Biological importance of retrograde axonal transport of nerve growth factor in adrenergic neurons.

Previous studies have shown that nerve growth factor (NGF) produces a selective induction of tyrosine hydroxylase (TH) in peripheral adrenergic neurons and that NGF is transported retrogradely with a high selectivity from the adrenergic nerve terminals to the perikaryon. In order to investigate the biological importance of retrograde NGF transport, the following experiments have been performed; (a) effect of NGF on TH activity in superior cervical ganglia (SCG) after unilateral injection into the anterior eye chamber and the submaxillary gland; and (b) effect of systemic injection of NGF on TH activity in SCG after blockage of retrograde axonal transport by axotomy. After unilateral injection of NGF into the anterior eye chamber and submaxillary gland of both 8-10-day-old rats and adult mice, the increase in TH activity in the SCG was considerably larger on the injected than on the non-injected side although the adrenergic neurons supplying the two organs do not account for more than 25% of the total number of adrenergic neurons in the SCG. A direct diffusion mechanism could be excluded by the fact that unilateral local injection of [125 I] produced no significant side difference in the accumulation of radioactivity in the SCG 2 after injection whereas after 14 h there was a several-fold difference between the injected and non-injected side. Moreover, the nodose ganglia which are located very close to the SCG exhibited no statistically significant difference in the accumulation of radioactivity at any time. Forty-eight hours after subcutaneous injections of 10 mg/kg of NGF the increase in TH activity of the SCG amounted to 154% on the intact side and to 92% on the axotomized side. However, these experiments do not permit decisions about the extent the axotomy, as such, impaired the response to NGF. It is concluded that the biological effect of NGF results to a considerable extent, from the moiety which reaches the cell body by retrograde transport from the nerve terminals.     

Selective trans-synaptic migration of tetanus toxin after retrograde axonal transport in peripheral sympathetic nerves: a comparison with nerve growth factor.

Adult rats were injected unilaterally into the anterior eye chamber and the submandibular gland with either [125I]tetanus toxin or [125I]nerve growth factor (NGF). Fourteen and 24 h later in electron microscopic autoradiographs of the superior cervical ganglia of the injected side the labeling was confined to a limited number (15-20%) of adrenergic ganglion cells and the silver grains were localized over axons, perikarya and dendrites providing evidence for a retrograde intraaxonal transport of the two macromolecules. Moreover, after injection of [125]tetanus toxin there was a very marked labeling of the presynaptic cholinergic nerve terminals. In contrast, after [125I]NGF these terminals were free of label. In both cases no specific labeling could be detected over glia and extracellular space. In the postganglionic axons the radioactivity seemed to be mainly associated with vesicles and smooth endoplasmic reticulum, in the perikarya and dendrites of the adrenergic neurons with secondary lysosomes, vesicles and smooth endoplasmic reticulum. The Golgi cisternae and the nuclei were free of radioactivity. The specific labeling of presynaptic terminals after injection of [125I]tetanus toxin together wirans-symaptic migration of [125I]tetanus toxin from the adrenergic ganglion cell to its innervating presynaptic terminals following retrograde intraaxonal transport.     

Specificity of the retrograde axonal transport of nerve growth factor

The specificity of the retrograde axonal transport of nerve growth factor (NGF) has been investigated by injecting¹²⁵I-labelled NGF and similar proteins (both with respect to molecular weight and electrical charge at physiological pH) into the anterior eye chamber of adult mice. Previous studies have shown that the difference between the accumulation of radioactivity in the superior cervical ganglion of the injected and non-injected sides is a measure for retrograde axonal transport. Of all the proteins studied (NGF, cytochrome c, insulin, horseradish peroxidase, ovalbumin, bovine albumin, ferritin), NGF was the only which exhibited a statistically significant (2–3 fold) difference between injected and non-injected sides. The specificity of the retrograde transport of NGF was further supported by the finding that relatively small chemical changes, such as oxidation of the tryptophan moieties of the NGF molecule, resulted in a marked reduction of retrograde transport.It is concluded that the system for providing information to the cell body from the adrenergic nerve terminals in the form of NGF is highly specific, and that this specificity does not depend on general physico-chemical properties of the molecule such as size of the molecule and electrical charge at physiological pH. However, the information available so far does not allow one to decide as to whether the selectivity resides in the transport system itself or in the specificity of the uptake mechanism at the nerve terminals.     

Selective uptake and retrograde axonal transport of dopamine-beta-hydroxylase antibodies in peripheral adrenergic neurons.

In the present experiments the uptake and retrograde axonal transport of antibodies to dopamine beta-hydroxylase (DBH) in adrenergic neurons was studied. When partially purified labelled antibodies to DBH were injected unilaterally into the vicinity of the adrenergic nerve terminals in the iris, radioactive substances accumulated preferentially in the superior cervical ganglia of the injected. By SDS (sodium dodecyl sulfate) gel electrophoresis and immunoprecipitation it could be shown that the accumulated radioactivity in the superior cervical ganglion represented antibodies to DBH. This retrograde accumulation was greatly reduced by colchicine, axotomy or destruction of the adrenergic nerve terminals by 6-hydroxydopamine. The rate of retrograde transport was the same as that of nerve growth factor (NGF) and tetanus toxin in sympathetic neurons. The retrograde transport of antibodies was confined to sympathetic neurons and could not be detect in either sensory or motor neurons.     

The significance of retrograde axonal transport for the accumulation of systemically administered nerve growth factor (NGF) in the rat superior cervical ganglion.

The present study has shown that after intravenous injection of [125I]NGF the time-course of appearance of radioactivity in all organs studied with the exception of sympathetic and sensory ganglia, roughly paralleled that of the blood. The highest levels were reached immediately after injection, after which the radioactivity decayed rapidly within the firsh hour. By contrast, in the superior cervical ganglion there was a small but significant increase within the first hour. After this the radioactivity remained constant for about 4 h and then increased dramatically (7-fold) when the radioactivity in other tissues had declined to very low levels. Measuring the proportion of radioactivity in the plasma which represents immunologically active NGF, we found that within 30 min after injection all the radioactivity represented unchanged [125I]NGF. After this time the proportion of immunologically active NGF decreased gradually and reached a final level of about 10-15%. Evidence that the radioactivity accumulated in the superior cervical ganglion by retrograde axonal transport represents unchanged [125I]NGF was provided by gel electrophoresis. The results are interpreted as follows: the initial small increase in the sympathetic ganglia may result either from [125I]NGF taken up by short collateral fibres within the ganglion or from a direct accumulation of blood-borne [125I]NGF by the cell bodies of the adrenergic neurones. The dramatic increase occurring after 4 h is caused by the moiety of [125I]NGF reaching the cell body by retrograde axonal transport. This interpretation is supported by autoradiographic studies which showed that 1 h after [125I]NGF injection there was only very sparse labelling of the ganglion, whereas 24 h later virtually all the cell bodies were heavily labelled. Moreover, it could be shown that the lag period between intravenous injection and subsequent accumulation of [125I]NGF in the adrenergic cell bodies was considerably shorter after transection of the postganglionic fibres distal to the cell body [the transected fibres were allowed to regenerate for 7 days] resulting in a reduction of the distance between the site of uptake and accumulation.     

The effect of the retrograde axonal transport of nerve growth factor on the morphology of adrenergic neurones.

An injection of nerve growth factor (NGF) into one eye of neonatal rats results in an increase in the tyrosine hydroxylase activity of the ipsilateral superior cervical ganglion. This effect was seen maximally after the intraocular injection of a depot preparation of NGF linked to cellulose. The sympathetic neurones that innervate the eye can be identified by autoradiography after the retrograde axonal transport of either NGF or tetanus toxin labelled with [125I]iodine. It was only those cells having their terminals in the vicinity of the depot preparation. This demonstrates that NGF transported from the periphery to the cell bodies is effectively retained within the transporting cell and is not released to act on extracellular receptors within the ganglion. It is suggested that this specificity of action for NGF reaching the ganglion in this fashion is important during normal development in determining the survival of adrenergic neurones.     

Selective induction of tyrosine hydroxylase and dopamine beta-hydroxylase by nerve growth factor: comparison between adrenal medulla and sympathetic ganglia of adult and newborn rats.

Administration of NGF to newborn and adult rats elicits a selective increase in TH and DBH both in sympathetic ganglia and adrenal medulla. This effect does not depend on intact preganglionic cholinergic fibers. The augmented enzyme activity results from enhanced enzyme synthesis since it can be abolished by cycloheximide and NGF has been shown to enhance the incorporation of [3H]leucine into DBH molecules. The responsiveness of the adrenal medulla to NGF is also supported by light and electron microscopic autoradiograms which show that intravenously injected 125I-NGF is accumulated with high selectivity in adrenal chromaffin as compared to adjacent adrenal cortical cells. In spite of the many similarities between the response of the adrenergic neurons and adrenal chromaffin cells to NGF, there are also two distinct differences. (a) In newborn rats the ratio between the TH increase effected by a single and 10 subsequent daily injections of NGF is 1:2 in the adrenal medulla and 1:7 in the superior cervical ganglia. (b) If adrenal medullae are transferred to organ culture after intravenous injection of NGF, maximal TH response is initiated 60-90 min after NGF administration. In superior cervical ganglia only a half-maximal response is initiated at that time. After a stationary phase a second increase starts after about 6 h to reach the maximum after 12 h. The biphasic time course of the initiation of TH induction by NGF in sympathetic ganglia is in agreement with the time course of 125I-NGF accumulation after intravenous injection27 reflecting the moiety of NGF reaching the cell bodies of the adrenergic neurons directly by the blood stream (initial accumulation) and by retrograde axonal transport (second phase).     

Characterization of the retrograde transport of nerve growth factor (NGF) using high specific activity [125I] NGF.

The process of the retrograde transport of nerve growth factor (NGF) has been recharacterized using a high specific activity preparation of[125I]NGF. Most of the general conclusions reached in the previous studies of Hendry, Thoenen and co-workers have been confirmed. However, significant quantitative differences were noted. Intraocular (anterior eye chamber) administration of[125I]NGF (less than 10 ng) resulted in accumulation in the superior cervical ganglia beginning at about 4 h. The ratio of radioactivity in the ipsilateral contralateral ganglia was 15--30:1. Maximal accumulation was seen at about 12h in the hamster and 16 h in rats. This pattern was quite different from that seen in other tissues. The uptake system from the eye of the rat was saturable (half-maximal at 15 ng) with maximal accumulation of 35--40 pg/ganglion. Systemic administration of[125I]NGF (200 ng) to adult rats resulted in no accumulation in SGG or celiac ganglion prior to 3 h, with subsequent rapid accumulation by 6 h and a rapid fall in radioactivity after 12 h. A similar time course was seen in 5-day-old rats, although the time curve was shifted slightly toward shorter time. The radioactivity in ganglia co-migrated with native NGF by SDS gell electrophoresis. Cytochrome c of comparable specific activity was not transported, and NGF did not stimulate the uptake and transport of cytochrome c. The retrograde transport of[125I]NGF was inhibited by the co-administration of biologically active, but not inactive, oxidized derivatives of NGF. By any route of administration, a significant percentage of the transported[125I]NGF was found in a purified nuclear fraction of the ganglia. Coupled with previous observations of specific nuclear NGF receptors in embryonic chick and sympathetic ganglia, this suggests that, after internalization and retrograde transport, NGF may directly act on the nucleus to produce at least some of its effects on the responsive cell.     

Basic fibroblast growth factor: receptor-mediated internalization, metabolism, and anterograde axonal transport in retinal ganglion cells.

Basic fibroblast growth factor (bFGF) was radiolabeled and used in axonal transport studies to determine whether certain neuronal populations express functional receptors for bFGF. Unlike 125I-NGF, 125I-bFGF was not retrogradely transported in the adult rat sciatic nerve or from iris to trigeminal ganglion or superior cervical ganglion. However, after intraocular injection of 125I-bFGF into the posterior chamber of the eye of adult rats, radioactivity was detected within the retinal ganglion cell projections. This radioactivity was localized to the ipsilateral optic nerve and in the contralateral lateral geniculate body and the contralateral superior colliculus by using autoradiographic techniques. Direct measurement of the radioactivity in dissected brain regions was used to study the process of 125I-bFGF uptake and transport by retinal ganglion cells. The uptake and transport were specific for biologically active bFGF since neither denatured, biologically inactive 125I-bFGF nor 125I-NGF was taken up and transported. The uptake and transport of 125I-bFGF were saturable phenomena since they were blocked in the presence of excess, unlabeled bFGF. Wheat germ agglutinin, but not heparinase, blocked uptake and transport of 125I-bFGF, a finding that is consistent with the uptake being mediated by high-affinity bFGF receptors. Radioactivity from 125I-bFGF was transported in retinal ganglion cell axons in an anterograde direction at a maximum rate in excess of 1.7 mm/hr. No specific retrograde transport of bFGF to the retina was detected after 125I-bFGF was injected into the superior colliculus. The radioactivity from 125I-bFGF that accumulated in the superior colliculus was lost from this tissue with a half-life of about 22 hr. Autoradiography of proteins separated by SDS-PAGE demonstrated that 125I-bFGF was not substantially degraded in the retina after internalization within retinal ganglion cells. During anterograde transport, however, 125I-bFGF underwent limited proteolytic cleavage resulting in 3 prominent 125I-bFGF derivatives of molecular weights greater than 7000 Da. Although these were the major radioactive species recovered from the superior colliculus after intraocular injection, some intact 125I-bFGF was also detected within the innervated target. These results indicate that retinal ganglion cells express high-affinity receptors for bFGF, that these receptors mediate the internalization of bFGF, that internalized bFGF undergoes limited proteolytic cleavage, and that bFGF and its derivatives are anterogradely transported to the lateral geniculate body and the superior colliculus. These data raise the possibility that bFGF or its derivatives may act as an anterograde trophic factor in the visual system, a system that is known to undergo anterograde transneuronal cell death.     

The role of axonal transport in the regulation of enzyme activity in sympathetic ganglia of adult rats

The relationship of perikaryal and presynaptic enzyme activity to axonal transport was studied in adult sympathetic neurons in the rat superior cervical ganglion (SCG). Surgical axotomy or local colchicine application to the postganglionic nerves resulted in a significant decrease in ganglionic tyrosine hydroxylase (T-OH) activity without a significant alteration in choline acetyltransferase activity. Colchicine did not appear to block axonal impulse conduction since pupillary and eyelid function remained normal. Consequently, the reduced T-OH activity resulted from alteration of other axonal functions. Axotomy or colchicine application decreased T-OH activity in decentralized ganglia, suggesting that the depression of perikaryal T-OH was not secondary to altered orthograde transsynaptic interactions. Colchicine did not prevent transsynaptic induction of T-OH by reserpine, suggesting that axonal transport is not necessary for enzyme induction. Nerve growth factor (NGF) treatment partially prevented the effects of colchicine application. It is concluded that in adult sympathetic neurons both orthograde transsynaptic mechanisms and the retrograde transport of NGF normally govern perikaryal T-OH activity.     

Retrograde transport of dopamine β-hydroxylase antibodies in sympathetic neurons: Effects of drugs modifying noradrenergic transmission

Antibodies to dopamine beta-hydroxylase (anti-D beta H) were taken up by noradrenergic nerve terminals in the iris following attachment to D beta H, and were transported back to, and accumulated in, the superior cervical ganglion (SCG). Concurrent, or prior destruction of noradrenergic terminals with 6-hydroxydopamine, injected intraocularly, blocked the retrograde transport of anti-D beta H. However, recovery was rapid, reaching 50% of control values within 1 day. Such transport was characterized by a shorter time period before accumulation could be detected in the SCG and by a slower rate of accumulation. These results suggest that noradrenergic neurons recover their ability to turn over synaptic vesicles by exocytosis and transport these back to the ganglion early during the period of axonal regeneration when the axonal length is shorter than normal. The uptake and transport of anti-D beta H was regulated by alpha-adrenergic agents administered locally in the vicinity of noradrenergic nerve terminals. Thus intraocular injection of phentolamine resulted in an increased accumulation of anti-D beta H in the SCG, while amphetamine and the postsynaptic alpha-receptor antagonist, phenylephrine, decreased accumulation. Clonidine and desipramine, which have a predominant presynaptic action, failed to influence the transport of anti-D beta H. These results suggest that in vivo the uptake of anti-D beta H can be increased more by local postsynaptic reflex actions than by a mechanism depending on the inhibition of presynaptic alpha-receptors.     

Retrograde axonal transport of horseradish peroxidase in peripheral autonomic nerves.

An exogeneous marker protein, horseradish peroxidase (HRP) was used to race peripheral autonomic pathways in adult guinea pigs and cats. Small doses of HRP were injected into various organs and after a brief survival period, HRP activity appeared in the perikarya of autonomic neurons that supplied each injection site. After injection of HRP into the anterior chamber of the eye, reaction product was detected in the postganglionic sympathetic neurons of the superior cervical sympathetic ganglion. In another experiment, HRP reaction product was found in the cell bodies of the preganglionic sympathetic neurons that supply the adrenal medulla. These were located in the lateral gray column of the spinal cord at T6 and T7 segmental levels. Reaction product appeared in intramural postganglionic parasympathetic neurons close to an injection site in the wall of the urinary bladder and in a similiar situation in Meissner's ganglia of the ileum. Following injection into the walls of the stomach and ileum, HRP labelled cells were detected in the nodose ganglion of the vagus and in preganglionic parasympathetic neurons in the dorsal motor nucleus of this nerve. After injection into the subepicardial tissue of the heart, reaction product appeared in the stellate ganglion and also in an upper thoracic dorsal root ganglion. These data suggest that HRP is taken up by peripheral autonomic nerves of all types, and then undergoes rapid retrograde axonal transport to the perikaryon. It appears, therefore, that HRP may be useful in tracing both motor and sensory peripheral autonomic pathways.     

Nerve growth factor (NGF) in the rat CNS: Absence of specific retrograde axonal transport and tyrosine hydroxylase induction in locus coeruleus and substantia nigra

Selective, highly efficient uptake of [125I]NGF by nerve terminals followed by retrograde axonal transport, and specific induction of tyrosine hydroxylase by NGF are well known phenomena in peripheral adrenergic neurons of adult rats. In the present study these parameters were used in order to detect possible interactions of NGF with central catecholaminergic neurons. No selective retrograde transport of [125I]NGF could be detected by light microscopic autoradiography from the caudate nucleus to the dopaminergic neurons in the substantia nigra or from the hippocampus to the noradrenergic nerve cells of the locus coeruleus. Biochemically, no change in tyrosine hydroxylase activity could be observed for up to 3 days after injection of either NGF, anti-NGF antibodies, or control proteins close to the nerve cell bodies in the substantia nigra or the locus coeruleus. These data suggest a fundamental difference between central and peripheral adrenergic neurons with regard to their responsiveness of NGF.     

Receptor-mediated retrograde transport in CNS neurons after intraventricular administration of NGF and growth factors.

Radiolabel tracer techniques were used to follow the distribution of nerve growth factor (NGF) and other neuromodulatory factors after intraventricular injection. Autoradiography showed that shortly after intraventricular injection of radio-iodinated NGF (125I-NGF), substantial amounts of radioactivity had penetrated the ventricular wall surfaces; this binding was transient and nonspecific. The 125I-NGF was progressively cleared from the central nervous system (CNS), presumably via the flow of cerebrospinal fluid (CSF) into the blood. A relatively small proportion of the injected 125I-NGF was taken up by NGF receptor-positive neurons in the CNS. Retrograde accumulation of radiolabel was observed within the basal forebrain cholinergic neurons at 5 hours after intraventricular injection. Labeling intensity was maximal at 18 hours and much reduced by 30 hours. This labeling was blocked by co-injection of an excess of unlabeled NGF. Specific and saturable retrograde labeling was also observed within other NGF receptor-bearing neurons, including the prepositus hypoglossal nucleus and the raphe obscurus nucleus. When epidermal growth factor (EGF), transforming growth factor-beta 1 (TGF-beta 1), platelet-derived growth factor-AA (PDGF-AA), PDGF-BB, leukemia inhibitory factor (LIF), insulin-like growth factor-I (IGF-I), or IGF-II was radiolabeled and injected intraventricularly, specific labeling of neurons was observed for 125I-IGF-II and 125I-LIF within separate subpopulations of the dorsal and medial raphe. No retrograde accumulation within neurons was observed for EGF, TGF-beta 1, PDGF-AA, PDGF-BB, or IGF-I. This study describes an in vivo method for identifying putative neuromodulatory factors and their responsive neurons.     

Protein car☐ymethylase activity in the rat superior cervical ganglion during development and after axonal injury

The activity of protein car☐ymethylase (PCM), which catalyzes the transfer of a methyl group from S-adenosyl-l-methionine to car☐yl side chains of proteins to form labile protein-methylesters, was examined in the rat superior cervical ganglion (SCG) and iris during development. In the ganglion the enzyme activity3.3 ± 0.3 (pmol methanol/ganglion/10 min) at birth, gradually increased reaching adult levels28.3 ± 3, by the 30th postnatal day; an 8-fold increase which parallels the increase in protein content. In the iris, one of the target tissues innervated by ganglion neurons, the activity,3.9 ± 0.09 at birth, increases only about 4-fold during development. The source of PCM activity in the iris is mainly in tissues other than sympathetic terminals, since 10 days after removal of the ganglion, about 85% of the enzyme activity is still present in the ipsilateral iris as compared to contralateral controls. One day after crushing the postganglionic nerve, enzyme activity in the proximal nerve stump increases to 126% of control values suggesting an accumulation due to blockade of axonal transport. PCM activity in SCG does not increase after postganglionic nerve section and there is only a transient increase in tyrosine hydroxylase activity. Because the protein content of the ganglion increases after axonal injury, there appear to be decreases in enzyme concentration relative to protein. The results of this study show that during postnatal development protein car☐ymethylase activity in the superior cervical ganglion gradually increases with growth; that the enzyme is present in neurons of the ganglion and may be transported down their axons; and that changes in the enzyme activity during the reaction to axonal injury are comparable to those of other enzymes important in neuronal function.     

Amino acid transmitter receptor binding in synaptic membranes from normal and vitamin B12 deficient fruit bats

The effect of nerve activity on the uptake and retrograde transport of nerve growth factor (NGF) and dopamine beta-hydroxylase (DBH) antibodies was studied by injecting 125I-labelled NGF and anti-DBH into the anterior eye chamber of guinea-pigs. Decentralization of the ipsilateral superior cervical ganglion (SCG) had no significant effect on the retrograde transport of either NGF or anti-DBH. Phenoxybenzamine produced a 50% increase in anti-DBH but not NGF accumulation and this effect was prevented by prior decentralization. This demonstrates that NGF is taken up independently of the retrieval of synaptic vesicle components.     

Retrograde axonal transport following injection of [3H]serotonin in the olfactory bulb. I. Biochemical study

A retrograde axonal transport from the serotonergic nerve terminals in the olfactory bulb (OB) to their parent cell bodies in the midbrain raphe nuclei has been demonstrated after stereotaxic injection of [2H]5-HT into the OB of rats pretreated with a monoamine oxidase (MAO) inhibitor: at various time intervals thereafter (4-92 h) there was a preferential accumulation of radioactivity mainly in the raphe dorsalis nucleus (RDN). Maximal accumulation occurred at 24 h. Of this radioactivity, 30-50% was recovered as 5-HT. The accumulation was estimated to take place at two rates: a fast one (48 mm/day) and a slower one (16 mm/day). Under the same experimental conditions there was no clear evidence for a retrograde accumulation of [3H]norepinephrine in the RDN. A passive diffusion mechanism could be excluded since the diffuson of tracer towards the cerebrospinal fluid was prevented by prior mechanical obstruction of the olfactory diverticle of the lateral ventricle. Furthermore, colchicine strongly reduced (by 80%) the radioactive accumulatin in the RDN. Destruction of serotonergic nerve terminals by 5,6-dihydroxytryptamine or inhibiton of 5-HT uptake by fluoxetine decreased this retrograde accumulation whereas destruction of catecholaminergic nerve terminals by 6-hydroxydopamine was without effect. Pretreatment with reserpine decreased the amount of radioactivity transported to the RDN by 40%. In the absence of MAO inhibition pretreatment, animals still presentd 35% of the tracer transported to the RDN. Intrabulbar injection of MAO inhibitor did not affect the accumulation rates when compared with animals which received the inhibitor by the intraperitoneal route. In conclusion, the retrograde axonal transport following [3H]5-HT injection in the serotonergic RDN-OB system occurs via an active process which depends on a colchicine-sensitive mechanism and is partially linked to a reserp ine-sensitive structure. During its transport, the amine seems to be relatively protected from metabolic inactivation.     

Graded inhibition of retrograde axonal transport by compression of rabbit vagus nerve

Effects of experimental compression at different pressures on retrograde axonal transport were studied in rabbit vagus nerve. Proteins in the sensory neurones were radiolabelled by injection of [3H]leucine into the nodose ganglion. Sixteen hours after labelling, a small compression chamber and/or ligatures were applied around the cervical part of the vagus nerve for 8 h. Compression of the vagus nerve at 20, 30 and 200 mm Hg pressure induced a graded inhibition of both retrograde and anterograde transport of the radiolabelled proteins. Neither retrograde nor anterograde transport was affected by the presence of the non-inflated chamber. The results indicate that compression at pressures similar to those found in human carpal tunnel syndrome can block retrograde axonal transport. The consequences of inhibition of retrograde and anterograde axonal transport for the metabolism in the nerve cell bodies are discussed.     

Axonal branching of canine sympathetic postganglionic cardiopulmonary neurons. A retrograde fluorescent labeling study

In 11 dogs fluorescent retrograde tracers were injected into physiologically identified left-sided sympathetic cardiopulmonary nerves. When two different ipsilateral cardiopulmonary nerves were injected, labeled cells from each injected nerve had overlapping distributions in the middle cervical and stellate ganglia. Most retrogradely labeled neurons were located in the middle cervical ganglion and cranial pole of the stellate ganglion. Following the injection of two different tracers into two different nerves, some neurons in the middle cervical ganglion were retrogradely labeled with two tracers. Double-labeled neurons were rarely found in the stellate ganglion. There were areas within the ganglia in which labeled neurons projected predominantly to one cardiopulmonary nerve. In the thoracic autonomic nervous system Fast Blue was transported most effectively. Bisbenzimide was not transported as well as Fast Blue and Nuclear Yellow was very poorly transported in cardiopulmonary nerves. The results demonstrate that some efferent postganglionic sympathetic neurons project axons into at least two different cardiopulmonary nerves and that an anatomical substrate for axo-axonal reflexes exists in the thoracic sympathetic nervous system.     

The allocation of nerve fibres to the anterior eye segment and peripheral ganglia of rats. I. The sensory innervation

The distribution of sensory trigeminal nerve fibres in the anterior eye segment and the autonomic eye related ganglia, i.e. the parasympathetic ciliary and pterygopalatine ganglia and the sympathetic superior cervical ganglion, was studied in rats. For this the trigeminal ganglion was injected with tritiated leucine and wheat germ agglutinin coupled to horseradish peroxidase (WGA-HRP). After injection of WGA-HRP into the trigeminal ganglion, ganglion cell somata in the superior cervical and the pterygopalatine ganglion were labelled. As labelling of these cell bodies with WGA-HRP is the result of retrograde transport it must be assumed that cell bodies in these ganglia project to the trigeminal ganglion. [3H]Leucine injection into the trigeminal ganglion revealed the presence of labelled nerve fibres in the pterygopalatine ganglion and the nodose ganglion i.e. the sensory ganglion of the vagus nerve. Labelled nerve fibres were absent in the ciliary and superior cervical ganglion. As [3H]leucine labelling of nerve fibres is the result of anterograde transport exclusively, it can be concluded that trigeminal nerve fibres project to the nodose ganglion and the pterygopalatine ganglion, but not to the ciliary and superior cervical ganglion. In the retrobulbar structures, sensory nerve fibres occurred between the inferior oblique and the lateral rectus muscle and were present medial to the medial rectus muscle. Within the anterior eye segment, sensory nerve fibres were found in the cornea epithelium, stroma and adjacent to the endothelium. In addition, labelled fibres were found in the anterior stroma of the ciliary body, throughout the iris up to the pupillary border and in the conjunctiva. Most sensory nerve fibres which innervate the cornea, the iris and the ciliary body traverse the ciliary cleft.