Dynamic studies of ototoxicity in mature avian auditory epithelium.

Hearing loss induced by ototoxicity is a worldwide problem despite the development of newer antibiotics and chemotherapy agents. The cellular mechanisms responsible for aminoglycoside-induced hearing loss are still poorly understood. We have developed two different methods of studying the dynamic cellular and subcellular changes in the chick auditory sensory epithelium that occur during hair cell death. The first study was performed in mature chicks after a single, high dose injection of gentamicin, which results in the rapid loss of all hair cells in the basal third of the cochlea. Chicks were sacrificed at discrete time points after drug treatment, and transmission electron microscopy was performed to study the ultrastructural changes in basal hair cells during the course of cell death. We noted various changes in the cell morphology including accumulation of cytoplasmic inclusion bodies, dispersion of the cytoplasmic polyribosomes, mitochondrial swelling, and cellular extrusion by 24 h after injection. The next two studies were performed using tissue cultures from mature avian auditory sensory epithelium. Cultured cells were labeled using vital fluorescent markers, and levels of intracellular calcium and reactive oxygen species within hair cells were studied following aminoglycoside exposure. We identified a dose-dependent increase in the levels of intracellular calcium, which was blocked by an inhibitor of voltage-gated calcium channels. We also found that levels of reactive oxygen species in hair cells greatly increased after exposure to gentamicin, and this response was blocked by two different antioxidants. These studies serve to identify key cellular and molecular changes in hair cells in response to ototoxic drugs. Further study of these processes may lead to a better understanding of how ototoxicity is induced and to potential preventative interventions.

Electron microscopic analysis of gamma-aminobutyric acid and glycine colocalization in rat trigeminal subnucleus caudalis.

Postembedding immunogold methods were used to examine the distribution of gamma-aminobutyric acid (GABA) and glycine and especially their colocalization in glomerular neuronal profiles adjacent to trigeminal primary afferent profiles in lamina II of rat subnucleus caudalis. We found that 60% of the profiles adjacent to the trigeminal primary afferent terminals exhibited colocalization of GABA and glycine. GABA alone was found to localize in 17% of the adjacent profiles. Glycine alone was found to localize in 18% of the adjacent profiles. Of interest, 10% of the trigeminal primary afferent fibers showed glycine localization. All the profiles with colocalization of GABA and glycine were identified as presynaptic axonal terminals, suggesting a possible cumulative effect by these two inhibitory neurotransmitters in presynaptic inhibition. These findings show that GABA and glycine colocalize in a subpopulation of presynaptic axonal terminals within lamina II of the subnucleus caudalis. The possible origins of these axons are discussed, as well as their potential involvement in presynaptic inhibition of orofacial nociception.

Morphological and functional characterization of an in vitro blood-brain barrier model.

Cell culture models have been extensively used for studies of blood-brain barrier (BBB) function. However, several in vitro models fail to reproduce some, if not most, of the physiological and morphological properties of in situ brain microvascular endothelial cells. We have recently developed a dynamic, tridimensional BBB model where endothelial cells exposed to intraluminal flow form a barrier to ions and proteins following prolonged co-culturing with glia. We have further characterized this cell culture model to determine whether these barrier properties were due to expression of a BBB phenotype. Endothelial cells of human, bovine or rodent origin were used. When co-cultured with glia, intraluminally grown endothelial cells developed features similar to in vivo endothelial cells, including tight junctional contacts at interdigitating processes and a high transendothelial resistance. This in vitro BBB was characterized by the expression of an abluminal, ouabain-sensitive Na/K pump, and thus favored passage of potassium ions towards the lumen while preventing K+ extravasation. Similarly, the in vitro BBB prevented the passage of blood-brain barrier-impermeant drugs (such as morphine, sucrose and mannitol) while allowing extraluminal accumulation of lipophylic substances such as theophylline. Finally, expression of stereo-selective transporters for Aspartate was revealed by tracer studies. We conclude that the in vitro dynamic BBB model may become an useful tool for the studies of BBB-function and for the testing of drug passage across the brain endothelial monolayer.

Fluid percussion injury causes disruption of the septohippocampal pathway in the rat.

Fluid percussion injury (FPI) causes memory deficits, loss of hippocampal neurons, and basal forebrain cholinergic immunoreactivity in rats. Basal forebrain septohippocampal projections terminate in specific hippocampal regions. The purpose of this study was to examine the effects of FPI on the septohippocampal pathway (SHP). Halothane-anesthetized rats received either a sham injury or a parasagittal FPI. To characterize the anatomical effects of FPI on the SHP, silver stains were performed on brains of animals at 1, 5, and 10 days following FPI and were compared to sham-injured preparations. To characterize the effects of FPI on retrograde transport in the SHP, a separate group of FPI and sham-injured animals with survival times of 2, 5, and 10 days received bilateral WGA-HRP injections into the hippocampal formation 24 h prior to sacrifice. Argyrophilic CA3 neurons were present 1 day following FPI. Five days following FPI, terminal degeneration was present in the inner third of the molecular layer of the dentate gyrus bilaterally that was not present 1 day after injury. Fiber and terminal degeneration was not observed in the basal forebrain until 10 days after FPI. WGA-HRP-labeled septal neurons decreased significantly (P < 0.05) ipsilateral to injury in animals sacrificed 5 and 10 days following FPI but not 2 days after injury. This investigation demonstrated that FPI produces focal injury in the hippocampal formation. In addition, the appearance of terminal degeneration in the dentate molecular layer correlated with the significant reduction in axonal transport 5 days following injury. This correlation illustrates the secondary processes that structurally damage the SHP up to 10 days after injury.

Electron microscopy of colocalization of GABA and tyrosine hydroxylase expression in rat olfactory bulb transplants.

Juxtaglomerular (JG) neurons of rat olfactory bulb (OB) are a subset of inhibitory interneurons within the OB, acting via lateral inhibition to modulate the afferent input of the primary olfactory nerve. The JG neurons, composed of periglomerular, external tufted, and short axon cells, have been found to express various neurotransmitters, including gamma-amino butyric acid (GABA) and dopamine. A specific set of neurons within the periglomerular population have also been shown to coexpress these neurotransmitters. Deafferentation or functional odor deprivation of the normal OB causes a loss of tyrosine hydroxylase (TH) (the rate limiting enzyme in the dopamine synthesis pathway) expression within the JG cell population, but appears to have no effect on GABA levels. Our laboratory has developed a transplantation model to further study the effects of deafferentation and subsequent reinnervation within this system. Sections from transplant (TX) OBs were reacted for GABA and TH using immunocytochemical localization protocols and studied by electron microscopy. Numerous neuronal populations were found to be either TH or GABA positive in this study, with a specific subpopulation showing colocalization of both. Although the architecture of the TX OB is somewhat disrupted and the TH- and GABA-positive cells were not as uniform in their arrangement as they are in the normal OB, we found that these cells in the TX OB were morphologically similar to the JG cells of normal OB. Positively labeled profiles were also found to receive and form numerous synaptic contacts with both host olfactory nerve axons as well as with the processes of donor neurons. These synaptic contacts were within areas that resemble the glomeruli of normal OB, suggesting that lateral inhibition may occur within the TX OB as it does in the normal. The coexpression of GABA and TH within specific neurons also indicates that a unique population of JG neurons that occur in normal OB are also found within this transplanted system as well.

Developmental localization of GAP-43 and olfactory marker protein in rat olfactory bulb transplants.

In an effort to identify and understand the laminar disorganization that occurs in the transplanted (TX) rat olfactory bulb (OB), we examined the development of fiber systems within these TX OBs. One antibody for olfactory marker protein (OMP) was used to identify axons of mature olfactory receptor neurons (ONs) and a second antibody, for a growth-associated protein (GAP-43), provided a marker for all extending or immature fibers. Donor OBs were taken from fetuses on embryonic days 14 or 15 (sperm-positive day is zero) and TX directly into the cavity produced by removal of an OB in 1-day-old hosts of the same strain. After survival times of 1 and 2 weeks and at maturity, adjacent 8 microns paraffin sections from the TX material were examined for OMP and GAP-43 reactivity. Fiber bundles, reactive for OMP, were found within the TX by 1 week post-TX, indicating rapid re-innervation of the donor OB by ONs. The appearance of OMP reactivity gradually shifted from tightly packed, well-defined fiber bundles at 1 week post-TX to a diffuse reticulated pattern of individual fibers emerging from bundles at maturity. The OMP-reactive fiber bundles of the TX OB also contained GAP-43-reactive fibers, but GAP-43 reactivity also extended to other (OMP-negative) bundles and fields. Reactivity for GAP-43 in the TX OB was nearly ubiquitous at 2 weeks post-TX but, as development progressed (in both the TX and normal OB), such reactivity gradually decreased. Thus, while maturation in sensory afferent fiber systems in the TX OB may be delayed, it eventually follows a pattern similar to that in the normal OB, suggesting that factors other than the timing of fiber extension may be responsible for the laminar disorganization of the TX OB.

Post-embedding immunogold labeling of gamma-aminobutyric acid in lamina II of the spinal trigeminal subnucleus pars caudalis: I. A qualitative study.

This study examines the normal synaptic organization of the feline spinal trigeminal nucleus pars caudalis (PC). A primary goal of this study is to identify and characterize the synaptic complexes within PC based on their specific neurotransmitter content. Post-embedding immunogold techniques are utilized with electron microscopy to determine the ultrastructural localization of gamma-aminobutyric acid (GABA) immunoreactivity within lamina II of PC. The colloidal gold particles (10 nm) are randomly distributed over immunoreactive (IR) profiles without preference toward membranous or cytoplasmic regions. GABA immunoreactivity occurs on small unmyelinated axons, on terminals which form synaptic contacts, and on some vesicle-containing dendrites. The GABA-IR terminals form symmetric (type II) contracts onto unlabeled somata and dendrites of various sizes, and onto other unlabeled axon terminals. The GABA-IR terminal in axo-axonic complexes is presynaptic to a round vesicle-containing terminal, which itself may form a type I asymmetric contact onto an unlabeled dendrite or soma. A proportion of vesicle-containing dendrites show GABA-immunoreactivity and are post-synaptic to unlabeled terminals with round vesicles. Other, but far fewer, vesicle-containing dendrites are GABA negative and postsynaptic to GABA-IR terminals. In summary, the findings are consistent with the localization of GABA in intrinsic neurons, and may be associated with presynaptic and postsynaptic inhibition within nociceptive related pathways.

Electron microscopic analysis of lesion-induced changes in synaptic structure and immunogold labeling of neurotransmitters within the feline trigeminal nucleus.

This report uses lesion and postembedding immunogold protocols to examine the ultrastructural details of lesion-induced synaptic and neurotransmitter changes in the feline trigeminal nucleus. Electron microscopic (EM) analysis concentrated on lamina II (substantia gelatinosa) of the subnucleus pars caudalis (PC) which is one relay site or trigeminal fibers involved in nociception. Special attention was directed to analysis of reoccupation of synaptic sites vacated by primary afferent degeneration. Primary afferents are caused to degenerate by performing unilateral retrogasserian rhizotomy. After survival times of 1, 2, 6, and 7 days, sections of PC were processed for postembedding immunogold labeling with antibodies to the neurotransmitters gamma aminobutyric acid (GABA) and glutamate (Glu). The results show: (1) degenerating primary afferent terminals were easily identified in various stages of degeneration; (2) Glu immunoreactivity was observed in early forms of degenerated primary afferent terminals with clumped vesicles as well as in the highly distorted, electron dense terminals of later degeneration; and (3) some GABA immunoreactive terminals formed atypical synapses which exhibited both asymmetric (excitatory) and symmetric (inhibitory) synaptic densities. A possible model is presented of the progression of events following trigeminal nerve lesion which results in atypical synapse formation. Such altered synaptic relationships seen in PC following trigeminal rhizotomy may be related to hyperactivity that is seen in animals and to the atypical facial pain following nerve lesions in humans.

Tyrosine hydroxylase expression in rat olfactory bulb transplants: an electron microscope study.

Juxtaglomerular (JG) neurons of rat olfactory bulb (OB) have been shown to express tyrosine hydroxylase (TH), the rate-limiting enzyme in the catecholamine synthesis pathway. These JG neurons act as inhibitory dopaminergic interneurons, modulating the incoming signal from the primary olfactory afferents. The JG neurons, comprised of periglomerular, external tufted, and short axon cells, stop expressing TH after lesions of the olfactory nerve or closure of the nares, both of which cause a loss of functional input. Upon reinnervation by a continuously regenerating olfactory nerve, these cells resume their expression of TH. In order to study deafferentation and subsequent reinnervation within this system, our laboratory utilizes a transplantation model. Sections from transplant (TX) OBs are reacted for TH using immunocytochemical localization protocols and studied by light- and especially electron microscopy (EM). Autoradiography of tritiated thymidine-labeled tissue was performed to confirm donor origin of the TX OBs. Although the architecture of the TX OB is somewhat disrupted and the TH-positive cells were not as uniform in their arrangement as they are in the normal OB, we found that the TH cells in the TH OB had a morphology similar to the JG cells observed in normal OB. These TH cells were also found to receive synaptic contacts with host olfactory nerve axons as well as make and receive contacts with the processes of donor neurons. These, synaptic contacts were formed within areas that resemble the glomeruli of normal olfactory bulb, suggesting that the inhibitory synaptic pathway is reestablished within the TX OB. These findings also suggested that host olfactory axons formed a functional contact with the TH cells, possibly inducing them to express this enzyme. This study implies that the TX OB retains a level of plasticity that enables it to recapitulate part of the interneuronal arrangement observed in the normal system.

Recovery of olfactory function in thirteen-day-old rats after olfactory bulb transplantation but not after olfactory bulb ablation.

Previous studies have shown recovery of olfactory ability along with reconnectivity of olfactory nerve (ON) following both olfactory bulb (OB) lesions and OB transplants (TX) when performed in newborn rats. The purpose of the present study is to correlate functional recovery with patterns of anatomical reconnectivity in older, postnatal (PN) 13-day-old rats (a possible critical period for plasticity in the system). Reinnervation of olfactory areas was seen in all OB TX animals regardless of the extent of functional recovery. Eight of nineteen animals with OB TXs demonstrated some degree of behavioral recovery. No reinnervation or behavioral recovery of OB lesion animals was observed. At this age, behavioral recovery is dependent upon reconnectivity within the system and transplantation may be required to facilitate this process.

Electron microscopy of immunoreactivity patterns for glutamate and gamma-aminobutyric acid in synaptic glomeruli of the feline spinal trigeminal nucleus (Subnucleus Caudalis).

We studied the ultrastructure of the synaptic organization in the feline spinal trigeminal nucleus, emphasizing specific neurotransmitter patterns within lamina II of the pars caudalis/medullary dorsal horn. Normal adults were perfused, and Vibratome sections from pars caudalis were processed for electron microscopy. Ultrathin sections were reacted with antibodies for the excitatory neurotransmitter glutamate (Glu) and for the inhibitory neurotransmitter gamma-aminobutyric acid (GABA) by using postembedding immunogold techniques. Both single- and double-labeled preparations were examined. Results with single labeling show that Glu-immunoreactive terminals have round synaptic vesicles and form asymmetric synaptic contacts onto dendrites. GABA-immunoreactive axon terminals and vesicle-containing dendrites have pleomorphic vesicles, and the axon terminals form symmetric contacts onto dendrites and other axons. Double labeling on a single section shows glomeruli with central Glu-immunoreactive terminals that are presynaptic to dendrites, including GABA+ vesicle-containing dendrites. These Glu+ terminals are also postsynaptic to GABA+ axon terminals, and these GABA-immunoreactive terminals may also be presynaptic to the GABA+ vesicle-containing dendrites. Quantitative analyses confirm the specificity of the Glu and GABA immunoreactivities seen in the various glomerular profiles. The results suggest that a subpopulation of Glu-immunoreactive primary afferents (excitatory) may be under the direct synaptic influence of a GABA-immunoreactive intrinsic pathway (inhibitory) by both presynaptic and postsynaptic mechanisms.

Light microscopic localization of calcitonin gene-related peptide in the normal feline trigeminal system and following retrogasserian rhizotomy.

Calcitonin gene-related peptide (CGRP) is a neuropeptide that has been implicated in the transmission and modulation of primary afferent nociceptive stimuli. In this study, we describe the light microscopic distribution of CGRP immunoreactivity (IR) within the feline trigeminal ganglion and trigeminal nucleus of normal adult subjects and in subjects 10 and 30 days following complete retrogasserian rhizotomy. Within the trigeminal ganglion of normal subjects, cell bodies and fibers showed CGRP-IR, whereas immunoreactive fibers were rare in the central root region. Within the normal spinal trigeminal and main sensory nuclei, CGRP-IR was seen to form a reproducible pattern that varied between the different nuclei. Following rhizotomy, most, but not all, of the CGRP-IR was lost from the spinal trigeminal and main sensory nuclei, except in regions where the upper cervical roots and cranial nerves VII, IX and X project into the trigeminal nucleus. The pattern seen at 10 days contained more CGRP-IR than that seen at 30 days and suggests that degenerating fibers still show CGRP-IR. In contrast to the decrease seen in the nuclei after rhizotomy, examination of the central root that was still attached to the trigeminal ganglion showed an increase in CGRP-IR within fibers, some of which ended in growth conelike enlargements. Rhizotomy induced a dramatic increase in CGRP-IR within trigeminal motoneurons and their fibers, which was strongest 10 days after rhizotomy and weaker at 30 days, which was still stronger than normal. These results indicate that the majority of CGRP-IR found in the trigeminal nucleus originates from trigeminal primary afferents and that an upregulation of CGRP-IR occurs in trigeminal motoneurons and in regenerating fibers in the part of the central root that was still attached to the ganglion. In addition, the persistence of CGRP-IR fibers in the trigeminal nucleus provides one possible explanation for the preservation of pain in humans following trigeminal rhizotomy.

Ligands for EPH-related tyrosine kinase receptors are developmentally regulated in the CNS.

Elk is a member of the eph family of receptor-like tyrosine kinases. Although its function is unknown, elk is postulated to play a role in nervous system development. Using Northern analysis, we examined the developmental regulation of RNAs encoding elk, and several ligands for the eph family of RTKs, the LERKs. Expression of elk, LERK-1, and LERK-2 RNAs is high in all regions examined in the embryonic and postnatal rat brain and decreases to low levels with age. One exception is the adult olfactory bulb which continues to express a moderate level of LERK-2. In contrast, moderate LERK-4 expression was limited to the developing hippocampus and cerebral cortex. These data indicate that elk and some of the LERKs may play a role in nervous system development, maintenance, and/or regeneration.

Olfactory bulb transplants establish afferent and efferent connections with host forebrain in rat.

We are using wheat germ agglutinin-conjugated horseradish peroxidase (WHRP) to study reconnectivity in the transplanted (TX) olfactory bulb (OB) in Sprague-Dawley rats. Tritium-labeled OBs from fetal rat donors of Embryonic Days 14-15 were immediately grafted into neonatal rats in the site from which the host OB had been removed. Following survival times of 7 weeks and longer, WHRP solution was injected into the TX OB, and subjects were perfused after 24 h. The WHRP transport is seen in fibers from the TX OB into layer I of the host olfactory peduncle (OP) and olfactory cortex (OC) and in cell bodies in layers II and III of the OP and OC, the lateral hypothalamus, and the contralateral anterior olfactory nucleus (AON). These findings reaffirm that the axons from a TX OB make connections with some appropriate areas of the host brain and also indicate that axons from cells in the target areas of the host brain, including contralateral AON, reinnervate the TX OB.

Host primary olfactory axons make synaptic contacts in a transplanted olfactory bulb.

Previous light microscopic studies have shown that host olfactory neurons are able to grow into a transplanted fetal olfactory bulb, and behavioral studies have shown that animals with transplanted olfactory bulbs recover functional olfactory abilities. We examined the olfactory bulb transplant at the ultrastructural level to determine whether synaptic contacts are reestablished between host olfactory neurons and donor olfactory bulb. Mature rats that, as neonates, had received embryonic olfactory bulb transplants following olfactory bulb removal were studied. An antibody specific for olfactory marker protein was used to identify the primary olfactory neurons; it was bound by a gold-conjugated secondary antibody for visualization. To preserve the antigenicity of the olfactory marker protein for immunolabeling, Lowicryl K4M hydrophilic resin was used. Synaptic contacts were unmistakable between labeled axons of host olfactory neurons and unlabeled processes within glomerulus-like areas of the transplanted olfactory bulb. The surrounding neuropil contained other elements similar to those found in normal tissue, including synaptic contacts between unlabeled profiles. We clearly show that the transplanted olfactory bulb exhibits sufficient plasticity to form an array of normal synaptic contacts, including the contacts from host primary olfactory neurons.

Olfactory ensheathing glia and platelet-derived growth factor B-chain reactivity in the transplanted rat olfactory bulb.

Using a monoclonal antibody against the B-chain of platelet-derived growth factor as a marker, we have examined the behavior of olfactory ensheathing glia in the normal and transplanted rat olfactory bulb. In the normal postnatal olfactory bulb, these glia are found to ensheath the bundles of incoming primary olfactory nerve fibers as well as those in the olfactory nerve layer. Olfactory marker protein antibody was used to identify the olfactory nerve proper. Within the transplant, the same glia: (1) ensheath bundles of both primary olfactory and non-primary olfactory axons, (2) ensheath axonal bundles deep within the donor tissue, and (3) eventually permit radiation of individual axons from bundles to surrounding neuropil. We believe that ensheathing glia (being rich in growth-related factors and extracellular matrix molecules) may be useful in providing trophic support and guidance for the reconstruction of developmentally or traumatically damaged neuronal pathways not directly related to the olfactory system. The evidence presented here indicates that ensheathing glia are capable of existing in deep brain areas and ensheathing other than primary olfactory axons. The special molecular characteristics of these glia along with the morphological findings presented here provide a foundation for further studies of these unique glia and their potential utility in the restoration of damaged neural pathways.

Recovery of olfactory behavior. I. Recovery after a complete olfactory bulb lesion correlates with patterns of olfactory nerve penetration.

The olfactory system is an excellent system in which to study issues related to potential functional recovery after a debilitating brain injury. The olfactory system is well-characterized, easily accessible and there are a vast number of studies available from a variety of perspectives. The experimental aim of this research is to examine the anatomical correlates associated with potential behavioral recovery in rats that receive complete olfactory bulb lesions as neonates or as adults. The results show that behavioral recovery occurs only when olfactory nerve penetration of the central nervous system is observed. Further, both olfactory nerve penetration and behavioral recovery are age-dependent phenomena. The olfactory nerve penetration only occurs when the olfactory bulb lesion is performed in neonates. Behavioral recovery of olfactory ability follows a linear trend and reaches near normal levels during the six weeks behavioral testing period. Histological analysis using an antibody for olfactory marker protein (an olfactory nerve-specific marker) reveals two potential candidates for the anatomical pathway responsible for behavioral recovery: olfactory nerve to orbital frontal cortex and olfactory nerve to olfactory peduncle. This report presents evidence that recovery of olfactory ability can occur in the absence of the olfactory bulb if the lesion is performed when the rat is still a neonate.

Recovery of olfactory behavior. II. Neonatal olfactory bulb transplants enhance the rate of behavioral recovery.

Previous experiments in this laboratory have shown that transplants of a fetal olfactory bulb into a neonatal rat are viable and that they establish connections with the olfactory peduncle and olfactory cortex. The focus of this experiment was to investigate the anatomical correlates of any behavioral recovery seen in rats that had one olfactory bulb removed along with an immediate transplant of a fetal olfactory bulb. Anatomical details, such as transplant organization and olfactory nerve repenetration patterns were analyzed using a variety of histological and immunohistochemical techniques. The rats in this experiment showed behavioral recovery of olfactory ability. The recovery rates observed in these animals were compared to two other groups of rats that this laboratory has shown to be behaviorally competent: normal rats and rats with neonatal ablations of the olfactory bulb but no transplant. Although the animals with transplants did not recover to completely normal levels of olfactory ability, they did start behavioral testing in a more behaviorally competent condition than rats with simple neonatal lesions. Anatomical analysis revealed that the transplanted olfactory bulb was heavily penetrated by incoming olfactory nerve fibers but olfactory nerve penetration was not limited to the transplanted olfactory bulb. The extra-bulbar host regions that were penetrated included the orbital frontal cortex and three olfaction-related areas; olfactory cortex, olfactory peduncle and the subependymal cell layer. The olfactory nerve penetration patterns observed beyond the transplant were essentially the same as those observed in rats with only neonatal lesions of the olfactory bulb. Thus, multiple pathways may have contributed to the recovery observed in the rats with olfactory bulb transplants.

Electron microscopic localization of nerve growth factor receptor (p75)-immunoreactivity in pars caudalis/medullary dorsal horn of the cat.

Previous studies have demonstrated the presence of nerve growth factor receptor [NGFr(p75)]-immunoreactivity (IR) in the spinal trigeminal nucleus of both 8-10 week-old kittens and mature cats. Most of the NGFr(p75)-IR is lost following retrogasserian rhizotomy, indicating that the majority of the NGFr(p75)-IR within the spinal trigeminal nucleus is of trigeminal primary afferent origin. Here, we examined the ultrastructural localization of NGFr(p75)-IR within lamina II outer of pars caudalis/medullary dorsal horn in the mature cat. Lamina II outer represents a location where dense NGFr(p75)-IR is seen with the light microscope. The NGFr(p75)-IR identified with the electron microscope was located within small thinly myelinated and unmyelinated axons and within axon terminals. The terminals with NGFr(p75)-IR typically formed asymmetric synaptic specializations onto dendritic profiles and at times were postsynaptic to other axon terminals at symmetric synaptic specializations. The terminals with NGFr(p75)-IR were either simple (associated with a single profile) or more complex, such as those that typically formed the central element in synaptic glomeruli. The NGFr(p75)-IR in terminals was especially prominent on microtubules and the plasmalemma and these findings are consistent with proposed roles for NGFr(p75) in axoplasmic/neuronal transport and as a membrane protein, respectively. The profiles with NGFr(p75)-IR seen with the electron microscope indicate a primary afferent origin and show some similarities when compared to other markers of primary afferent fibers such as calcitonin gene-related peptide. In addition, a possible role for NGFr(p75) in the transmission of nociceptive stimuli is also discussed.

Nerve growth factor receptor (p75)-immunoreactivity in the normal adult feline trigeminal system and following retrogasserian rhizotomy.

The 75 kDa protein nerve growth factor receptor [NGFr(p75)] is a neurotrophin receptor that is able to bind different members of the neurotrophin family of molecules implicated in affecting neuronal survival. Here we describe the light microscopic distribution of NGFr(p75)-immunoreactivity (IR) within the feline trigeminal brainstem sensory nuclear complex and trigeminal ganglion of normal adult subjects and in subjects 10 and 30 days following retrogasserian rhizotomy. Within the trigeminal ganglion of normal subjects, numerous fibers and most of the neuronal cell bodies showed NGFr(p75)-IR that varied in intensity, while cells and fibers with NGFr(p75)-IR were less numerous within the mesencephalic trigeminal nucleus. Within the main sensory and spinal trigeminal nuclei, NGFr(p75)-IR formed a reproducible pattern that varied between the different subnuclei. The NGFr(p75)-IR consisted both of dense pockets and a low level NGFr(p75)-IR that was selective to the trigeminal neuropil. Following rhizotomy, most of the NGFr(p75)-IR was lost from the main sensory and spinal trigeminal nuclei, except in regions where the upper cervical roots and cranial nerves VII, IX, and X project. In contrast, examination of the central root that was still attached to the trigeminal ganglion showed increased NGFr(p75)-IR in fibers and supporting cells, as did the motor root within the peripheral mandibular division. These results indicate that the majority of the NGFr(p75)-IR within the main sensory and spinal trigeminal nuclei originates from primary trigeminal afferents and that retrogasserian rhizotomy leads to an up-regulation of NGFr(p75)-IR in the part of the central root that is contiguous with the ganglion.