Hypersensitivity to ovalbumin induces chronic intestinal dysmotility and increases the number of intestinal mast cells

Undiagnosed food allergies have been proposed as possible causes of promoting and perpetuating irritable bowel syndrome . Our aim was to find out if sensitization could induce chronic functional motor disturbances in the intestine and the mechanisms implicated. Rats were sensitized to ovalbumin (OVA) following three hypersensitivity induction protocols, two parenteral and one oral. Rat mast cell protease II (RMCP II) release in response to OVA challenge and immunoglobulin E (IgE) concentration were measured in serum. At least 1 week after challenge, small intestinal motility was evaluated using strain gauges. Intestinal tissue samples from orally sensitized rats were checked for in vitro stimulation with OVA. Mucosal mast cells were counted from duodenum sections. All sensitized rats showed intestinal hypermotility. Only rats sensitized by parenteral procedure showed an increase in RMCP II after OVA challenge in serum. IgEs increased only in the Bordetella pertussis sensitized group. Small intestine sections from orally sensitized rats released more RMCP II than sections from control rats. All sensitized rats showed an increase in the number of mucosal mast cells in duodenum. In conclusion, hypersensitivity to food proteins induces chronic motor alteration that persists long after antigen challenge and an excited/activated state of sensitized mucosal mast cells.     

Diabetic Schwann cells suffer from nerve growth factor and neurotrophin‐3 underproduction and poor associability with axons

Schwann cells (SCs) are integral to peripheral nerve biology, contributing to saltatory conduction along axons, nerve and axon development, and axonal regeneration. SCs also provide a microenvironment favoring neural regeneration partially due to production of several neurotrophic factors. Dysfunction of SCs may also play an important role in the pathogenesis of peripheral nerve diseases such as diabetic peripheral neuropathy where hyperglycemia is often considered pathogenic. In order to study the impact of diabetes mellitus (DM) upon the regenerative capacity of adult SCs, we investigated the differential production of the neurotrophic factors nerve growth factor (NGF) and neurotrophin‐3 (NT3) by SCs harvested from the sciatic nerves of murine models of type 1 DM (streptozotocin treated C57BL/6J mice) and type 2 DM (LepR^?/? or db/db mice) or non‐diabetic cohorts. In vitro, SCs from diabetic and control mice were maintained under similar hyperglycemic and euglycemic conditions respectively. Mature SCs from diabetic mice produced lower levels of NGF and NT3 under hyperglycemic conditions when compared to SCs in euglycemia. In addition, SCs from both DM and non‐DM mice appear to be incapable of insulin production, but responded to exogenous insulin with greater proliferation and heightened myelination potentiation. Moreover, SCs from diabetic animals showed poorer association with co‐cultured axons. Hyperglycemia had significant impact upon SCs, potentially contributing to the pathogenesis of diabetic peripheral neuropathy. GLIA 2013;61:1990–1999     

Neurotrophin 3 promotes purification and proliferation of olfactory ensheathing cells from human nose

Several studies have demonstrated the potential of olfactory ensheathing cells for the repair of central and peripheral nerve injury. However, the majority of these studies have been performed with olfactory ensheathing cells derived from the olfactory bulbs, situated inside the skull. A more clinically relevant source of olfactory ensheathing cells is the olfactory mucosa, located in the nose. To be successful, an autologous transplant of nasal ensheathing glia would require a large number of purified cells. To address this issue, we have focused our research on three neurotrophic factors, namely nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF), and neurotrophin 3 (NT3). We show here that their respective receptors, TrkA, TrkB, TrkC, as well as p75(NTR) (the low affinity NGF receptor), are expressed in vitro by the nasal ensheathing cells; the three neurotrophins promote purification and proliferation of these glial cells, with an optimal concentration of 50 ng/ml; and human ensheathing cells can be easily biopsied and highly purified using a serum-free medium supplemented with NT3. This technique opens the door for clinical trials in which nasal ensheathing cells will be autotransplanted in humans suffering from nerve injury.     

Transforming growth factor alpha, but not epidermal growth factor, promotes the survival of sensory neurons in vitro.

Transforming growth factor alpha (TGF alpha) is a mitogenic polypeptide that is structurally homologous to epidermal growth factor (EGF) and appears to bind to the same receptor in all systems tested previously. In the present study, TGF alpha was found to enhance survival and neurite outgrowth of cultured neonatal rat dorsal root ganglion (DRG) neurons in a dose-dependent manner. This effect was observed with TGF alpha concentrations as low as 17.8 pM. By contrast, EGF at concentrations up to 83 nM was ineffective. Moreover, EGF did not antagonize the TGF alpha survival-promoting effect unless present in large excess (500-fold the concentration for which TGF alpha is effective); even in this case, only partial antagonism was achieved. Survival of neurons from nodose, trigeminal, and sympathetic ganglia was not increased by TGF alpha. Both a subpopulation of DRG neurons and of macrophages in the cultures bound iodinated TGF alpha. This binding was inhibited by excess unlabeled TGF alpha but not EGF. Our data are consistent with the possibilities that the actions of TGF alpha on DRG neurons occur indirectly via unidentified neurotrophic molecules other than NGF as well as directly on the neurons themselves. Thus, TGF alpha, in contrast to EGF, may act as a survival or maintenance factor for a subset of rat sensory neurons. Mediation of this neurotrophic effect appears to occur via a new form of TGF alpha receptor.     

The low-affinity nerve growth factor receptor p75NGFR mediates death of PC12 cells after nerve growth factor withdrawal

We have investigated the role of the low-affinity nerve growth factor (NGF) receptor p75^NGFR in determining the death of neuronally differentiated PC12 cells after withdrawal of NGF. A range of high and low p75^NGFR-expressing cells were obtained by a combination of fluorescence activated cell sorting (FACS) and stable transfection with a p75^NGFR expression vector. Cells were readily differentiated to a neuronal phenotype irrespective of the level of p75^NGFR expression. However, the rate and extent of neuronal death following NGF deprivation were extremely sensitive to the level of p75^NGFR expression. The highest expressing cells died most rapidly. Cells selected for very low levels of p75^NGFR expression exhibited resistance to NGF withdrawal, and remained as viable, differentiated neurons, with minimal cell death, for at least 5 days in the absence of NGF. Antisense oligonucleotides against p75^NGFR were shown to down-regulate p75^NGFR in PC12 cells and, further, to significantly enhance survival in the absence of NGF. These results consolidate and generalize our previous findings that p75^NGFR induces cell death in postnatal sensory neurons in the absence of NGF. The ability to induce cell death in the absence of NGF appears to be a more general role of p75^NGFR in differentiated neurons, and an important new paradigm for the mechanism of NGF-dependent survival. © 1996 Wiley-Liss, Inc.     

Matrix metalloproteinase-9 promotes nerve growth factor-induced neurite elongation but not new sprout formation in vitro

Matrix metalloproteinase-9 (MMP-9) is a basal-lamina-degrading protease that we have recently shown to be localized in regenerating sciatic nerve. We now demonstrate that MMP-9 colocalizes with growth-associated protein GAP-43 in regenerating nerves in vivo and is involved in vitro in axonal sprouting. By using a PC12 cell model for neuronal sprouting, we analyzed the effects of recombinant MMP-9, MMP-9-neutralizing antibody, and a broad-spectrum MMP inhibitor (Ro 31-9790) on sprout formation, elongation, and branching. Quantitative phase-contrast microscopy showed that MMP-9 elongated neuronal sprouts by 67% and increased their branching by 14% but did not change the number of sprouts relative to nerve growth factor (NGF) treatment. Double immunofluorescence for GAP-43, a marker for growth cones, and alpha-tubulin, a marker for axonal microtubules, showed that MMP-9-treated cells had increased distribution of alpha-tubulin but no effect on GAP-43. Western blot analyses of cell lysates demonstrated that the NGF-induced increase in GAP-43 was unchanged with MMP-9 treatment or inhibition, confirming that MMP-9 had no effect on new sprout formation. However, Ro 31-9790 reduced GAP-43 levels to those seen in untreated cells, suggesting that an MMP other than MMP-9 is important for sprout formation. Finally, phosphorylated neurofilament M (NFM-p), a marker for regenerative elongation, was induced with MMP-9 treatment and was inhibited by the anti-MMP-9 antibody treatment, confirming the role of MMP-9 in axonal elongation. NFM-p colocalized with MMP-9 in regenerating sciatic nerve fibers. These findings suggest that MMP-9 regulates neurite extension in regenerating peripheral nerve fibers and, therefore, might be of therapeutic value in promoting regeneration in vivo.     

Natural killer cells do not mediate facial motoneuron survival after facial nerve transection

The goal of the current study was to determine if natural killer (NK) cells mediate facial motoneuron (FMN) survival following injury. Wild-type (WT), perforin/recombinase activating gene-2 knockout (pfp/RAG-2 KO), and common gamma-chain (gammac)/RAG-2 KO mice received a right facial nerve axotomy. In WT mice, FMN survival was 86+/-1.0% relative to the contralateral control side. In contrast, pfp/RAG-2 and gammac/RAG-2 KO mice exhibited significant decreases in FMN survival ( approximately 20% and approximately 30%, respectively), relative to WT. Reconstitution of pfp/RAG-2 and gammac/RAG-2 KO mice with normal NK cells alone, failed to restore FMN survival levels to those of WT, but did restore functional lytic activity against YAC-1 cells. Reconstitution of pfp/RAG-2 and gammac/RAG-2 KO mice with splenocytes, and pfp/RAG-2 KO mice with CD4+ T-lymphocytes alone or in combination with NK cells, restored FMN survival levels to those of WT. Thus, NK cells appear to not be a component of immune cell-mediated rescue of motoneurons from axotomy induced cell death.     

Loss of the activity of human coagulation factor xii by a chymotrypsin-like protease activated in rat mast cells during degranulation with compound 48/80.

Mediator release from mast cells is an initial step in the immediate-type hypersensitivity. Thus, the interaction of neutral proteases released from mast cells with plasma kallikrein-kinin system was investigated. Two proteases, chymotrypsin-like (CHY) and trypsin-like (TRY) proteases, were activated in purified rat mast cells after degranulation with compound 48/80. Three fourths of the CHY activity remained in the cell residue, and the activity was inhibited by chymostatin, whereas most of the TRY activity was released in the medium and was inhibited by leupeptin. The incubation of rat or human plasma with degranulated mast cell (DMC) suspension did not cause the activation of plasma prekallikrein, but did cause a loss in the activity of coagulation factor XII, as ascertained by the lack of activation of prekallikrein in either the DMC-treated plasma by glass powder or in the incubation of DMC-treated human plasma with factor XII deficient plasma activated by kaolin. The prekallikrein and high-molecular-weight kininogen levels were sufficient for activation of factor XII.     

Nerve growth factor regulates the subcellular localization of the nerve growth factor-inducible protein PC4 in PC12 cells

The immediate early gene (IEG) PC4, which encodes a protein related to γ interferon, is activated at the onset of the neuronal differentiation induced by nerve growth factor (NGF) in PC12 cells. With an antibody raised to a bacterial β gal-PC4 fusion protein, the PC4 protein is detected as an immunoreactive molecular species of 49 kDa, whose synthesis is rapidly induced by NGF in parallel with the induction of its mRNA. Immunofluorescence, electron microscopy and subfractionation studies indicate that the PC4 immunoreactivity is localized in the cytoplasm of PC12 cells, where it is increased transiently by NGF within 3 hr of treatment. In addition, the PC4 immunoreactivity presents an NGF-dependent pattern of intracellular localization. In fact, within 3 hr after addition of NGF, PC4 is also significantly expressed on the inner face of the plasma membrane, to which it is physically associated. After longer NGF treatment, PC4 disappears from the plasma membrane and appears in the nucleus, with reduced cytoplasmic expression. Localization in the nucleus is reversed by removal of NGF and closely parallels changes in the state of differentiation of the cell. The existence within the PC4 protein of a consensus sequence for the addition of myristic acid and of a putative sequence for the nuclear localization suggests possible mechanisms for the NGF-dependent redistribution. For an NGF-inducible IEG product, such growth factor-dependent localization of PC4 is a novel type of regulation in the pathways from the NGF receptor to the adjacent membrane proteins and to the nucleus. © 1994 Wiley-Liss, Inc.     

Intramuscular interstitial cells of Cajal associated with mast cells survive nitrergic nerves in achalasia

Achalasia is dominated by injury to inhibitory nerves. As intramuscular interstitial cells of Cajal (ICC-IM) are proposed to form functional units with nitrergic nerves, their fate in achalasia may be critically important. We studied the relationship between loss of nitrergic nerves and injury to ICC-IM in patients with achalasia and determined associations between ICC-IM and mast cells (MC), using quantitative immunohistochemistry and electron microscopy. Loss of neuronal nitric oxide synthase (nNOS) immunoreactivity was completed within 3 years of acquiring achalasia. Thereafter, progressive ultrastructural injury to remaining nerve structures was evident. Within the first 2 years, the number of ICC-IM did not decline although ultrastructural injury was already present. Thereafter, loss of ICC-IM occurred unrelated to duration of disease. Damage to ICC-IM appeared unrelated to nerve injury. A significant MC infiltration was observed in the musculature; the number of MC was positively related to the persistent number of ICC-IM. Mast cell formed close contacts with ICC-IM and piecemeal-degranulation occurred towards ICC-IM. In conclusion, injury to ICC-IM in achalasia is variable, but not related to duration of disease and injury to nitrergic nerves. MC are prominent and form close functional contact with ICC-IM which may be responsible for their relatively long survival.     

Role of mast cell activation in inducing microglial cells to release neurotrophin

The brain‐derived neurotrophic factor (BDNF) plays a critical role in pain hypersensitivity. BDNF is the ligand of P2X4 receptors (P2X4R) in the microglia. The causative factors involving the P2X4R over expression in the microglia remains unclear. Mast cell activation has a close relation with pain hypersensitivity. However, the underlying mechanism between mast cell activation and pain hypersensitivity is unknown. The present study aimed to elucidate the mechanism by which mast cell activation promoted the expression of P2X4R in the microglia. The results of present study showed that mast cell activation markedly promoted the expression of P2X4R and BDNF in microglial cells, which significantly enhanced the release of BDNF from microglial cells upon exposure to adenosine triphosphate. Mast cell‐derived tryptase activated PAR2 that resulted in promoting the expression of P2X4R in microglial cells. Pretreatment with antibodies against tryptase or PAR2, or using tryptase‐deficient HMC‐1 cells or PAR2‐deficient microglial cells abolished the increase in P2X4R expression and BDNF release. Increase in mitogen activated protein kinase phosphorylation was observed in the processes of mast cell‐induced BDNF release and P2X4R expression. We conclude that mast cell activation has the capacity to promote the expression of P2X4R and BDNF in microglial cells. © 2009 Wiley‐Liss, Inc.     

Excess nerve growth factor in the periphery does not obscure development of whisker-related patterns in the rodent brain

We have addressed the issue of whether or not peripherally expressed nerve growth factor (NGF) influences the formation of whisker-specific patterns in the brain by regulating the survival of sensory neurons. Transgenic mice that overexpress an NGF cDNA in the skin were examined. In these animals, excess NGF expression is controlled by promoter and enhancer sequences of a keratin gene, thus restricting the higher levels of NGF expression to basal keratinocytes of the epidermis. Twice the number of trigeminal sensory neurons survive in transgenic mice as in normal animals, and a corresponding hyperinnervation of the whisker pad is noted, both around the vibrissa follicles and along the intervibrissal epidermis. However, the increased survival of sensory neurons and the enhanced peripheral projections do not interfere with the development of whisker-specific patterns in the trigeminal brainstem, in the ventrobasal thalamic complex or in the face-representation region of the primary somatosensory (SI) cortex. These results demonstrate that vibrissa-related central patterns are able to form in the virtual absence of trigeminal ganglion cell death and suggest that mechanisms other than a selective elimination of sensory neurons control the development of whisker-specific neural patterns in the brain. © 1996 Wiley-Liss, Inc.     

Nerve growth factor expression in human dystrophic muscles

Nerve growth factor (NGF) is a neurotrophin that is expressed during muscle development and is also capable of favoring muscle regeneration in experimental studies. The presence of NGF in muscular dystrophies, such as Duchenne and Becker muscular dystrophies, has never been fully explored. By means of immunohistochemistry, we show that regenerating muscle fibers from such patients consistently express NGF, as do myofibroblasts and mast cells. By contrast, rest fibers from dystrophic patients, as well as muscle fibers from healthy, control patients and even regenerative muscle fibers in polymyositis do not show NGF immunoreactivity. The paracrine effect of NGF on muscle regeneration, as well as its chemoattractant capacities for mast cells, may contribute to explaining why regenerating fibers most frequently occur in clusters and why mast cells are more numerous in dystrophic muscles. Moreover, being a mediator of wound healing and tissue fibrosis, NGF may contribute to long-term muscle regeneration impairment by tissue fibrosis in the muscular dystrophies.     

Class 1 heparin binding growth factor promotes the differentiation but not the survival of ciliary neurones in vivo.

Molecules isolated from target tissues of various neuronal populations have been shown to enable the survival of those innervating neurones. A molecule derived from bovine heart which can support the survival of parasympathetic neurones of the chick embryo ciliary ganglion in vitro has been sequenced and identified as a member of the class 1 heparin binding growth factors (HBGF-1). When injected into developing chick embryos during the period of naturally occurring cell death in the ciliary ganglion, HBGF-1 failed to rescue those neurones which normally die. There was, however, a premature increase in the activity of choline acetyltransferase within the ganglion and a shift to the right in the size distribution of the neurones. We conclude that HBGF-1 may promote the differentiation of some subpopulation of neurones of the ciliary ganglion of the chick embryo but does not act in vivo as a survival molecule.