Null Mutation of c-fos Causes Exacerbation of Methamphetamine-Induced Neurotoxicity

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The Journal of Neuroscience, November 15, 1999, 19(22):10107-10115

Null Mutation of c-fos Causes Exacerbation of Methamphetamine-Induced Neurotoxicity
Xiaolin Deng, Bruce Ladenheim, Li-I Tsao, and Jean Lud Cadet
Molecular Neuropsychiatry Section, National Institute on Drug Abuse Intramural Research Program, Baltimore, Maryland 21224

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Methamphetamine neurotoxicity has been demonstrated in rodents and nonhuman primates. These neurotoxic effects may be associatedwith mechanisms involved in oxidative stress and the activationof immediate early genes (IEG). It is not clear, however, whetherthese IEG responses are involved in a methamphetamine-inducedtoxic cascade or in protective mechanisms against the deleteriouseffects of the drug. As a first step toward clarifying this issuefurther, the present study was thus undertaken to assess the toxiceffects of methamphetamine in heterozygous and homozygous c-fosknock-out as well as wild-type mice. Administration of methamphetaminecaused significant reduction in [¹²⁵I]RTI-121-labeled dopamine uptake sites, dopamine transporterprotein, and tyrosine hydroxylase-like immunohistochemistry inthe striata of wild-type mice. These decreases were significantlyexacerbated in heterozygous and homozygous c-fos knock-out mice,with the homozygous showing greater loss of striatal dopaminergicmarkers. Moreover, in comparison with wild-type animals, bothgenotypes of c-fos knock-out mice showed more DNA fragmentation,measured by the number of terminal deoxynucleotidyl transferase-mediateddUTP nick-end-labeled nondopaminergic cells in their corticesand striata. In contrast, wild-type mice treated with methamphetaminedemonstrated a greater number of glial fibrillary acidic protein-positivecells than did c-fos knock-out mice. These data suggest that c-fosinduction in response to toxic doses of methamphetamine mightbe involved in protective mechanisms against this drug-inducedneurotoxicity.

Key words: methamphetamine; neurotoxicity; c-fos mutant; glial fibrillary acidic protein; DNA fragmentation; cell death; apoptosis

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Methamphetamine (METH) is an illicit drug that is abused throughout the world (Miller, 1991; Greberman and Wada, 1994; Shaw,1999). The acute administration of this agent can cause neuropsychiatriccomplications including psychosis, coma, and death (Lan et al.,1998). Abrupt cessation of use can cause withdrawal symptoms akinto a suicidal depressive state (Murray, 1998). Although the acuteeffects of the drug might be caused by increases in the levelsof synaptic dopamine (DA) (Stephans and Yamamoto, 1995), the long-termeffects might be secondary to persistent perturbations in monoaminergicsystems (Cadet and Brannock, 1998). For example, the administrationof METH can cause marked depletion of dopaminergic or serotonergicmarkers in rodents (Ricaurte et al., 1982; Matsuda et al., 1988;O'Callaghan and Miller, 1994; Hirata and Cadet, 1997a,b; Fukumuraet al., 1998), nonhuman primates (Villemagne et al., 1998), andhuman METH users (Wilson et al., 1996; McCann et al., 1998).

Several laboratories are actively seeking to decipher the cellular and molecular mechanisms of METH-induced neurotoxicity.A consensus has been built that indicates that superoxide radicals,hydrogen peroxide, and hydroxyl radicals (De Vito and Wagner,1989; Cadet et al., 1994; Giovanni et al., 1995; Hirata et al.,1996, 1998b; Fumagalli et al., 1998, 1999; Itzhak et al., 1998a;Jayanthi et al., 1998; Yamamoto and Zhu, 1998) as well as nitricoxide (Itzhak and Ali, 1996; Sheng et al., 1996c; Itzhak et al.,1998b) might play major roles in METH toxicity. However, becausethe formation of reactive species is associated with complex pathophysiologicalchanges, much remains to be done to understand fully the mechanismsinvolved in the pathobiological substrates induced by this drug.This laboratory has conducted studies aimed at elucidating possibleroles of immediate early genes (IEGs) and their relationshipsto METH-mediated free radical production (Sheng et al., 1996a,b;Asanuma and Cadet, 1998; Hirata et al., 1998a). These investigationshave documented an association between METH-induced superoxideradical production and IEG activation because transgenic micethat overexpress the antioxidant enzyme CuZn superoxide dismutase(SOD) showed marked attenuation of these IEG responses, includingc-fos- (Hirata et al., 1998a) and AP-1-binding activity (Shenget al., 1996a,b). On the basis of these results, however, it isnot clear whether METH-associated c-fos induction results in eitherprotoxic or protective events. A protective role for c-fos issupported by the demonstration that cells, which do not expressc-fos, are more sensitive to DNA-damaging agents (Haas and Kaina,1995; Kaina et al., 1997). c-fos has also been shown to be importantfor activating some neurotrophic and/or neuroprotective factors(Herdegen and Leah, 1998).

The existence of a null mutation of c-fos in mice (Johnson et al., 1992; Wang et al., 1992) offers a system in which the roleof c-fos in drug-induced neurodegeneration can be investigated.We, thus, used these mutant mice to assess METH-induced deleteriouseffects in the brain. We now report that the neurotoxicity ofMETH on both dopaminergic and nondopaminergic systems is exacerbatedin heterozygous (+/ $-$ ) and homozygous ( $-$ / $-$ ) c-fos mutantmice.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals, drug treatment, and temperature measurement. Homozygous (Homo; $-$ / $-$ ) and heterozygous (Het; +/ $-$ ) c-fos knock-out aswell as wild-type (WT; +/+) mice obtained from The Jackson Laboratory(Bar Harbor, ME) were used in these experiments. The generationand derivation of these mice have been described previously indetail (Johnson et al., 1992). All animal use procedures wereaccording to the National Institutes of Health Guide for the Careand Use of Laboratory Animals and were approved by the local animalcarecommittee.

Homo, Het, and WT mice were given four injections of 10 mg/kg METH or saline at 2 hr intervals. Similar protocols of METHadministration have been used extensively by us (Hirata et al.,1996) and others (Pu and Vorhees, 1995; Fumagalli et al., 1998).Core body temperature was able to be recorded in WT and +/ $-$ c-fosmice at 30 min intervals by the use of a mouse rectal probe (YSI,Yellow Springs, OH), whereas $-$ / $-$ c-fos mice were very susceptibleto rectal injury and did not survive this procedure in conjunctionwith METH administration. The mice were killed at various timepoints after drug treatment. Brain tissues were processed forthe various assays as describedbelow.

Autoradiographic assays. Binding assays for DA transporters (DAT) were performed essentially as described previously by thislaboratory with [¹²⁵I]RTI-121 (specific activity, 2200 Ci/mmol) and 10 µM GBR-12909to determine nonspecific binding (Hirata et al., 1996; Asanumaet al., 1998). [¹²⁵I]RTI-121 binding in striatum was quantified using a Macintoshcomputer-based image analysis system (Image, NIH) with standardcurves generated from ¹²⁵Imicroscales.

Tyrosine hydroxylase and glial fibrillary acidic protein immunohistochemistry. The animals were perfused transcardially, underdeep pentobarbital anesthesia, first with saline followed by 40ml of 4% paraformaldehyde in 0.1 M phosphate buffer at 4°C. Thebrains were removed, post-fixed overnight in 4% paraformaldehyde,and then allowed to equilibrate in 30% sucrose for 24 hr. Thirtymicrometer coronal sections were then cut in a cryostat (BrightInstrument Company, Huntindon, United Kingdom). Free-floatingsections containing striatal areas were used for tyrosine hydoxylase(TH) and glial fibrillary acidic protein (GFAP) immunostaining.Briefly, sections were exposed to 1% hydrogen peroxide for 20min and then incubated for 30 min in 1% bovine serum albumin and0.3% Triton X-100, followed by incubation with either the TH (Calbiochem,La Jolla, CA; polyclonal; 1:5000) or GFAP (Novo Laboratories;monoclonal; 1:100) primary antibody. Subsequent processing withbiotinylated secondary antibody and ABC complex was performedaccording to the manufacturer's procedures described in the ABCkit (Vector Laboratories, Burlingame, CA). The free-floating sectionswere then reacted with 3,3'-diaminobenzidine (DAB) and hydrogenperoxide to visualize the peroxidase reaction. At the end of thereaction, the sections were mounted on microscope slides for furthervisualization andanalysis.

To measure the relative intensity of TH-immunoreactivity (TH-IR), we collected striatal image from each photomicrograph usingAdobe Photoshop. Image analysis of optical density (arbitraryunit) used the computer-based program NIH Image. A similar approachto the assessment of TH-IR fiber density has been validated previouslyusing 6-hydroxydopamine-induced destruction of nigrostriatal DApathways in the rat (Burke et al., 1990). In that report, it wasshown that there was a significant correlation between circlingbehavior and the density of TH fibers measured by image analysis.Subsequently, that approach was used to demonstrate increasedTH-IR fiber density after perinatal asphyxia (Burke et al., 1991).GFAP-positive astrocytes were counted in randomly chosen striatalsubfields (600 × 900 µm). TH and GFAP immunohistochemistry datawere obtained from six sections per animal (five to eight animalsper group). Statistical analyses are describedbelow.

Western blot. Analysis of DAT protein concentration in the striata of c-fos knock-out and WT mice was performed by Westernblot (Fumagalli et al., 1999). Briefly, dissected striata werehomogenized in a buffer containing 320 mM sucrose, 5 mM HEPES,1 µg/ml leupeptin, 1 µg/ml aprotinin, and 1 µg/ml pepstatin. Homogenateswere centrifuged at 2000 × g for 5 min, and the supernatant fractionwas subsequently centrifuged at 30,000 × g for 30 min. The resultingpellet was resuspended in the sample buffer (62.5 mM Tris-HCl,20% glycerol, 2% SDS, 0.01% bromphenol blue, and 1 mM dithiothreitol)and subjected to SDS-PAGE (10%). Proteins were electrophoreticallytransferred to a polyvinylidene difluoride (PVDF) membrane, andnonspecific sites were blocked in 5% nonfat dry milk in Tris-bufferedsaline (135 mM NaCl, 2.5 mM KCl, 50 mM Tris, and 0.1% Tween 20,pH 7.4). Membranes were then incubated in the presence of a polyclonalantibody to the N terminus of DAT (DAT-Nt) (Chemicon, Temecula,CA; 1:500) in Tris-buffered saline. DAT antibody binding and chemiluminescenceenhancement were performed using the ECL Western blotting analysissystem (Pharmacia, Piscataway, NJ). Densitometric analysis wasperformed and calibrated to coblotted dilutional standards ofcontrol striatum. Blots were then stripped for 20 min at 80°C(8 M urea, 100 mM 2-mercaptoethanol, and 62.5 mM Tris, pH 6.8)and reprobed with an antibody to $alpha$ -tubulin (Sigma, St. Louis,MO; 1:2000).

Terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling histochemistry. A standard terminal deoxynucleotidyltransferase-mediated dUTP nick-end labeling (TUNEL) procedurefor frozen tissue sections was performed according to the manufacturer'smanual (Boehringer Mannheim, Indianapolis, IN). Briefly, slide-mountedsections were rinsed in 0.3% hydrogen peroxide-methanol to blockendogenous peroxidase. They were then rinsed in 0.1% Triton X-100in 0.1% sodium citrate for 2 min on ice to increase permeabilizationof the cells. To label damaged nuclei, 50 µl of the TUNEL reactionmixture was added onto each sample in a humidified chamber followedby a 60 min incubation at 37°C. The peroxidase reaction was visualizedwith DAB-substrate solution. Procedures for negative controlswere performed as described in the manufacture's manual and consistedof not adding the label solution (terminal deoxynucleotidyl transferase)to the TUNEL reaction mixture. No TUNEL-positive cells were observedin the negative controls. TUNEL-positive cells were counted inthe frontal cortex and striatum using a Zeiss microscope (600× 900 µm).

Statistical analyses. All data are presented as means ± SEM. The data were analyzed by ANOVA followed by Fisher's protectedleast significant difference test using the statistical programStatview 4.02. Criteria for significance were set at the 0.05level.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

[¹²⁵I]RTI-121-binding autoradiography and Western blotting for DAT

To test the long-term toxic effects of METH on DA terminals in these mice, we performed DAT binding on coronal sections usingreceptor autoradiographic technique and Western blot analysisof DATprotein.

Representative photomicrographs of [¹²⁵I]RTI-121-labeled DAT in the striata are shown in Figure 1. The intensity of binding issimilar in saline-injected animals from the three genotypes (Fig.1A-C). As expected from our previous results (Hirata and Cadet,1997b; Tsao et al., 1998), METH injections caused marked decreasesin the intensity of labeling in the striata of mice killed 1 weekafter drug treatment. The METH-induced decreases were more apparentin the c-fos knock-out mice (compare Fig. 1F with D,E). Figure1G shows the quantitative data obtained from the image analysis.There was no significant difference in [¹²⁵I]RTI-121-labeled DAT among animals of the three genotypes treatedwith saline. Injections of METH caused marked decreases in striatal[¹²⁵I]RTI-121-labeled DAT in the three genotypes, with the Het andHomo c-fos knock-out mice showing somewhat greater loss of binding.For example, METH caused ~72.7, 79.1, and 87.0% loss of DAT bindingin WT, Het, and Homo c-fos mice, respectively.

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Figure 1. A-F, Effects of METH on [¹²⁵I]RTI-121-labeled striatal DA uptake sites in WT (A, D), heterozygous (B, E), and homozygous (C, F) c-fos mutant mice. Animals received saline (A-C) or METH (D-F) as described in Materials and Methods. They were killed 1 week after drug treatment. [¹²⁵I]RTI-121-binding density is similar in the three saline-treated genotypes (A-C). METH administration caused marked reduction of DA uptake sites (D-F), with the greatest decreases occurring in c-fos $-$ / $-$ mice (F). G, The results of the statistical analyses of the quantitative data obtained from the image analyses. Values represent means ± SEM of five to eight animals per group. Key to statistics: *p < 0.0001 in comparison with saline-treated mice of similar genotypes; ! p < 0.05, and !!p < 0.0001 in comparison with METH-treated WT mice.

DAT binding reflects interaction of the radioactive ligand [¹²⁵I]RTI-121 with its binding site on the DAT protein. This mightnot necessarily reflect the concentration of protein or loss ofDA terminals because a number of factors including redox statuscan affect the interaction of receptors with their ligands. Thus,a rapid decrease in DAT function has been reported after METHadministration, at a time when there is no evidence of loss ofDA terminals (Fleckenstein et al., 1997). This loss of functionhas been attributed to the production of superoxide radicals (Fleckensteinet al., 1997). Therefore, the concentration of DAT protein wasmeasured by the use of Western blotting. These experiments showedno significant differences in DAT protein levels between the saline-injectedWT, +/ $-$ , and $-$ / $-$ c-fos knock-out mice (Fig. 2). Administrationof METH reduced the DAT protein expression by 44.6, 57.9, and78.8% in WT, +/ $-$ , and $-$ / $-$ c-fos mutant mice, respectively. Fumagalliet al. (1999) have also reported significant METH-induced decreasesin DAT protein.

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Figure 2. Representative immunoblot of the effects of METH on DAT protein concentration. Lanes 1, 3, 5, From saline-injected +/+, +/ $-$ , and $-$ / $-$ c-fos mutant mice, respectively. Lanes 2, 4, 6, From METH-injected +/+, +/ $-$ , and $-$ / $-$ c-fos knock-out mice, respectively. There were significant changes in DAT concentration consisting of 44.6 ± 4.7, 57.9 ± 6.8, and 78.8 ± 5.3% decreases in +/+, $-$ / $-$ , and $-$ / $-$ c-fos knock-out mice, respectively. $alpha$ -Tubulin is also shown and reveals similar loading for all groups (6 mice per group). Nt, Antibody against N terminus of the protein.

TH immunohistochemistry

The use of DAT binding and Western blotting, described above, reflects events at the level of striatal DA terminals that mightnot necessarily reflect the integrity (or lack thereof) of DAaxons. Thus, to test further the toxic effects of METH on thestriatal dopaminergic system, we also used TH immunohistochemistryto examine the architecture and density of DA fibers in mice killed1 week aftertreatment.

Representative striatal sections for TH-IR are shown in Figure 3. In the control groups, densely stained and closely packedTH-positive nerve processes are observed throughout the striataof all three genotypes (Fig. 3A,C,E). In mice killed 1 week afterthe last injection of the drug, there was a marked reduction inTH staining that led to a looser-distributed TH fiber network(Fig. 3B,D,F). These changes were much more evident in $-$ / $-$ c-fosknock-out mice, which showed a very substantial reduction in TH-IRin their striata (Fig. 3F). Figure 3G shows the quantificationof METH-induced TH staining by the Image program. There was nosignificant difference in the density of TH fibers between animalsfrom the three genotypes injected with saline. However, therewere marked differences in the toxic effects of METH between thethree genotypes, with the $-$ / $-$ c-fos knock-out showing the greatestdecreases. For example, in comparison with mice of the same genotypeinjected with saline, the optical density of fibers that remainedTH-positive after METH treatment were ~79.0, 60.3, and 23.6% in+/+, +/ $-$ , and $-$ / $-$ c-fos knock-out mice, respectively. Those resultsare somewhat parallel to those obtained for DAT protein, as reportedabove.

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Figure 3. Effects of METH on TH-like immunoreactivity in mice. A-F, Animals were treated with either saline (A, C, E) or METH (B, D, F) 1 week after drug treatment as described in Materials and Methods. The intensity of staining is comparable in the saline-treated mice of the three genotypes (A, C, E). METH administration caused a visually obvious reduction of TH staining (B, D, F), which was more severe in homozygous c-fos knock-out mice (F). G, The results of the statistics for the semiquantitative data obtained using image analysis are shown. Values represent means ± SEM of five to eight animals (6 sections per animal) per group. Key to statistics: *p < 0.001, and **p < 0.0001 in comparison with saline-treated mice of similar genotypes; !p < 0.001, and !!p < 0.0001 in comparison with METH-treated WT mice. Scale bar, 100 µm.

TUNEL histochemistry in the frontal cortex and the striatum

The data about DAT and TH reflect the typical toxic effects of METH on striatal dopaminergic systems. Recently, however, ithas been reported that METH can cause apoptosis both in vitro(Cadet et al., 1997; Stumm et al., 1999) and in vivo (Iwasa etal., 1996). Thus, to assess the time course of possible METH-inducedDNA fragmentation, detected by the TUNEL reaction, we used animalskilled at 3 d and at 1 week after drug treatment. These time pointscorrespond to times used previously by us (Hirata and Cadet, 1997a,b)and others (Pu et al., 1996; Sonsalla et al., 1996) to assessthe toxic effects of METH mostly on dopaminergic systems. In thecase of apoptotic DNA fragmentation, it is important to assessearly time points because cells undergoing apoptosis might beremoved by endogenous phagocytes and microglias before the damagedcells can lyse and spill their contents into surrounding areas.Removal of these cells helps to preserve the functional integrityof the surrounding tissue (Ferrer et al., 1995; Sonnenfeld andJacobs, 1995). Thus, attempts to detect and quantify cells withdouble-stranded DNA breaks at much later time points might beunsuccessful because the presence of these changes might haveoccurred much earlier after a course of drugtreatment.

As is observed in Figures 4, 5, and 6, very few TUNEL-positive cells are seen in the frontal cortices and the striata of animalsfrom the three genotypes injected with saline. However, the administrationof doses of METH that are known to cause significant perturbationin dopaminergic systems (Hirata and Cadet, 1997b) (see above)caused marked increases in TUNEL-positive staining in nondopaminergiccells in the cortex and striatum at both time points used in thepresent study. In addition, the increases were more prominentat the 3 d time point (Figs. 4-6). Counterstaining with toluidineblue indicated that the TUNEL-positive cells were of neuronalorigin (data not shown).

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Figure 4. Representative photomicrographs of TUNEL-stained frontal cortices of mice. Very few positive cells appeared in the frontal cortices of saline-treated mice of the three genotypes (A, D, G). METH caused marked increases in TUNEL-positive cells at 3 d (B, E, H) and 1 week (C, F, I) after drug treatment. The arrows point to typical positive cells. These photomicrographs were generated by using a Carl Zeiss Laser Scanning Confocal System with Axiovert 135-inverted microscopy. The objective lens was 40×. Quantitative data are provided below (see Fig. 6).

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Figure 5. Representative photomicrographs of TUNEL-stained striata of mice. Very few positive cells could be seen in the striata of saline-treated mice (A, D, G). As in the cortex, METH caused marked increases in TUNEL-positive cells at 3 d (B, E, H) and 1 week (C, F, I). The arrows point to typical positive cells. The photomicrographs were generated as described in Figure 4. Quantitative data are provided below (see Fig. 6).

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Figure 6. METH caused greater increases in TUNEL-positive cells in the frontal cortex and striatum of c-fos knock-out than in WT mice. The animals were treated and the brains were processed as described in Materials and Methods. Values represent means ± SEM of five to eight mice per group. Key to statistics: *p < 0.05, **p < 0.001, and ***p < 0.0001 in comparison with METH-treated WT mice killed at similar time points; !p < 0.05, !!p < 0.001, and !!!p < 0.0001 in comparison with saline-treated mice of similar genotypes.

Quantification of these changes revealed that, at the 3 d time point, METH caused ~5.2-, 10.2-, and 17.1-fold increases inTUNEL-positive cells in the cortices of +/+, +/ $-$ , and +/ $-$ c-fosmice, respectively; these increases at 1 week were ~2.7-, 5.0-,and 9.3-fold, respectively. A recent paper has also reported thatdegenerating Fluoro-Jade-positive nondopaminergic neurons in therat cortex occurred in the greatest number at 3 d after METH treatment(Eisch et al., 1998). In the striatum, at the 3 d time point,the changes were ~5.0-, 7.3-, and 10.8-fold in the +/+, +/ $-$ , and $-$ / $-$ c-fos knock-out mice, respectively; at 1 week, these increaseswere 2.8-, 4.3- and 6.0-fold, respectively (Fig. 6).

GFAP immunohistochemistry

Increased gliosis has been reported after a number of toxic injuries to brain (Norton et al., 1992). Similar results havebeen observed after METH administration to rodents (Pu and Vorhees,1995; Fukumura et al., 1998). We, thus, sought to determine whetherMETH-induced toxicity would be associated with reactive gliosisin the present model. A few small GFAP-positive astrocytes wereobserved in the brains of mice from all three genotypes injectedwith saline (Fig. 7A,C,E). These astrocytes are characterizedby small cell bodies and very fine and short processes. As reportedpreviously (Pu and Vorhees, 1995; Fukumura et al., 1998), METHtreatment causes marked increases in the number of astrocytesin the striata of mice killed 1 week after drug treatment (Fig.7B,D,F). The METH-induced astrocytes in the wild-type mice werecharacterized by large densely stained cell bodies as well aslonger and extensive processes (Fig. 7B). However, the METH-inducedastrocytes in the +/ $-$ and $-$ / $-$ c-fos knock-out mice did not showmuch of an increase in their size, in the number of processes,or in the intensity of GFAP staining (compare Fig. 7B with D,F).Moreover, the number of METH-induced astrocytes in the striataof the c-fos knock-out mice was less than the number in the WTmice. Figure 7G shows the quantitative data and revealed thatthe increases in METH-induced glial cells showed a gene-dosagephenomenon, with the heterozygous and homozygous c-fos knock-outmice showing respective changes that were 77.4 and 48.1% of thoseobserved in wild-type mice.

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Figure 7. A-F, Effects of METH on GFAP-like immunohistochemistry in the striata of +/+ (A, B), +/ $-$ (C, D), and $-$ / $-$ (E, F) c-fos knock-out mice. A few small positive astrocytes are seen in the striata of saline-treated mice (A, C, E). METH caused marked increases in the number of astrocytes in the striatum in mice killed 1 week after drug treatment (B, D, F). METH-induced astrocytes were hypertrophic and densely stained in the WT mice (B). However, in the c-fos +/ $-$ (D) and $-$ / $-$ (F) mice, METH treatment caused a measurable increase in the number of astrocytes, but these were small in size and weakly stained. The arrows point to typical positive cells. G, The statistical analyses of the data obtained from the counts of GFAP-positive cells in the striatum. Values represent means ± SEM from five to eight animals (6 sections per mouse) per group. Key to statistics: *p < 0.0001 in comparison with saline-treated mice of similar genotypes; !p < 0.01 in comparison with METH-treated WT mice. Scale bar, 100 µm.

Temperature fluctuation

Because it has been reported that METH neurotoxicity is generally related to increases in core body temperature (Bowyer etal., 1992; Miller and O'Callaghan, 1994), we measured the effectsof METH on these mice. Figure 8 shows that METH caused increasesof core body temperature from 37.2 to ~39.5°C both in WT and +/ $-$ c-fos knock-out mice. Statistical analyses revealed no significantdifferences between the wild-type and heterozygous mice.

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Figure 8. Effects of METH on core temperature in WT and heterozygous c-fos mutant mice. Core temperature was recorded in animals every 30 min during the administration of METH. Values represent means ± SEM from seven mice per group. There were no statistical differences in the METH-induced temperature elevation between the two genotypes of mice. Saline-treated animals did not exhibit changes in core body temperature over time (data not shown for the sake of clarity). Recorded ambient temperature was between 20.5 and 21.2°C.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The main finding of this study is that METH neurotoxicity is exacerbated in c-fos mutant mice. This is supported by the followingobservations. First, METH caused greater depletion of markersof dopaminergic systems in the striata of +/ $-$ and $-$ / $-$ c-fos knock-outmice, with markers at the levels of DA terminals (DAT bindingand DAT protein) being more severely affected by METH. Second,METH-induced DNA fragmentation, measured by TUNEL-positive cells,was also more prominent in nondopaminergic cells of the corticesand striata of these c-fos mutant mice. It should be noted thatthis is the first demonstration, using the TUNEL approach, thatMETH can cause apoptotic DNA fragmentation in the brain. Theseresults are consistent with both in vitro (Cadet et al., 1997;Stumm et al., 1999) and in vivo (Iwasa et al., 1996) studies showingthat METH can cause cell death via an apoptoticprocess.

Increased core body temperature has been reported to play a role in METH neurotoxicity (Bowyer et al., 1992, 1994; Millerand O'Callaghan, 1994; LaVoie and Hastings, 1999). Although mostdrugs that cause hypothermia tend to offer protection againstMETH-induced damage (Ali et al., 1994; Albers and Sonsalla, 1995),treatment with reserpine, a well known hypothermic agent, hasactually been reported to exacerbate METH-induced toxicity (Wagneret al., 1983). When taken together, these data suggest that increasedtemperature is one participant in a complex series of events thatcause the toxicity of METH. In the present experiments, we didexamine the possible contribution of temperature in the exacerbationof METH-induced damage in the c-fos mutant mice; however, becausethere were no significant differences in temperature elevationbetween WT and +/ $-$ c-fos mice, it is very likely that the observedincreased toxicity in c-fos mutants is not secondary to a temperatureeffect.

Another mechanism for the potentiation of METH-induced neurotoxicity involves the possibility that METH metabolism might havebeen altered in the c-fos mutant mice in such a way that METHmight have accumulated to a higher concentration in the brainsof these mice. This accumulation in METH might have occurred becausethe absence of c-fos could have led to downregulation of the cytochromeP450 isoenzymes that are involved in the metabolism of the drug(Baba et al., 1988; Lin et al., 1995, 1997) because of a lackof stimulation of putative AP-1-binding sites that have been foundin some cytochrome P450 genes (Shaw et al., 1996; Quattrochi etal., 1998). This hypothesized increase in METH levels might havecaused greater increases in DA release, higher temperature, aswell as increased toxicity in the mutant mice. However, we failedto find any evidence of differences in METH-induced temperatureregulation in the WT and c-fos mutants, thus suggesting that changesin METH metabolism might not be sufficient to explain the exacerbationin toxicity observed in these mice. Nevertheless, it could stillbe argued that, even in the absence of increased METH levels inthe brains of c-fos mutants, it is still possible that METH mighthave caused greater displacement of DA from storage vesicles intothe cytosol with secondary generation of reactive oxygen species(ROS) within that compartment. However, this argument would holdfor only the exacerbations observed in the deleterious effectsof METH on striatal DA terminals of the c-fos knock-outmice.

Possible role of oxidative stress in METH-induced apoptosis

Although this discussion of METH-mediated toxicity via ROS had been applied mainly to the pathological changes observed inmonoaminergic terminals (for review, see Cadet and Brannock, 1998),it is becoming quite clear that METH can exert its nefarious effectsbeyond these systems. In the present study, we have shown thatMETH administration is associated with DNA fragmentation in intrinsicnondopaminergic neurons located in cortical and striatal regionsof mouse brains. The observations in the cortex are compatiblewith other reports that METH can damage cortical cell bodies inrats (Pu et al., 1996; Eisch et al., 1998). Although similar findingsare now being reported in mice for the first time, these resultsare consistent with observations that METH can alter the dynamicsof antioxidant enzymes in cortical regions of mice (Jayanthi etal., 1998). It is also consistent with the recent demonstrationthat METH can cause apoptosis and activation of cell death-relatedgenes in cortical cell cultures (Stumm et al., 1999). The observationsof DNA fragmentation in intrinsic striatal cell bodies are alsoconsistent with our recent suggestions that METH can damage cellslocated postsynaptic to DA terminals (Cadet et al., 1998). Althoughthis remains to be fully clarified, it is very likely that thereare links between the pathways that cause perturbations in DAterminals and DA axons and the mechanisms that damage intrinsiccell bodies. Therefore, when taken together, the exacerbationof METH-induced toxic effects on both dopaminergic (terminal andfiber damage) and nondopaminergic (apoptosis) systems suggeststhat c-fos might be involved in stimulating coordinated protectivepathways against toxicinjuries.

Possible role of c-fos in protective mechanisms

The IEG c-fos, a component of the AP-1 transcription factor (Rauscher et al., 1988), is widely distributed in the CNS (Senbaand Ueyama, 1997) and is easily induced by multiple stimuli (Herdegenand Leah, 1998). In addition to its activation being dependenton cellular redox status (Chakraborti and Chakraborti, 1998),c-fos can also activate some antioxidant enzymes. For example,c-fos can interact with the promoter of the glutathione S-transferasegene and cause an increase in enzymatic activity (Moffat et al.,1994; Pinkus et al., 1995). Glutathione S-transferase is knownto act in the glutathione pathway as a detoxifying enzyme, whichgets rid of free radicals (Hayes and Strange, 1995). c-fos canalso stimulate the antioxidant response element in the human NAD(P)H:quinoneoxidoreductase gene (Li and Jaiswal, 1992). Moreover, c-fos canincrease the levels of trophic or scaffolding factors via interactionwith AP-1-binding sites located on the promoters of their genes(for review, see Herdegen and Leah, 1998). These include nervegrowth factor, basic FGF, and BDNF (Shibata et al., 1991; Herdegenand Leah, 1998). Some of these factors can increase the activityof antioxidant enzymes in addition to acting as survival factors(Mattson et al., 1995; Skaper et al., 1998). Thus, c-fos inductionby toxic doses of METH (Sheng et al., 1996a,b; Hirata et al.,1998a) might serve as an oxidative stress response that couldactivate downstream molecular and cellular events that participatein a coordinated protective response against METH. These argumentsfor c-fos as a protective agent are supported by reports thatcells lacking c-fos are more sensitive to some DNA-damaging agentsin vitro (Haas and Kaina, 1995; Kaina et al., 1997), in concordancewith our present observations of increased METH toxicity in c-fosknock-out mice. Thus, the prolonged absence of c-fos could haverendered the brain more susceptible to METH-induced injury byaltering cellular redox status in themice.

Possible role of c-fos in reactive gliosis

An unexpected finding in this report is the observation that, although c-fos mutants are more susceptible to the toxicityof METH, these mice show much less of a reactive gliotic responseto the drug. The attenuated gliotic response in the c-fos mutantmight be caused by a lack of stimulation of the AP-1-binding sitelocated on the promoter of the GFAP gene (Sarid, 1991) and suggeststhat transcription control of the GFAP gene might be dependentmostly on c-fos. This line of reasoning is compatible with previousdata that had implicated c-fos expression in astrocytic replication(Masood et al., 1993; Pennypacker et al., 1996). Thus, it mightnot be unreasonable to suggest that, because of the blunted glialresponse in the c-fos mutant mice, METH-induced astrogliosis mightactually be involved in mechanisms aimed at protecting the brainor meant to help in axonal regeneration, in addition to beinga marker of neurotoxicity. This notion, although speculative,is supported by reports that astrocytes can synthesize and releaseneurotrophic factors that protect neurons from injury and death(Ridet et al., 1997; Kariko et al., 1998). For example, conditionedmedia from nigral astrocytes have been shown to improve the survivalof dopaminergic neurons (O'Malley et al., 1992, 1994). Moreover,these ideas are also supported by observations that astrocytescontain high intracellular concentrations of antioxidants (Juurlink,1997; Wilson, 1997). These ideas will need to be evaluated inthese mutants using various neurotoxic models that feature reactivegliosis.

Summary

In conclusion, this is the first report showing that c-fos mutant mice are more sensitive to the toxic effects of METH onboth dopaminergic and nondopaminergic systems in the brains. Thesedata indicate that METH-induced c-fos activation is probably involvedin a cascade that stimulates pleiotropic protective mechanismsagainst the deleterious effects of the drug. The present studyalso provides more evidence to support the view that METH notonly causes degeneration of monoaminergic terminals but also causesdamage to intrinsic striatal and cortical cells via an apoptoticprocess. Further studies are also needed to dissect the rolesthat METH-induced activated astrocytes might play, via epigeneticmechanisms, in the repair of brain regions affected by thedrug.

  FOOTNOTES

Received April 28, 1999; revised Aug. 25, 1999; accepted Aug. 25, 1999.

We thank the staff of the Animal Care Facility at the Division of Intramural Research of the National Institutes of Health-NationalInstitute on Drug Abuse for the impeccable care of the animals.We also thank Dr. Teruo Hayashi for help with the Western andconfocal microscopy. We are very grateful to Ann Rea for helpwith the figures. We are also very thankful to the reviewers whosesuggestions helped to improve thispaper.
Correspondence should be addressed to Dr. Jean Lud Cadet, Molecular Neuropsychiatry Section, National Institutes of Health-NationalInstitute on Drug Abuse Intramural Research program, 5500 NathanShock Drive, Baltimore, MD 21224. E-mail: JCADET{at}intra.nida.nih.gov.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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Methamphetamine-Induced Neurotoxicity Is Attenuated in Transgenic Mice with a Null Mutation for Interleukin-6
Mol. Pharmacol., April 13, 2001; 58(6): 1247 - 1256.
[Abstract] [Full Text]

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