Abstract
Elevation of inflammatory cytokines in the striatum precedes symptoms in a number of motor dysfunctions, but it is unclear whether this is part of the disease process or an adaptive response to the pathology. In pyramidal cells, TNFα drives the insertion of AMPA-type glutamate receptors into synapses, and contributes to the homeostatic regulation of circuit activity in the developing neocortex. Here we demonstrate that in the mouse dorsolateral striatum, TNFα drives the internalization of AMPARs and reduces corticostriatal synaptic strength, dephosphorylates DARPP-32 and GluA1, and results in a preferential removal of Ca2+-permeable AMPARs. Striatal TNFα signaling appears to be adaptive in nature, as TNFα is upregulated in response to the prolonged blockade of D2 dopamine receptors and is necessary to reduce the expression of extrapyramidal symptoms induced by chronic haloperidol treatment. These data indicate that TNFα is a regulator of glutamatergic synaptic strength in the adult striatum in a manner distinct from its regulation of synapses on pyramidal cells and mediates an adaptive response during pathological conditions.
Introduction
The striatum, which serves as the information processing hub of the basal ganglia, integrates sensorimotor, cognitive, and motivation-related information. The GABAergic medium spiny neurons (MSNs) comprise >90% of neurons in the striatum and constitute its sole output, thus representing a critical node for information coding in the basal ganglia (Murer et al., 2002). MSNs integrate dopaminergic afferents from the midbrain and glutamatergic input from cortex and thalamus, and alterations in glutamatergic function are observed early in neurodegenerative diseases associated with movement disorders, such as Parkinson's disease (PD) and Huntington's disease (HD), as well as in several psychiatric disorders, such as drug addiction and schizophrenia (Kreitzer and Malenka, 2008). During many of these diseases, neuro-inflammatory processes are considered one of the key elements in the pathophysiology, especially the proinflammatory cytokine TNFα (McCoy and Tansey, 2008). TNFα is elevated in patients and in animal models of these diseases, even before the clinical manifestation of the disease (Khandelwal et al., 2011).
There is increasing evidence that TNFα has a neuroregulatory function in addition to its role in the inflammatory response and in cell survival. In the hippocampus (Stellwagen et al., 2005) and cortex (He et al., 2012), TNFα regulates neurotransmitter receptor trafficking, with exogenous application of TNFα leading to a dramatic and rapid exocytosis of AMPA receptors (AMPARs) on excitatory pyramidal neurons. Furthermore, continual release of TNFα may be necessary for maintaining the surface expression of AMPARs, as blockade of TNFα signaling leads to decreased strength at hippocampal synapses (Beattie et al., 2002). Importantly, TNFα released from glia is a key mediator of homeostatic synaptic plasticity. In this context, TNFα modifies both AMPAR and GABAAR trafficking in pyramidal cells to normalize activity levels in a neuronal circuit in response to chronic activity manipulations (Stellwagen and Malenka, 2006). Furthermore, TNFα mediates homeostatic plasticity in vivo, as it is necessary for the increase in visual cortical response after chronic monocular deprivation during a developmental critical period (Kaneko et al., 2008; Ranson et al., 2012).
Here we investigate the contribution of TNFα to AMPAR trafficking in MSNs from the dorsal striatum and its relevance to motor disorders. At striatal glutamatergic synapses, TNFα application results in a decreased AMPA/NMDA ratio, which is accompanied by decreased AMPAR rectification and spontaneous EPSC (sEPSC) amplitude. Given recent evidence suggesting that the development and expression of drug-induced movement disorders are linked to aberrant striatal plasticity (Breakefield et al., 2008), we took advantage of a haloperidol-induced extrapyramidal syndrome model to investigate the role of TNFα in striatal function in vivo. We show here that, in the absence of TNFα signaling, both the physiological and behavioral consequences of chronic haloperidol treatment are augmented relative to controls. Critically, this deficit can be rescued by restoring TNFα signaling. This study thus identifies TNFα as a key regulator of striatal synaptic function.
Materials and Methods
Animals.
TNFα−/− mice were obtained from The Jackson Laboratory (RRID:IMSR_JAX:005540), bred homozygously, and compared with wild-type mice of matched genetic background (C57BL/6J), also bred in house. Experiments only used male mice at 8–11 weeks of age. Animal procedures were performed in accordance with the guidelines of the Canadian Council for Animal Care and the Montreal General Hospital Facility Animal Care Committee.
Drugs.
Mouse TNFα was obtained from Kamiya Biomedical. Haloperidol decanoate (Haloperidol-LA) (Sandoz) was administered at a concentration of 50 mg/kg, intramuscularly. This decanoate formulation is known to result in constant plasma levels in the 2.5 mg/kg/d range (Ethier et al., 2004). Haloperidol (Sandoz) was injected intraperitoneally at a concentration of 0.1 or 0.5 mg/kg. XENP1595 (DN-TNF; Biotherapeutics Xencor) was injected subcutaneously at 30 mg/kg, 2 d before recording. Striatal slices were incubated with 10 μg/ml DN-TNF in the recording chamber. For behavioral experiments, XENP1595 was maintained at 15 mg/kg, injected SC every 2 d. IEM-1460 (Tocris Bioscience) was injected intraperitoneally at 3 mg/kg, 20 min before assessment.
Electrophysiology.
The 240-μm-thick coronal slices containing dorsal striatum were prepared from TNFα−/− or C57BL/6J mice. Transverse hippocampal slices (300 μm) were prepared from C57BL/6J mice. After a 1 h recovery period, slices were placed in a submersion-type recording chamber and perfused (1.5–2 ml/min) at 30°C with a bicarbonate-buffered artificial CSF saturated with 95% O2/5% CO2 and containing the following (in mm): 119 NaCl, 2.5 KCl, 1 NaH2PO4, 1.3 MgCl2, 2.5 CaCl2, 26.2 NaHCO3, 11 glucose, 0.05 picrotoxin. Whole-cell voltage-clamp recordings were obtained under visual control using infrared-differential interference contrast microscopy (Olympus, BX51WI). Whole-cell electrodes (4–6 mΩ) were filled with internal solution containing the following (in mm): 120 Cs-gluconate, 10 HEPES, 10 EGTA, 15.5 CsCl, 8 NaCl, 2 MgATP, and 0.3 GTP, pH 7.3. All signals were acquired with an Axopatch 200B (Molecular Devices), filtered at 2 kHz and digitized at 10 kHz, and recorded using Clampex 10.2 (Molecular Devices). Passive membrane properties of the cells were monitored throughout the experiment. The series resistance was <25 mΩ and was not compensated. If the series resistance changed >20% during the course of an experiment, the data were discarded.
Stimulus-evoked EPSCs were evoked using stainless-steel bipolar stimulating electrodes placed in the cortical areas close to the recording electrode or in the white matter between the cortex and the striatum to preferentially activate corticostriatal fibers. The slight paired pulse depression (0.95–0.98; see Fig. 1I) observed suggests some degree of contamination with thalamic and other glutamatergic inputs, but corticostriatal fibers are predominant. To calculate AMPA/NMDA ratios, we collected evoked synaptic responses at −70 mV to measure AMPAR-mediated EPSCs and at +40 mV to measure NMDAR-mediated EPSCs. The peak AMPA response was used to calculate the AMPAR component, and the amplitude of the NMDA component was measured 40 ms from the AMPAR peak response at −70 mV. This offset method represents a relatively pure NMDA component. The rectification index (RI) was calculated as the ratio of EPSC amplitudes between −70 and +40 mV. All RI experiments were performed in slices bathed in picrotoxin to block GABAA receptor-mediated responses and AP-5 (50 μm) to block NMDA receptor-mediated responses.
To estimate the paired pulse ratio (PPR), 15 paired pulse synaptic stimulations with an interstimulus interval of 50 ms at a holding potential of −70 mV were delivered through the stimulating electrode with 10 s intervals. The traces were averaged, and PPR was expressed as percentage of the ratio of the second pulse to the first one in the series. The amplitude and frequency of sEPSCs were sampled over 2 min, at a holding potential of −70 mV. sEPSCs were analyzed off-line using the threshold detection option in Clampfit 10.2 (Molecular Devices). The threshold amplitude for the detection of an event was set at 5 pA.
Quantification of vacuous chewing movements (VCMs).
To quantify the occurrence of oral movements, mice were placed individually in observation cages and the frequency of vacuous chewing movements was quantified. Vacuous chewing movements are operationally defined as single mouth openings in the vertical plane not directed toward physical material. If vacuous chewing movements occurred during a period of grooming, they were not taken into account. The animals were observed for 3 consecutive sessions of 3 min each, for a total observation period of 9 min. Average VCM scores per 3 min were then calculated from these observations.
Catalepsy test.
Catalepsy was measured as the length of time a mouse maintained an imposed abnormal posture. Mice were gently positioned with both front legs on a 2-mm-diameter horizontal rod placed at a height of 3 cm. The time elapsed, up to 60 s, before the mouse returned both front paws to the ground was measured. Mice were observed at intervals of 15, 30, 60, and 90 min after intraperitoneal administration of haloperidol (0.1 mg/kg).
Surface biotinylation and Western blots.
Surface biotinylation was performed essentially as described previously (Jones et al., 2011). Striatal slices were incubated with sulfo-NHS-SS-biotin in aCSF (1 mg/ml) for 40 min at 4°C. The biotin reaction was quenched using aCSF containing 100 mm glycine. Slices were lysed on ice with PBS/1% Triton X-100/0.1% SDS supplemented with protease inhibitors, sodium fluoride, PMSF, and sodium orthovanadate. An aliquot of lysate was kept for analysis of total protein levels. Biotinylated receptors were precipitated with Neutravidin beads for 1 h at 4°C on a rotating platform and eluted with 3× sample buffer. Samples were resolved using SDS-PAGE and transferred to PVDF membrane. Blots were incubated overnight at 4°C using the following antibodies: GluA1 (Millipore, catalog #AB1504, RIID:AB_2113602), GluN1 (BD Biosciences, catalog #556308, RIID:AB_396353), GluA1 phospho-S831 (EMD Millipore, catalog #04–823, RIID:AB_1977218), GluA1 phospho-S845 (EMD Millipore, catalog #04–1073, RIID:AB_1977219), DARPP-32 phospho-T34 (R&D Systems, catalog #AF2847, RIID:AB_2252832), total DARPP-32 (Abcam, catalog #ab40801, RIID:AB_731843), D2 receptor (Abcam, catalog #ab85367, RIID:AB_10674739), and GAPDH (Millipore, catalog #MAB374, RIID:AB_2107445). After incubation with HRP-conjugated secondary antibody (Jackson ImmunoResearch Laboratories), blots were developed using ECL substrate (34096, Thermo Scientific). Band intensities were determined using ImageJ and normalized as follows: for surface GluA1, surface GluN1, and surface D2, surface values were normalized to their corresponding inputs and to biotinylated GAPDH (to normalize for differential permeabilization); p-S831 and p-S845 were normalized to total GluA1; p-T34 DARPP-32 was normalized to total DARPP-32; and total DARPP-32 was normalized to GAPDH.
Statistical analysis.
Statistical analyses were performed using JMP 8 (SAS Institute) and Prism 5 (GraphPad Software). All data are presented as mean ± SEM. Data were tested for normality using the Shapiro–Wilk Test and then compared using the two-tailed Student's t test; multiple comparisons were analyzed by one-way ANOVA for independent and/or repeated measures followed by post hoc Fisher's least significant difference. The Mann–Whitney test was used for Western blot analyses. The significance level was established at p < 0.05.
Results
TNFα regulates AMPA receptor content at corticostriatal synapses
To investigate the effect of TNFα at synapses onto MSNs in the dorsolateral striatum, we incubated acutely prepared coronal slices from mice with 100 ng/ml TNFα for 1–2 h and then assayed the strength of the glutamatergic input by measuring the ratio of AMPAR- to NMDAR-mediated EPSCs. Based on stimulating electrode placement and paired pulse response (Ding et al., 2008), the input predominantly consists of corticostriatal fibers with some contamination of thalamic and other inputs. Incubation of striatal slices with TNFα significantly reduced the AMPA/NMDA ratio compared with interleaved control slices from the same animal (Fig. 1A,B). TNFα treatment did not significantly alter the decay kinetics of either the AMPA current (Cont: τ = 3.35 ± 0.09; n = 16; TNFα: 3.58 ± 0.11 n = 11; p = 0.16) or the NMDA current (Cont: τ = 30.94 ± 1.47; n = 16; TNFα: 34.32 ± 1.63 n = 13; p = 0.14). To verify that the reduction in AMPA/NMDA ratio observed in the MSNs in response to TNFα is distinct from the increase in AMPA/NMDA ratio in hippocampal pyramidal cells (Stellwagen and Malenka, 2006) and not the result of differences in experimental design (age of animal or dosage of TNFα), we repeated the above experiment in adult hippocampal slices. As expected, incubation of adult hippocampal slices with 100 ng/ml TNFα significantly enhanced the AMPA/NMDA ratio in CA1 pyramidal cells compared with control slices from the same animal (Fig. 1A,B). This indicates the response of MSNs to TNFα is fundamentally different from the response of hippocampal or cortical pyramidal cells.
TNFα regulates AMPA receptor content at striatal synapses. A, Representative traces from striatal (top) medium spiny neurons and from CA1 pyramidal neurons (bottom) with the cell held at −70 mV and +40 mV from control slices (left), and TNFα-treated slices (100 ng/ml; 1–2 h) (right). B, Group data showing that TNFα significantly reduced the ratio of AMPA to NMDA current amplitudes in striatal cells (n = 13–15; p = 0.0002), whereas in CA1 pyramidal neurons TNFα significantly enhanced the ratio of AMPA to NMDA current amplitudes (n = 10; p = 0.035). AMPA/NMDA ratios were calculated using the peak amplitude at −70 mV for AMPA and the amplitude at +40 mV taken 40 ms after the peak at −70 mV. C, Representative recording of sEPSCs from control slices and slices treated with 100 ng/ml TNFα. D, Mean sEPSC amplitude is significantly decreased by TNFα treatment (17.7 ± 0.7 pA vs 15.7 ± 0.5 pA; n = 14–15; p = 0.03). E, Cumulative distributions of sEPSC amplitudes from cells shown in C. F, Sample traces of isolated AMPAR EPSCs at +40 and −70 mV. G, Group data demonstrating that synapses from TNFα-treated slices have significantly less rectification than untreated slices. The RI is expressed as EPSC amplitude+40 mV/EPSC amplitude−70 mV, with a larger ratio indicating less rectification (n = 10–12; p = 0.002). H, Sample traces of isolated AMPAR EPSCs at −70 mV before and after IEM-1460 perfusion. I, Group data demonstrating that EPSC ratio is significantly reduced in control slices after IEM-1460 compared with TNFα-treated slices (n = 6). p < 0.05. Data are mean ± SEM. *p < 0.05. **p < 0.01. ***p < 0.001.
To determine whether the change in AMPA/NMDA ratio in the MSNs was the result of a change in AMPAR content, we examined spontaneous EPSC (sEPSC) amplitude after TNFα treatment. TNFα significantly decreased sEPSC amplitude compared with untreated MSNs (Fig. 1C–E) but had no significant impact on spontaneous event frequencies (50.9 ± 4.5 events/min; n = 15 for control; 56.9 ± 3 events/min; n = 14 for TNFα treatment; p = 0.29). sEPSCs, unlike miniature EPSCs (mEPSCs), could be contaminated by spontaneously occurring action potentials that would potentially activate multiple synapses and complicate interpretation. However, the cell bodies of the glutamatergic afferents are not located in the slice, making this unlikely; and sEPSCs in dorsostriatal slices have been shown to be action potential independent (Tang and Lovinger, 2000). Furthermore, we compared sEPSCs to mEPSCs by adding TTX during recording. TTX treatment did not reduce the frequency of sEPSCs (67 ± 9.6 events/min preTTX; 79 ± 9 events/min after TTX; p > 0.40; n = 4 cells), suggesting that few, if any, action potentials are occurring. The sEPSC data suggest that TNFα treatment decreases AMPAR content but has no effect on release probability. To determine whether TNFα signaling has an effect on presynaptic function, we also examined PPR, which is inversely correlated with the probability of neurotransmitter release (Dobrunz and Stevens, 1997). There were no significant differences in PPR between the different groups (0.94 ± 0.03; n = 12 for control; 0.98 ± 0.03; n = 8 for TNFα; p = 0.39), suggesting that TNFα is not altering presynaptic properties at these synapses. On pyramidal cells, TNFα increases the synaptic content of Ca2+-permeable AMPARs (CP-AMPAR) (Ogoshi et al., 2005; Stellwagen et al., 2005), which are characterized by an inward-rectifying current–voltage relationship (Bowie and Mayer, 1995; Kamboj et al., 1995). In MSNs, the corticostriatal synapse is thought to contain a small population of Ca2+-permeable AMPA receptors (Carter and Sabatini, 2004; but see Gittis et al., 2011). We observed a substantial amount of rectification at striatal synapses, indicting the presence of CP-AMPARs (Fig. 1F). Incubation of striatal slices with TNFα significantly decreased this rectification compared with untreated slices (Fig. 1F,G). To further evaluate the effects of TNFα on CP-AMPARs, we incubated slices treated with TNFα or control with IEM-1460, an inhibitor of CP-AMPARs, and measured the change in the EPSC. IEM-1460 significantly reduced EPSCs in control slices but did not affect TNFα-treated slices (Fig. 1H,I). Together, these results suggest that TNFα treatment results in preferential removal of CP-AMPARs on MSNs.
To directly assess whether there is a downregulation in the surface expression of AMPARs, we used surface biotinylation on striatal slices treated with 100 ng/ml TNFα for 1 h and compared this with untreated slices from the same animals. TNFα treatment markedly decreased the surface expression of GluA1 and, to a lesser extent, surface expression of GluA2, but had no effect on the requisite NMDAR subunit GluN1 (Fig. 2A). This is consistent with the electrophysiological data suggesting that the TNFα-induced change in AMPA/NMDA ratio is the result of a change in AMPARs and not NMDARs. In MSNs, the surface expression of AMPARs is regulated by protein phosphatase 1 (PP1), which in turn is regulated by DARPP-32 (Yan et al., 1999). Dephosphorylation of DARPP-32 at T34 results in dissociation of DARPP-32 and PP1, activation of PP1, and AMPAR endocytosis (Yan et al., 1999). TNFα may act through this pathway, as we observed a decrease in DARPP-32 T34 phosphorylation in TNFα-treated slices, compared with untreated slices from the same animal (Fig. 2B), without affecting the total protein level (96.5 ± 10.9% of control). Consistent with a decrease in AMPAR surface expression as well as the activation of PP1, we also observed a decrease in phosphorylation of both S845 and S831 on GluA1 in the total protein fraction of TNFα-treated slices (Fig. 2B), without a change in total GluA1 (105.6 ± 10.8% of control). Together, these data suggest that, through the regulation of DARPP-32 activity, TNFα drives the endocytosis of AMPARs in MSNs, as opposed to the exocytosis of AMPARs observed with pyramidal cells.
TNFα treatment significantly reduces surface AMPAR levels in the striatum. Striatal slices were treated with TNFα 100 ng/ml for 1 h and analyzed by surface biotinylation for (A) surface GluA1 (n = 10 mice), surface GluA2 (n = 7 mice) and surface GluN1 (n = 8 mice) and were compared with the total corresponding protein level. The protein loading for surface exceeds the loading for total in some cases. Only the decrease in AMPAR subunit surface expression was significant (GluA1: p = 0.002; GluA2: p = 0.02; GluN1: p = 0.96). B, TNFα treatment significantly decreased the phosphorylation of DARPP-32 T34 (n = 7 mice), and both GluA1–S831 (n = 7 mice) and GluA1–S845 (n = 8 mice) (p-T34: p = 0.02; p-S831: p = 0.0011; p-S845: p = 0.001), with no change in total protein expression of either DARPP-32 or GluA1 (GluA1: p = 0.96; DARPP-32: p = 0.17). Data are mean ± SEM. *p < 0.05. **p < 0.01.
TNFα regulates the development of dyskinetic symptoms induced by haloperidol
TNFα is known to homeostatically regulate circuit function in the hippocampus and the visual cortex (Stellwagen and Malenka, 2006; Kaneko et al., 2008). Although the effect of TNFα on AMPAR trafficking is reversed in MSNs compared with pyramidal cells, we wanted to test whether TNFα was still acting to normalize circuit function in the striatum.
To test the role of TNFα in regulating striatal-dependent behavior, we first examined the effect of inhibiting TNFα signaling at synapses onto MSNs. We used both genetic and pharmacological methods to block TNFα signaling. We first examined the effect of genetically deleting TNFα by using knock-out mice (TNFα−/− mice). Basal AMPA/NMDA current amplitudes were significantly higher in the TNFα−/− mice compared with WT mice (Fig. 3A,B), suggesting ongoing TNFα signaling in the striatum. However, to exclude compensatory mechanisms resulting from the absence of TNFα during development creating this change, we pharmacologically blocked the soluble form of TNFα in adult mice using XENP1595 (an engineered dominant-negative variant of TNFα [DN-TNF] that rapidly binds with soluble TNFα to give heterotrimers that neither bind to nor stimulate signaling through TNF receptors) (Steed et al., 2003). WT mice were administered DN-TNF (30 mg/kg, i.p.) 2 d before striatal slice preparation, and slices were subsequently incubated in 10 μg/ml DN-TNF to block any TNFα released because of slicing. Blocking TNFα signaling increased AMPA/NMDA ratios (Fig. 3A,B) to a similar degree observed in the TNFα−/− mice. Furthermore, blocking TNFα signaling for 48 h in vivo significantly increased the sEPSC amplitude compared with control (Fig. 3C–E) but did not significantly affect spontaneous event frequencies (89.1 ± 14 events/min; n = 14 for control; 63.8 ± 10 events/min; n = 14 for DN-TNF treatment; p = 0.16). Consistent with the lack of change in sEPSC frequency, we did not observe any significant differences in PPR between the different groups (0.94 ± 0.03; n = 12 for control; 0.89 ± 0.04; n = 9 for DN-TNF; p = 0.4). In addition, we also examined the rectification of the AMPA-mediated EPSC after DN-TNF treatment. Synapses from DN-TNF-treated slices showed increased rectification compared with untreated slices (Fig. 3F,G). Together, these results suggest that there is ongoing TNFα signaling in the striatum that downregulates surface AMPARs and limits synaptic strength at corticostriatal synapses.
Blocking TNFα signaling increases AMPA receptor content at striatal synapses. A, Representative traces from striatal medium spiny neurons with the cell held at −70 mV (bottom) and +40 mV (top) in slices from WT mice (left), TNFα−/− mice (TNFKO) (middle), and WT slices treated with a dominant-negative form of TNFα (DN-TNF) (right). B, Group data showing that, in TNFα−/− mice and WT slices treated with DN-TNF, there is a significantly higher ratio of AMPA to NMDA current amplitudes. AMPA/NMDA ratios were calculated using the peak amplitude at −70 mV for AMPA and the amplitude at +40 mV taken 40 ms after the peak at −70 mV. A one-way ANOVA demonstrated a significant effect of the treatment (n = 15–17 per group; F(2,48) = 3.9, p < 0.026). C, Representative recordings of sEPSCs from control slices and slices treated with DN-TNF. D, Mean sEPSC amplitude is significantly increased by DN-TNF treatment (18.2 ± 0.6 pA vs 15.3 ± 0.4 pA; n = 14; p = 0.001). E, Cumulative distributions of sEPSC amplitudes. F, Sample traces of isolated AMPAR EPSCs at +40 and −70 mV. G, Group data demonstrating that synapses from DN-TNF-treated slices have increased rectification relative to untreated slices. The RI is expressed as EPSC amplitude+40 mV/EPSC amplitude−70 mV, with a larger ratio indicating less rectification (n = 10–12). p = 0.005. Data are mean ± SEM. *p < 0.05. **p < 0.01.
Abnormalities in the corticostriatal pathway are associated with a number of movement disorders, such as drug-induced extrapyramidal symptoms (Centonze et al., 2004), PD (Watson et al., 2009), and HD (Milnerwood and Raymond, 2007), which are all associated with increased striatal TNFα levels (Bishnoi et al., 2008; Khandelwal et al., 2011; Smith et al., 2012). This raises the possibility that TNF-mediated plasticity is a compensatory response to the development of striatal dysfunctions. To investigate the role of TNFα in an experimental movement disorder, we used a mouse model of extrapyramidal disorder induced by subchronic blockade of striatal dopamine D2 receptors by antipsychotic drugs and characterized by involuntary movements, particularly of the face and neck. In mice, subchronic haloperidol is associated with reduced dynorphin and substance P, similar to that seen with an animal model of Parkinsonism and drug-induced extrapyramidal symptoms (Egan et al., 1996) and manifests as purposeless mouth openings in the vertical plane, or VCMs. In this model, TNFα levels were shown to be elevated in the striatum after chronic administration of haloperidol (Bishnoi et al., 2008; Wang et al., 2012), accompanied with increased striatal AMPA binding (Schmitt et al., 2003).
To get higher and more stable VCMs, we generated the VCMs by a single injection of a high dose of the slow release formulation of the drug (Ethier et al., 2004), haloperidol decanoate (50 mg/kg, i.m., equivalent of 2.5 mg/kg/d) to WT mice and TNFα−/− mice. Although both strains of mice developed VCMs, the VCMs scores were significantly higher in TNFα−/− mice compared with WT mice (Fig. 4A). Furthermore, a small group of mice were monitored for an extended period of time, and VCMs were still elevated after 10 weeks in the TNFα−/− mice as opposed to WT mice that returned to basal levels after 8 weeks. These results suggest that TNFα is reducing the adverse effects of chronic administration of haloperidol. To exclude the possibility that TNFα was simply modulating the response to haloperidol, we tested the acute response to haloperidol. As opposed to the chronic response to slow-release haloperidol, acute administration of fast-acting haloperidol induces a rapid cataleptic state mainly because of the blockade of dopamine receptors in the nigrostriatal pathway (Sanberg, 1980). This profound cataleptic state can be measured by an increase in the latency to initiate voluntary movement, such as removing the forelimbs from an elevated bar (Sanberg et al., 1988). To verify that TNFα is not involved in the acute response to haloperidol, we injected WT and TNFα−/− mice with fast-acting haloperidol (0.1 mg/kg i.p.) while monitoring cataleptic behavior in the elevated bar test, and found no significant differences between the two groups of mice (Fig. 4B; n = 9). In addition, no significant differences were observed with a higher dosage (0.5 mg/kg i.p.) (two-way repeated-measures ANOVA; genotype, F(1,116) = 0.1, p = 0.36; time, F(3,14) = 4.94, p < 0.004; genotype × time, F(3,14) = 0.26, p = 0.62; n = 5). These results suggest that TNFα only regulates the chronic but not the acute response to haloperidol. To ensure that the increased response to chronic haloperidol observed in the TNFα−/− mice is not the result of any compensatory mechanisms resulting from the absence of TNFα during development, we treated WT mice with DN-TNF (30 mg/kg) 2 d before haloperidol injection and every other day thereafter at 15 mg/kg for 2 weeks. As with the TNFα−/− mice, WT mice treated with DN-TNF had significantly higher VCM scores compared with control mice (Fig. 4C; n = 8 for control and DN-TNF). This suggests that soluble TNFα is regulating the development of the VCMs in a manner that limits the behavioral consequence of chronic haloperidol treatment. However, it is possible that, rather than chronically suppressing VCMs, TNFα signaling alters striatal plasticity in some way to limit the development of the motor symptoms in response to haloperidol. To address this possibility, we treated WT mice with haloperidol for 2 weeks, allowing the VCMs to develop normally. We measured the level of VCMs and then treated the animals with 30 mg/kg DN-TNF, and reassessed VCMs 24 h later. Even this relatively acute blockade of TNFα signaling for previously established dysfunction resulted in a significant increase in VCMs (Fig. 4D). Together, these data suggest that ongoing TNFα signaling is suppressing the behavioral expression of the haloperidol-induced extrapyramidal symptoms.
Loss of TNFα signaling exacerbates the extrapyramidal symptoms caused by chronic haloperidol. A, Effects of chronic haloperidol on the development of VCMs in TNFα−/− and WT mice. VCMs were generated by a single administration of long-acting haloperidol decanoate (50 mg/kg, i.m., equivalent of 2.5 mg/kg/d) and evaluated weekly (Ethier et al., 2004). TNFα−/− mice had significantly more VCMs than WT mice (n = 8 per group). Two-way repeated-measures ANOVA: genotype, F(1,14) = 1.14, p = 0.001; days, F(4,11) = 14.9, p < 0.0001; genotype × days, F(4,11) = 2.54, p = 0.0047. A small group of mice were monitored for an extended period and checked for VCM at 55 and 69 d after haloperidol injection. TNFα−/− mice still had significant levels of VCMs, whereas WT mice had returned to baseline levels (n = 4 per group). Two-way repeated-measures ANOVA: genotype, F(1,6) = 6.36, p = 0.0008; days, F(1,6) = 0.12, p = 0.42; genotype × days, F(1,6) = 0.0007, p = 0.95. B, Effects of acute haloperidol on catalepsy. WT or TNFα−/− mice received an intraperitoneal injection of haloperidol (0.1 mg/kg) and were tested 15, 30, 60, and 90 min later. No significant differences in cataleptic behavior were observed between the different strains. Two-way repeated-measures ANOVA: genotype, F(1,16) = 0.005, p = 0.76; time, F(3,14) = 7.68, p < 0.0001; genotype × time, F(3,14) = 0.09, p = 0.73. C, Effects of chronic haloperidol on VCMs in WT mice treated with DN-TNF. Top, Schematic of the experimental design. Mice were injected with DN-TNF (30 mg/kg initial dose; 15 mg/kg every 2 d thereafter) before baseline VCM monitoring and haloperidol injection. Bottom, DN-TNF treatment significantly increased VCMs. Two-way repeated-measures ANOVA: treatment, F(1,14) = 0.83, p = 0.004; days, F(2,13) = 5.33, p < 0.001; treatment × days, F(2,13) = 1.11, p = 0.007. D, Effect of acute blockade of TNFα signaling on a previously established dyskinesia. Top, Schematic of the experimental design. Mice were injected with haloperidol and evaluated 14 d later for VCMs; mice were then injected with DN-TNF (30 mg/kg) and reevaluated 24 h later. Bottom, Acute DN-TNF treatment significantly increased VCMs. Paired t test (p = 0.0003; n = 5). Each data point represents VCM scores, mean ± SEM. *p < 0.05. **p < 0.01. ***p < 0.001.
To verify that TNFα does not regulate the surface expression of the dopamine D2 receptor, the target of haloperidol, we examined surface biotinylation of D2 receptors. The surface levels of D2 receptors from TNFα-treated striatal slices were insignificantly different compared with untreated slices from the same animals (Fig. 5A). Further, TNFα−/− mice have normal surface expression of D2 receptors (Fig. 5B). There was also no change in total D2 receptor expression in either case (TNFα treatment: 102.8 ± 9.6% of control; TNFα−/− mice: 88.2 ± 21.5% of wild-type; n = 7 per group). Overall, this suggests that the observed differences in VCMs are not the result of altered levels of D2 dopamine receptor. We further tested whether DARPP-32 phosphorylation is engaged during haloperidol-induced extrapyramidal symptoms. Phosphorylation of DARPP-32 is increased by acute haloperidol treatment (Håkansson et al., 2006), but the effects of chronic treatment are unknown. We assessed the level of phospho-Thr34-DARPP-32 in animals treated for 2 weeks with haloperidol and compared it with animal that were treated with haloperidol for 2 weeks and then with DN-TNF for 24 h. Mice treated with haloperidol had significantly less phospho-Thr34-DARPP-32 compared with control mice, and this decrease was completely reversed with acute DN-TNF treatment (Fig. 5C). Thus, TNFα induces a downregulation of phospho-Thr34-DARPP-32 in mice chronically treated with haloperidol and may alter corticostriatal synaptic strength in this model.
TNFα treatment reduces DARPP-32 phosphorylation in the striatum after haloperidol treatment. A, Striatal slices were treated with TNFα 100 ng/ml for 1 h and analyzed by surface biotinylation for dopamine D2 receptors (n = 7 mice). No significant difference was observed (p = 0.35). B, Striatal slices from TNFα−/− mice were compared with WT mice for the surface expression of D2 receptors (n = 7 mice per group). No significant difference was observed (p = 0.68). C, Mice were treated with haloperidol for 2 weeks and analyzed for total DARPP-32 and phospho-DARPP-32 T34 in the striatum. Two weeks of haloperidol significantly reduced striatal Thr34 phosphorylation compared with untreated control striatum; however, 24 h treatment with DN-TNF in haloperidol-treated mice restored Thr34 phosphorylation to control levels (n = 4 mice per group). Data are mean ± SEM. A, B, *p < 0.05, versus control (Mann–Whitney test). C, *p < 0.05, versus control (one-way ANOVA with a post hoc Kruskal–Wallis test).
TNFα signaling reduces the synaptic and behavioral alteration induced by chronic haloperidol
To examine the physiological correlate of the behavior, we measured the effect of subchronic haloperidol treatment on AMPAR- to NMDAR-mediated synaptic currents from MSNs in the dorsolateral striatum in WT and TNFα−/− mice. Subchronic (14 d) haloperidol significantly increased the ratio of AMPA/NMDA current amplitudes in TNFα−/− mice but only slightly but not significantly increased AMPA/NMDA ratio in WT mice (Fig. 6A,B). In WT mice, the increase in AMPA/NMDA ratio was accompanied by an increase in rectification of the AMPA currents (Fig. 6C), suggesting the preferential insertion of CP-AMPARs. To test whether these additional CP-AMPARs contribute to the extrapyramidal symptoms, we measured VCMs in WT mice treated with haloperidol for 2 weeks and injected 3 mg/kg of the CP-AMPAR antagonist IEM-1460 (i.p.), and reassessed the mice 20 min later. IEM treatment significantly reduced the number of VCMs by almost 30% (Fig. 6D), whereas saline treatment led to a slight increase in VCMs, probably because of habituation to the assessment chamber (Fig. 6E). IEM-1460 alone, at this concentration, has been shown to have no adverse impact on motor performance on the rotarod (Kobylecki et al., 2010), although unilateral injection of IEM-1460 directly into the dorsolateral striatum can induce dystonia-like symptoms (Gittis et al., 2011). Therefore we evaluated whether the protocol we used can induced abnormal movement. Naive WT mice were injected intraperitoneally with 3 mg/kg IEM-1460 or saline, and monitored 20 min later for VCM development and overall locomotor activity. IEM did not induce VCMs (control, 0.16 ± 0.16; n = 4; IEM, 0.33 ± 0.13; n = 4; p > 0.46) or significantly alter locomotion (distance: control, 1670 ± 64 cm; n = 4; IEM, 1538 ± 68; n = 4; p > 0.2; average velocity: control, 5.6 ± 0.2 cm/s; n = 4; IEM, 5.2 ± 0.26; n = 4; p > 0.32). Furthermore, mice injected with IEM displayed normal grooming behavior with no visible abnormal postures or movements.
TNFα signaling limits the abnormal synaptic and behavioral alterations induced by chronic haloperidol. A, Representative traces from striatal medium spiny neurons held at −70 mV (bottom) and +40 mV (top) 14 d after haloperidol injection in WT mice or TNFα−/− mice. B, Group data showing that haloperidol significantly increased the ratio of AMPA to NMDA current amplitudes in TNFα−/− compared with naive mice, but this effect was not significant in WT (n = 15 or 16 per group). A one-way ANOVA indicates a significant difference between the groups (F(3,61) = 9.52, p < 0.0001). C, Group data demonstrating that synapses from slices obtained from mice after 14 d of haloperidol have a significantly higher rectification. The RI is expressed as EPSC amplitude+40 mV/EPSC amplitude−70 mV, with a larger ratio indicating less rectification (n = 9 haloperidol, 13 control; p = 0.015). D, Effects of acute blockade of CP-AMPAR on VCMs at day 14 after haloperidol. WT mice were injected with haloperidol. After 14 d VCMs were counted and mice were injected with IEM-1460 (3 mg/kg) or saline. At 20 min later, VCMs were counted again. IEM-1460 significantly reduced VCM levels (paired t test; p = 0.02; n = 8). E, In contrast, mice treated with saline had significantly higher levels of VCMs after injection (paired t test; p = 0.04; n = 7). F, Striatal slices from TNFα−/− mice chronically treated with haloperidol for 14 d were treated ex vivo with 100 ng/ml TNFα for 1–2 h. TNFα treatment significantly reduced the AMPA/NMDA ratio (n = 11–13; p = 0.0017). G, Effects of chronic haloperidol on VCMs after stopping treatment with dominant-negative TNFα. WT mice were administered with DN-TNF either for 2 weeks or just for the first week and compared with untreated mice. Stopping the treatment of DN-TNF reduced the level of VCMs to that of control mice (n = 9–11 mice per group). Two-way repeated-measures ANOVA: treatment, F(2,26) = 0.05, p = 0.0048; days, F(1,26) = 0.17, p = 0.042; treatment × days, F(2,26) = 0.28, p = 0.038. Data are mean ± SEM. *p < 0.05. **p < 0.01.
Overall, haloperidol leads to an increase in CP-AMPARs at MSN synapses, and these receptors contribute in part to the expression of VCMs. As the level of AMPAR insertion was significantly higher in haloperidol-treated TNFα−/− mice than in haloperidol-treated WT mice, we then examined whether exogenous application of TNFα would reduce the elevated AMPA/NMDA ratio in TNFα−/− mice. Acute striatal slices from TNFα−/− mice chronically treated with haloperidol for 14 d were treated ex vivo with 100 ng/ml TNFα for 1–2 h. This treatment significantly reduced the ratio of AMPA/NMDA current amplitudes compared with untreated TNFα−/− (Fig. 6F), to levels indistinguishable from WT mice. These data suggest that TNFα is part of an adaptive response to the change in circuit function due to subchronic blockade of D2 receptors, and that by reducing the synaptic changes in the striatum, TNFα may reduce the expression of VCMs.
To test this idea, we examined whether increasing the levels of TNFα could reduce VCMs induced by haloperidol. Given that injection of TNFα systemically or locally can induce sickness behavior as well as increased levels of other proinflammatory cytokines (Cao et al., 1998; Chida and Iwakura, 2007), we repeated the VCM behavioral experiment using DN-TNF, except that in one group we administered DN-TNF for only 1 week, which allows the gradual return of soluble TNFα signaling during the second week. Although both DN-TNF-treated groups had higher VCM scores after 1 week compared with control, stopping the treatment of DN-TNF reduced the VCM scores to control levels at week 2 (Fig. 6G). These results indicate that restoring physiological levels of TNFα can return the expression of VCMs to normal levels. Together, these data suggest that TNFα is mediating an adaptive response in the striatum to the chronic presence of haloperidol.
Discussion
Our data demonstrate that TNFα is a regulator of AMPAR content at the corticostriatal pathway, with some selectivity for the removal of CP-AMPAR. Furthermore, TNFα has an adaptive role in restricting both the physiological and behavioral effects of chronic haloperidol treatment. Our findings suggest that TNFα is a major regulator of striatal function and loss of TNFα signaling increases vulnerability to corticostriatal dysfunction.
TNFα treatment was previously shown to induce the rapid exocytosis of CP-AMPARs in excitatory neurons, whereas blocking TNFα reduced AMPAR surface expression in cortical (He et al., 2012) and hippocampal pyramidal cells (Ogoshi et al., 2005; Stellwagen et al., 2005) and in motor neurons (Ferguson et al., 2008). In contrast, TNFα signaling reduces AMPAR content in MSNs through the preferential removal of CP-AMPARs. One possible explanation for this discrepancy is a developmental regulation of TNFα-mediated trafficking, with this work being done in relatively mature tissue (8- to 10-week-old mice) compared with earlier experiments. However, treatment of TNFα in acute hippocampal slices from adult mice resulted in an increase of AMPA/NMDA ratio in the CA1 pyramidal neurons. Moreover, neurons in the adult amygdala respond to acute TNFα treatment by strengthening glutamatergic synapses (Chen et al., 2013). More likely, the difference is the result of MSNs being inhibitory cells. Reducing excitatory drive on inhibitory neurons will lead to an overall decrease in inhibition; thus, TNFα would have a similar effect on circuit properties in both systems. Our results are supported by the observation that blocking activity in hippocampal cultures, which leads to TNFα-dependent increase of AMPARs on excitatory pyramidal neurons, reduces AMPARs on a subset of parvalbumin-expressing interneurons (Chang et al., 2010). Another possibility is that MSNs express high levels of DARPP-32 (Walaas et al., 1983) and that, in these cells, TNFα signaling through the DARPP-32 pathway inverts the AMPAR trafficking through activation of PP1. TNFα is known to activate PP1 in hippocampal pyramidal neurons, but this activity is localized to inhibitory synapses where it is required for the TNFα-induced endocyosis of GABA-A receptors (Pribiag and Stellwagen, 2013). Whereas the regulation of various PP1 binding proteins can be similar, the targeting can be different. Thus, MSNs, which express DARPP-32 unlike hippocampal cells, may target PP1 to excitatory synapses and result in the endocytosis of AMPARs.
Striatal levels of TNFα increase during many motor disorders and inflammatory conditions, which are also accompanied with alterations in the corticostriatal pathway. As TNFα is involved in homeostatic synaptic plasticity, we hypothesized that the increase of TNFα is part of a compensatory response to the abnormal corticostriatal plasticity. To test this idea, we selected a simple animal model of abnormal striatal function involving elevated TNFα levels in the striatum (Bishnoi et al., 2008) as well as alterations in AMPARs and enhanced excitatory transmission in the corticostriatal pathway (Schmitt et al., 2003; Centonze et al., 2004). Subchronic haloperidol, as generally used here, is more likely a model of Parkinsonism and drug-induced extrapyramidal symptoms, whereas chronic haloperidol transitions into a model of tardive dyskinesia (Egan et al., 1996). However, based on the elevated VCMs across a 10 week experiment, TNFα signaling likely diminishes both of these striatal motor dysfunctions.
Dopamine is well documented as a regulator of corticostriatal synapses (Chase and Oh, 2000; Chase et al., 2003; Calabresi et al., 2010), and dysregulation of these synapses is thought to underlie extrapyramidal syndromes (Chase, 2004; Calabresi et al., 2010; Sgambato-Faure and Cenci, 2012). Inhibition of D2 receptors or activation of D1 receptors leads to PKA-dependent phosphorylation of both DARPP-32 (resulting in inhibition of PP1) and S845 on GluA1. This will increase the surface expression of GluA1-containing AMPARs (Mangiavacchi and Wolf, 2004).
Acute haloperidol treatment has been observed to transiently increase both DARPP-32 and GluA1-S845 phosphorylation in vivo (Håkansson et al., 2006). However, with chronic haloperidol, there is a downregulation of phospho-Thr34-DARPP-32 because of an increase in TNFα signaling. Correspondingly, acute haloperidol was shown to increase phosphorylation of ribosomal protein S6, which required Thr34 phosphorylation of DARPP32; however, this effect is lost when haloperidol is administered chronically (Valjent et al., 2011). Similar changes in DARPP32 occur during other striatal dysfunctions, suggesting a broader role for TNFα in regulating striatal synapses. As with haloperidol, acute injection of cocaine is also associated with increase phospho-Thr34-DARPP-32 in the striatum (Nishi et al., 2000), whereas chronic treatment with cocaine is associated with a decrease in phospho-Thr34-DARPP-32 (Bibb et al., 2001). A related extrapyramidal syndrome, l-DOPA induced dyskinesia, which is primarily mediated through D1 activation, is also associated with strengthening of corticostriatal synapses (Jenner, 2008; Calabresi et al., 2010; Cenci and Konradi, 2010). The added AMPARs may be Ca2+-permeable, as we observe an increase in AMPAR rectification, and the VCMs can be partially blocked by IEM-1460. This regimen was similarly effective against l-DOPA-induced dyskinesia, without generally affecting motor function (Kobylecki et al., 2010); a partial blockade of all AMPARs also reduces l-DOPA-induced dyskinesia (Konitsiotis et al., 2000). Furthermore, treatment with l-DOPA did not reduce inward-rectifying AMPAR currents induced by 6-OHDA-lesion. However pramipexole, which was shown to have antiparkinsonian effects and be associated with reduced dyskinesia, could reverse the alteration of glutamatergic transmission as well as restore rectification values to control levels (Bagetta et al., 2012). Controlling the CP-AMPAR content of synapses may therefore be critical to treating striatal motor dysfunctions.
To fully understand the effect of TNFα on striatal function will necessitate examining the effect of TNFα on the direct and indirect pathway MSNs. Although we do not directly address this issue here, it seems likely that TNFα acts on both types of MSNs. All MSNs appeared to have reduced AMPA/NMDA ratios in response to TNFα (Fig. 1B), and the reduction in AMPAR surface expression is too large for TNFα to be acting at a subset of MSNs. However, TNFα may have a stronger effect on recently altered MSN synapses. Chronic haloperidol increases AMPAR rectification, suggesting the insertion of new CP-AMPARs. As TNFα preferentially acts on these receptors, TNFα will more strongly affect newly altered synapses and thereby help restore circuit function.
Our data support a model of enhanced corticostriatal transmission in the development of drug induced extrapyramidal symptoms and the increase in synaptic strength correlates with the degree of motor dysfunction. Blocking TNFα signaling increases both the corticostriatal synaptic strength and the level of VCMs. TNFα appears to act through a similar pathway as dopamine in regulating these synapses, by dephosphorylating DARPP-32 and GluA1 and thereby decreasing the surface expression of AMPARs. Critically, even an acute blockade of TNFα can worsen symptoms, and restoring TNFα signaling will reverse this effect. This suggests that TNFα is acting adaptively to reduce the aberrant corticostriatal synaptic strength and suppress the magnitude of the VCMs. Similarly, in humans, polymorphism in the TNFα promoter that results in increased TNFα production is associated with less severe symptoms of tardive dyskinesia (Wang et al., 2012), a consequence of chronic haloperidol administration. However, we cannot rule out that, with progression of striatal disorders, TNFα levels could increase to levels that can lead to TNFα-induced cell death. It is important to note that the incidence of tardive dyskinesia is significantly lower with atypical antipsychotic drugs, such as clozapine (Margolese et al., 2005). One possible reason for the lower incidence is that chronic haloperidol increases AMPAR binding in striatum, nucleus accumbens, cingulated cortex, and insular cortex, whereas clozapine shows increased AMPAR binding only in the anterior cingulated cortex (McCoy et al., 1996; Schmitt et al., 2003). Alternatively, clozapine may cause smaller changes within the striatum that can be fully compensated by TNFα signaling, whereas haloperidol causes larger increases in synaptic strength that can only be partially compensated by TNFα.
In the CNS, the effects of TNFα are complex, with evidence for both injury-promoting and neuroprotective effects (Fontaine et al., 2002; McCoy and Tansey, 2008; Chertoff et al., 2011). Moreover, TNFα levels are elevated in patients and animal model of movement disorder, such as HD (Sapp et al., 2001), PD (Mogi et al., 1999), and other basal ganglia disorders, such as OCD (Konuk et al., 2007), schizophrenia (Miller et al., 2011), and addiction (Yamada and Nabeshima, 2004). Although it has been suggested that TNFα is detrimental in these pathologies, we propose that, at early stages of striatal dysfunction, TNFα has an adaptive role by specifically inducing endocytosis of CP-AMPARs and reducing synaptic strength of the corticostratal pathway. Thus, blocking TNFα signaling in the treatment of movement disorders may complicate the therapies and exacerbate the motor symptoms in early phases of the disease. However, constant activation of this compensatory system may lead to persistent high levels of TNFα that could also be detrimental to the system. Overall, our data establish that TNFα is a key element in maintaining the normal function of this circuit and that the robustness of striatal compensatory systems may set the symptom susceptibility in these maladies.
Footnotes
This work was supported by Canadian Institutes of Health Research Grant 89904, Natural Sciences and Engineering Research Council, and the National Alliance for Research on Schizophrenia and Depression Young Investigator Award to D.S., the Ronald Peter Griggs Memorial Postdoctoral Fellowship in ALS Research to G.M.L., Fonds de la Recherche en Santé du Québec doctoral training award to H.P., and an award from the McGill University Psychiatry program to M.S.-H. We thank Joseph Lee for technical assistance and Dr. David E. Szymkowski (Biotherapeutics Xencor, Inc) for providing us with XENP1595 (DN-TNF).
The authors declare no competing financial interests.
- Correspondence should be addressed to Dr. David Stellwagen, Centre for Research in Neuroscience, The Research Institute of the McGill University Health Centre, Montreal General Hospital L7-217, 1650 Cedar Avenue, Montréal, Québec H3G 1A4, Canada. david.stellwagen{at}mcgill.ca
