Analysis of low affinity nerve growth factor receptor during pulpal healing and regeneration of myelinated and unmyelinated axons in replanted teeth.

Nerve regeneration was examined in rat molars that were briefly extracted and then replanted in the socket for 1-90 days. Immunocytochemistry was used to evaluate neural and nonneural immunoreactivity (IR) for low affinity nerve growth factor receptor (p75-NGFR) and for laminin and calcitonin gene-related peptide (CGRP). Three different types of pulpal response to replantation were found. Type I: Some replanted teeth had mild injury and still contained coronal odontoblasts and associated fibroblasts that retained p75-NGFR-IR; they continued regular dentin formation and had excellent reinnervation. Type II: Teeth with intermediate injury lost most or all of the coronal pulp tissue, but they regenerated odontoblast-like cells that formed irregular dentin, they had numerous dispersed p75-NGFR-IR fibroblasts in crown pulp during early regeneration, and they had excellent reinnervation. Type III: Severely injured teeth lost their original pulp; they filled with dense connective tissue and bone and had poor reinnervation. After Type I or II injury the Schwann cells around degenerating myelinated and unmyelinated axons had increased expression of p75-NGFR by 1-3 days. By 7-10 days those Schwann cells had formed hollow tubes (bands of Bungner) along the degenerating axon tracks. They maintained their increased p75-NGFR-IR during and after regeneration of unmyelinated axons, whereas Schwann cells involved in remyelination lost p75-NGFR-IR at that stage. The number of CGRP-IR axons in the regenerating pulp increased from 7 to 90 days. Laminin-IR increased in all replanted teeth at 3-10 days and only returned to normal patterns in teeth with Type I or Type II response at 20-90 days. The special p75-NGFR-IR of pulpal fibroblasts of adult rat molars did not usually persist in regenerated, reinnervated pulp. The extensive depletion of fibroblast p75-NGFR-IR and the continuing enhanced p75-NGFR-IR in unmyelinated nerve fibers at 90 days show that altered growth factor conditions characterize regenerated pulp of replanted teeth.

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.

Nerve growth factor: increased angiogenesis without improved nerve regeneration.

Nerve growth factor (NGF) and laminin are important factors for neural development and regeneration. We examined the effects of increasing the local concentration and duration of action of NGF and laminin on peripheral nerve regeneration in the adult mouse sciatic nerve. A Silastic (silicone rubber) channel with intraluminal NGF solution was secured between transected nerve ends. The second channel tested, formed from a polysaccharide called chitosan, was prepared with NGF and laminin in the channel walls and provided a sustained release of NGF. At six weeks post-implantation, no improvement in nerve regeneration was identified in those channels prepared with NGF when comparing electromyographic thresholds (microA), maximum potentials (mV), nerve diameter, myelin sheath thickness, myelinated axon counts, or diameter. However, increased angiogenesis was demonstrated within the chitosan and Silastic channels prepared with NGF compared to those channels without NGF. Silastic exhibited minimal inflammation. Chitosan was associated with inflammation in many nerve channels.

Adsorption of Thermomonospora fusca E5 and Trichoderma reesei cellobiohydrolase I cellulases on synthetic surfaces.

The interfacial behavior of Thermomonosporafusca E5 and Trichoderma reesei cellobiohydrolase I (CBHI) cellulases were studied at synthetic surfaces. For this purpose, colloidal silica and polystyrene particles were used to prepare cellulase-particle suspensions that could be analyzed by solution-phase techniques. Circular dichroism spectroscopy of each cellulase, alone as well as in suspension with silica, was used to determine whether structural changes occurred on adsorption. Changes in spectra were observed for CBHI, but not for E5. Gel-permeation chromatography of the cellulase-particle suspensions showed that neither cellulase binds to silica, suggesting that changes in spectra for CBHI were a result of solution-phase phenomena. Microfiltration of cellulase-polystyrene suspensions showed that both cellulases bind to polystyrene. However, circular dichroism experiments with polysterene proved unworkable, owing to excessive light absorption by the polystyrene. Adsorption kinetics of each cellulase were recorded, in situ, at hydrophilic and silanized, hydrophobic silica surfaces using ellipsometry. Ellipsometric data recorded for each cellulase at hydrophilic silica showed insignificant adsorption. Binding did occur between each cellulase and silanized silica, most likely mediated through hydrophobic associations. Adsorption in this case was irreversible to dilution.

Spatiotemporal patterns of expression of NGF and the low-affinity NGF receptor in rat embryos suggest functional roles in tissue morphogenesis and myogenesis.

We show here that NGF and its low-affinity receptor (p75NGFR) are expressed during rat embryogenesis at sites that are known to have important roles in tissue morphogenesis and myogenesis. The developing skin of the maxilla, the mandible, and the limb showed very similar patterns of NGF and p75NGFR expression. However, NGF and p75NGFR expression in the developing limb initiated at the limb bud stage and was concentrated at proximal and distal developmental sites that have been reported to be involved in limb morphogenesis. Expression at the proximal/distal ends of the limb persisted throughout limb development, with some of the highest levels of expression occurring at the limb axillary sites, which were not highly innervated. We have also found p75NGFR expression at sites of mesenchymal/epithelial interactions in several developing organs that do not appear to have an adjacent source of NGF and may therefore be sites that bind and respond to the other members of the NGF family (brain-derived neurotrophic factor and neurotrophin-3). These organs include the lung, testes, and kidney, where expression of p75NGFR occurred during the morphogenesis of specific epithelial structures and was coexpressed with the cell adhesion molecule NCAM. In addition, we found that NGF and p75NGFR were expressed during myogenesis. p75NGFR was observed in myoblast cells expressing MyoD1, a myoblast differentiation marker, and NGF transcripts in cells just adjacent to the developing myoblasts. When the myoblasts differentiate into myotubes, p75NGFR and MyoD1 cease to be expressed and the adjacent cells concomitantly cease to be make NGF. However, NGF and p75NGFR were not present in the early muscle precursor cells of the myotome of the somites but were observed in the dermatome and sclerotome, respectively. These results suggest that NGF and p75NGFR have functional roles in developmental processes that affect morphogenesis and cell differentiation.

Altered expression of NGF and P75 NGF-receptor by fibroblasts of injured teeth precedes sensory nerve sprouting.

Profuse sprouting of sensory nerve fibers occurs in tooth pulp by 1-4 days following dentin injury. A possible role for nerve growth factor (NGF) in that neural response is suggested here by the demonstration that NGF mRNA and protein are increased 6 hr after injury to adult rat molars. The enhanced expression of NGF mRNA was localized to fibroblasts underlying the injury. A concomitant depletion of mRNA encoding the 75 Kd NGF receptor (NGFR) was observed in those fibroblasts. The increase in NGF mRNA was transitory and mRNA levels fell below normal levels by 2 days after injury. Both NGF and NGFR mRNA remained low thereafter in injured pulp. The inverse shifts in fibroblastic mRNA encoding NGF and NGFR were not affected by prior denervation of the tissue, or by pretreatment with dexamethasone. The regulatory mechanisms therefore must involve endogenous, non-neuronal, non-inflammatory factors that are released in response to injury.

The relationship between glandular kallikrein and growth factor-processing proteases of mouse submaxillary gland.

Three highly specific trypsin-like proteases from mouse submaxillary gland; nerve growth factor gamma subunit, beta nerve growth factor-endopeptidase, and epidermal growth factor-binding protein were tested for kallikrein activity. Low molecular weight kininogen was purified from mouse plasma and used as substrate for the three enzymes, and the kinin released by the enzymes was assayed by its ability to induce contraction of isolated rat uterus. All three enzymes were found to have significant kininogenase activity, and the most active enzyme, beta nerve growth factor-endopeptidase, has activity comparable to authentic kallikreins from other glandular sources. Essentially all of the kininogenase activity of submaxillary gland co-purifies with beta nerve growth factor-endopeptidase. Hence, beta nerve growth factor-endopeptidase appears to be identical with submaxillary gland kallikrein. Nerve growth factor gamma subunit, epidermal growth factor-binding protein, and beta nerve growth factor-endopeptidase have similar amino acid compositions and molecular weights, and are immunologically similar. Comparison of published partial primary sequence data confirms our conclusion that nerve growth factor gamma subunit, epidermal growth factor-binding protein, and kallikrein are very closely related enzymes. It is postulated that these three enzymes are members of a larger family of similar enzymes, all of which are involved in the processing of precursors to polypeptide hormones and growth factors.

Multiple functions for NGF receptor in developing, aging and injured rat teeth are suggested by epithelial, mesenchymal and neural immunoreactivity.

We have used immunocytochemistry to analyse expression of nerve growth factor receptor (NGFR) in developing, aging and injured molar teeth of rats. The patterns of NGFR immunoreactivity (IR) in developing epithelia and mesenchyme matched the location of NGFR mRNA assayed by in situ hybridization with a complementary S35-labeled RNA probe. The following categories of NGFR expression were found. (1) There was NGFR-IR in the dental lamina epithelium and in adjacent mesenchyme during early stages of third molar formation. (2) NGFR-IR nerve fibers were posterior and close to the bud epithelium. (3) During crown morphogenesis NGFR expression was prominent in internal enamel epithelium and preodontoblasts; it faded as preameloblasts elongated and as odontoblasts began to make predentin matrix; and it was weak or absent from outer enamel epithelium, the cervical loop, and differentiated ameloblasts and odontoblasts. (4) When NGFR-IR nerve fibers entered the molars late in the bell stage, they innervated the most mature peripheral pulp and dentin in an asymmetric pattern which correlated more with asymmetric enamel synthesis than with mesenchymal NGFR-IR distribution. (5) The mesenchymal pulp cells continued to have intense NGFR expression in adult teeth, especially near coronal tubular dentin. (6) The pulpal NGFR-IR decreased in very old rats or subjacent to reparative dentin (naturally occurring or experimentally induced). (7) During root formation, the preodontoblasts had NGFR-IR but most root mesenchymal cells and Hertwig's epithelial root sheath did not. This work suggests that there are important epithelial and mesenchymal targets of NGF regulation during molar morphogenesis that differ for crown and root development and that do not correlate with neural development. The continuing expression of NGFR-IR by pulpal mesenchymal cells in adult rats was most intense near coronal odontoblasts making tubular dentin; and it was lost during aging, or subjacent to sites of dentin injury that caused a phenotypic change in the odontoblast layer.

Localization of nerve growth factor receptor immunoreactivity in the trigeminal nucleus of kittens.

A monoclonal antibody raised against the human nerve growth factor receptor (NGFr) was used to map the distribution of NGFr-immunoreactivity (IR) in the trigeminal nuclear complex of 8- to 10-week-old, immature felines. Somata and fibers show NGFr-IR within the trigeminal ganglion and the mesencephalic trigeminal nucleus. NGFr-IR is also found in fibers within the trigeminal root entry zone, the spinal trigeminal tract, and in fibers and terminals within all the central trigeminal sensory nuclei. The NGFr-IR found within the trigeminal sensory nuclei typically occurs in circumscribed zones that vary in position for the different subnuclei. NGFr-IR is found in the dorsomedial and ventrolateral subdivisions of the main sensory nucleus, in the dorsomedial and occasionally in ventral positions within pars oralis, in dorsal and ventral regions within pars interpolaris, and primarily in outer lamina II with fibers that project to lamina V within pars caudalis/medullary dorsal horn. These results show some overlap with the central distribution of trigeminal primary afferent nociceptive fibers such as those found from the tooth pulp and overlap with the central distribution of such peptides as calcitonin gene-related peptide and substance P, but NGFr-IR is more restricted. Thus, it appears that NGFr-IR is associated with the endings of primary afferent fibers in the brain stem, and that these fibers may represent a certain subclass of primary afferent nociceptors. It is speculated that fibers showing NGFr-IR may have the ability to alter their response to peripheral deafferentation when compared to fibers lacking NGFr-IR.

Neurotrophin receptors and nerve growth factor are differentially expressed in adjacent nonneuronal cells of normal and injured tooth pulp.

High-affinity tyrosine kinase A (trkA) neurotrophin receptors on neurons and nonneuronal cells elicit differentiation or survival functions in response to nerve growth factor (NGF), whereas the low-affinity neurotrophin (p75) receptor modulates trkA activity or can independently cause apoptosis or NFkappaB-mediated survival functions. We examined dental tissues for the presence of trkA-like immunoreactivity (trkA-IR), to determine which nonneuronal cell types express it in normal compared with inflamed teeth and how the trkA-positive cells relate to those expressing the p75 receptor and/or NGF. Normal and injured rat molars (dentin cavity for 4 h, 16-24 h, 3 days, 16 days, or 5 weeks) were immunoreacted using the ABC detection system for two anti-trkA antibodies (sTA, Santa Cruz Biotechnology; rTA, L. Reichardt) and antibodies against p75 and NGF, all of which also stained pulpal nerve fibers. We report that, when using the sTA antibody (recognizing the intracellular carboxy terminal), nonneuronal trkA-IR was found in odontoblasts of normal teeth and also in invading polymorphonuclear leukocytes (PMNs) and reparative odontoblasts after injury. When using rTA (recognizing the extracellular domain of the receptor), nonneuronal trkA-IR was only found in odontoblasts. Odontoblasts also had NGF-IR but did not label for NGF mRNA. The lack of odontoblast NGF mRNA suggests that NGF is passed from fibroblasts to the adjacent odontoblasts, where it is picked up by receptor-mediated mechanisms for regulation of odontoblast function. Tooth injury disrupts this system such that trkA-IR decreases in injured odontoblasts, p75 decreases in fibroblasts, and NGF is upregulated by fibroblasts and accumulates in the injured pulp and surviving odontoblasts. Pulpal NGF may contribute to chemoattraction for the invading leukocytes or their sTA-IR may have been induced in response to pulpal NGF. Thus, tooth pulp has a different distribution of nonneuronal NGF and its paracrine receptors during inflammation compared with normal conditions.