltrating ED1+ cells increased in the SCG to a density about twofold greater than that previously seen after axotomy. Both the densities of ED2+ and OX6+ cells were essentially unchanged after decentralization, though a large increase in OX6+ cells occurred after axotomy. Proliferation among the ganglion's total non-neuronal cell population was examined and found to increase about twofold after decentralization and about fourfold after axotomy. Double-labeling experiments indicated that some of these proliferating cells were macrophages. After both surgical procedures, the percentage of proliferating ED2+ macrophages increased, while neither procedure altered the proliferation of ED1+ macrophages. Axotomy, though not decentralization, increased the proliferation of OX6+ cells. Future studies must address what role(s) infiltrating and/or resident macrophages play in regions of decentralized and axotomized neurons and, if both are involved, whether they play distinct roles.     

Biosynthesis of prostaglandin E by rat superior cervical ganglia.

Abstract— —The biosynthesis of immunoreactive prostaglandin E (iPGE) was examined in homogenates of rat superior cervical ganglia and in isolated intact ganglia incubated in vitro. Ganglia homogenates produced iPGE from exogenous arachidonic acid. Prostaglandin synthesis by the homogenates was inhibited by the prostaglandin synthetase inhibitors, eicosatetraynoic acid, indomethacin and sodium meclofenamate and was stimulated by norepinephrine and dopamine. Whole ganglia incubated in Krebs-bicarbonate solution also synthesized iPGE which was released into the incubation bath in a time-dependent manner. As observed in the homogenates, norepinephrine and dopamine enhanced iPGE formation by the intact tissue. Phospholipase A also stimulated iPGE synthesis by the whole ganglia. The effect of phospholipase A was antagonized by dibutyryl cyclic AMP but not by dibutyryl cyclic GMP. The results suggest that neuronally synthesized prostaglandins may be available for modulating adrenergic neuron function and that endogenous neuronal constituents such as catecholamines and cyclic AMP may influence the activity of the prostaglandin synthetase system.     

A comparison of the changes in the non‐neuronal cell populations of the superior cervical ganglia following decentralization and axotomy

Transecting the axons of neurons in the adult superior cervical ganglion (SCG; axotomy) results in the survival of most postganglionic neurons, the influx of circulating monocytes, proliferation of satellite cells, and changes in neuronal gene expression. In contrast, transecting the afferent input to the SCG (decentralization) results in nerve terminal degeneration and elicits a different pattern of gene expression. We examined the effects of decentralization on macrophages in the SCG and compared the results to those previously obtained after axotomy. Monoclonal antibodies were used to identify infiltrating (ED1+) and resident (ED2+) macrophages, as well as macrophages expressing MHC class II molecules (OX6+). Normal ganglia contained ED2+ cells and OX6+ cells, but few infiltrating macrophages. After decentralization, the number of infiltrating ED1+ cells increased in the SCG to a density about twofold greater than that previously seen after axotomy. Both the densities of ED2+ and OX6+ cells were essentially unchanged after decentralization, though a large increase in OX6+ cells occurred after axotomy. Proliferation among the ganglion's total non‐neuronal cell population was examined and found to increase about twofold after decentralization and about fourfold after axotomy. Double‐labeling experiments indicated that some of these proliferating cells were macrophages. After both surgical procedures, the percentage of proliferating ED2+ macrophages increased, while neither procedure altered the proliferation of ED1+ macrophages. Axotomy, though not decentralization, increased the proliferation of OX6+ cells. Future studies must address what role(s) infiltrating and/or resident macrophages play in regions of decentralized and axotomized neurons and, if both are involved, whether they play distinct roles. © 2002 Wiley Periodicals, Inc. J Neurobiol 53: 68–79, 2002     

Differences in neuronal lipid composition between superior cervical ganglia and nodose ganglia of the rat

The lipid content and composition of rat superior cervical ganglia containing sympathetic motor neurons and nodose ganglia containing parasympathetic sensory neurons were studied for the first time to elucidate the mechanism of the different effects of exogenous gangliosides on these neurons in the culture medium. The ganglioside content of the superior cervical ganglia was almost 3-times that of the nodose ganglia. Although both ganglia contained GM3, GD3, GD1b and GT1b as major gangliosides, the nodose ganglia additionally contained a significant amount of sialosyllactoneotetraosylceramide LM1 (10% of total sialic acids). Contrasting with nodose ganglia, vagus fiber and dorsal root ganglia of rats, superior cervical ganglia had a higher content of sulfatide than galactosylceramide. The phospholipid content was lower in superior cervical ganglia than in nodose ganglia. Superior cervical ganglia contained less ethanolamine plasmalogen and more phosphatidylcholine than nodose ganglia. Sphingomyelin in superior cervical ganglia contained mainly medium-chain fatty acids, while that in nodose ganglia contained mainly longer-chain fatty acids. Differences in the fatty acid composition of glycerophospholipids were also observed. The results indicate that the properties of neuronal cell membranes from superior cervical ganglia and nodose ganglia are quite different, and that the differences may reflect the physiological roles of these ganglia.     

Nerve growth factor induced turnover of phosphatidylinositol in rat superior cervical ganglia

The addition of nerve growth factor to organ cultures of superior cervical ganglia from immature rats specifically stimulated the incorporation of 32P-orthophosphate into phosphatidylinositol fraction. Equimolar concentrations of other hormones such as insulin, glucagon, thyroxine and growth hormone did not cause any stimulation of the incorporation of 14C-myoinositol into phosphatidylinositol. The stimulation of phosphatidylinositol turnover was observed over a concentration of nerve growth factor ranging from 10^?10M to 10^?7M. Nerve growth factor specific “inositide effect” was found to be sensitive to nerve growth factor antibody, 2,4-dinitrophenol, a high concentration of bovine growth hormones but not to Actinomycin D. The physiological significance of this finding in relation to nerve growth factor action in this target tissue is discussed.     

Three-dimensional distribution of Ag-NOR proteins in rat superior cervical ganglia nucleoli according to circadian rhythm

A three-dimensional reconstruction of the distribution of Ag-NOR proteins in nucleoli of sympathetic neurons of a rat killed during the dark period of its light-dark cycle was compared with previously reported analyses on the three-dimensional distribution of fibrillar centers, the high-resolution localization of these proteins, and the morphometric results. The domain occupied by these proteins appeared to far exceed that of the fibrillar centers and included the dense fibrillar RNP component. In the present material this component in turn provided partial bridging between the units consisting of the fibrillar centers plus their surrounding dense fibrillar component.     

Preganglionic discharge induced by acetylcholine in the superior cervical ganglia of the rat

ACh (5.10(-4) M), when applied to isolated ganglion preparations elicited an apparently antidromic discharge in the cervical sympathetic trunk. The intensity of this back-firing was found to be about 10 times lower than that of the postganglionic discharge evoked by ACh in the internal carotid nerve. Both responses however displayed a similar time course consisting mainly of an early and a late component. In the back-firing the early component died out in few seconds, while the late one lasted 20-30 seconds. The two components were cancelled by d-tubocurarine (5.10(-6) M) and atropine (10(-6) M) respectively, suggesting that both nicotinic and muscarinic cholinoceptive sites are involved. In chronically decentralized preparations ACh evoked a clear back-firing response not substantially different from that elicited in normal ganglia. Therefore it is likely that the back-firing phenomenon is not due to antidromic activation of preganglionic fibers. The back-firing observed in the rat superior cervical ganglion was interpreted as being due to activation of sympathetic neurons, known to give rise to recurrent axons in the cervical sympathetic cord.     

Hormone effects on muscarinic cholinergic binding in bovine and rat sympathetic superior cervical ganglia

Muscarinic receptors were assessed by [3H]-quinuclidinyl benzilate (QNB) binding in 900 xg supernatants of bovine superior cervical ganglia (SCG). At 30 degrees C half maximal binding was reached within 3 min and equilibrium within 30 min. Scatchard analysis revealed a single population of binding sites with dissociation constant (Kd) = 0.15 +/- 0.01 nM and site concentration (Bmax) = 101 +/- 4 fmoles/mg prot. Binding was specific for muscarinic drugs. Incubation of bovine SCG with different hormones (10(-7)M) indicated that LH, TRH and testosterone depressed significantly Bmax, and that prolactin decreased both Kd and Bmax of [3H] -QNB binding. Several other hormones tested (TSH, GH, FSH, LHRH, angiotensin II, bradykinin, melatonin, estradiol, thyroxine and triiodothyronine) did not affect QNB binding. Hormone effects were not due to a direct interference with radioligand binding to membrane. The injection of LH to orchidectomized rats depressed Bmax of SCG QNB binding without changing the Kd. These results suggest that muscarinic cholinergic neurotransmission in SCG may be affected by hormones.     

Nerve growth factor-mediated induction of tyrosine hydroxylase in rat superior cervical ganglia in vitro.

Exposure of rat sympathetic ganglia to 3 microgram/ml of 2.5 S nerve growth factor (NGF) resulted in a 100% increase in tyrosine hydroxylase activity within 48 h. Pulselabeling of proteins with [3H]leucine, followed by immunoprecipitation with antibodies to tyrosine hydorxylase and isolation of the precipitated enzyme by gel electrophoresis, demonstrated that the increase in tyrosine hydroxylase activity was due to enhanced de novo synthesis. The incorporation of [3H]leucine into tyrosine hydroxylase was increased by 150% compared to a 17% increase in total protein synthesis, which was not statistically significant. The fact that the half-life of pulse-labeled tyrosine hydroxylase was the same for NGF-treated and control organ cultures of superior cervical ganglia excludes the possibility that enhanced tyrosine hydroxylase labeling by NGF is due to decreased degradation. We conclude that, without modulatory factors which play a role in vivo, NGF can enhance the synthesis of tyrosine hydroxylase in sympathetic ganglia in vitro, provided organ culture conditions which permit optimal survival of adrenergic neurons are selected.     

Depolarization regulates expression of a synaptic vesicle protein in rat superior cervical ganglia in vitro

The role of membrane depolarization in the regulation of expression of a neuron specific protein was evaluated by culturing superior cervical ganglia from neonatal rats in defined medium and manipulating neuronal activity by depolarizing agents. P65 is an integral membrane protein of synaptic vesicles and can be used as a marker for general neuronal maturation. P65 antigen levels were quantified by indirect radioimmunoassay, using monoclonal antibodies. The expression of p65 in ganglion explants increased by 40-100% when the cultures were treated with the depolarizing agents, veratridine or high potassium. The veratridine effect could be blocked by simultaneous treatment with the sodium channel blocker, tetrodotoxin (TTX). The rise in p65 was not evident until 36 h after depolarizing treatment had begun and reached peak levels after 48 h, with no further increases observed with sustained treatment. After removal of the depolarizing treatment, p65 levels returned to control values after 24 h. P65 joins a growing number of molecules whose expression is regulated by membrane depolarization.     

Retrograde alteration of 6-phosphogluconate dehydrogenase in axotomized superior cervical ganglia of the rat.

Mechanisms underlying increased activity of 6-phosphogluconate dehydrogenase (6-phospho-D-gluconate: NADP oxidoreductase [decarboxylating] EC 1.1.1.44) in axotomized rat superior cervical ganglia were explored using a highly sensitive micro-immunochemical assay employing antibodies raised in rabbits against the purified enzyme. 6-Phosphogluconate dehydrogenase was purified from rat brain more than 1700-fold by salt fractionation, anion exchange, and immunoaffinity chromatography. The purified enzyme consisted of identical subunits having molecular weights of about 48,800 which could aggregate to catalytically active isomers of various sizes; however, only one form of the enzyme was detected in freshly prepared homogenates of rat neural tissue. Physical and immunological properties of the enzyme from rat brain were similar to those from superior cervical ganglia and liver. Augmented 6-phosphogluconate dehydrogenase activity noted in superior cervical ganglia 2 days after transection of major postganglionic nerve trunks was accompanied by a parallel increase in immunoreactive protein. Michaelis constants of the enzyme were the same in control and axotomized ganglia, and the presence of activators and inhibitors was not detected. It is concluded that increases in 6-phosphogluconate dehydrogenase subsequent to axotomy can be accounted for entirely by an increase in the steady state concentration of this protein.