Neuronal metabolism and DOPA decarboxylase immunoreactivity in terminal noradrenergic sympathetic axons of rat.

This study was undertaken to determine whether immuno-histochemical staining for DOPA decarboxylase (DDC) is present in axons of rat noradrenergic sympathetic neurons. A sparse plexus of varicose axons exhibiting DDC-like immunoreactivity (DDC-IR) was associated with blood vessels and acini in the submandibular gland, but this was much less extensive than the population that exhibited tyrosine hydroxylase-like immunoreactivity (TH-IR). The varicose terminal TH-IR axons in atrium, spleen, and vas deferens were devoid of DDC-IR both in grown rats and during the post-natal period of axon growth, although weak DDC-IR was seen in large pre-terminal nerve bundles. Similar patterns of staining were seen with paraffin-embedded and with frozen, formaldehyde-fixed material. No enhancement of DDC-IR was seen in any tissue after chronic alteration of catecholamine turnover with reserpine or alpha-methyl-para-tyrosine, and the numbers of submandibular DDC-IR axons were not increased by disruption of axonal transport with colchicine or by decentralization of the superior cervical ganglion. We conclude that terminal noradrenergic axons contain insufficient DDC-IR for microscopic visualization, regardless of their metabolic state, reinforcing previous evidence that DDC-IR can be used as a histochemical marker for dopaminergic axons. By this criterion, the rat submandibular gland may receive a sparse dopaminergic innervation.     

Effects of heterologous cross-suture between the postganglionic sympathetic and the preganglionic parasympathetic nerve trunks of submandibular glands in cats

Summary After sectioning the postganglionic adrenergic sympathetic nerve trunk for the submandibular gland, as close to the submandibular artery as practicable, its central end was sutured to the peripheral end of the preganglionic cholinergic parasympathetic nerve trunk for the gland, the chorda, which had been sectioned where it left the lingual nerve. The effects of this heterologous cross-sature were studied at different times, up to 1 year afterwards, by assessing the physiological and pharmacological responses of the glands and the neuro-histochemical changes in the nerve trunks and in the nerves within the glands.In all cases adrenergic sympathetic nerves grew across the site of suture and down the erstwhile cholinergic parasympathetic trunk, eventually to develop connections in the gland. In some cases the functional adrenergic reinnervation of the submandibular gland appeared to result exclusively or predominantly from the direct downgrowth of adrenergic axons to the gland, via the crossed nerves. In other cases however, in addition to a direct glandular reinnervation, there was some physiological and morphological evidence which suggested that possible heterogenous synaptic contacts may have been created between postganglionic sympathetic axons and cholinergic ganglion cells in the chorda nerve.This work was supported by a grant from the Joint Research Committee, King's College Hospital.     

Experimental American trypanomiasis in rats: sympathetic denervation, parasitism and inflammatory process

Tissue parasitism, inflammatory process (histologic methods) and sympathetic denervation (glyoxylic acid-induced histofluorescence for demonstration of catecholamines) were studied in the heart (atrium and ventricle) and the submandibular gland of rats infected with the Y strain of Trypanosoma cruzi. In the heart paralleling intense parasitism and inflammatory process, the sympathetic denervation started at day-6 of infection and at the end of the acute phase (day 20) practically no varicose nerve terminals were found in both myocardium and vessels. In the submandibular gland, in spite of the rarity of amastigote pseudocysts and the scarcity of inflammatory foci, slight to moderate (days 13-15 of infection) or moderate to severe denervation (day 20) was found. At day 120 of infection both organs exhibited normal pattern of sympathetic innervation and only the heart showed some inflammatory foci and rare pseudocysts (ventricle). Our data suggest the involvement of circulating factors in the sympathetic denervation phenomena but indicate that local inflammatory process is, at least, an aggravating factor.     

Developmental status of sympathetic innervation in relation to calcium accumulation by submandibular gland following reserpine, surgical sympathectomy or cyclocytidine

Sympathectomy (Sx) of the submandibular gland was induced at various postnatal ages by ip administration of a single dose of reserpine or by unilateral excision of a superior cervical ganglion. If animals were 12 days old or less at the time of drug administration, [Ca] of the submandibular gland was not measurably increased 24 hr later; if rats were 14 days of age or older, [Ca] of the gland 24 hr after reserpine injection was nearly double that of untreated controls. Two days after surgical Sx, [Ca] of the denervated submandibular gland was unchanged from that of the innervated member of a pair if animals were less than 14 days of age at the time of denervation; [Ca] was twice that of glands of control rats if animals were older than 14 days of age when the denervation was performed. The anti-tumor agent, cyclocytidine (CC), given daily for 3 days in an ip dose of 500 mg/kg, also caused a two- to threefold increase in [Ca] of the submandibular gland when rats were more than 12 days of age at the time of the initial injection of the drug, but in rats younger than this age, CC caused no change in the [Ca] of the submandibular gland. Present data show that there are age-related differences in the ability of the submandibular gland to accumulate calcium following sympathetic denervation or treatment with a norepinephrine-releasing drug. These differences may be attributed either to incomplete development of calcium transport mechanisms, or incomplete development of the sympathetic innervation before 14 days of age.     

Impulse Activity Evokes Precocious Sprouting of Nociceptive Nerves into Denervated Skin

We have studied the sprouting of intact high-threshold mechanosensory nerves into adjacent denervated trunk skin in adult rats behaviorally, histologically, and electrophysiologically. In the anesthetized animal, stimulation of high-threshold endings in back skin by localized pinching elicits a bilateral reflex excitation of the underlying skeletal muscle, the cutaneous trunci muscle (CTM), visible as a twitch-like puckering of the skin. The reflex was also evoked by electrical excitation of Aδ and of C fibers in the dorsal cutaneous nerves (DCNs), with characteristic latencies of 7–20 msec and 40–60 msec, respectively; excitation of low-threshold (Aα) fibers was ineffective. After cutting selected DCNs, the deprived skin became insensible, but pinch responsiveness gradually recovered over the following 2 weeks. Regeneration of cut axons was not responsible for this recovery; when neighboring intact DCNs were cut, however, all responses were abolished in the recovered skin that had been initially denervated. By 3–5 days after denervation, axons in the dermis were all histologically absent or degenerating; when pinch sensitivity was restored to such skin, silver-stainable axons reappeared in the formerly empty Schwann tubes. During the work we noticed that the periodic examination by pinching, used to follow the time course of recovery of function in individual animals, led to an earlier development of this recovery than in animals that were examined only once at a specified time after denervation, This apparent acceleration in the redevelopment of pinch sensitivity was correlated with the appearance of axons in the recovered skin, and was shown to be due to the impulse activity evoked in the remaining nerves by the periodic pinching; it did not occur when the nerves were blocked by tetrodotoxin (TTX), and it was mimicked by a brief (10-min) period of electrical excitation of the Aδ fibers in a remaining nerve carried out at the time when the denervation of skin was done. The time course of the phenomenon suggested that the principal effect of the impulses was to shorten the latency to the onset of sprouting in the activated Aδ axons; that is, they induced precocious sprouting. The impulses needed to be conducted centrally for the effect to occur, and precocious sprouting failed to occur if the impulses were allowed to proceed only distally toward the skin.     

Sympathetic axons surround nerve growth factor-immunoreactive trigeminal neurons: Observations in mice overexpressing nerve growth factor

It has been postulated that the aberrant projection of sympathetic axons to individual primary sensory neurons may provide the morphological basis for pain-related behaviors in rat models of chronic pain syndrome. Since nerve growth factor (NGF) can elicit the collateral sprouting of noradrenergic sympathetic terminals, it might be predicted that NGF plays a role in mediating the sprouting of sympathetic axons into sensory ganglia. Using a line of transgenic mice overexpressing NGF among glial cells, it was first found that trigeminal ganglia from adult transgenic mice possessed significantly higher levels of NGF protein in comparison to age-matched wild-type mice; as well, detectable levels of NGF mRNA transgene expression were present in both the ganglia and brain stem. Within the trigeminal ganglia, a small proportion of the sensory neuronal population stained immunohistochemically for NGF; a higher percentage of NGF-positive neurons was evident in transgenic mice. New sympathetic axons extended into the trigeminal ganglia of transgenic mice only and formed perineuronal plexuses surrounding only those neurons immunostained for NGF. In addition, such plexuses were accompanied by glial processes from nonmyelinating Schwann cells. From these data, we propose that accumulation of glial-derived NGF by adult sensory neurons and its putative release into the ganglionic environment induce the directional growth of sympathetic axons to the source of NGF, namely, the cell bodies of primary sensory neurons. © 1998 John Wiley & Sons, Inc. J Neurobiol 34: 347–360, 1998     

The relationship between nerves and smooth muscle cells in the rat iris

Summary The sphincter muscle in the rat iris forms irregular strands in the stroma. Bundles of unmyelinated axons run among the muscle cells. After sympathetic denervation some axons degenerate. This should indicate that sympathetic and parasympathetic nerves are present in the same nerve net. The parasympathetic axons possess varicosities, that is, enlargements containing mitochondria and synaptic vesicles. These varicosities show a similar structural relationship to the muscle cells as do the varicosities of sympathetic nerves. No obvious ultrastructural difference is observed between the sympathetic and parasympathetic varicosities.This study has been supported by research grants (U267 and Y247) from the Swedish Medical Research Council and by a Public Health Service Research Grant (NB05236-01) from the National Institute of Neurological Diseases and Blindness.     

The pattern of innervation in serially duplicated axolotl limbs: further evidence for the existence of local pathway cues?

The innervation of the biceps muscle was examined in regenerated and vitamin A-induced serially duplicated axolotl forelimbs using retrograde transport of horseradish peroxidase. The regenerated biceps muscle becomes innervated by motor neurones in the same position in the spinal cord as the normal biceps motor pool. In previous experiments in which the innervation of a second copy of a proximal limb muscle was examined in serially duplicated limbs (Stephens, Holder & Maden, 1985), the duplicate muscle was found to become innervated by motor neurones that would normally have innervated distal muscles. In the present study, the innervation of the second copy of biceps was examined under conditions designed to encourage nerve sprouting from 'correct' biceps axons. Following either partial limb denervation or denervation coupled with removal of the proximal biceps, the second copy of the muscle was still innervated by inappropriate motor neurones, which again would normally innervate distal limb muscles. These results are interpreted as evidence for the necessity for an appropriate local environment for axonal growth to allow reformation of a correct pattern of motor innervation in the regenerated limb.     

Neuroplasticity in the smooth muscle of the myenterically and extrinsically denervated rat jejunum

The objective of this study was to examine the effects of two different denervation procedures on the distribution of nerve fibers and neurotransmitter levels in the rat jejunum. Extrinsic nerves were eliminated by crushing the mesenteric pedicle to a segment of jejunum. The myenteric plexus and extrinsic nerves were eliminated by serosal application of the cationic surfactant benzyldimethyltetradecylammonium chloride (BAC). The effects of these two denervation procedures were evaluated at 15 and 45 days. The level of norepinephrine in whole segments of jejunum was initially reduced by more than 76% after both denervation procedures, but by 45 days the level of norepinephrine was the same as in control tissue. Tyrosine hydroxylase (nor-adrenergic nerve marker) immunostaining was absent at 15 days, but returned by 45 days. However, the pattern of noradrenergic innervating axons was altered in the segment deprived of myenteric neurons. Immunohistochemical studies showed protein gene product 9.5 (PGP 9.5)-immunoreactive fibers in whole-mount preparations of the circular smooth muscle in the absence of the myenteric plexus and extrinsic nerves. At 45 days, the number of nerve fibers in the circular smooth muscle increased. Vasoactive intestinal polypeptide (VIP)-immunoreactive fibers, a subset of the PGP 9.5 nerve fibers, were present in the circular smooth muscle at both time points examined. Choline acetyltransferase (CAT) activity and VIP and leucine enkephalin levels were measured in separated smooth muscle and submucosa-musosal layers of the denervated jejunum. VIP and leucine-enkephalin levels were no different from control in tissue that was extrinsically denervated alone. However, the levels of these peptides were elevated two-fold in the smooth muscle 15 and 45 days after myenteric and extrinsic denervation. In the submucosa-mucosa, VIP and leucine enkephalin levels also were elevated two-fold at 15 days, but comparable to control at 45 days. CAT activity was equal to control in the smooth muscle but elevated two-fold in the submucosa-mucosa at both times. These results provide evidence for innervation of the circular smooth muscle by the submucosal plexus. Moreover, these nerve fibers originating from the submucosal plexus proliferate in the absence of the myenteric plexus. Furthermore, the myenteric neurons appear to be essential for normal innervation of the smooth muscle by the sympathetic nerve fibers. It is speculated that the sprouting of the submucosal plexus induced by myenteric plexus ablation is mediated by increased production of trophic factors in the hyperplastic smooth muscle.     

Terminal Schwann cells guide the reinnervation of muscle after nerve injury

Schwann cells and axons labeled by transgene-encoded, fluorescent proteins can be repeatedly imaged in living mice to observe the reinnervation of neuromuscular junctions. Axons typically return to denervated junctions by growing along Schwann cells contained in the old nerve sheaths or “Schwann cell tubes”. These axons then commonly “escape” the synaptic sites by growing along the Schwann cell processes extended during the period of denervation. These “escaped fibers” grow to innervate adjacent synaptic sites along Schwann cells bridging these sites. Within the synaptic site, Schwann cells, originally positioned above the synaptic site continue to cover the acetylcholine receptors (AChRs) immediately following denervation, but gradually vacate portions of this site. When regenerating axons return, they first deploy along the Schwann cells and ignore sites of AChRs vacated by Schwann cells. In many cases these vacated sites are never reinnervated and are ultimately lost. Following partial denervation, Schwann cells grow in an apparently tropic fashion from denervated to nearby innervated synaptic sites and serve as the substrates for nerve sprouting. These experiments show that Schwann cells provide pathways that stimulate axon growth and insure the rapid reinnervation of denervated or partially denervated muscles.     

Sprouting and regeneration of frog motoneurons during synapse elimination

The ability of frog axons to sprout and reinnervate during the period of synapse elimination was examined in the cutaneous pectoris muscle from young postmetamorphic frogs using histological staining of nerve terminals and postsynaptic acetylcholinesterase. Partial denervation of the cutaneous pectoris muscle during the period of synapse elimination produced rapid sprouting of the intact axons. The majority of denervated endplates were being reinnervated by sprouts within 3 days. In addition, total denervation performed by either sectioning or crushing the nerve was followed by functional reinnervation. Approximately 98% of the endplates were being reinnervated within 7 days after a nerve crush and 10 days after sectioning the nerve.     

Sympathetic and parasympathetic regulation of cystatin S gene expression

The autonomic nervous system plays a regulatory role in the differentiation and growth of salivary glands, and in the expression of salivary specific genes. Cystatin S, a member of the evolutionarily conserved family 2 of the cysteine proteinase inhibitor superfamily, expressed in submandibular and parotid glands of rats during development, can be induced in adults by the beta-adrenergic agonist isopreterenol (IPR). It was shown previously that unilateral sympathectomy or bilateral parasympathectomy reduces IPR-induced cystatin S expression. The present experiments demonstrate that IPR-induced cystatin S gene expression in submandibular glands is reduced as early as 3 days post bilateral denervation of both branches of the autonomic nervous system. The reduction is nearly equal to that of either sympathectomy or parasympathectomy alone, suggesting that factor(s) in both sympathetic and parasympathetic fibers are simultaneously required for IPR-induced cystatin S gene expression.     

Neuromuscular activity impairs axonal sprouting in partially denervated muscles by inhibiting bridge formation of perisynaptic Schwann cells

Following partial denervation of rat hindlimb muscle, terminal Schwann cells extend processes from denervated endplates to induce and guide sprouting from the remaining intact axons. Increased neuromuscular activity significantly reduces motor unit enlargement and sprouting during the acute phase of sprouting. These findings led to the hypothesis that increased neuromuscular activity perturbs formation of Schwann cell bridges and thereby reduces sprouting. Adult rat tibialis anterior (TA) muscles were extensively denervated by avulsion of L4 spinal root and were immediately subjected to normal caged activity or running exercise (8 h daily) for 3, 7, 14, 21, and 28 days. Combined silver/cholinesterase histochemical staining revealed that the progressive reinnervation of denervated endplates by sprouts over a 1 month period in the extensively partially denervated TA muscles was completely abolished by increased neuromuscular activity. Immunohistochemical staining and triple immunofluorescence revealed that the increased neuromuscular activity did not perturb the production of Schwann cell processes, but prevented bridging between Schwann cell processes at innervated and denervated endplates. Our findings suggest that failure of Schwann cell processes to bridge between endplates accounts, at least in part, for the inhibitory effect of increased neuromuscular activity on sprouting.     

Structural basis of sympathetic-sensory coupling in rat and human dorsal root ganglia following peripheral nerve injury

Tyrosine hydroxylase immunocytochemistry was used to reveal the sympathetic postganglionic axons that sprout to form basket-like skeins around the somata of some primary sensory neurons in dorsal root ganglia (DRGs) following sciatic nerve injury. Ultrastructural observations in rats revealed that these sprouts grow on the surface of glial lamellae that form on the neurons. Sciatic nerve injury triggers glial cell proliferation in the DRG, and the formation of multilamellar pericellular onion bulb sheaths, primarily around large diameter DRG neurons. We infer that these glia participate in the sprouting process by releasing neurotrophins and expressing growth supportive cell surface molecules. Many DRG cell somata, and their axons in intact nerves and nerve end neuromas, express α2A adrenoreceptors intracytoplasmically and on their membrane surface. However, sympathetic axons never make direct contacts with the soma membrane. The functional coupling known to occur between sympathetic efferents and DRG neurons must therefore be mediated by the diffusion of neurotransmitter molecules in the extracellular space. Sympathetic basket-skeins were observed in DRGs removed from human neuropathic pain patients, but the possibility of a functional relation between these structures and sensory symptoms remains speculative.     

Nerve growth factor-induced growth of sympathetic axons into the optic tract of mature mice is enhanced by an absence of p75NTR expression

Postganglionic sympathetic axons display a remarkable ability for new collateral growth in response to local increases in nerve growth factor (NGF). Elevating NGF levels within the brain also induces the directional growth of sympathetic axons, but not within myelinated pathways of adult mammals. In this investigation, we provide in vivo evidence that sympathetic axons are capable of NGF-induced collateral growth through the microenvironment of mature myelinated pathways, especially in the absence of the p75 neurotrophin receptor (NTR). In transgenic mice overexpressing NGF centrally and expressing p75NTR, only a few varicose sympathetic axons invade the optic tract after the first month of postnatal life. In other transgenic mice overexpressing NGF centrally but lacking p75NTR expression, the incidence of sympathetic axons within this myelinated tract substantially increases. Moreover, numerous unmyelinated sympathetic axons cluster together to form large processes extending through the optic tract; such structures are first seen 8 weeks after birth. Only these large axon bundles display prominent immunostaining for GAP-43, which is preferentially localized to the sympathetic fibers, since nonmyelinating Schwann cells are not associated with these axon bundles. These data provide the first direct evidence that sympathetic axons are indeed capable of NGF-induced collateral growth into myelinated tracts of mature mammals, and that their continued growth through this microenvironment is markedly enhanced by the absence of p75NTR expression. We propose that p75NTR among sympathetic axons may either directly or indirectly limit collateral branching of these fibers in response to increased levels of NGF.     

Nerve fiber production by intraocular adrenal medullary grafts: Stimulation by nerve growth factor or sympathetic denervation of the host iris

Summary This study evaluates the production of adrenergic nerve fibers by adrenal medullary tissue of the adult rat grafted to the anterior chamber of the eye of adult recipients. The chromaffin grafts attach to and become vascularized by the host iris. They decrease in size intraocularly during the first 3 weeks. This decrease is somewhat counteracted by sympathetic denervation of the host iris, and better counteracted by sympathetic denervation and addition of nerve growth factor (NGF, given at grafting and 1 and 2 weeks after grafting). Outgrowth of adrenergic nerve fibers from the grafts into the host iris was studied in wholemount preparations by use of the Falck-Hillarp technique 3 weeks after grafting. The innervated area of the host iris was approximately doubled in the chronically sympathectomized group and doubled again in the chronically sympathectomized NGF-supplemented group. Chronic sympathetic denervation had no effect on density of outgrowing nerves, whereas addition of NGF more than doubled nerve density. Since sympathetic denervation causes a slight elevation of NGF activity in the iris, the present experiments are taken as evidence that the level of NGF in the iris regulates formation of nerve fibers by adrenal medullary tissue grafts from adult rats.     

Nerve growth factor–induced growth of sympathetic axons into the optic tract of mature mice is enhanced by an absence of p75NTR expression

Postganglionic sympathetic axons display a remarkable ability for new collateral growth in response to local increases in nerve growth factor (NGF). Elevating NGF levels within the brain also induces the directional growth of sympathetic axons, but not within myelinated pathways of adult mammals. In this investigation, we provide in vivo evidence that sympathetic axons are capable of NGF‐induced collateral growth through the microenvironment of mature myelinated pathways, especially in the absence of the p75 neurotrophin receptor (NTR). In transgenic mice overexpressing NGF centrally and expressing p75^NTR, only a few varicose sympathetic axons invade the optic tract after the first month of postnatal life. In other transgenic mice overexpressing NGF centrally but lacking p75^NTR expression, the incidence of sympathetic axons within this myelinated tract substantially increases. Moreover, numerous unmyelinated sympathetic axons cluster together to form large processes extending through the optic tract; such structures are first seen 8 weeks after birth. Only these large axon bundles display prominent immunostaining for GAP‐43, which is preferentially localized to the sympathetic fibers, since nonmyelinating Schwann cells are not associated with these axon bundles. These data provide the first direct evidence that sympathetic axons are indeed capable of NGF‐induced collateral growth into myelinated tracts of mature mammals, and that their continued growth through this microenvironment is markedly enhanced by the absence of p75^NTR expression. We propose that p75^NTR among sympathetic axons may either directly or indirectly limit collateral branching of these fibers in response to increased levels of NGF. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 51–66, 1999     

Changes in surviving nerve fibers associated with submucosal arteries following extrinsic denervation of the small intestine

Summary The neuropeptide content of nerve fibers associated with submucosal arteries in the small intestine of guinea pigs was studied in whole-mount preparations using immunohistochemical methods. Tissues were obtained from normal animals or animals in which the small intestine had been extrinsically denervated. In normal animals, submucosal arteries are innervated by extrinsic sensory nerve fibers which contain both substance P and calcitonin gene-related peptide, and by sympathetic noradrenergic nerve fibers. In preparations obtained from animals 5–9 days after denervation, nerve fibers which contained substance P without detectable calcitonin gene-related peptide were associated with a few submucosal arteries. Nerve fibers which contained vasoactive intestinal peptide were also associated with some arteries. By 42–48 days after extrinsic denervation, substance P-containing fibers (without calcitonin gene-related peptide) and vasoactive intestinal peptide-containing fibers were associated with nearly every blood vessel. The extrinsic sympathetic nerve fibers did not regenerate during the course of this study. The nerve fibers associated with submucosal arteries in denervated tissues were not sensitive to capsaicin treatment.The alteration in the innervation of submucosal arterioles that follows extrinsic denervation of the gut may reflect either an increase in the neuropeptide content of the fibers, synthesis of a new peptide, or an increase in the number of fibers as a result of axonal sprouting.     

Competitive reinnervation of salamander skin by regenerating and intact mechanosensory nerves

We have investigated in the salamander the possibility that regenerating mechanosensory nerves might prefer the epidermal Merkel cells (their specific targets) that are located within their segmental domain to those within a "foreign" domain. Since regerating nerves cross domain boundaries with no evidence of the marked delay exhibited by intact sprouting nerves, we examined situations in which the regenerating axons of one segmental nerve were effectively in equal competition for denervated skin with those of another segmental nerve. Additionally, we investigated whether there were differences between regenerating axons and intact sprouting axons of the same segmental nerve, in their ability to innervate available skin both inside and outside the parent domain. No preference was detected of any type of nerve, regenerating or intact, for particular skin regions, or for Merkel cells as indicated by the numbers of mechanosensory thresholds of the touch spots that developed in reinnervated skin. Neither was there any indicating of displacement of "foreign" nerves from a particular region by appropriate axons. When regenerating and intact (sprouting) axons invaded denervated skin more or less simultaneously, the former appeared to have a slight advantage since a significantly greater proportion of skin was innervated by regenerated fibres. With this one exception, all the results were explained most simply by assuming that the axon that first arrives at a denervated Merkel cell establishes a permanent association with that cell and at the same time causes it to lose its "target character" for other axons.