Lesion response of long-term and recently immigrated resident endoneurial macrophages in peripheral nerve explant cultures from bone marrow chimeric mice

Resident macrophages of the peripheral nervous system have recently been shown to respond rapidly to Wallerian degeneration before the influx of blood-derived macrophages. Because resident endoneurial macrophages are slowly but incompletely exchanged from the blood within 3 months, they could potentially comprise a heterogenous cell population consisting of long-term resident cells and more mobile cells undergoing turnover. We used bone marrow chimeric mice created by transplanting bone marrow from green fluorescent protein-transgenic mice into irradiated wildtype recipients to selectively analyse the response of these two resident macrophage populations to Wallerian degeneration in sciatic nerve explant cultures. In such nerves, recently immigrated macrophages exhibit green fluorescence whereas long-term resident macrophages do not. Studies in cultures from wildtype controls revealed rapid morphological changes of resident macrophages towards a bloated phenotype, a proliferative response resulting in a 3.7-fold increase of macrophage numbers over 2 weeks, and phagocytosis of myelin basic protein-immunoreactive myelin debris. When chimeric mice were analysed, both populations of resident endoneurial macrophages participated in morphological transformation, proliferation and phagocytosis. Quantitative studies revealed a stronger proliferative and phagocytic response in long-term resident endoneurial macrophages compared with recently immigrated macrophages. Our results point towards subtle, but not principal, differences between the two macrophage populations, which might indicate different stages of macrophage differentiation rather than the existence of entirely distinct endoneurial macrophage populations. The results further underline the versatility of resident endoneurial macrophages following peripheral nerve injury, which is reminiscent of the lesion response of microglial cells within the brain.     

Macrophage apolipoprotein synthesis and endoneurial distribution as a response to segmental demyelination

The synthesis and endoneurial distribution of apolipoproteins in response to myelin degradation was elucidated morphologically and biochemically in rodent models of segmental demyelination. At the onset of acute demyelination induced by tellurium (Te) poisoning, macrophages infiltrated the endoneurium and then began to express cytoplasmic immunoreactivity for apolipoprotein E (apo E). When demyelinating nerve slices were incubated with S35-methionine, radiolabeled apo E was released, showing that apo E was actively synthesized by the macrophages. Macrophages secreted apo E into the endoneurial spaces, leading to dense endoneurial accumulations. Other apolipoproteins (apo A1 and albumin) were not synthesized in the endoneurium, but they entered edematous nerves, presumably through an early breakdown in the blood-nerve barrier. During the phagocytosis of myelin, plasma-derived apolipoproteins accumulated within some of the macrophages. In chronic demyelination caused by lead poisoning, the cellular and extracellular distribution of apolipoproteins was similar to Te neuropathy; the amount of apo E accumulation and the macrophage density were proportional to the prevalence of active demyelination in teased fibers. Similar patterns of endoneurial apo E were present in an inherited form of demyelination in the twitcher mouse, after antibody-mediated demyelination, and in demyelination secondary to axonal degeneration. Human sural nerve biopsies had patterns of apolipoprotein E antigenicity that were comparable to the rodent models. We conclude that secretion of apo E by infiltrating macrophages is a generalized response to demyelination, and that endoneurial edema leads to the accumulation of certain plasma apolipoproteins within macrophages. These data suggest that endoneurial apolipoproteins and macrophages might mediate important functions in patients recovering from primary and secondary demyelination.     

Contribution of resident endoneurial macrophages to the local cellular response in experimental autoimmune neuritis

Macrophages are intimately involved in the pathogenesis of inflammatory neuropathies. The contribution of resident endoneurial macrophages is unknown since their differentiation from infiltrating macrophages is difficult due to missing cellular markers. Previous studies demonstrated the participation of resident macrophages in Wallerian degeneration and the pathogenesis of hereditary neuropathies. The question arises whether resident macrophages are involved in experimental autoimmune neuritis (EAN) where they could contribute to immunosurveillance and antigen presentation. To address this question we used bone marrow chimeric rats, allowing the differentiation between resident and hematogenous cells. Immunohistochemistry and in situ hybridization were applied on to identify and characterize resident macrophages in terms of morphological features, expression of activation markers, proliferation, phagocytosis, and MHC-II expression. Endoneurial macrophages of resident origin were detectable at all stages of disease with a contribution of at least 27% of the total macrophages. They appeared activated by morphological and immunohistochemical criteria and proliferated early. MHC-II-positive resident macrophages were observed that had phagocytosed myelin. These results demonstrate that the macrophage response in EAN is partly of intrinsic origin. The rapid activation and proliferation of resident endoneurial macrophages points toward an active role of these cells in inflammatory peripheral nerve disease, especially early in disease.     

On the longevity of resident endoneurial macrophages in the peripheral nervous system: a study of physiological macrophage turnover in bone marrow chimeric mice

Macrophages are intimately involved in the pathogenesis of peripheral nervous system (PNS) disorders. Recently, we characterized a resident endoneurial macrophage population, which contributes rapidly to the endoneurial macrophage response in PNS diseases. Unlike microglial cells, resident macrophages undergo a physiological turnover of 50% in the sciatic nerve and 80% in dorsal root ganglia (DRG) within 12 weeks. Further information about the dynamics of this turnover is not available. This study examined the macrophage turnover in the sciatic nerve and DRGs over a longer period and addresses the question whether the turnover of resident macrophages is complete or whether there is a truly resident endoneurial macrophage population. We used chimeric mice carrying GFP(+) bone marrow and immunohistochemistry to detect hematogenous (GFP(+)) endoneurial macrophages after turnover. Non-exchanged, resident macrophages were GFP(-). Quantification of GFP(+) and GFP(-) macrophages revealed a maximal turnover of 75%, reached in DRGs after 12 weeks and in sciatic nerves after 36 weeks. GFP(-) long-term resident macrophages were further characterized after sciatic nerve injury, where they participated in the early macrophage response of Wallerian degeneration. Our results point toward a small but truly resident PNS macrophage population. These macrophages are an interesting target for further characterization and might have a distinct role in peripheral nerve disease.     

Homeostatic regulation of the endoneurial microenvironment during development,aging and in response to trauma,disease and toxic insult

The endoneurial microenvironment, delimited by the endothelium of endoneurial vessels and a multi-layered ensheathing perineurium, is a specialized milieu intérieur within which axons, associated Schwann cells and other resident cells of peripheral nerves function. The endothelium and perineurium restricts as well as regulates exchange of material between the endoneurial microenvironment and the surrounding extracellular space and thus is more appropriately described as a blood–nerve interface (BNI) rather than a blood–nerve barrier (BNB). Input to and output from the endoneurial microenvironment occurs via blood–nerve exchange and convective endoneurial fluid flow driven by a proximo-distal hydrostatic pressure gradient. The independent regulation of the endothelial and perineurial components of the BNI during development, aging and in response to trauma is consistent with homeostatic regulation of the endoneurial microenvironment. Pathophysiological alterations of the endoneurium in experimental allergic neuritis (EAN), and diabetic and lead neuropathy are considered to be perturbations of endoneurial homeostasis. The interactions of Schwann cells, axons, macrophages, and mast cells via cell–cell and cell–matrix signaling regulate the permeability of this interface. A greater knowledge of the dynamic nature of tight junctions and the factors that induce and/or modulate these key elements of the BNI will increase our understanding of peripheral nerve disorders as well as stimulate the development of therapeutic strategies to treat these disorders.     

Further evidence for a crucial role of resident endoneurial macrophages in peripheral nerve disorders: lessons from acrylamide-induced neuropathy

Endoneurial macrophages are crucially involved in the pathogenesis of neuropathies. Historically, the macrophage response in neuropathies is believed to be of hematogenous origin. However, recent studies could demonstrate an intrinsic generation of the early macrophage response by resident endoneurial macrophages after traumatic nerve injury and in a model of hereditary neuropathy. We hypothesized that the local macrophage response might suffice to generate an appropriate macrophage response in mild neuropathies, supplemented by infiltrating macrophages only in severe nerve pathology. To clarify this assumption, we investigated the macrophage response in acrylamide-induced neuropathy as a model of a slowly progressive neuropathy with a defined onset. We induced the neuropathy in bone marrow chimeric mice carrying green fluorescent protein transgenic bone marrow, allowing the differentiation of resident (GFP(-)) and invading hematogenous endoneurial (GFP(+)) macrophages. Quantification of GFP(-) and GFP(+) endoneurial macrophages in the sciatic nerve revealed an increase only of resident macrophages in proximal parts, whereas in distal parts a minor additional influx of hematogenous macrophages was observed. The immunohistochemical profile of GFP(-) and GFP(+) macrophages was similar but distal GFP(-) macrophages were differentially activated than their GFP(+) counterparts. Characterization of CCR2-deficient mice revealed a function for this chemokine system in attracting hematogenous macrophages but not in generating the intrinsic macrophage response. In conclusion, we provide evidence for a role of resident macrophages in acrylamide-induced neuropathy. Resident endoneurial macrophages intrinsically generate the macrophage response in this slowly progressive neuropathy, which only becomes supplemented by hematogenous macrophages in distal areas of more pronounced damage.     

Macrophage colony stimulating factor is a crucial factor for the intrinsic macrophage response in mice heterozygously deficient for the myelin protein P0

Mouse mutants heterozygously deficient for the myelin protein P0 (P0+/-) resemble certain forms of human hereditary neuropathies. Endoneurial macrophages of intrinsic origin are intimately involved in the pathogenesis of the demyelinating neuropathy in these mutants. We have previously shown that deficiency for macrophage colony stimulating factor (M-CSF) prevents an increase of the number of endoneurial macrophages and alleviates the mutants' demyelinating phenotype. The aim of this study was to investigate which population of endoneurial macrophages - long-term resident macrophages or recently infiltrated macrophages - is affected by M-CSF deficiency. For this purpose, we generated bone marrow chimeric mice by transplanting GFP+ bone marrow into P0 mutants (P0+/-) and P0 mutants that lack M-CSF (P0+/- mcsf-op). This enabled us to discriminate recently infiltrated short-term resident GFP+ macrophages from long-term resident GFP- macrophages. Three months after bone marrow transplantation, P0+/- mice expressing M-CSF showed a substantial upregulation and activation of both GFP- and GFP+ macrophages in femoral nerves when compared to P0+/+ mice. In contrast, in P0+/- mcsf-op mutants, both GFP- and GFP+ macrophages did not substantially increase. Only small numbers of GFP+ but no GFP- macrophages were activated and phagocytosed myelin in chimeric P0+/- mcsf-op mutants, possibly reflecting recent activation outside the endoneurium before entering the nerve. Our findings demonstrate that M-CSF is crucial for the activation, in situ increase and myelin phagocytosis of both long-term and short-term resident endoneurial macrophages in P0+/- myelin mutants. M-CSF is, therefore, considered as a target candidate for therapeutic strategies to treat human demyelinating neuropathies.     

Relationships between glial and neuronal elements in the development of long term cultures of the spinal cord of the fetal mouse

The development of glial and synaptic relations has been studied in long term cultures of spinal cord by light and electron microscopy. During the first three days in vitro there is extensive cell death in the superficial parts of the explants, where one sees many phagocytes and much cellular debris. The ependyma of the explants early forms a closed sac in the deep parts of the culture next to the collagen substrate. Cells migrate from this sac to form a continuous basal layer upon the substrate. Some of these cells turn around the edges of the explant and migrate onto its surface, where they contribute to an ependyma-like epithelial covering. As the explants mature most of the cellular debris is cleared; the epithelial covering separates the neuronal elements from the feeding solution and from phagocytes, most of which migrate to lie freely on the surface of the epithelium. Two types of outgrowth are formed. The first consists of bundles of nerve fibers which are accompanied by individual undifferentiated glial cells. The second forms as a broad sheet of undifferentiated glial cells and astrocytes and this is continuous, at the edge of the explant, with the glia of the basal layer. Nerve fibers that grow into this sheet appear to survive better than nerve fibers that grow out in bundles. Oligodendroglial cells become recognizable by electron microscopical criteria when the axons start to myelinate. Dendrites can be identified in the sheet-like outgrowth but not in the bundles. Synapses are seen only where dendrites are identifiable. Serial axo-axonal junctions have not been found and axosomatic synapses are relatively rare.     

Variation in content and function of non-neuronal cells in the outgrowth of sympathetic ganglia from embryos of differing age

Studies on cellular interactions in the developing nervous system are greatly facilitated by the availability of tissue culture preparations that contain single or combined populations of neurons and non-neuronal cells (NNCs). Using superior cervical ganglia (SCG) from early E15 rats on air-dried collagen, we were able to prepare cultures containing neurons along with Schwann cells (SCs) as the only NNC type present without the use of antimitotic treatment and cultures containing only neurons, following brief antimitotic treatment. Light-microscopic observation of E15 outgrowth showed a uniform population of flattened cells, unlike that of E20 cultures, which contained a mixture of spindle-shaped and flattened cells. Autoradiograms following [3H]thymidine administration to E15 cultures revealed a striking gradient of nuclear labeling: Only a few cells were labeled near the explant and nearly all cells were labeled at the growth front. This was in marked contrast to E20 cultures, in which nuclei were labeled throughout the outgrowth. The conclusion that the labeling gradient is explained by the presence of SCs without other NNC types in E15 cultures was confirmed by immunocytochemical studies. Anti-laminin antibodies stain only those extracellular matrix components related to the SC surface, whereas anti-fibronectin antibodies stain fibroblast-related components (Cornbrooks et al., 1983a). Anti-laminin antibodies stained cell surfaces in both E15 and E20 outgrowth. E15 outgrowth did not stain with anti-fibronectin antibodies although marked staining was obtained in E20 cultures. Electron microscopy confirmed the presence of only SCs in E15, and of both SCs and fibroblasts in E20 outgrowth. Thus, it appears that there is a narrow developmental window in which the ganglia contain neurons and SCs but relatively few fibroblast components; cultures prepared from ganglia at this stage form outgrowth containing only neurites and SCs without antimitotic treatment. Surprisingly, neither SC ensheathment nor SC basal lamina formation was normal in E15 and E20 outgrowth. When either E15 or E20 SCG SCs were transplanted onto dorsal root ganglion neurons free of endogenous SCs, however, the sensory neurites were typically ensheathed or myelinated and basal lamina appeared 9 d later, identifying the SCG NNCs as functionally competent SCs.(ABSTRACT TRUNCATED AT 400 WORDS)     

Production of "ectopic" vasoactive intestinal peptide-like and neurotensin-like immunoreactivity in human pheochromocytoma cell cultures

Neoplastic chromaffin cells from human pheochromocytomas can exhibit extensive spontaneous and nerve growth factor (NGF)-induced outgrowth of neurite-like processes in vitro, despite the absence of such processes in vivo. To determine whether acquisition of neuron-like features by human pheochromocytoma cells in culture is accompanied by functional alterations, process outgrowth, vasoactive intestinal peptide-like immunoreactivity ( VIPLI ), neurotensin-like immunoreactivity (NTLI), and catecholamine content were studied in freshly dissociated cells and in 21-day-old cultures from six human pheochromocytomas. All of the cultures produced VIPLI and exhibited spontaneous process outgrowth. NGF stimulated process outgrowth and enhanced production of VIPLI . Dexamethasone inhibited process outgrowth and tended to decrease production of VIPLI . NTLI was detected in cells from only one of the tumors, and its production appeared to be regulated comparably to that of VIPLI . Catecholamine content decreased markedly in all of the cultures and was not regulated in parallel with either VIPLI or NTLI. The findings suggest that human pheochromocytoma cultures may help to elucidate cellular and molecular mechanisms regulating ectopic and normal VIP production.     

The effects of canine distempr virus on explant tissue cultures of canine cerebellum

Summary Canine cerebellar explant cultures were employed as a model for studying the effects of the virus associated with demyelinating canine distemper encephalomyelitis. Cultures which were inoculated after four to seven days of growth with distemper virus (Lederle strain) had beginning cytopathic effect (CPE) in the peripheral outgrowth on the eighth post-inoculation day. The cells predominantly affected were astroglia and mesenchymal cells. The cellular lesions consisted of inclusion body development (intracytoplasmic and intranuclear), syncytial giant cell formation, and production of a reticular pattern in the outgrowth. Astrocytes subsequently became affected in the inner outgrowth and explant. Cellular degeneration was common, but a high degree of apparent coexistence of virus (inclusion bodies) and cells was a characteristic feature.Neuronal degeneration followed either a lack of myelin development or demyelination in infected cultures. Three to four weeks post-inoculation, infected cultures had few or no large neurons (Purkinje cells or neurons of the cerebellar nuclei), whereas these cells were numerous in the controls. Smaller neurons (granule and stellate cells) also became degenerated (three weeks post-inoculation) and frequently contained intranuclear inclusions following staining and/or silver impregnation.Immunofluorescent studies established that cytoplasmic, as well as nuclear, inclusion material of astrocytes and mesenchymal cells contained viral antigen. The areas of antigen concentration were comparable in shape, size and time of occurrence with inclusions demonstrated in stained preparations. Intranuclear viral antigen was also occasionally detected in granule cells.Supported in part by Grants NBO3423 and CAO8502 from the National Institutes of Health.     

Stimulation of nerve regeneration by macrophages in granulation tissue

The effects of granulation tissue exposure on regeneration of sensory axons after a test crush lesion in rat sciatic nerves were studied. Chromic catgut threads were applied subcutaneously in the back of rats. Three weeks later the surrounding granulation tissue was isolated and transposed to the sciatic or tibial nerve in the same rat. Immunocytochemical, light and electron microscopic evaluation of the isolated granulation tissue revealed numerous EDI and ED2 positive macrophages. After an additional three weeks the sciatic nerves were crushed and the axonal outgrowth lengths were measured by the pinch reflex test and by neurofilament staining 3 or 6 days later. The regeneration distances in the sciatic nerve exposed to granulation tissue were significantly longer compared with that of nerves to which only subcutaneous tissue was transposed. Thus, the nerve had become conditioned by the transposure of macrophage rich tissue. After the transposure macrophages were present close to the nerve at the time point of the test crush lesion, but no signs of degeneration or inflammation in the endoneurial space were observed. It was also found that the outgrowth lengths in the tibial nerve branch were consistently longer than in the peroneal branch of the sciatic nerve. It is concluded that granulation tissue, containing macrophages, can induce a conditioning effect in the sciatic nerve. We suggest that this effect is related to factors emanating from macrophages in the transposed tissue.     

Cellular uptake of exogenous horseradish peroxidase in mouse peripheral nerve

Summary Horseradish peroxidase (HRP) was given to adult normal mice either intravenously or locally around the sciatic nerve. After varying time intervals the animals were sacrificed and fixed by whole body perfusion. The sciatic nerve was sampled and the distribution of peroxidatic activity was studied by light and electron microscopy.After both types of HRP administration the tracer was rapidly taken up by epi- and endoneurial cells with the ultrastructural features of macrophages. When increasing doses of HRP were injected intravenously a diffuse endoneurial extravasation was observed 30 min after the injection.It is concluded that a passage of HRP takes place over some endoneurial vessels. The nature and significance of endoneurial macrophages are discussed.     

Origin of pathogenic macrophages and endoneurial fibroblast-like cells in an animal model of inherited neuropathy

Macrophages have recently been shown to be critically involved in the pathogenesis of genetically determined demyelination in mice heterozygously deficient for P0 (P0(+-)). Since little is known about the origin of these cells, we created chimeric P0(+-) mice by transplanting bone marrow from green fluorescent protein (GFP)-transgenic mice into irradiated P0(+-) mice. When analyzing chimeric P0(+-) mice, we could determine two populations (GFP(+) and GFP(-)) of endoneurial macrophages that became phagocytic for myelin and increased in number. We found that both GFP(-) resident macrophages and GFP(+) macrophages proliferated in peripheral nerves of P0(+-) mice but not in nerves of chimeric or nonchimeric P0(++) mice. These findings demonstrate a so far poorly recognized role of resident endoneurial macrophages in demyelinating neuropathies. Surprisingly, we also found GFP(+) cells that unequivocally showed the morphological characteristics of fibroblasts. These blood-borne fibroblast-like cells express the common hematopoetic stem cell marker CD34 and might comprise another cell type of potential importance for immune regulation in hereditary demyelinating neuropathies.     

Quantitative Effects of Peripheral Monocytes and Nerve Growth Factor on CNS Neural Morphometric Outgrowth Parametersin Vitro

Wound healing of the central nervous system (CNS) is a complex process involving interactions between cells from both the vascular and the neural environments, extracellular matrix proteins, and a cocktail of agonistic and antagonistic bioactive molecules. Vascular cells, particularly peripheral monocytes and macrophages, are believed to play an important role in organizing and mediating CNS tissue reactions subsequent to penetrating injuries that compromise the blood–brain barrier. Although many investigators have studied the effect of macrophages and microglia (resident brain macrophages) on neural outgrowth, little is known regarding monocyte effects. We have combined tissue culture, video microscopy, and digital image processing and analysis to quantify morphometric parameters of neurons exposed to monocyte secretory productsin vitro.The experimental system developed is simple in design but provides a quantitative understanding of cellular function and molecular mechanisms and has the ability to both study processes of graded complexity and relate cellular function to overall systems behavior. We evaluate the efficacy of the experimental model developed by measuring morphometric parameters of human neural cells (hNT cell line) in the presence of nerve growth factor (NGF). Results suggest that monocyte-conditioned media (MCM) increases neuron outgrowth parameters, such as neuritic output, mean arbor output, neurite branching, and effective cell diameter. Moreover, we show that the bioactive factor present in MCM is not IL-1 and the activity of the factor with respect to neural outgrowth is between that of 10 and 100 ng/ml NGF.     

Significance of degenerating endoneurial cells in peripheral neuropathy

Summary In 42 human sural nerve biopsies degeneration of endoneurial cells was evaluated semiquantitatively at the electronmicroscopic level. These cells were of non-Schwannian origin since they were not surrounded by a basement membrane. Most of the degenerating cells resembled endoneurial fibroblasts: their remaining cytoplasmic processes were quite extensive, not finger-like as in macrophages, and their cytoplasm did not contain conspicuous lysosomes or phagolysosomes that would identify them as degenerating macrophages. Criteria for regarding these cells as degenerating were defects of the cytoplasmic surface membrane with extracellularly situated organelles. The ratio between normal and degenerating endoneurial cells in five different groups of peripheral neuropathies was compared to a group of normal controls. No degenerating endoncurial cells were found in the latter. The largest proportion of degenerating endoneurial cells was noted in patients with panarteritis nodosa (30% of the endoneurial cells evaluated). Between 9% and 18% of the evaluated endoneurial cells were seen degenerating in hereditary motor and sensory neuropathies, in neuropathies associated with IgG or IgM gammopathy, and in chronic demyelinating inflammatory polyradiculoneuropathy. These findings suggest that degeneration of endoneurial cells is a nonspecific sign of peripheral neuropathy occurring in various types of neuropathy, although vasculitis represents the most frequent cause. Thus, degeneration of endoneurial cells can be added to the growing list of changes that possibly indicate an inflammatory disorder, even during the intervening stage when apparent inflammatory cell infiltrates are lacking.     

Triiodothyronine Exerts a Trophic Action on Rat Sensory Neuron Survival and Neurite Outgrowth through Different Pathways

Apart from several growth factors which play a crucial role in the survival and development of the central and peripheral nervous systems, thyroid hormones can affect different processes involved in the differentiation and maturation of neurons. The present study was initiated to determine whether triiodothyronine (T₃) affects the survival and neurite outgrowth of primary sensory neurons in vitro. Dorsal root ganglia (DRG) from 19-day-old embryos or newborn rats were plated in explant or dissociated cell cultures. The effect of T₃ on neuron survival was tested, either in mixed DRG cell cultures, where neurons grow with non-neuronal cells, or in neuron-enriched cultures where non-neuronal cells were eliminated at the outset. T₃, in physiological concentrations, promoted the growth of neurons in mixed DRG cell cultures as well as in neuron-enriched cultures without added nerve growth factor (NGF). Since neuron survival in neuron-enriched cultures cannot be promoted by endogenous neurotrophic factors synthesized by non-neuronal cells, the increased number of surviving neurons was due to a direct trophic action of T₃. Another trophic effect was revealed in this study: T₃ sustained the neurite outgrowth of sensory neurons in DRG explants. The stimulatory effect of T₃ on nerve fibre outgrowth was considerably reduced when non-neuronal cell proliferation was inhibited by the antimitotic agent cytosine arabinoside, and was completely suppressed when the great majority of non-neuronal cells were eliminated in neuron-enriched cultures. These results indicate that the stimulatory effect of T₃ on neurite outgrowth is mediated through non-neuronal cells. It is conceivable that T₃ up-regulates Schwann cell expression of a neurotrophic factor, which in turn stimulates axon growth of sensory neurons. Together, these results demonstrate that T₃ promotes both survival and neurite outgrowth of primary sensory neurons in DRG cell cultures. The trophic actions of T₃ on neuron survival and neurite outgrowth operate under two different pathways.     

Proteasome inhibition arrests neurite outgrowth and causes "dying-back" degeneration in primary culture

Proteasome inhibitors such as lactacystin were first isolated when assaying their ability to stimulate neurite outgrowth in neuronal-like cell lines; however, their effect on neurites in primary culture has been largely neglected. We report here that lactacystin causes immediate arrest of nerve growth factor (NGF)-stimulated neurite outgrowth in sympathetic and sensory explant cultures. This is followed by neurite degeneration that in sympathetic cultures has a distinctive "dying-back" morphology. Remarkably, this occurs even at concentrations below that required to induce neurite outgrowth in PC12 cells. Thus, lactacystin opposes rather than potentiates the effect of NGF on sympathetic neurite outgrowth and the role of the ubiquitin proteasome pathway in growth and long-term maintenance of axons and dendrites differs from that in neuritogenesis in neuronal-like cell lines. Retrograde degeneration caused by blocking of the ubiquitin proteasome pathway may mimic some aspects of gracile axonal dystrophy, a dying-back axonopathy in mice caused by ubiquitin hydrolase (Uch-l1) deficiency, and may be relevant to human neurodegenerative diseases involving ubiquitination or proteasome abnormalities.     

Nerve growth factor and proprotein convertases furin and PC7 in transected sciatic nerves and in nerve segments cultured in conditioned media: Their presence in Schwann cells,macrophages, and smooth muscle cells

Synthesis of proteins such as nerve growth factor (NGF) is induced after nerve lesion. The NGF precursor (pro-NGF) requires a posttranslational processing by proprotein convertases to become active. In this report, we re-examine the localization of NGF protein and mRNA in injured nerve and show that the candidate pro-NGF convertases furin and PC7 colocalize with NGF in non-neuronal cells in nerve. By Northern blot analysis, 1.5-kb and 1.3-kb NGF mRNAs were shown to be increased in distal and immediately proximal nerve segments on days 1, 4, and 14 after lesion; by Western blot analysis, NGF proteins of high molecular weight were detected after injury. In vivo, two phases of NGF immunopositivity were observed, in macrophages and perivascular cells shortly after lesion and in endoneurial cells on day 1 and 4. To identify the cells containing NGF, nerve segments were incubated in serum-containing medium with or without conditioning by white blood cells isolated from the circulation. Both hybridization and immunoreactivity signals for NGF were elevated after incubation of nerve segments for 4 hours in conditioned media, so that cells with NGF immunoreactivity could be identified by antibodies to specific cell markers. In these nerve fragments, Schwann cells, perivascular smooth muscle cells, and macrophages contained NGF immunoreactivity. The concentration of furin and PC7 mRNA also increased in lesioned nerves. By immunocytochemical investigation of nerve explants, furin and PC7 were detected in endoneurial cells, macrophages and perivascular cells and were colocalized with NGF. These in vitro and in vivo findings suggest that both furin and PC7 are associated with NGF in several cell types of the sciatic nerve and, hence, may be implicated in intracellular processing of pro-NGF. J. Comp. Neurol. 403:471–485, 1999. © 1999 Wiley-Liss, Inc.     

Basic FGF partially prevents degeneration of paraventricular vasopressin neurons after hypophysectomy

Invading and resident macrophages were studied in the regenerating rat vagus nerve in vivo and in vitro, using antibodies to invading (EDI) and resident (ED2) macrophages. Fresh vagus nerves contained no EDI positive macrophages as revealed by immunocytochemical staining. In crush lesioned nerves in vivo, the number of EDI positive cells around and distal to the crush lesion, increased dramatically with time. Interestingly, EDI positive cells, although few, appeared in the cultured vagus nerves subjected to a crush lesion. Resident ED2 positive macrophages were abundant in fresh nerves. In vivo, there was a small increase of ED2 positive macrophages at the crush area as regeneration proceeded. In contrast, no increase was observed in vitro and after 3 days no ED2 stained macrophages were found. Immunocytochemical staining for low-affinity NGF-receptors showed a dramatic increase at the crush and distal to it in vivo, while in vitro, the receptors were upregulated along the entire nerve. The results suggest that invading macrophages may not be crucial for the initial and early outgrowth of sensory nerve fibres in peripheral nerves.