Effect of early postnatal division of the postganglionic nerves on the development of principal cells and small intensely fluorescent cells in the rat superior cervical ganglion

Neurturin regulates postnatal differentiation of parasympathetic pelvic ganglion neurons, initial axonal projections, and maintenance of terminal fields in male urogenital organs

We have investigated the development of autonomic nerves in the urogenital tract of male mice and the effect of neurturin gene deletion on this process. At birth, autonomic innervation of the reproductive organs was sparse, but urinary bladder smooth muscle was well innervated. Further innervation of reproductive tissues occurred until P21, but noradrenergic axons established their complete terminal field later than nitrergic cholinergic axons: in adults the former are more prevalent, yet this became apparent only at P7 (vas deferens, seminal vesicles), P14 (prostate) or after P14 (penis). Neurturin was essential for initial projection of axons (mucosa of vas deferens), maintenance of terminal fields (prostate and seminal vesicles), or both functions (cavernosum of penis). In contrast, some targets (e.g., bladder muscle and suburothelium, vas deferens smooth muscle) were unaffected by neurturin gene deletion. Pelvic ganglion neurons more than doubled between birth and adulthood, probably as aresult of continued maturation of p75-positive undifferentiated neuronal precursors rather than cell division. The adult number of neurons was achieved by P7 (sympathetic) or P21 (parasympathetic). In adult neurturin knockout mice, there were approximately 25% fewer parasympathetic neurons compared with wild types, because of failure of differentiation after P14. This study revealed the complexity of postnatal maturation of urogenital innervation, with each organ showing a distinct chronology of innervation and different requirement for neurturin. Our results also indicate that in adults there will be distinct differences in neurturin dependence between organs, such that proregenerative therapies may have to be tailored specifically for the nerve pathway of interest.

Differential expression and regulation of the high-affinity choline transporter CHT1 and choline acetyltransferase in neurons of superior cervical ganglia

Previous studies revealed that leukemia inhibitory factor (LIF) and retinoic acid (RA) induce a noradrenergic to cholinergic switch in cultured sympathetic neurons of superior cervical ganglia (SCG) by up-regulating the coordinate expression of choline acetyltransferase (ChAT) and the vesicular acetylcholine transporter. Here, we examined the effect of both factors on high-affinity choline uptake (HACU) and on expression of the high-affinity choline transporter CHT1. We found that HACU and CHT1-mRNA levels are up-regulated by LIF and down-regulated by RA in these neurons. Thus, in contrast to LIF, RA differentially regulates the expression of the presynaptic cholinergic proteins. Moreover, we showed that untreated SCG neurons express HACU and CHT1-mRNAs at much higher levels than ChAT activity and transcripts. In intact SCG, CHT1-mRNAs are abundant and synthesized by the noradrenergic neurons themselves. This study provides the first example of CHT1 expression in neurons which do not use acetylcholine as neurotransmitter.

The ratio of pre- to postganglionic neurons and related issues in the autonomic nervous system

The motor outflow of the autonomic nervous system (ANS) is differentiated into two major divisions, parasympathetic (PSNS) and sympathetic (SNS). Both are organized hierarchically into pre- and postganglionic levels, but classically the two divisions have been assumed to differ in their ratios of pre- to postganglionic neurons. The PSNS been characterized as having lower ('one-to-few') ratios, whereas the SNS has been described as possessing higher ('one-to-many') ratios. These patterns have been assumed to measure differing divergences of the outflows. In this review, a ratio of pre- to postganglionic neurons is called a ratio index, and the idea that the PSNS and SNS have characteristically different ratio indexes and divergences is called the ratio rule. The putative differences in the ratio indexes of the two divisions - as well as Fulton's influential proposal that they form one of the bases of contrasting functional capacities of the PSNS and SNS - have been widely accepted for nearly for nearly three quarters of a century. A survey of the original observations yielding the concept of the ratio rule as well as the more recent estimates of pre- and postganglionic numbers, however, challenges both the generality and the adequacy of the ratio rule and indexes. The originally formulated differences between the PSNS and SNS represent an overgeneralization since they were based on observations of only two ganglia, the ciliary ganglion in the PSNS and the superior cervical ganglion in the SNS. Furthermore, these original estimates were based on limited samples and were subject to a number of counting artifacts. A survey of the literature suggests that ratio indexes vary much more within each ANS division than they do between the two divisions. When ganglia other than the ciliary and superior cervical are examined, the two divisions of the ANS have broad, largely overlapping ranges of ratio indexes. Additionally, other PSNS-SNS pairs can be found in which the relative sizes of their respective indexes are completely contrary to the ratio rule. For a given ganglion, there are substantial differences in the ratio index between species, between individuals of the same species, and between stages of development in the same species. Furthermore, both divisions of the ANS have wide and largely overlapping ranges of physiological effects varying from specific to diffuse, from local to widespread. Finally, the ratio index measure ignores the degree of convergence found in different ganglia, and it is insensitive to the fact that many ganglia have multiple functionally distinct motor neuron pools, each with separate inputs varying in their degrees of divergence and/or convergence. Thus ratio indexes do not differentiate the PSNS from the SNS, and conclusions based on such putative distinctions are questionable.

Principal neurons of the lumbar sympathetic ganglia increase in number with body size

Neuron number appears to be matched to body size during early development by the modulation of the processes of proliferation and naturally occurring cell death. However, body size increases rapidly as the juvenile becomes an adult, long after these processes cease to operate. The present study shows that principal neurons of lumbar sympathetic ganglia increase in number four- to fivefold during postmetamorphic life of the bullfrog. Rana catesbeiana. This increase in neuron number cannot be attributed to either counting error or selection bias and was associated with greater innervation of particular hindlimb targets, as demonstrated by retrograde labeling with horseradish peroxidase. Injection of [3H]thymidine (a marker of DNA synthesis) every third day for 20-22 weeks failed to provide evidence of neuron proliferation, although, on the basis of changes in body length during this period, substantial numbers of neurons likely were added. These results combined with previous studies of hindlimb motor and sensory neuron addition are consistent with the hypothesis that the population of sympathetic neurons is augmented by late differentiation of existing precursor cells.

Small, intensely fluorescent cells and the paraneuron concept

Sympathetic ganglia contain large principal nerve cells and, in addition, many smaller cells that resemble the endocrine cells of the adrenal medulla in morphology and chromaffinity. The advent of the formaldehyde-induced fluorescence technique proved to be an invaluable tool for studying this unique cell type, and it was this method that accounted for their descriptive name of small, intensely fluorescent cells, now universally abbreviated to SIF cells. Electron microscopy also proved of great importance in detailing the structure of SIF cells and their relationship with neighbouring neurones. Fine structural observations revealed that the cells contained numerous dense-cored granules, and this led to their electron microscopic name of small, granule-containing cells. SIF cells are most abundant, and very well studied, in the rat superior cervical ganglion, where they both receive and give synapses. Early researchers suggested that SIF cells were interneurones appropriately situated between pre- and postganglionic elements and thus capable of influencing ganglion signals. SIF cells also are known to exist in the form of richly vascularized, compact clusters of varying size. Clustered chromaffin cells do not necessarily give rise to processes that would contact the principal neurones. The existence of singly occurring as well as clustered SIF cells has given rise to a proposed designation of type I and type II cells, with I representing the interneuronal-like form and II possibly performing as an endocrine-like component. Despite a wealth of knowledge concerning SIF cells, their exact role(s) in the overall functioning of the autonomic nervous system is still not completely understood.

Outgoing synapses of small granule-containing cells in the rat superior cervical ganglion after post-ganglionic axotomy

Small granule-containing cells are intrinsic and interneurone-like in the rat superior cervical ganglion, being innervated by preganglionic axons and giving outgoing synapses of asymmetrical type to the principal neurones. A quantitative ultrastructural investigation has been made of the effect on these outgoing synapses of axotomy of the major post-ganglionic nerve trunks 18.5 h-390 days previously. Cutting, or cutting and ligating, the internal and external carotid nerves 2-3 mm from the ganglion in rats aged 1.5-5.5 months resulted in a statistically significant mean loss of up to 85% of the asymmetrical synapses given by small granule-containing cells in the injured ganglion. The reduction of synapses was maximal 5-9 days post-operatively, and thereafter the incidence of synapses showed significant signs of progressive recovery. The time course and magnitude of the change in incidence of these synapses resembled those found earlier (Matthews & Nelson, 1975) for the loss of preganglionic synapses to principal neurones in the same ganglia, and after an identical post-ganglionic lesion. Control experiments showed that there was no loss of outgoing synapses from the small granule-containing cells as a result of surgical stress or of simple ageing. Older rats (5.5 and 13 months) showed a small but significant increase in the incidence of these synapses. Unilateral post-ganglionic axotomy produced the same reaction in the injured ganglia as did bilateral lesions. Uninjured ganglia contralateral to unilateral axotomies, however, also showed some deficit of outgoing synapses from small granule-containing cells, but this was slight, amounting to 9.9% over-all in comparison to normal values in young rats, and this difference did not reach statistical significance. Cutting the cervical sympathetic trunk to produce preganglionic denervation 2 days before surgical removal of ganglia for analysis did not alter the incidence of outgoing synapses of the small granule-containing cells, either in ganglia post-ganglionically axotomized 5-128 days earlier or in contralateral ganglia, indicating that at no stage was any significant proportion of these synapses given to preganglionic axons. These findings suggest that most of the outgoing synapses from the intra-ganglionic small granule-containing cells are directed to principal neurones whose axons leave with the injured branches, the internal and external carotid nerves.(ABSTRACT TRUNCATED AT 400 WORDS)

Pre- and postnatal development of 5-hydroxytryptamine-immunoreactive cells in the superior cervical ganglion of the rat

The pre- and postnatal development of 5-hydroxytryptamine (5-HT)-immunoreactive cells in the superior cervical ganglion of the rat was studied by indirect immunofluorescence method with an antibody to a conjugate of bovine serum albumin and 5-HT. The superior cervical ganglia from 11-day-old embryos to 90-day-old postnatal rats were examined. 5-HT-immunoreactive cells were first detected in the superior cervical ganglion on the 12th day of gestation. At this stage of development the ganglionic cells formed a condensed group, and most of them showed 5-HT-immunoreactivity. During later prenatal development the relative number of the 5-HT-immunoreactive cells in the ganglion decreased and most ganglionic cells appeared as non-reactive. 5-HT-immunoreactive cells showed some variation in size and fluorescence intensity during the whole prenatal development. In the ganglia of newborn rats a wide range of 5-HT-immunoreactive cell sizes was detected. Two types of 5-HT-immunoreactive cells were distinguished in the ganglia of 7- to 35-day-old rats: small (5-15 microns in diameter) cells and large (15-30 microns in diameter) cells, resembling in size small intensely fluorescent (SIF) cells and principal nerve (PN) cells, respectively. The relative number of the large 5-HT-immunoreactive cells gradually decreased after the first postnatal week, and these cells were not detected in the ganglia of 90-day-old rats. Small 5-HT-immunoreactive cells constantly formed clusters in the ganglia of postnatal rats. A marked, statistically significant increase in the density of 5-HT-immunoreactive cells occurred during the 4th postnatal week. The 5-HT-immunoreactive cells appeared in the prenatal superior cervical ganglion of the rat approximately at the same time as the cells showing formaldehyde-induced catecholamine fluorescence. Transient occurrence of the large 5-HT-immunoreactive cells during the first postnatal weeks of development indicates, that in the superior cervical ganglion of the rat, 5-hydroxytryptamine may be expressed in some developing PN cells early postnatally. After the 5th postnatal week, the large 5-HT-immunoreactive neuronal cells cannot be detected, and 5-HT is expressed only in the SIF cells.

Neurotransmitter synthesis, storage, and turnover in neonatally deafferented sympathetic neurons

In the superior cervical sympathetic ganglion (SCG) of the rat, a significant amount of morphological and biochemical maturation occurs in the first few postnatal weeks. The specific activity of tyrosine hydroxylase (TH), the rate-limiting enzyme in the synthesis of norepinephrine (NE), increases during this time and is subject to transsynaptic regulation by the preganglionic inputs. In the present study, we examined the normal postnatal development of NE stores in sympathetic neurons and the transsynaptic regulation of this development. NE content undergoes an 8-fold increase from the time of birth, and stabilizes at adult levels at one month. Following neonatal deafferentation, there is a temporary stunting of NE accumulation in sympathetic neurons and a permanent reduction in the activity of TH, whether or not regeneration of the afferents occurs. When regeneration is prevented, the turnover of NE is significantly reduced, while NE levels rise to near normal levels. When regeneration is permitted, however, both the stored amount and turnover of NE attain normal levels. These data suggest that there is a critical period during the first two postnatal weeks when transsynaptic influences from afferents are necessary for the induction of TH in sympathetic neurons. Levels and turnover of transmitter do not have this critical period, but appear to depend solely on the functional integrity of the system.

A quantitative study of structural features, synapses and nearest-neighbour relationships of small, granule-containing cells in the rat superior cervical sympathetic ganglion at various adult stages

Groups and sub-groups (clusters) of small granule-containing cells ("small cells") were analysed at 3 and 6 micron intervals and in serial sections, in rats aged 2-13 months. Fully intraganglionic clusters of small cells were all found to receive an incoming ("afferent") innervation, of the order of 3-6 afferent terminals per cell, derived from axons of preganglionic type via multifocal, symmetrical, mainly axosomatic synapses. No evidence was obtained of sharing of preganglionic inputs between small cells and principal neurones. Intraganglionic clusters also regularly gave outgoing ("efferent") synapses of the asymmetrical type, of the order of 2-6 per cell, to intraganglionic nerve elements; 30-50% of these synapses were given from somata, 50-70% from processes of the small cells. Whenever the postsynaptic structure was identifiable these synapses were all found to be given to postganglionic neurones or their dendrites, principally to spine-like processes or slender twigs. In some ganglia a few efferent synapses to other small cells were observed; these were of the symmetrical type. Efferent synapses to nerve profiles resembling chemosensory axon terminals, also of the symmetrical type, were extremely infrequent (fewer than 1% of all efferent synapses) in intraganglionic small cell groups and appeared virtually restricted to glomus-like clusters of small cell, which lay intracapsularly, or in and near the bases of nerves entering or leaving the ganglion. Almost all groups and clusters of small cells were located near to fenestrated capillary vessels, which are not found elsewhere in the ganglion. The implications of possible non-synaptic release of material from small cells via membrane regions not covered by satellite cell cytoplasm, were explored in a nearest-neighbour analysis. These "exposed" regions comprised 1-3% of the small cell surface, a proportion comparable with those engaged in receiving afferent synapses or in giving efferent synapses. The majority of such regions faced toward other nerve profiles (axons and dendrites) ensheathed in satellite cytoplasm (mean 30%), intraganglionic tissue spaces wider than 3 micron (mean, 30%) or other small cells (mean, 14%); 25% faced toward blood vessels, but of these vascularly directed regions, only one fifth (or 5% of the total) on average faced directly toward fenestrated endothelium, the rest being non-fenestrated and/or separated by pericyte processes from the exposed regions of small cell membrane. Thirty-three percent of the small cells in a sample of 242 lay within 2 micron of the nearest blood vessel.(ABSTRACT TRUNCATED AT 400 WORDS)

Clustering of intensely fluorescent sympathetic cells in embryonal and postnatal rats

A fluorescence microscopic study has been performed on the ontogenetic appearance of clusters of small intensely fluorescent (SIF) cells in the superior cervical ganglion of the rat. Small SIF cell clusters were observed after the 13th embryonal day. Postnatally, the number of clusters first reversibly decreased, while after the 2nd week, the adult level was reached. Since the total number of SIF cells greatly increased after the 3rd week, the mean size of the clusters increased. From the 1st postnatal week, SIF cell clusters were present also in the external carotid nerve, and from the 2nd postnatal week in the internal carotid nerve. In adult rats, SIF cell clusters were constantly observed in the main postganglionic nerve trunks or near their outlet. The fine structure of the SIF cell clusters in the ganglion and in the nerve trunks was essentially similar. Widened intercellular spaces between adjoining SIF cells, sometimes closed by mutual membrane thickenings, were separated from the pericapillary space often only by a basal lamina. Opening of coated pits into the intercellular spaces was a common occurrence, suggesting that catecholamines may be secreted by the SIF cells into intercellular canaliculi, possibly then diffusing into the pericapillary space. Coated pits were occasionally observed also in the immediate vicinity of synapsing nerve endings that contained small agranular vesicles, suggesting a reciprocal synaptic mechanism. Occurrence of presumable postganglionic axons and SIF cell processes within the same sheath cell enwrapment provides indirect evidence for the idea that the SIF cells may affect the axon, in addition to the cell soma, of the postganglionic neuron.

Glucocorticoid regulation of phenylethanolamine N-methyltransferase (PNMT) in organ culture of superior cervical ganglia

Glucocorticoid regulation of the adrenergic enzyme, phenylethanolamine N-methyltransferase (PNMT) was studied in organ cultures of the superior cervical ganglion (SCG) from newborn rats. Although PNMT catalytic activity was present in control ganglia, enzyme levels were too low to allow visualization of PNMT immunofluorescent cells. Addition of dexamethasone (DEX) or corticosterone to the medium resulted in a large increase in PNMT activity and bright PNMT immunoreactive (PNMT-IR) staining in cells resembling small, intensely fluorescent (SIF) cells. Addition of non-glucocorticoid steroids was ineffective. Exposure to a brief, 2-hr pulse of DEX (10(-6) M) in vitro elicited the same increase in PNMT as continual exposure to DEX. Studies using metabolic inhibitors demonstrated that the steroid-dependent increase in PNMT activity required both protein and RNA synthesis. Furthermore, the increase was inhibited by cytochalasin B and by the glucocorticoid receptor antagonists, DEX 21-mesylate and cortisol 21-mesylate. These observations suggest that glucocorticoids increase PNMT protein in SIF cells by interacting with specific steroid receptors that undergo translocation to the nucleus.

Effect of pre- and/or postganglionic nerve division on hydrocortisone-induced small intensely fluorescent cells in the rat superior cervical ganglion

Daily hydrocortisone injections into newborn rats cause in a week about a 10-fold increase in the number of small intensely fluorescent cells in the superior cervical ganglion of the rat, as compared with untreated rats of the same age. The glucocorticoid-induced increase in the number of small intensely fluorescent cells is reversible. After discontinuation of the glucocorticoid treatment there is a significant decrease in the number of these cells during the 2nd postnatal week. The purpose of the present study was to investigate the significance of the innervation of the superior cervical ganglion on the fate of newly formed, hydrocortisone-induced small intensely fluorescent cells after discontinuation of the hydrocortisone treatment. Three-day-old rats were injected daily with hydrocortisone for 7 days. At the age of 10 days the pre- and/or postganglionic trunk(s) on one side were divided and the contralateral side served as control. Seven or thirty days after discontinuation of the hydrocortisone injections and the operation (i.e. at the age of 17 or 40 days) the rats were killed and the small intensely fluorescent cells were counted. The number of small intensely fluorescent cells, as expected, was greatly increased by the hydrocortisone injections. However, discontinuation of the treatment resulted in a decrease in the number of these cells in unoperated 40-day-old rats to a level, which is significantly less than the mean cell number/ganglion in totally untreated adult rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Developmental neuron death in the rat superior cervical sympathetic ganglion: cell counts and ultrastructure

Counts of neurons of the rat superior cervical ganglion (SCG) were made at two days before birth and at several postnatal ages. There is a significant decline in the number of apparently normal neurons over the first postnatal week, with the number falling from 39 500 at 3 days to 26 500 at 7 days. Cell numbers then remained constant up to day 60 when the number of neurons was 27 500. The incidence of degenerating neurons, identified by light and electron microscopy, was correlated temporally with the loss of normal neurons. The early manifestations of the neuron degeneration were chromatin clumping and the presence of free monoribosomes. Later stages were characterized by increased chromatin clumping, dense aggregations of monoribosomes, numerous intracytoplasmic vacuoles, and only short segments of rough endoplasmic reticulum. The ultrastructure of the majority of these dying neurons is similar to the 'nuclear' types of degeneration described by Pilar & Landmesser (1976) and Chu-Wang & Oppenheim (1978). Based on the presence of degenerating neurons coincident with the reduction in neuron numbers, we conclude that neuron death is an important aspect of early postnatal development in the rat SCG.

Neuron numbers in the superior cervical sympathetic ganglion of the rat: a critical comparison of methods for cell counting

Published values for the number of neurons in the superior cervical ganglion of the adult rat range from 13 000 to 45 000. These studies have employed different methods for determining what unit to count (cell body, nucleus, nucleolus), how many sections to count, and how to correct the raw counts for split particles and for profiles that are too small to resolve. The purpose of this study was to examine the extent to which these parameters may influence the calculated value for the total number of neurons, using computer simulations of neuron populations. These simulations permitted us to determine the effects on neuron number of varying the diameter of the neuronal nucleus, the size of the smallest resolvable profile, and the thickness of the section. The data from the simulations were used to test the validity of several methods that are in common use for correction of neuron counts. Our results indicate that most of the methods that are in routine use are unsatisfactory. We propose the use of either one of two methods that consistently result in highly accurate estimates of neuron numbers. These are: (1) a modification of the method proposed by Hendry (1976), using computer analysis; or (2) a modification of the method proposed by Abercrombie (1946), which does not require the use of a computer.

Increase in the number of non-neuronal cells in superior cervical ganglia of developing rats after contralateral ganglionectomy

The left superior cervical ganglion of 3-day-old rats was subjected to preganglionic nerve division, ganglionectomy, or sham operation, while the right ganglion was left intact. Thirty days later, both the left and the right ganglia were perfusion-fixed and examined for weight and volume, as well as for the number and the density of the principal nerve cells and the non-neuronal cells. The small intensely fluorescent cells were counted from a separate set of freeze-dried ganglia. Unilateral preganglionic nerve division caused in the left operated side a significant loss of ganglion weight and volume due to a decreased number of non-neuronal cells, while no significant changes occurred in the right intact ganglion. Unilateral left ganglionectomy caused a significant increase in the mean ganglion weight and in the number and the density of the non-neuronal cells in the right intact ganglion, while the number and the density of the principal nerve cells and the small intensely fluorescent cells were not affected by this operation. It is suggested that normal development of the ganglionic satellite cells requires the presence of normally innervated principal cells. Furthermore, unilateral ganglionectomy induces a greater than normal proliferation of the satellite cells contralaterally, possibly by causing an increase in the activity of the contralateral ganglion.

Neonatal testosterone treatment increases neuron and synapse numbers in male rat superior cervical ganglion

Neonatal treatment with gonadal steroids has been reported to alter morphological as well as functional development in various regions of the brain and spinal cord. Among the observed alterations are changes in numbers of neurons and in the organization and numbers of synapses. These regions have been found to be sexually dimorphic, and the dimorphism dependent upon gender differences in circulating levels of gonadal steroids. Neonatal treatment with testosterone has been shown to produce an increase in the number of neurons in the superior cervical sympathetic ganglion in female rats. The present studies were designed to investigate the possibility of a normally occurring sexual dimorphism in the SCG of the rat, and to characterize the effect of neonatal treatment with testosterone on neurons and synapses in the male rat. We report a sexual dimorphism in the number of neurons but not in the number of preganglionic axons or ganglionic synapses. In addition, neonatal administration of testosterone propionate results in a 40% increase in the number of superior cervical ganglion neurons in treated male rats over the control male number at 15 and 30 days of age. The testosterone propionate treatment results in a 66% increase in the number of synapses in male superior cervical ganglia, without a concomitant increase in the number of preganglionic axons.

Effect of hydrocortisone on catecholamines and the enzymes synthesizing them in the developing sympathetic ganglion

Newborn rats were daily injected with 0.2 mg hydrocortisone acetate for seven days. They were killed 1, 7 or 21 days after the last injection, together with untreated controls. Hydrocortisone caused a great increase in the number of the small, intensely fluorescent (SIF) cells and the appearance of similar small cells with intense immunohistochemical reactions for tyrosine hydroxylase (TH), dopamine-beta-hydroxylase (DBH) and phenylethanolamine (noradrenaline) N-methyltransferase (PNMT) in the superior cervical ganglion. At the same time, the adrenaline content and the PNMT activity of the ganglion greatly increased, while no significant changes were observed in the dopamine or noradrenaline content or TH or DBH activity. All these changes essentially disappeared after a recovery period of seven or 21 days. It is concluded that hydrocortisone caused a temporary increase in the number of SIF cells by causing a synthesis of TH, DBH and PNMT in previously existing small, non-fluorescent cells, which start to synthesize and store adrenaline, thus becoming intensely fluorescent SIF cells. These SIF cells are different from the normal SIF cells of the same ganglion, most of which appear at a later stage of postnatal development when response to hydrocortisone is lost, which contain TH but neither DBH nor PNMT, and which permanently remain in the ganglion.

Number of neurons and dexamethasone-induced SIF cells in developing sympathetic ganglia and in intraocular ganglion transplants

Daily dexamethasone (DM) injections to newborn rats caused in a week an increase in the number of small intensely fluorescent (SIF) cells in the superior cervical ganglion to a value 9 times that in the ganglia of saline-treated controls. The number of SIF cells (per ganglion) decreased in another week both in ganglia transplanted into the anterior chamber of the eye of an adult rat and in intact ganglia of rats allowed to live for another week after discontinuation of the DM treatment. However, in both cases the number of SIF cells was significantly higher than that in the newborn rat ganglia. The number of SIF cells also decreased in transplanted ganglia from saline-treated controls, the number of SIF cells in transplants from DM-treated rats being 10 times as high as that in the transplants from saline-treated rats. The SIF cells formed large clusters in transplants from DM-treated rats and their density (cells/mm3) was significantly higher than that in the ganglia left in situ for one week after discontinuation of the DM treatment. Therefore, visual examination suggested that there is little or no loss of SIF cells due to transplantation. The transplantation caused an over 90% loss of neurons and a marked decrease in ganglion volume.

Effect of pre- and postganglionic nerve divisions on normal postnatal and hydrocortisone-induced development of small intensely fluorescent cells in rat superior cervical ganglion

The left superior cervical ganglion of 3- or 23-day-old rats was subjected to pre- and/or postganglionic nerve division or sham operation, while the right ganglion was left intact. The animals were killed 20 or 60 days after the operation. Some animals were injected with 20 mg/kg hydrocortisone daily for 7 days and killed on the 8th day. Fluorescence microscopical examination revealed a normal postnatal increase in the number of small intensely fluorescent cells/ganglion after pre- or postganglionic nerve division, in spite of marked decreases in the volume of the operated ganglia. Combined pre- and postganglionic nerve division, which caused a dramatic loss of ganglion volume, entirely prevented the postnatal increase in the number of small intensely fluorescent cells. Hydrocortisone caused a large increase in the number of small intensely fluorescent cells both in intact and operated ganglia, including those in whom both pre- and postganglionic nerves had been divided. It is concluded that combined pre- and postganglionic denervation, in contrast to either operation alone, prevents the normal proliferation of the small intensely fluorescent cells possibly by causing an extensive loss of principal nerve cells which deprives the small intensely fluorescent cells of their normal contacts with the principal cells. Since the increase in the number of small intensely fluorescent cells due to hydrocortisone injections was not prevented by pre- and postganglionic denervation it must be due to a mechanism different from that responsible for the formation of small intensely fluorescent cells during normal postnatal development.