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Inflammatory Cytokines IL-1, IL-1ß, IL-6, and TNF- Impart Neuroprotection to an Excitotoxin Through Distinct Pathways¹

Noel G. Carlson^*,§, Whitney A. Wieggel, Jian Chen, Annalisa Bacchi, Scott W. Rogers^*,,§ and Lorise C. Gahring^2,*,,

^* Geriatric Research Education and Clinical Center, Veterans Administration Medical Center, Salt Lake City, UT 84112; Human Molecular Biology and Genetics Program, and Departments of Internal Medicine and ^§ Neurobiology and Anatomy, University of Utah, Salt Lake City, UT 84112

	Abstract

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The proinflammatory cytokines IL-1, IL-1ß, IL-6, and TNF- are produced within the CNS, and, similar to the periphery, they have pleotrophic and overlapping functions. We have shown previously that TNF- increases neuronal survival to a toxic influx of calcium mediated through neuronal N-methyl-D-aspartic acid (NMDA) glutamate-gated ion channels. This process, termed excitotoxicity, is a major contributor to neuronal death following ischemia or stroke. Neuroprotection by this cytokine requires both activation of the p55/TNF receptor type I and the release of TNF- from neurons, and it is inhibited by the plant alkaloid nicotine. Here, we report that other inflammatory cytokines (IL-1, IL-1ß, and IL-6) are also neuroprotective to excessive NMDA challenge in our system. Neuroprotection provided by IL-1 is distinct from TNF- because it is inhibited by IL-1 receptor antagonist; it is not antagonized by nicotine, but it is inhibited by a neutralizing Ab to nerve growth factor (NGF). Similar to IL-1, IL-6-mediated neuroprotection is also antagonized by pretreatment with IL-1 receptor antagonist and it is not affected by nicotine. However, neutralizing anti-NGF only partially blocks IL-6-mediated protection. These studies support an important role for distinct but overlapping neuroprotective cytokine effects in the CNS.

	Introduction

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Many of the inflammatory cytokines commonly associated with the peripheral immune system are also found and produced within the CNS (1, 2, 3, 4). Peripheral sources of CNS cytokines include immune cells such as macrophages, T lymphocytes, and B lymphocytes, but also a variety of other cells such as fibroblasts and keratinocytes. Access of cytokines produced in the periphery to cells in the CNS has been suggested to occur through a variety of routes. First, access of cytokines to the CNS can occur through regions of the brain that possess a poor blood brain barrier (BBB) with fenestrated capillaries from which molecules as large as 500,000 m.w. can escape to adjacent brain parenchymal cells (5). These regions include the circumventricular organs (organum vasculosum of the lamina terminalis, median eminence, subfornical organ, and area prostrema). Second, a saturable transport system has been proposed to allow passage of cytokines through the BBB (6, 7), and finally BBB permeability can increase during systemic inflammatory responses that induce fever and even following epileptic seizure or trauma (8, 9, 10).

Cytokines present in the CNS originate not only from the immune system but also through endogenous production by cells of the brain, including astrocytes and neurons (11) whose production can be stimulated by peripheral cytokines. In the CNS, cytokines exert their function through both traditional engagement of their receptors, which are expressed by both glial and neuronal cells (11, 12, 13, 14), and through less traditional means such as modulation of neurotransmitter receptor function (15, 16). For example, IL-1 modulates -aminobutyric acid-responsive neurotransmitter receptors to enhance inhibitory responses (16). Both IL-1 (17, 18) and IL-6 also modulate synaptic plasticity through inhibiting formation of long-term potentiation (19, 20). Further, we (21) and others (22, 23, 24) have reported that TNF- functions in the CNS to modulate responses of neurons to a class of ionotropic glutamate receptors (GluR) known for their activation by the agonist N-methyl-D-aspartic acid (NMDA).³ Excessive activation of NMDA receptors results in the death of neurons through a process termed excitotoxicity (25, 26). Excitotoxicity is a major pathway (27) of neuronal cell death that is associated with ischemia, trauma, and neurodegenerative diseases and results from an uncontrolled elevation in intracellular calcium that enters the cell through chronically activated NMDA receptors. Agents such as antioxidants, growth factors, and certain cytokines protect against excitotoxicity, either through directly modulating receptor function or indirectly through inhibiting key metabolic steps subsequent to GluR activation. TNF- has been demonstrated to protect cultured neurons against an excitotoxic death induced by the GluR agonist NMDA (21, 23). Further, in an animal model of stroke, mice deficient for TNF- receptors have enhanced sensitivity to ischemic brain damage following arterial occlusion (23), again alluding to the neuroprotective role of TNF- in the brain.

We have previously demonstrated (21) that: 1) the neuroprotective activity of TNF- in cultured cortical neurons is mediated through the p55/TNF receptor type I (TNFRI), 2) the release of TNF- from neurons plays a role in neuroprotection, and 3) the plant alkaloid nicotine inhibits TNF--induced neuroprotection. In this report, we demonstrate that IL-1 (both and ß) and IL-6 are also neuroprotective cytokines. However, the mechanisms of neuroprotection induced by IL-1 and IL-6 are distinct from TNF--induced neuroprotection. These studies support an important role of cytokines in the CNS and suggest that neuroprotective cytokine networks in the CNS function through distinct but overlapping mechanisms.

	Materials and Methods

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Reagents

Recombinant human TNF- (hTNF-), hamster monoclonal anti-p55/TNFRI agonist Ab, and recombinant murine IL-1 were purchased from Genzyme (Cambridge, MA). Recombinant murine IL-Iß and recombinant murine IL-6 were purchased from BioSource International (Camarillo, CA). Mouse monoclonal anti-nerve growth factor (NGF)-neutralizing Ab and the TUNEL apoptosis detection kit were purchased from Boehringer Mannheim (Indianapolis, IN). Rabbit polyclonal (purified IgG) anti-mouse TNF--neutralizing Ab was purchased from Endogen (Cambridge, MA)

Murine IL-1 receptor antagonist (IL-1ra) was a generous gift from Dr. Michael Bienkowski (Department of Cell Biology, Upjohn, Kalamazoo, MI). Nicotine, NMDA, and -bungarotoxin were obtained from Research Biochemical International (Natick, MA). To stain dead cells, ethidium homodimer was used according to the manufacturer’s instructions (Molecular Probes, Eugene, OR).

Cortical cell cultures

Enzymatically dissociated cells from cortices of E14-16 embryos (mouse strain CD1; The Jackson Laboratory, Bar Harbor, ME) were plated onto 35-mm diameter Corning (Corning, NY) culture dishes coated with poly-L-lysine at a density of 1.3 x 10⁶ trypan blue-excluding cells/plate. Cells were plated in 2 ml of MEM with Earle’s salts/5% horse serum (heat-inactivated) and 5% FBS (heat-inactivated) and grown at 37°C in humidified chambers with 5% CO₂. Every 2–3 days, cultures were replenished with growth media (MEM with Earle’s salts/10% horse serum, 30 mM glucose, 2 mM glutamine). Arabinose-cytosine was added for 24 h (final concentration of 10 µM) 7 days after plating to limit growth of mitotic cells. Cultures were allowed to recover for 1 day after feeding before using them in excitotoxicity experiments. Cultures were used between days 16 and 21 after plating.

Excitotoxicity assay

Neuronal cell death was induced by prolonged NMDA (20–25 µM) exposure and quantitated by morphological inspection of three to four fields (200 neurons per field before NMDA) per culture dish before and after NMDA treatment. If lower concentrations of NMDA were applied to cultures, less neuronal death occurred. Our experiments were designed to use an amount of NMDA sufficient to impart 85–90% neuronal death. This paradigm allows for a consistent ability to count viable cells accurately and in turn minimizes sampling variability. In each experiment, the concentration of NMDA required to elicit 85–90% death of neurons was determined just before the actual experiment using an NMDA concentration response curve on cultures from the same cell preparation. Culture dishes were marked with reference points, or etched cover slips were used (CELLocate, Eppendorf), so that the same cell fields could be relocated and photographed before and 20 h after NMDA treatment. The criteria for scoring live cells was verified by assuring that these cells were not positive for staining by either the TUNEL detection stain for apoptosis (Boehringer Mannheim) or the ethidium homodimer dead cell stain (Molecular Probes). Neuroprotective agents or vehicle controls were added directly into the growth media at the final concentrations listed and incubated at 37°C for 24 h (unless otherwise specified), whereupon NMDA was added directly into the same growth media. During the time frame of the experiments (maximum of 48 h), no neuronal death was detected in the absence of NMDA or in the presence of cytokines alone, nicotine alone, or any of the reagents used in these experiments (e.g., anti-NGF or anti-mTNF-). Therefore, the basal level of neuronal survival is defined as 100% and the basal level of death as 0. All values are expressed as a percentage of the total number of cells that were counted in the culture before treatment. Each of the experiments presented was repeated as independent experiments a total of three or more times.

	Results

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The neuroprotective effects of recombinant cytokines against assault by the glutamate receptor agonist NMDA were determined using the assay diagramed in Fig. 1A. Murine cortical cultures were pretreated for 24 h with the agent to be tested (e.g., TNF-) before addition of NMDA. Before the addition of NMDA (25 µM), three to four fields per 35-mm culture were photographed (200 neurons per field), and the cultures maintained with NMDA for 20 h, at which time the same fields in the cultures are again photographed and scored for surviving neurons (see Materials and Methods). In the absence of NMDA, no evidence of cell death was apparent after addition of any of the cytokines (IL-1, IL-1ß, IL-6, or TNF-) over the same time course as determined by: 1) visual inspection as above, 2) ethidium homodimer dye exclusion, and 3) TUNEL analysis to measure apoptosis. This chronic NMDA treatment paradigm results in the death of 85–90% of the neurons, but not monolayer cells consisting mostly of glial cells that lack NMDA receptors. The concentration of NMDA used was deliberately selected to induce high, but not complete, neuronal death (85% of the neurons die, leaving 15% survival). This provides for the accurate quantitation of surviving neurons. Under these conditions, TNF- pretreatment routinely increased the percent of surviving neurons to 25–30% ( Ref. 21 , and below). In Fig. 1B, a subregion of a neuronal field (approximately one-ninth of one field of neurons) was photographed under phase microscopy both before and after treatment with NMDA. Representative live cells are depicted by white arrows (other live cells are also present). Also visible is the monolayer on which the neurons lie.

View larger version (65K): [in this window] [in a new window]   FIGURE 1. Experimental design for neuroprotection assay and the dose-dependent activity of TNF- in this assay. The cytokines tested in this assay (IL-1, IL-1ß, IL-6, or hTNF- at concentrations between 5 and 100 ng/ml) are by themselves not toxic to neurons in the time frame examined (data not shown). This was determined by photographing fields of neurons before the addition of cytokines and the same fields of cells 24 h after the addition of the cytokine. A, Cultured cortical neurons (matured 15–20 days in vitro, see Materials and Methods) were examined for viability and treated with the cytokine to be tested (e.g., TNF-) for 24 h. Before the addition of NMDA (25 µM), four fields of cells are photographed and counted, and these same fields were photographed and counted 20 h later. Neuronal survival following NMDA treatment is expressed as percent (%) survival that equals: [(the number of live neurons counted after NMDA)/(the number of live neurons present before NMDA)] x 100. B, Phase microscopy of murine cortical neurons in culture before and 20 h after the addition of 25 µM NMDA. This field of neurons represents approximately one-ninth of a field of neurons in the schematic above. White arrows indicate examples of some neurons that survived the NMDA treatment. C, Concentration-dependent response of neuronal cultures to TNF-. Cultures were treated with between 5 and 200 ng/ml of hTNF- for 24 h before the addition of NMDA. Control cultures were treated with the vehicle for TNF- (Veh, 0.9% saline). Neuronal fields were photographed and counted (no difference in viability between Veh and TNF--treated cultures was detected) and then treated with NMDA for 20 h. Neuronal survival following NMDA was determined to be optimal using 100 ng/ml of TNF- and significantly (**, p < 0.01) better than vehicle-treated. *, p < 0.05.

Other inflammatory cytokines have been tested for their neuroprotective properties. IL-1, IL-1ß, or IL-6 when added to neuronal cultures 24 h before the addition of NMDA were also neuroprotective (Fig. 2). This observation lead us to test the relatedness of mechanisms through which these individual cytokines induce neuroprotection. Cultured neurons express TNF-, as measured by immunocytochemistry, and this immunoreactivity diminishes upon stimulation with hTNF- (or anti-p55/TNFRI agonist Ab), consistent with release of mature TNF- (11, 21). Further, TNF--induced neuroprotection is blocked by addition of an anti-mouse-specific TNF--neutralizing Ab to cultures immediately before p55/TNFRI activation. Therefore, we determined whether neuroprotection conferred by IL-1, IL-1ß, or IL-6 also required the release of murine TNF-. To test this possibility, neutralizing Ab to mouse TNF- was added to cultures 1 h before the addition of either IL-1, IL-1ß, or IL-6. Concentrations of anti-mouse TNF--neutralizing Ab, sufficient to block neuroprotection by hTNF- (21) or p55/TNFRI agonist Ab (Fig. 3), had no effect on the neuroprotection conferred by IL-1, IL-1ß, or IL-6 (Fig. 3). This indicates that IL-1 and IL-6 are not dependent on mTNF- for their neuroprotective effects.

View larger version (43K): [in this window] [in a new window]   FIGURE 2. Induction of neuroprotection by IL-1( and ß) and IL-6. hTNF- (100 ng/ml), murine IL-1 (10–50 ng/ml), murine IL-1ß (10–50 ng/ml), or murine IL-6 (2.5–10 ng/ml) was added to neuronal cultures 24 h before the addition of NMDA (25 µM), as described in Fig. 1. Neuronal survival was determined for each concentration of cytokine and compared with that observed in vehicle-treated cultures (Veh). None of the cytokines tested induced cell death in the absence of NMDA over the 48 h of this assay. Neuroprotection was optimal and significant with IL-1 at 25–50 ng/ml (**, p < 0.01), IL-1ß at 25–50 ng/ml (**, p < 0.01), and IL-6 at 10 ng/ml (**, p < 0.01). In experiments described subsequent to this, we therefore chose to use IL-1 and IL-1ß at 25 ng/ml and IL-6 at 10 ng/ml). *, p < 0.05.

View larger version (35K): [in this window] [in a new window]   FIGURE 3. The effect of a neutralizing Ab to mouse TNF- on neuroprotection induced by TNF- agonist Ab, IL-1 ( or ß), or IL-6. Neutralizing anti-mouse TNF- (-mTNF-, 10 µg/ml) was added to cultures 1 h before the addition of either vehicle (Veh, saline), anti-p55/TNFRI (TNFRI) agonist Ab, IL-1 (25 g/ml), IL-1ß (25 ng/ml), or IL-6 (10 ng/ml). Neutralizing anti-mouse TNF- had no effect by itself on neuronal survival, inhibited neuroprotection induced by the anti-p55/TNFRI agonist Ab, but did not affect neuroprotection induced by IL-1, IL-1ß, or IL-6. **, p < 0.01; *, p < 0.05.

View larger version (35K): [in this window] [in a new window]   FIGURE 4. The effect of IL-1ra on neuroprotection induced by IL-1, IL-6, or TNF-. IL-1ra (100 µg/ml) added to neuronal cultures had no effect on viability either in the absence (data not shown) or presence of NMDA relative to controls. IL-1ra was added 1 h before the addition of TNF- (100 ng/ml), IL-1 (25 ng/ml), IL-1ß (25 ng/ml), or IL-6 (10 ng/ml). NMDA was added to cultures 24 h after the addition of cytokines and neuronal viability determined as described in Fig. 1. Significant neuroprotection was induced with all of the cytokines. **, p < 0.01; *, p < 0.05.

View larger version (33K): [in this window] [in a new window]   FIGURE 5. Neutralization of NGF inhibits neuroprotection induced by IL-1 or IL-6. Neutralizing anti-NGF Ab was added to cultures 30 min before the addition of TNF- (100 ng/ml), IL-1ß (25 ng/ml), or IL-6 (10 ng/ml) followed by 25 µM NMDA 24 h following cytokine addition. The optimal concentration of anti-NGF-neutralizing Ab was determined using IL-1ß as a positive neuroprotective cytokine whose activity was known to be inhibited by this reagent (data not shown). Anti-NGF (NGF, 50 ng/ml)-neutralizing Ab by itself had no effect on NMDA-induced cell death. IL-1ß-induced neuroprotection was inhibited by the addition of anti-NGF, and IL-6-induced neuroprotection was partially inhibited. This experiment has been repeated at least three times. **, p < 0.01; *, p < 0.05.

View larger version (38K): [in this window] [in a new window]   FIGURE 6. Nicotine inhibits neuroprotection induced by TNF-, but not IL-1 ( or ß) or IL-6. A total of 10 µM of nicotine added 24 h before the addition of NMDA is also neuroprotective but blocks neuroprotection induced by TNF- (21 ). The optimal concentration of nicotine for these experiments was previously determined (21 ). Nicotine (10 µM) was added just before the addition of hTNF- (100 ng/ml), mouse IL-1 (25 ng/ml), mouse IL-1ß (25 ng/ml), or mouse IL-6 (10 ng/ml). Nicotine (10 µM) inhibited only neuroprotection induced by TNF- (n = 3). **, p < 0.01; *, p < 0.05.

	Discussion

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Of note is the finding that nicotine inhibits TNF--induced, but not IL-1- or IL-6-induced neuroprotection. Nicotine stimulates neurons via activation of nAChRs and, specifically for neuroprotection, those nAChR composed of 7 subunits (31, 32). Activation of this ligand-gated ion channel induces a flux of calcium into the cell as well as other intracellular events (40, 41, 42, 43). How these intracellular events interfere with TNF--induced effects is unknown. Numerous signal transduction pathways activated by TNF- through p55/TNFRI have been reported (44, 45, 46, 47, 48). For example, TNF- stimulates sphingomyelinase(s) activity to enhance the hydrolysis of sphingomyelin to ceramide and sphingosine (49, 50). In fact, ceramide is a major mediator of TNF--induced cellular events (51), and cell permeable analogues of ceramide can mimic the effect of TNF- and confer neuroprotection to ß-amyloid toxicity (52, 53). IL-1 has also been shown to generate ceramide (54, 55), but it is not yet known if ceramide generated subsequent to IL-1 receptor activation contributes to neuroprotection. However, phospholipase A2-associated release of arachidonic acid and metabolism by lipoxygenase accompanying activation of the IL-1 receptor has been shown to play an integral part in IL-1 stimulation of NGF secretion in astrocytes in culture (56).

Since TNF- has been shown by many groups (1, 2, 3, 4, 45) to induce IL-1 and IL-6 production in peripheral cells, why is IL-1 or IL-6 neuroprotection not conferred subsequent to TNF- stimulation? First, the TNF--stimulated protein production may not be temporally compatible with the likely narrow window in which these cytokines must function to impart protection (21). Second, normal caspase (e.g., IL-1 converting enzyme) activation could be altered in our system, resulting in inappropriate protein processing or release. This latter point is particularly crucial when examining inflammatory cytokine function in cellular systems, since cytokine-mediated neuroprotection does not occur when concentrations are either too low or too high. Resolution of these issues will await further kinetic and biochemical analysis of the pathways defined in this report.

This study outlines the beneficial effects of IL-1 and IL-6 in promoting neuronal survival in an in vitro system. There are, however, numerous studies in vivo indicating that these cytokines may have a deleterious effect on neuronal survival. Notably, most of these reports are in the context of pathological conditions such as cerebral ischemia, where the expression of both IL-1 and IL-6 is induced and the increased expression of IL-1 appears to contribute to neuronal death (57). Further, increased expression of IL-1ra can be neuroprotective in some instances (1, 2, 58). In contrast to our studies, where we see IL-1 as a neuroprotective agent, the concentrations of IL-1 are considerably higher when used as an agent of neuronal death. Further, while IL-6 has also been reported by others to diminish excitotoxic neuronal death in vitro (59) and in vivo following cerebral ischemia (60), in transgenic animals, overexpressioning IL-6 pathogenic alterations in the CNS are readily apparent (61, 62, 63). These findings underscore the importance of understanding the effects of CNS cytokines and cytokine networks in various physiological contexts, including the presence and identity of participating cytokines, their concentration, and their participation in neurotransmitter function.

	Footnotes

 
¹ This work was supported by a Department of Veterans Affairs Merit grant (to L.C.G.), National Institutes of Health Grants RO1AA11418 (to L.C.G.) and RO1NS35181 (to S.W.R.), and the Val A. Browning Foundation of Utah.

² Address correspondence and reprint requests to Dr. Lorise C. Gahring, Human Molecular Biology and Genetics Program, 15 North 2030 East Room 2100, University of Utah School of Medicine, Salt Lake City, UT 84112-5330. E-mail address:

³ Abbreviations used in this paper: NMDA, N-methyl-D-aspartic acid; TNFRI, TNF receptor type I; hTNF-, human TNF-; NGF, nerve growth factor; IL-1ra, IL-1 receptor antagonist; nAChR, nicotinic acetylcholine receptor.

Received for publication April 19, 1999. Accepted for publication July 14, 1999.

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