Beverly Bealmear

TNF-α and TGF-β act synergistically to kill Schwann cells

Interactions between cytokines and Schwann cells (SC) are important in development, repair, and disorders of the peripheral nervous system (PNS). Tumor necrosis factor‐α (TNF‐α) and transforming growth factor‐β (TGF‐β) are two prominent cytokines which may be involved in these processes and their gene products are upregulated in some experimental neuropathies. This study focuses on thein vitro effects of these cytokines, both singly and in combination, on cultured SC. Expression of both Type I and Type II TNF‐α receptors was demonstrated on the SC surface by immunocytochemistry. Treatment of SC with a combination of TNF‐α plus TGF‐β causes significant detachment and cell death while treatment with each cytokine alone is not significantly cytotoxic. When compared with control cultures, SC treated with the combination of cytokines exhibit an increase in the number of cells with condensed nuclei and evidence of DNA fragmentation, characteristics consistent with cells undergoing programmed cell death. Thus, TNF‐α plus TGF‐β induce SC loss of adhesion which is predominantly due to cell death. Apoptotic mechanisms are likely to contribute to some extent to this cell death. These findings provide in vitro evidence to support the hypothesis that cytokines can directly damage SC in PNS disorders. J. Neurosci. Res. 53:747–756, 1998.

The Role of Cytokines in Schwann Cell Damage, Protection, and Repair

Cytokines, proteins that are secreted by many cells, including inflammatory and glial cells, mediate interactions between cells, generally through paracrine and autocrine networks. Their effects are highly pleiotropic, with overlap of some activities. The pathogenesis of Guillain-Barré syndrome (GBS), especially the classic inflammatory demyelinating polyneuropathy form, seems to involve lymphocytes and macrophages, which are rich sources of cytokines. Macrophages likely have a role in the pathogenesis of the primarily axonal, less inflammatory forms of GBS. Cytokines appear to be involved in damage to Schwann cells, myelin, and axons, although the exact roles of the different cytokines is uncertain. There is increasing evidence that cytokines, including some proinflammatory cytokines that ordinarily cause damage, may also protect the cells of the peripheral nervous system and aid in its repair. The evolution of inflammatory and demyelinating disorders, including the degree of recovery, is probably dependent on the interactions of the different cytokines.

Autoantibodies to Agrin in Myasthenia Gravis Patients

To determine if patients with myasthenia gravis (MG) have antibodies to agrin, a proteoglycan released by motor neurons and is critical for neuromuscular junction (NMJ) formation, we collected serum samples from 93 patients with MG with known status of antibodies to acetylcholine receptor (AChR), muscle specific kinase (MuSK) and lipoprotein-related 4 (LRP4) and samples from control subjects (healthy individuals and individuals with other diseases). Sera were assayed for antibodies to agrin. We found antibodies to agrin in 7 serum samples of MG patients. None of the 25 healthy controls and none of the 55 control neurological patients had agrin antibodies. Two of the four triple negative MG patients (i.e., no detectable AChR, MuSK or LRP4 antibodies, AChR-/MuSK-/LRP4-) had antibodies against agrin. In addition, agrin antibodies were detected in 5 out of 83 AChR+/MuSK-/LRP4- patients but were not found in the 6 patients with MuSK antibodies (AChR-/MuSK+/LRP4-). Sera from MG patients with agrin antibodies were able to recognize recombinant agrin in conditioned media and in transfected HEK293 cells. These sera also inhibited the agrin-induced MuSK phosphorylation and AChR clustering in muscle cells. Together, these observations indicate that agrin is another autoantigen in patients with MG and agrin autoantibodies may be pathogenic through inhibition of agrin/LRP4/MuSK signaling at the NMJ.

Induced upregulation of IL-1, IL-1RA and IL-1R type I gene expression by Schwann cells

We analyzed two distinct phenotypes of Schwann cells (SC), non-differentiated and differentiated, for their ability to produce IL-1alpha and IL-1beta, and to express message for IL-1 receptor antagonist (IL-IRA) and IL-1R type I, in vitro. SC were stimulated with: lipopolysaccharide (LPS), products of activated splenocytes (ASP), products from LPS stimulated SC (SCP), rat recombinant IL-1beta (rrIL-1beta) or dexamethasone. IL-1alpha, IL- 1beta and IL-1RA mRNA levels were highly upregulated after stimulation with LPS, ASP, SCP or rrIL-1beta. SC constitutively expressed low levels of message for IL-1alpha and IL-1beta but not IL-1RA. Specific mRNAs for both IL-1 isotypes were highly upregulated 2 to 4 h after LPS stimulation and then decreased and were undetectable by 24 h. IL-1RA mRNA was detectable after 6 h of LPS stimulation and was maximally upregulated at 24 h. IL-1 gene expression was inducible in both SC phenotypes. IL-1beta could be detected by immunofluorescence in SC, one to three days after LPS stimulation. At the same time IL-1 bioactivity was maximal in SC supernatants. Treatment with either SCP, rrIL-1beta or dexamethasone induced upregulation of IL-1R type I mRNA with maximal expression between 2 to 4 h, in SC. Inducible expression of genes for IL-1alpha, IL-1beta, IL-1RA and IL-1R type I in both differentiated and non-differentiated SC suggest autocrine and paracrine regulation of IL-1 by SC.

Cytokines regulate neuronal gene expression: Differential effects of Th1, Th2 and monocyte/macrophage cytokines

Inflammatory mediators, including cytokines, contribute to neuronal and axonal dysfunction and cell death. To examine the roles of cytokines in pathogenesis and regeneration in the central nervous system (CNS), we analyzed effects of cytokines on early gene regulation (6h) in neuronal cultures, employing gene arrays. Our hypothesis is that neuronal gene expression is differentially regulated in vitro by cytokine mixtures typical of Th1 and Th2 T cells and monocytes/macrophages (M/M). Th1 and M/M cytokines showed similar patterns for regulation of numerous pathways including cytokine-receptor interactions, MAP kinase, toll like receptors, apoptosis, PPAR signaling, cell adhesion molecules (CAMS), antigen processing, adipocytokine, and JAK-STAT signaling. M/M cytokines uniquely regulated genes in T cell, B cell and ECM receptor signaling pathways. Th2 cytokines had few effects on pathways regulated by Th1 and MM cytokines, but uniquely regulated genes related to neuroactive ligand-receptors and calcium. Th1 and MM cytokines markedly upregulated a wide array of cytokine-related genes. Notably, M/M cytokines uniquely upregulated G-CSF, GM-CSF, CXCL5 and lymphotactin (Xcl1). Th2 cytokines did not upregulate cytokine-related genes, with the exception of CCL11 and FMS-like tyrosine kinase 1, a VEGF receptor. In neuroactive ligand-receptor pathways, Th1 and M/M cytokines upregulated gene expression for tryptophan hydroxylase. Th1 cytokines upregulated gene expression for GABA A receptor, delta, while Th2 cytokines downregulated GABA A receptor, gamma 3. Significant changes occurred in several genes in the wnt and Notch signaling pathways, which are highly conserved and play critical roles in neuronal and glial differentiation. In the ubiquitin-proteasome pathway, proinflammatory cytokine mixtures induced upregulation of several genes, notably ubiquitin D (Ubd/FAT10), ubiquitin ligase and several proteasomal proteins. In agreement with microarray results, QRT-PCR showed marked upregulation of gene expression for Ubd with Th1 and M/M, for transglutaminase 2 with M/M, and for arginase 1 with Th2 cytokines. Expression of Ubd in the nervous system has not been previously reported. Both message and protein for Ubd are expressed in neurons, and upregulated by pro-inflammatory cytokines. Transglutaminase 2 has been implicated in neurodegenerative diseases, and proposed as a therapeutic target. Upregulation of arginase by Th2 cytokines could be potentially neuroprotective by decreasing NO generation and enhancing neurite outgrowth. Our analysis of changes in neuronal gene expression at the time of initial exposure to an abnormal cytokine milieu provides the opportunity to identify early changes that could be reversed to prevent later irreversible neuronal damage and death in multiple sclerosis and other CNS diseases.

Differential effects of Th1, monocyte/macrophage and Th2 cytokine mixtures on early gene expression for glial and neural-related molecules in central nervous system mixed glial cell cultures: neurotrophins, growth factors and structural proteins.

BackgroundIn multiple sclerosis, inflammatory cells are found in both active and chronic lesions, and it is increasingly clear that cytokines are involved directly and indirectly in both formation and inhibition of lesions. We propose that cytokine mixtures typical of Th1 or Th2 lymphocytes, or monocyte/macrophages each induce unique molecular changes in glial cells.MethodsTo examine changes in gene expression that might occur in glial cells exposed to the secreted products of immune cells, we have used gene array analysis to assess the early effects of different cytokine mixtures on mixed CNS glia in culture. We compared the effects of cytokines typical of Th1 and Th2 lymphocytes and monocyte/macrophages (M/M) on CNS glia after 6 hours of treatment.ResultsIn this paper we focus on changes with potential relevance for neuroprotection and axon/glial interactions. Each mixture of cytokines induced a unique pattern of changes in genes for neurotrophins, growth and maturation factors and related receptors; most notably an alternatively spliced form of trkC was markedly downregulated by Th1 and M/M cytokines, while Th2 cytokines upregulated BDNF. Genes for molecules of potential importance in axon/glial interactions, including cell adhesion molecules, connexins, and some molecules traditionally associated with neurons showed significant changes, while no genes for myelin-associated genes were regulated at this early time point. Unexpectedly, changes occurred in several genes for proteins initially associated with retina, cancer or bone development, and not previously reported in glial cells.ConclusionEach of the three cytokine mixtures induced specific changes in gene expression that could be altered by pharmacologic strategies to promote protection of the central nervous system.

Differential effects of Th1, monocyte/macrophage and Th2 cytokine mixtures on early gene expression for molecules associated with metabolism, signaling and regulation in central nervous system mixed glial cell cultures

BackgroundCytokines secreted by immune cells and activated glia play central roles in both the pathogenesis of and protection from damage to the central nervous system (CNS) in multiple sclerosis (MS).MethodsWe have used gene array analysis to identify the initial direct effects of cytokines on CNS glia by comparing changes in early gene expression in CNS glial cultures treated for 6 hours with cytokines typical of those secreted by Th1 and Th2 lymphocytes and monocyte/macrophages (M/M).ResultsIn two previous papers, we summarized effects of these cytokines on immune-related molecules, and on neural and glial related proteins, including neurotrophins, growth factors and structural proteins. In this paper, we present the effects of the cytokines on molecules involved in metabolism, signaling and regulatory mechanisms in CNS glia. Many of the changes in gene expression were similar to those seen in ischemic preconditioning and in early inflammatory lesions in experimental autoimmune encephalomyelitis (EAE), related to ion homeostasis, mitochondrial function, neurotransmission, vitamin D metabolism and a variety of transcription factors and signaling pathways. Among the most prominent changes, all three cytokine mixtures markedly downregulated the dopamine D3 receptor, while Th1 and Th2 cytokines downregulated neuropeptide Y receptor 5. An unexpected finding was the large number of changes related to lipid metabolism, including several suggesting a switch from diacylglycerol to phosphatidyl inositol mediated signaling pathways. Using QRT-PCR we validated the results for regulation of genes for iNOS, arginase and P glycoprotein/multi-drug resistance protein 1 (MDR1) seen at 6 hours with microarray.ConclusionEach of the three cytokine mixtures differentially regulated gene expression related to metabolism and signaling that may play roles in the pathogenesis of MS, most notably with regard to mitochondrial function and neurotransmitter signaling in glia.

Differential effects of Th1, monocyte/macrophage and Th2 cytokine mixtures on early gene expression for immune-related molecules by central nervous system mixed glial cell cultures.

Cytokines secreted within the central nervous system (CNS) are important in the development of multiple sclerosis (MS) lesions. The balance between Th1, monocyte/macrophage (M/M) and Th2 cytokines in the CNS may be pivotal in determining the outcome of lesion development. We examined the effects of mixtures of cytokines on gene expression by CNS glial cells, as mixtures of cytokines are present in MS lesions, which in turn contain mixtures of glial cells. In this initial analysis by gene array, we examined changes at 6 hours to identify early changes in gene expression that represent primary responses to the cytokines. Rat glial cells were incubated with mixtures of Th1, M/M and Th2 cytokines for 6 hours and examined for changes in early gene expression employing microarray gene chip technology. A minimum of 814 genes were differentially regulated by one or more of the cytokine mixtures in comparison to controls, including changes in expression in a large number of genes for immune system-related proteins. Expression of the proteins for these genes likely influences development and inhibition of MS lesions as well as protective and regenerative processes. Analysing gene expression for the effects of various combinations of exogenous cytokines on glial cells in the absence of the confounding effects of inflammatory cells themselves should increase our understanding of cytokine-induced pathways in the CNS.

A mouse embryonic stem cell model of Schwann cell differentiation for studies of the role of neurofibromatosis type 1 in Schwann cell development and tumor formation

The neurofibromatosis Type 1 (NF1) gene functions as a tumor suppressor gene. One known function of neurofibromin, the NF1 protein product, is to accelerate the slow intrinsic GTPase activity of Ras to increase the production of inactive rasGDP, with wide‐ranging effects on p21ras pathways. Loss of neurofibromin in the autosomal dominant disorder NF1 is associated with tumors of the peripheral nervous system, particularly neurofibromas, benign lesions in which the major affected cell type is the Schwann cell (SC). NF1 is the most common cancer predisposition syndrome affecting the nervous system. We have developed an in vitro system for differentiating mouse embryonic stem cells (mESC) that are NF1 wild type (+/+), heterozygous (+/−), or null (−/−) into SC‐like cells to study the role of NF1 in SC development and tumor formation. These mES‐generated SC‐like cells, regardless of their NF1 status, express SC markers correlated with their stage of maturation, including myelin proteins. They also support and preferentially direct neurite outgrowth from primary neurons. NF1 null and heterozygous SC‐like cells proliferate at an accelerated rate compared to NF1 wild type; this growth advantage can be reverted to wild type levels using an inhibitor of MAP kinase kinase (Mek). The mESC of all NF1 types can also be differentiated into neuron‐like cells. This novel model system provides an ideal paradigm for studies of the role of NF1 in cell growth and differentiation of the different cell types affected by NF1 in cells with differing levels of neurofibromin that are neither transformed nor malignant.

Antibodies to interleukin-1 inhibit cytokine-induced proliferation of neonatal rat Schwann cells in vitro.

Unfractionated cytokines have been shown to induce in vitro proliferation of neonatal rat Schwann cells but the nature of the mitogen(s) is not known. A mixture of rabbit antibodies specific for recombinant interleukin-1 alpha (IL-1 alpha) and interleukin-1 beta (IL-1 beta) inhibited Schwann cell proliferation induced by unfractionated human cytokines whereas antibodies to interleukin-2 (IL-2) and control IgG did not. However, purified human IL-1 and recombinant human IL-1 alpha or beta did not induce Schwann cell proliferation on their own.