Biochemical studies of trophic dependencies in crayfish giant axons

Medial giant (MGA) and lateral giant (LGA) axons of crayfish were doubly cut in order to selectively isolate axonal segments from perikaryal and transsynaptic sources of trophic input. Isolated MGA segments remained morphologically intact for over 43 days, whereas isolated LGA segments usually degenerated within one week. The glial sheaths around isolated MGA segments had significantly increased in thickness within one week, but severed LGA segments showed no increase in sheath thickness at any time after lesioning. These data suggest that cells of the surrounding glial sheath can provide trophic support to isolated MGA segments but not to isolated LGA segments. Extent of glial hypertrophy seems dependent upon specific spatiotemporal parameters.The diameters of isolated MGA segments decreased more rapidly than the diameters of singly cut MGA segments. These data suggest that the MGA also receives some trophic support from pre- or postsynaptic sources. Conversely, some singly cut LGA segments completely degenerated within one week, whereas other singly cut LGA segments remained intact for at least 43 days after lesioning. Such results suggest that the LGA receives a significant trophic input from pre- or postsynaptic structures.     

Biochemical studies of trophic dependences in crayfish giant axons.

Data from previous histological studies indicate that long-term survival of crayfish medial giant axons might be due in part to trophic support from cells of the surrounding glial sheath which often hypertrophy in response to transection of the medial giants. The biochemical studies reported herein show that segments from transected ventral nerve cords (VNC) always incorporate more [3H]leucine into protein than do corresponding segments from intact VNCs. Furthermore, the relative amount of [3H]leucine incorporation in severed segments seems to be influenced by distance and direction from the lesion site as well as time after lesioning. Similar spatiotemporal parameters were previously shown to be correlated with extent of glial hypertrophy around severed medial giant axons. Quantitative autoradiography of medial giant axons after incubation in [3H]leucine revealed that the grain density of label in glial sheaths surrounding severed medial giants was over two-fold greater than in sheaths around corresponding control axons. Moreover, the grain density in the axoplasm of severed medial giants was nearly four-fold greater than the grain density in the axoplasm of control axons. Data from experiments using short or long labeling intervals suggests that labeling in the medial giant axoplasm may be due more to transfer from glial sheath cells than from inherent axonal synthetic mechanisms. In light of this and other data, we concluded that long-term survival of severed medial giant axons is probably due to the direct transfer of trophic substances from cells of the glial sheath into the axon.     

Axon-glia transfer of a protein and a carbohydrate

We have investigated the transfer of a fluorescent protein, the fluorescein isothiocyanate derivative of bovine serum albumin (FITC-BSA), and a fluorescent carbohydrate, FITC-dextran, from the crayfish medial giant axon (MGA) to the periaxonal glial cells. The dialyzed tracer was injected into one of the two MGAs, and, after a transfer period of 15-60 min, the tissue was fixed for histological examination of fluorescence distribution. With each tracer, the periaxonal sheath of the injected MGA was specifically labeled. Similar results were obtained with several different fixatives. During the transfer period, there was no appreciable change in the resting potential or conducted action potential of the MGA or in the resting potentials of the adaxonal glial cells. Polyacrylamide gel electrophoresis indicated that the axoplasmic and sheath fluorescence was produced by the intact tracers. These results suggest that "foreign" macromolecules can be exchanged from crayfish axons to glia under physiological conditions. Such transfers may indicate a substantial intercellular traffic of molecules or a means whereby neurons can eliminate waste materials.     

Glial polypeptides transferred into the squid giant axon

The proteins synthesized by the glial sheath of an isolated segment of squid giant axon and by the cell bodies of the giant axon in the isolated stellate ganglion were labeled by incubation in the presence of [3H]leucine. The axoplasm, which contained labeled proteins transferred from the glial sheath, was separated from the sheath by mechanical extrusion. The labeled proteins in the axoplasm, the empty sheath and the stellate ganglion were analyzed and compared by one- and two-dimensional polyacrylamide gel electrophoresis. Over 80 glial polypeptides were found to be selectively transferred into the axoplasm and many of these were distinct from stellate ganglion polypeptides which presumably could be supplied to the axon via axonal transport. Three of the more highly labeled transferred glial polypeptides (TGPs) were actin, a fodrin-like polypeptide and a polypeptide we have named traversin. Our observations, considered in the context of other reports, suggest that the squid axon receives a large number of polypeptides from its surrounding glia either by phagocytozing glial cell process that project into it or via cytoplasmic channels between adaxonal glia and the axon. These TGPs may help the axon survive unfavorable conditions.     

Development of myelinated nerve fibers in the sixth cranial nerve of the rat: a quantitative electron microscope study

Myelination was studied quantitatively in the sixth cranial nerves of rats by counting and measuring all myelinated fibers during the first three postnatal weeks. In transverse semithin and thin sections cut serially at a well-defined anatomical site in the midsphenoid region, only a few axons (mean 12) were myelinated at birth. On days 2, 4, and 8, counts of myelinated fibers were respectively 5 times (mean 57), 20 times (mean 230), and 24 times (mean 273) the number seen at birth. During the second postnatal week, the number of myelinated fibers remained constant, whereas growth of axons and their myelin sheaths continued. By 15 days these fibers were large and relatively uniform in size; they had compact, circular myelin sheaths. During the third postnatal week, myelination of previously unmyelinated, smaller axons began. The number of myelinated fibers increased again and the size distribution of myelinated fibers became bimodal. Axon diameters, fiber diameters, and myelin sheath dimensions for all fibers were calculated from measurements made on electron micrographs. The transverse length of the myelin membrane increased exponentially with time. The growth increased rapidly during the formation of the first 20 spiral layers and remained relatively constant during the subsequent enlargement of the compact sheath. The association of axon diameter and myelin sheath thickness was poor at young ages, but it improved progressively with maturation of the sheath. The results show that myelination begins around axons that have a wide range of diameters. Also, the first axons to be myelinated become the large myelinated fibers of the sixth nerve. The small myelinated fibers originate from axons that do not become myelinated until the third postnatal week. Myelination, though differing in onset by 2 weeks, appeared to be similar in both populations as judged by similarity of sheath morphology and growth rates. It is of interest that at the level studied, the sixth nerve also contains a fascicle of unmyelinated cranial sympathetic fibers.     

The growth and myelination of central and peripheral segments of ventral motoneurone axons. A quantitative ultrastructural study.

This study compares the growth and myelination of those parts of cervical ventral motoneurone axons in the spinal cord (the intramedullary segments) and in the ventral roots of fetal and young rats (up to 21 days postnatal). The same fibre bundles are examined centrally and peripherally. Myelination begins centrally and peripherally at about birth. However, the peripheral segments of some fibres may begin to become myelinated before the central. Over the first 3 weeks after birth the minimum circumference of peripheral segments of myelinated axons remains relatively constant at 3 mum but that of central segments falls from 2.5 mum to just over 1 mum. Axons within the same fibre bundles tend to be thinner and less heavily myelinated centrally than peripherally. With ageing, axon circumference becomes more strongly correlated with sheath thickness. The thickness of the sheath surrounding an axon of a given circumference does not differ statistically from one age to another or between central and peripheral segments. Studies of myelin sheath growth rate show that in the early stages glial and Schwann cells vary independently of one another in the rates at which they add new turns to sheaths around central and peripheral segments of axons in the same bundles.     

Mu and delta opioid receptor-like immunoreactivity in the cervical spinal cord of the rat after dorsal rhizotomy or neonatal capsaicin: an analysis of pre- and postsynaptic receptor distributions

Opioid compounds have powerful analgesic properties when administered to the spinal cord. These effects are exerted through mu and delta opioid receptors, and both pre- and postsynaptic mechanisms have been implicated. To specifically address the relative pre- and postsynaptic contribution to spinal opioid analgesia, we have quantitatively assessed the pre- vs. postsynaptic distribution of the mu-opioid (MOR-1, MOP₁) and delta-opioid receptors (DOR-1, DOP₁). We also examined the rostro-caudal arborization of MOR-1 and DOR-1 immunoreactive primary sensory neurons, using an isolated dorsal root preparation. These results were compared to those obtained by labeling for calcitonin gene-related peptide (CGRP), a neuropeptide whose expression in the spinal cord is restricted to the terminals of small diameter primary sensory neurons. We estimate that approximately one half of MOR-1 and two thirds of DOR-1 immunoreactivity in the cervical spinal cord is located on primary afferent fibers. These fibers have a broad rostro-caudal distribution, extending at least three segments rostral and caudal to their segment of entry. Regardless of marker used, the rostral projection was greatest, however, the distribution of CGRP-immunoreactive fibers differed somewhat in that they had a much smaller projection to the most caudal segments examined. Our results suggest that presynaptic delta opioid actions predominate, but that there are mixed pre- and postsynaptic inhibitory effects exerted by opioid analgesics that act at the spinal cord mu opioid receptor.     

Trans-glial channel-facilitated translocation of tracer protein across ventral nerve root sheaths of crayfish.

Trans-glial channels, which traverse the multilamellate glial sheath of crayfish nerves, are easily recognized in freeze-fracture preparations. Their structure and position in the glial layers of the sheath strongly supports the suggestion that they serve to facilitate rapid movement of molecules and fluids from outside the sheath to the surface of axons contained within. Segments of ventral ganglion nerve roots, which were ligated at their free ends, were immersed in crayfish Ringer solution containing 10 mg/ml horseradish peroxidase (HRP). Electron microscopic examination of the nerve sheath 30 sec after exposure to peroxidase showed that the protein had passed across the sheath and was present near the axon surface. Reaction product was present in trans-glial channels as well as in extracellular clefts and adaxonal tubular lattices thereby supporting the notion that these structures constitute a specialized conduit traversing the sheath. Often, 'fronts' of reaction product were observed across the sheath from its exterior to the interior reflecting a gradual accumulation of protein in extracellular clefts toward the axon. After 5 min in HRP-Ringer, protein appeared in all channels, extracellular clefts, and tubular lattices. With increased length of exposure of ligated nerve segments to HRP-Ringer, reaction product was found in vesicles in glial cytoplasm adjacent to axons. Results from this study suggest that trans-glial channels constitute an efficient system for rapid solute movement across nerve sheaths and may represent a mechanism whereby ions and nutrients are made available to nerves isolated in an avascular sheath.     

Effects of freezing a segment of peripheral nerve on subsequent protein release and axonal regeneration in the frog.

Previous studies in frogs have shown that axons from the proximal stump of a cut nerve will grow toward the distal stump, possibly in response to diffusible trophic factors produced by cells of the nerve sheath. In the present experiments, the synthesis and release of proteins in vitro, from proximal and distal stumps of frog sciatic nerves, were studied 1, 4, and 14 days after nerve section in vivo. Using two-dimensional gel electrophoresis to separate released proteins, a marked increase in the synthesis of two lipoproteins of 37 and 67 kDa was seen, initially in both proximal and distal stumps, but by 14 days these proteins were produced exclusively by the distal stump. To see if the production of these proteins was correlated with subsequent reinnervation of the distal stump, isolated nerve segments were removed from the frogs and either replaced immediately or frozen (to kill sheath cells) and replaced. After 2 weeks, the pattern of newly synthesized proteins released by both the frozen and nonfrozen nerve segments was similar although freezing severely impaired the reinnervation of the nerve segment. These results suggest that although the 37- and 67-kDa lipoproteins may have a role in nerve regeneration, their presence per se is not sufficient to support the reinnervation of a distal stump of a cut peripheral nerve and that additional factors may therefore be required.     

The regulation of synaptic strength within motor units of the frog cutaneous pectoris muscle

The physiological properties of frog neuromuscular junctions may vary widely in a single muscle. In order to understand the factors that contribute to this variation, we have studied populations of synapses belonging to individual motor units of the frog cutaneous pectoris muscle. Motor units in this muscle differ widely in twitch strength. A motor axon's synaptic contacts could be found throughout the muscle, at both singly and polyneuronally innervated endplates. Indeed, over 36% of the endplates contacted by each isolated motor axon were polyneuronally innervated. Comparisons of synapses on muscle fibers in large twitch motor units with those in small twitch motor units reveal that endplate potential amplitude, transmitter release, and muscle fiber diameter are positively correlated with the strength of the motor unit contraction. Large and small twitch motor units differ more in their transmitter release than in their nerve terminal length, indicating that larger twitch motor units have a higher release per unit length of terminal. Among motor units of roughly similar twitch tension, transmitter release at endplates receiving only one axonal input is remarkably constant, independent of postsynaptic muscle fiber input resistance, or, presumably, nerve terminal size. In cases where two different motor axons contribute to a single endplate, the synaptic strength of each input is again related to properties of the contributing motoneuron, although the individual synaptic inputs are markedly reduced in strength and size relative to singly innervated endplates. Additionally, the diameter of polyneuronally innervated muscle fibers appears related to properties of both innervating motoneurons. Thus, the pre- and postsynaptic characteristics of neuromuscular junctions may be determined both by the motoneuron and by peripheral interactions between motoneurons.     

Autocrine action of BMP2 regulates expression of GDNF-mRNA in sciatic Schwann cells

Schwann cell is a cell type that forms myelin sheath and provides trophic supports for neuronal cells by producing neurotrophic factors in both normal and traumatic situations. It was recently reported that after lesion of sciatic nerve, mRNA for glial cell line-derived neurotrophic factor (GDNF) is induced in nonneuronal cells in the nerve. However, the mechanism regulating GDNF-mRNA has remained largely unknown. In the present study, we searched for factors regulating the GDNF-mRNA expression in Schwann cells. First, we found that after transfer into explant culture as an in vitro lesion model, sciatic nerve segments began to express mRNA for bone morphogenetic protein-2 (BMP2) concomitantly with the induction of GDNF-mRNA. Treatment of the Schwann cells isolated from the sciatic nerve with combination of BMP2 and retinoic acid (RA) dramatically induced GDNF-mRNA, while BMP2 or RA alone had no effect. Furthermore, ionomycin, a calcium ionophore, which had even stronger activity on the induction of GDNF-mRNA also induced also BMP2-mRNA in cultured Schwann cells. Effects of inhibitors of intracellular signaling pathways such as protein kinase C inhibitor and MAPKK inhibitor suggested that the molecular mechanism of the induction of GDNF-mRNA is distinct from that of BMP2-mRNA. These results suggest that the Schwann cell-produced BMP2 plays an important role in the induction of GDNF after nerve injury in an autocrine fashion.     

The axon reaction of lamprey spinal interneurons

Axotomy and partial denervation of giant interneurons (GIs) and lateral cells (LCs) were produced by complete spinal transection in the larval lamprey spinal cord. Both cell types demonstrated a reduction in cytoplasmic basophilia, increase in cell size, nuclear eccentricity, and formation of a chromophilic nuclear cap. This was quantified in the case of cell diameter. During the first 8 weeks of recovery, the GIs with the largest diameters were found progressively further from the scar and this peak change moved at approximately 0.5 mm/day. The increase in size of GIs remained up to 20 weeks post-transection, long after the time required for their axons to regenerate across the scar and form functioning synapses. GIs injected intracellularly with horseradish peroxidase (HRP) also showed this increase in diameter as well as a simplification of their dendritic trees. Intracellular recordings from GIs revealed changes in the frequency and amplitude of spontaneous synaptic input. In the first two weeks after transection, spontaneous excitatory postsynaptic potentials (EPSPs) and inhibitory postsynaptic potentials (IPSPs) were less frequent than in control cells. After 6 weeks of recovery they became more frequent than in control cells. EPSPs predominated in axotomized GIs, while in control cells they constituted only 36% of the total of spontaneous potentials. A reversible increase in the amplitude of these EPSPs occurred at 3-4 weeks of recovery time. The resting membrane potential was significantly reduced by the 6th week after transection and returned to normal after the 22nd week.     

Synaptic organization of cholinergic neurons in the monkey neostriatum

Cholinergic neurons in the monkey neostriatum were examined at the light and electron microscopic level by immunohistochemical methods in order to localize choline acetyltransferase (ChAT), the synthesizing enzyme for acetylcholine. At the light microscopic level a sparse distribution of cholinergic neurons was identified throughout the caudate nucleus. Neurons had large (25-30 microns) somata, eccentric invaginated nuclei, primary dendrites of unequal diameters, and varicosities on distal dendritic branches. Ultrastructural study showed that the cholinergic cells had a cytoplasm abundant in organelles. Within dendritic branches, mitochondria and cisternae were localized primarily to varicosities. Synaptic inputs were distributed mostly to the dendrites and at least four types that formed symmetric or asymmetric synapses were observed. Immunoreactive fibers were relatively numerous within the neuropil and exhibited small diameters (0.1-0.15) micron) and swellings at frequent intervals. Cholinergic boutons that formed synapses were compared to unlabeled terminals making asymmetric synapses with dendritic spines. Results showed that ChAT-positive axons had significantly smaller cross-sectional areas, shorter synaptic junctions, and a higher density and surface area of mitochondria than the unlabeled boutons. Cholinergic axons formed symmetric synapses mostly with dendritic spines (53%) and the shafts of unlabeled primary and distal dendrites (37%). A relatively small proportion of the boutons contacted axon initial segments (1%) and cell bodies (9%) that included medium-sized neurons with unindented (spiny) and indented (aspiny) nuclei. The majority of dendritic spines contacted by cholinergic axons were also postsynaptic to unlabeled boutons forming asymmetric synapses. The results suggest that cholinergic neurons in the primary neostriatum belong to a single morphological class corresponding to the large aspiny (type II) interneuron identified in previous Golgi studies. Present results along with earlier Golgi-electron microscopic observations from this laboratory suggest that neostriatal cholinergic cells integrate many sources of intrinsic and extrinsic inputs. The observed convergence of ChAT-immunoreactive boutons and unlabeled axons onto the same dendritic spines suggests that intrinsic cholinergic axons modulate extrinsic inputs onto neostriatal spiny neurons at postsynaptic sites close to the site of afferent input.     

Fiber formation and myelinization of cultivated dissociated neurons from chicken dorsal root ganglia: an electron microscopic and scanning electron microscopic study

Dissociated neurons from chicken embryo dorsal root ganglia were cultivated in Rose chambers for up to 5 weeks. Newly formed fibers appeared as single fibers or grouped in bundles. During the first week of cultivation microtubules and microfilaments were frequently observed. The diameters of the fibers increased progressively and a number of varicosities appeared. In some distal portions of fibers large vesicles could be observed. During the second week in culture Schwann cells were easily recognized. They appeared as both dark and light cells. During this period myelinization of some fibers was seen to commence. High glucose concentrations were not observed to influence the process of myelinization. Essentially the important factors were the number of cells present in the culture and also the presence of NGF in the medium. Schwann cells myelinated nerve fibers exclusively. Two types of abnormalities in myelin formation were recognized: one Schwann cell myelinating two fibers and one fiber being myelinated twice, by two Schwann cells. Concomitantly with myelinization, myelin degeneration was observed. Histiotypic fascicles, typical constituents of the outgrowth zone of cultivated intact dorsal root ganglia, bundles of fibers, surrounded by connective tissue, are not formed. The surface ultrastructure of nerve fibers, as studied by scanning EM, was seen to be covered by numerous spherical elements as well as by small fibers and irregular elements. The growth cones of fibers were void of any glial contact. Myelinization occupied individual isolated segments along with nerve fibers and evidenced the absence of nodes of Ranvier. Relationships between single elements in the dissociated culture system are discussed, with respect to the possibilities for analysis of some of the elementary mechanisms of cellular and molecular interaction responsible for the development of the peripheral nervous system.     

Cellular and subcellular localization of androgen receptor immunoreactivity relative to C1 adrenergic neurons in the rostral ventrolateral medulla of male and female rats

In male and female rats, high androgen levels can increase blood pressure. The C1 area of the rostral ventrolateral medulla (RVLM), which is crucial for blood pressure regulation, contains estrogen receptors (ERs) in pre- and postsynaptic neuronal compartments and is modulated by estrogens (Wang et al. [2006] Brain Res 1094:163-178). In this study, the cellular and subcellular localization of androgen receptors (ARs) in the C1 area was examined in sections from male, proestrus (high estrogen) and diestrus (low estrogen) female rat brains that were immunocytochemically labeled for AR and tyrosine hydroxylase (TH). By light and electron microscopy, AR-labeled nuclei were scattered among TH-labeled somata in the RVLM; significantly more AR-labeled nuclei were seen males compared to females. Electron microscopy revealed that extranuclear AR-immunoreactivity (ir) was in similar profile types in male and female rats. AR-ir was almost exclusively in myelinated and unmyelinated axons and in glia. Rarely, AR-ir was in axon terminals that contacted TH-containing dendrites. AR-labeled axon terminals had large diameters and contained numerous dense-core vesicles, resembling peptide-containing hypothalamic or solitary tract inputs. No nuclear or extranuclear AR-ir was found in TH-labeled perikarya and dendrites although a few non-TH- labeled dendrites contained AR-ir. Qualitatively, more axonal profiles appeared to be present in males compared to females. These studies suggest that, unlike ERs, ARs in male and female rats are almost exclusively positioned on afferents and glia, suggesting that androgens modulate RVLM C1 neurons, and thus blood pressure, through presynaptic and glial signaling.     

Myelin sheath survival following axonal degeneration in doubly myelinated nerve fibers.

Axonal contact plays a critical role in initiating myelin formation by Schwann cells. However, recent studies of "double myelination" have indicated that myelin maintenance continues in Schwann cells completely displaced from physical contact with the axon. This raises the possibility either that diffusible trophic factors are produced by the axon, or that the axon is not required for myelin maintenance by these displaced Schwann cells. To test these hypotheses, the axons involved in double myelination in the mouse superior cervical ganglion (SCG) were transected surgically by a transganglionic lesion. The inferior pole of the SCG was resected to limit axonal regeneration. This method produced a typical Wallerian pattern of degeneration in the superior pole, without compromising the blood supply or introducing nonspecific trauma. EM analysis at 1 and 5 d postoperatively showed that initially the axon degenerated, followed by breakdown of the inner myelin sheath. In those configurations where the outer Schwann cell was only partly displaced from the axon, the outer myelin sheath degenerated simultaneously. However, in completely displaced internodes the outer sheath survived degeneration of the axon and inner sheath. Outer internodes remained intact for at least 5 weeks after transection (the longest time point in this study), at which time they enclosed reorganized processes of the inner Schwann cells, their basal lamina, and numerous collagen fibrils. Axonal regeneration within surviving outer internodes was rare and was characterized by the development of typical Remak ensheathment by the inner Schwann cells. We conclude that in the mouse SCG, myelin maintenance does not depend on the continued presence of the axon. These data suggest further that myelin breakdown in Wallerian degeneration may be initiated by mechanisms other than absence of a viable axon.     

Sprouts emerging from the dendrites of axotomized lamprey central neurons have axonlike ultrastructure

We have examined the dendritic and axonal ultrastructure of intact anterior bulbar reticulospinal neurons (ABCs) in the CNS of the larval sea lamprey and compared it with that of the dendrites and neuritic sprouts from ABCs examined 2 months following axotomy. Dendrites and axons of intact ABCs are distinguishable from one another by several ultrastructural criteria: (1) the predominance of microtubules in the dendritic cytoskeleton and neurofilaments in that of the axon, (2) the exclusively postsynaptic status of the dendrites versus the presynaptic status of the axon, and (3) the presence of polyribosomes and large numbers of mitochondria in the dendrites and their respective absence and scarcity in the axon. The ultrastructure of axonal sprouts evoked by axotomy of ABCs 1-1.5 mm from their somata ("intermediate axotomy") in many ways resembled that of intact axons. Axonal sprouts were presynaptic to other neurons, and their cytoskeletons consisted mainly of neurofilaments. They also exhibited some features not seen in either axons or dendrites, such as numerous clusters of small vesicles that were not associated with synapses and, in some cases, close associations with glial elements. We also examined sprouts emerging from the dendrites of ABCs following axotomy within 500 microns of their somata ("close axotomy") and found that such "dendritic" sprouts closely resembled axonal sprouts; they possessed neurofilament-dominated cytoskeletons, were presynaptic to other neurons, and were often associated with glial elements. The dendrites of ABCs undergoing dendritic sprouting retained their normal gross morphology but possessed a mixture of "axonal" and "dendritic" ultrastructural characteristics, exhibiting neurofilament-dominated cytoskeletons while remaining entirely postsynaptic to other neurons. However, there were significantly fewer synapses on the dendrites of axotomized cells than were found on the dendrites of intact ABCs. We conclude that sprouts evoked by axotomy are intrinsically axonal in character whether they originate from the axon stump or from the dendritic tree. Our results also suggest that the materials necessary for axonal regeneration may displace elements of the dendritic cytoskeleton as they are transported through the dendrites to the emerging "dendritic" sprouts following close axotomy.     

A decline in glial cell-line-derived neurotrophic factor expression is associated with impaired regeneration after long-term Schwann cell denervation.

In the peripheral nervous system, regeneration of motor and sensory axons into chronically denervated distal nerve segments is impaired compared to regeneration into acutely denervated nerves. In order to find possible causes for this phenomenon we examined the changes in the expression pattern of the glial cell-line-derived neurotrophic factor (GDNF) family of growth factors and their receptors in chronically denervated rat sciatic nerves as a function of time with or without regeneration. Among the GDNF family of growth factors, only GDNF mRNA expression was rapidly upregulated in Schwann cells as early as 48 h after denervation. This upregulation peaked at 1 week and then declined to minimal levels by 6 months of denervation. The changes in the protein expression paralleled the changes in the expression of the GDNF mRNA. The mRNAs for receptors GFRalpha-1 and GFRalpha-2 were upregulated only after maximal GDNF upregulation and remained elevated as late as 6 months. There were no significant changes in the expression of GFRalpha-3 or the tyrosine kinase coreceptor, RET. When we examined the expression of GDNF in a delayed regeneration paradigm, there was no upregulation in the distal chronically denervated tibial nerve even when the freshly axotomized peroneal branch of the sciatic nerve was sutured to the distal tibial nerve. This study suggests that one of the reasons for impaired regeneration into chronically denervated peripheral nerves may be the inability of Schwann cells to maintain important trophic support for both motor and sensory neurons.     

Cells in laminae III and IV of rat spinal dorsal horn receive monosynaptic primary afferent input in lamina II

In order to determine how information conveyed by fine primary afferent fibres might reach the deeper laminae of the spinal dorsal horn, 5 Golgi-stained neurones with somata in lamina III or IV and dendrites that entered lamina II were examined by electron microscopy. Three of the cells were from animals in which 2 or 3 dorsal roots had been cut 26 or 30 hours previously. These cells received numerous synapses in lamina II, and between 13 and 16% of these (24-31% of asymmetric synapses) were from degenerating axons. Synapses with degenerating axons were found throughout the depth of lamina II, including the dorsal part, which receives primary afferent input from myelinated nociceptors and from unmyelinated axons. In addition, all 3 cells were postsynaptic to degenerating axons within lamina III. The 2 cells from unoperated animals also received many synapses within lamina II and at some of these the presynaptic axon was the central terminal of a glomerulus. Only one example of a dendrodendritic synapse involving a stained dendrite was seen. Cells of laminae III and IV may therefore not be a major target for presynaptic dendrites of cells in lamina II. It is concluded that one way in which information carried by primary afferents passes from the superficial dorsal horn to the deeper laminae is through monosynaptic contacts between these afferents and the dorsal dendrites of some cells whose somata are situated in laminae III and IV. If the axons of these cells generate local collaterals, this may account for some of the activation of cells whose dendrites do not enter lamina II.     

Peripheral organization and central projections of the electrosensory nerves in gymnotiform fish

The electrosensory system of weakly electric gymnotiform fish is described from the receptor distribution on the body surface to the termination of the primary afferentsin the posterior lateral line lobe (PLLL). There are two types of electroreceptor(ampullary and tuberous) and a single type of lateral line mechanoreceptor (neuromast). Receptor counts in Apteronotus albifronsshow that (1) neuromasts are distributed as in other teleosts; (2) ampullary receptors number 151 on one side of the head and 208 on one side of the body; (3) tuberous receptors were estimated to number 3,000-3,500 on one side of the head and 3,500-5,000 on one side of the body. The distribution of each receptor type is described. Each receptor is innervated by a single primary afferent. Electro-sensory afferents have myelinated cell bodies in the ganglion of the anterior lateral line nerve (ALLN). The distribution of these ganglion cell diameters is strongly bimodal in Apteronotus and Eigenmannia: The smaller-diameter cells may be those which innervate ampullary electroreceptors, the larger-diameter tuberous electroreceptors. Transganglionic HRP transport techniques were used to determine the first-order connections of the anterior lateral line nerve in six species of gymnotiform fish. Small branches of the ALLN were labeled so as to determine the somatotopic organization in the PLLL. The PLLL is divided into four segments from medial to lateral, termed medial, centromedial, centrolateral, and lateral segments (Heiligenberg and Dye, '81). Representations of the head are found rostrally in each zone, and the trunk is mapped caudally in each zone. Thus there are four body maps in the PLLL. The medial segment receives ampullary input (Heiligenberg and Dye, '82) and maps the dorsoventral body axis mediolaterally, as does the tuberous centrolateral segment. The tuberous centromedial and lateral segments map the dorsoventral axis lateromedially. Thus the medial and centromedial segments meet belly to belly, the centromedial and centrolateral segments meet back to back, and the centrolateral and lateral segments meet belly to belly. Adjacent electrosensory maps within the PLLL are therefore always mirror images.