Abstract
Both the glutamatergic and serotonergic (5-HT) systems are implicated in the modulation of mood and anxiety. Descending cortical glutamatergic neurons regulate 5-HT neuronal activity in the midbrain raphe nuclei through α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and N-methyl-D-aspartate (NMDA) receptors. To analyze the functional role of GLUA1-containing AMPA receptors in serotonergic neurons, we used the Cre-ERT2/loxP-system for the conditional inactivation of the GLUA1-encoding Gria1 gene selectively in 5-HT neurons of adult mice. These Gria15-HT−/− mice exhibited a distinct anxiety phenotype but showed no alterations in locomotion, depression-like behavior, or learning and memory. Increased anxiety-related behavior was associated with significant decreases in tryptophan hydroxylase 2 (TPH2) expression and activity, and subsequent reductions in tissue levels of 5-HT, its metabolite 5-hydroxyindoleacetic acid (5-HIAA), and norepinephrine in the raphe nuclei. However, TPH2 expression and activity as well as monoamine levels were unchanged in the projection areas of 5-HT neurons. Extracellular electrophysiological recordings of 5-HT neurons revealed that, while α1-adrenoceptor-mediated excitation was unchanged, excitatory responses to AMPA were enhanced and the 5-HT1A autoreceptor-mediated inhibitory response to 5-HT was attenuated in Gria15-HT−/− mice. Our data show that a loss of GLUA1 protein in 5-HT neurons enhances AMPA receptor function and leads to multiple local molecular and neurochemical changes in the raphe nuclei that dysregulate 5-HT neuronal activity and induce anxiety-like behavior.
Similar content being viewed by others
INTRODUCTION
In the central nervous system (CNS), serotonin (5-HT) is exclusively synthesized by serotonergic neurons originating in the raphe nuclei. The dorsal and median raphe nuclei of the midbrain give rise to ascending projections that, due to their widespread distribution and extensive connectivity, are involved in many physiological processes underlying cognition, emotions, and perception (Cools et al, 2008; Heninger, 1997). These include the control of many complex behaviors such as aggression, impulsive behavior, decision making, responsiveness to punishment and aversive signaling or anxiety (Carver and Miller, 2006; Cools et al, 2008; Dayan and Huys, 2009; Lucki, 1998; Rogers, 2011). Accordingly, serotonergic dysregulation during development and/or adulthood has been associated with many psychiatric disorders with diverse psychopathology (Carver and Miller, 2006; Finger et al, 2007; Geyer and Vollenweider, 2008; Gordon and Hen, 2004; Mann, 2003; Pardo and Eberhart, 2007; Zill et al, 2004).
5-HT neurons in the midbrain raphe nuclei receive modulatory inputs from glutamatergic neurons (Jacobs and Azmitia, 1992), which influence 5-HT neuronal firing and 5-HT release both locally as well as in distant target brain areas (Celada et al, 2002; Tao and Auerbach, 2000). The principal receptor for fast glutamate-mediated signal transmission is the AMPA receptor. In the raphe nuclei, it has been shown that activation of AMPA receptors on 5-HT neurons leads to increased firing in these neurons and increased 5-HT release (Gartside et al, 2007; Levine and Jacobs, 1992). Four subunits of the AMPA receptor, GLUA1–A4, contribute to the formation of different cell-type-dependent heterotetrameric receptors (Dingledine et al, 1999). Within this family, the function of the GLUA1-containing AMPA receptor appears to be unique. Thus, as demonstrated in hippocampal CA1 pyramidal cells, GLUA1-containing AMPA receptors are not critically involved in synaptic signal transmission, but they constitute a pool of extrasynaptic AMPA receptors that is necessary for activity-induced increases in synaptic transmission (Jensen et al, 2003; Zamanillo et al, 1999). Global GLUA1-deficient mice exhibit impairments in many different forms of learning and memory (for review see (Sanderson et al, 2008) as well as alterations in depressive and anxiety-like behaviors (Bannerman et al, 2004; Chourbaji et al, 2008c; Fitzgerald et al, 2010; Vekovischeva et al, 2004). Given the involvement of 5-HT in mood and anxiety, we hypothesised that these latter effects of the global Gria1 deletion involve changes in 5-HT function.
To examine the role of GLUA1 subunit containing AMPA receptors in serotonergic neurons, we generated 5-HT neuron-specific GLUA1-deficient mice (Gria15HT−/−). To exclude developmental adaptations and indirect effects, we used the transgenic CreERT2/loxP-system that allows inducible deletion of the loxP-flanked Gria1 gene (encoding GLUA1) selectively in 5-HT neurons in adult mice (Gria15-HT−/−). Using behavioral, neurochemical, molecular, and electrophysiological assays, we identified a distinct anxiety phenotype in Gria15-HT−/− mice that most likely involves altered serotonergic signaling and dysregulation of 5-HT neuronal firing.
MATERIALS AND METHODS
Generation of Transgenic Gria15-HT−/− Mice
All experiments were approved by German animal welfare authorities (Regierungspräsidium Karlsruhe). We used an inducible 5-HT neuron-specific CreERT2-driver line (TgTPH2-CreERT2; (Weber et al, 2009) to generate homozygous TgTPH2-CreERT2/Gria1fl/fl mice. Transgenic TgTPH2-CreERT2 mice were previously generated by DNA microinjection into the pronucleus of C57BL/6N mouse oocytes, and transgenic offspring were always maintained on a C57BL/6N background. Gria1fl/fl mice were generated by homologous recombination in R1 embryonic stem cells (Zamanillo et al, 1999) that were injected in C57BL6/N blastocysts. Gria1fl/fl mice are available from Jackson laboratories (B6N.129-Gria1tm2Rsp/J). Gria1fl/fl mice were backcrossed on a C57BL/6N background to attain fully congenic C57BL/6N Gria1fl/fl mice before matings started with TgTPH2-CreERT2 mice.
To generate 5-HT neuron-specific Gria1-knockout mice (Gria15-HT−/−), adult (9–12 weeks), TgTPH2-CreERT2/Gria1fl/fl mice were injected twice daily for five consecutive days with 1 mg (100 μl) of tamoxifen i.p. (Sigma) (dissolved in a vehicle of corn oil/ethanol (10 : 1)). This tamoxifen induction protocol has previously shown superior recombination rates (Leone et al, 2003; Mori et al, 2006) and showed highly efficient recombination when used with TgTPH2-CreERT2 mice (Weber et al, 2009). Gria1fl/fl littermates receiving tamoxifen as above served as the control group.
PCR-Based Detection of Raphe Nuclei-Specific Gria1 Gene Deletion
Four weeks after tamoxifen treatment, brains were dissected and snap-frozen. Brain region-specific tissue punches of the dorsal raphe nucleus (DRN) and the cerebellum were cut on a cryostat (Leica). The following primers were used to detect the 250-bp fragment of the non-recombined loxP-flanked Exon 11 of Gria1: MH60 (5′-CACTCACAGCAATGAAGCAGGAC-3′) and 3int3′ (5′-CTGCCTGGGTAAAGT GACTTGG-3′). The primers 1005 (5′-AATGCCTAGTACTATAGTGCACG-3′) and 3int3′ detect both the non-recombined loxP-flanked exon 11 of Gria1 at 1500 bp and the recombined deleted exon 11 at 250 bp. All PCR reactions were performed as follows: 94 °C denaturation for 4 min; 35 cycles of 94 °C denaturation for 30 s, 60 °C annealing for 30 s, 72 °C elongation for 30 s and finally 72 °C elongation for 4 min.
Immunohistochemical Detection of 5-HT Neuron-Specific Loss of GLUA1 Protein
Immunohistochemistry (IHC) was carried out using dual-label immunofluorescence as previously described (Aguado et al, 2013). In brief, after perfusion and postfixation with 4 % PFA at 4 °C, 60 μm coronal sections were cut on a vibratome (Leica V1000). The following antibodies were used for IHC: rabbit anti-TPH2 (Dianova; 1 : 1000) mouse anti-GLUA1 (NeuroMab; 1 : 400). Secondary antibodies were goat anti-rabbit Alexa-488 (Life Technologies; 1 : 1000) and goat anti-mouse Alexa-498 (Life Technologies; 1 : 1000). Fluorescent signals were examined using a confocal laser-scanning microscope (Zeiss LSM 710). Images of slices showing staining for THP2 were acquired. The ratio of GLUA1−/TPH2+ neurons to all TPH2+ neurons was calculated separately for median and dorsal raphe nuclei in Gria1fl/fl (n=3) and Gria15-HT−/− (n=3) mice.
Neurochemistry
Concentrations of monoamines and their metabolites as well as TPH2 and Tyrosine Hydroxylase (TH) activity were determined in Gria1fl/fl and Gria15-HT−/− mice 4 weeks after tamoxifen treatment (Berger et al, 2012) (see Supplementary Methods for details). Using punching needles, brain region-specific tissue samples punches were acquired from brain slices (200 μm) cut on a cryostat (Leica). For determination of the rate of TPH2 and TH activity, mice were injected with the L-aromatic amino acid decarboxylase inhibitor NSD 1015 (m-hydroxybenzyl-hydrazine; 100 mg/kg i.p.) 30 min before brain dissection. Accumulation of the serotonin and dopamine precursor molecules 5-hydroxytryptophan (5-HTP) and dihydroxyphenylalanine (L-DOPA) was determined.
TPH2 Western Blot
SDS–PAGE and immunoblot analyses with TPH2 antibodies (Dianova) were performed as described previously (Lau et al, 2010). Brains for quantitative immunoblot analysis were snap-frozen, and brain region-specific homogenates (midbrain raphe nuclei, hippocampus, prefrontal cortex) were prepared from Gria1fl/fl and Gria15-HT−/− mice. IR-dye conjugated secondary antibodies were detected using the Odysses CLx imaging system (Li-Cor Biosciences). Macro-based quantification of TPH2 signals was performed using the ImageJ software (NIH). TPH2-dependent fluorescence intensities (A.U.) were measured as intensity/area covered by immuoreactive bands. For each brain region, lysates of five animals were immunoblotted.
Extracellular Electrophysiology
Gria1fl/fl and Gria15-HT−/− mice aged 14–16 weeks were taken from the home cage and briefly anesthetized with Isoflurane and killed by cervical dislocation. Coronal slices (300 μm thick) containing the DRN were prepared, and recordings of the firing activity of presumed 5-HT neurons in the continuous presence of the α1-adrenoceptor agonist phenylephrine (PE, 3 μM) were made using glass microelectrodes as described previously (Ayissi Mbomo et al, 2012). Multiple units encountered during multiple electrode tracks through the DRN were recorded. The waveform signal was recorded at 10 KHz using Spike2 (version 4.02) (CED) and stored for off-line analysis. Isolated units were tested with 2-min pulses of 5-HT (50 μM) and AMPA (1 and 3 μM). All drug solutions were made up in aCSF containing PE (3 μM).
Offline, spikes were converted to events in Spike2 (CED) or Offline sorter (Plexon) using thresholding and/or template matching (Spike2) or principal component analysis (Offline sorter). The basal firing rate (in the presence of PE) was determined in a 2-min period at the start of the recording: the waveform average and interspike interval histogram were also examined in this period. To quantify drug responses, firing rates were determined during the 2 min baseline before each drug and in a period of 2 min following drug application, covering the maximum change from the baseline. Responses to 5-HT are quoted as % inhibition (reduction in firing rate during 5-HT perfusion as a percentage of the baseline rate) and responses to AMPA are quoted as extra spikes (i.e., number of spikes above baseline firing during the 2 min drug response).
8-OH-DPAT-Induced Hypothermia
The hypothermic response to 5-HT1A receptor activation was assessed in Gria1fl/fl and Gria15-HT−/− mice. Mice were singly housed in clean cages for 10 min and three baseline rectal temperature measurements were then taken at 15 min intervals. Immediately after the third baseline measurement, animals received 8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT; Sigma) intraperitoneally (0.5 mg/kg) and body temperature was monitored every 15 min for a total of 90 min. The dose of 0.5 mg/kg 8-OH-DPAT has previously been shown to produce a robust, but submaximal, hypothermic response in mice thus excluding the possibility of a ceiling effect (Goodwin et al, 1985a).
Behavioral Experiments
Behavioral experiments were conducted at least 4 weeks after the last tamoxifen injection (Vogt et al, 2008). Male mice were single-housed in a reversed dark-light cycle and were supplied with food and water ad libitum. All experiments were performed during the dark cycle. Animals were subjected to tests of locomotion, exploration, anxiety, depression, and learning and memory. To avoid interference between the different tests, three clusters of tests were used: one cohort was subjected to Novel Cage Test, Open field and Novel Object Exploration, Dark–Light-Box, Hotplate Test, Tail Suspension Test, Porsolt Forced Swim Test and Learned Helplessness Paradigm, a second cohort performed Open field and Novel Object Exploration, Hotplate Test, Fear Conditioning and Morris Water Maze; and a third cohort was assigned to Novel Cage Test, Open field and Novel Object Exploration, Elevated O-Maze, Dark-Light-Box and Conditioned Taste Aversion. An additional cohort was assigned to the tail-flick test. Animals were randomly assigned to one cohort, resulting in animal numbers of 10–14 animals per genotype per cohort. To reduce the confounding effects of previous test situations potentially interfering with subsequent behavioral testing, we applied a test order from less to more stressful tests (Chourbaji et al, 2008a; McIlwain et al, 2001) and assessed the behavior with a minimum interval of 48 h between different tests, with longer intervals up to 14 days after more stressful, exhausting or aversive tests (eg, Porsolt Forced Swim Test, Fear Conditioning).
Open Field and Novel Object Exploration
As previously described (Hellweg et al, 2007), activity monitoring was conducted in a square, white, open field, measuring 50 × 50 cm2 and illuminated from above with dim red light. Data were analyzed using the image processing system EthoVision 3.0 (Noldus Information Technology, Wageningen, The Netherlands). Parameters assessed were distance moved, velocity, and time in center. After 10 min, a novel object was introduced into the middle of the arena. Object exploration was assessed for 10 min, recording the latency of first approach, as well as the total number of approaches (Gria1fl/fl: n=37; Gria15-HT−/−: n=37).
Novel Cage
Animals were placed into a novel environment (macrolon cage type II) with a thin layer of bedding, as described previously (Chourbaji et al, 2006). Rearings were counted for 300 s (Gria1fl/fl: n=25; Gria15-HT−/−: n=24).
Dark–Light Box
The Dark–Light Box consisted of a dark and a 600 lux illuminated plastic chamber, connected by a tunnel as described previously (Fuss et al, 2010). Mice were placed into the dark compartment and latency to first exit, number of exits, and total time in the light compartment were recorded for 5 min (Gria1fl/fl: n=25; Gria15-HT−/−: n=24).
Elevated O-Maze
The maze consists of a gray plastic annular runway (width 6 cm, outer diameter 46 cm, 50 cm above ground level) with two opposing 90° sectors protected by walls (height 10 cm). As previously described (Fuss et al, 2010), animals were placed in one of the protected sectors and observed for 5 min analyzing latency to first exit, number of exits, and total time spent in the open parts (Gria1fl/fl: n=11; Gria15-HT−/−: n=10).
Porsolt Forced Swim Test
Mice were placed into a glass cylinder (23 cm height, 13 cm diameter) filled with water (21 °C) up to a height of 12 cm, as described earlier (Chourbaji et al, 2006). During a test period of 6 min, onset of immobility and percentage of time spent immobile were determined using EthoVision 3.0 (Gria1fl/fl: n=14; Gria15-HT−/−: n=13).
Tail Suspension Test
As previously described (Chourbaji et al, 2006), mice were suspended by their tails with adhesive tape attached to a hook, which was coupled to a computer-assisted energy meter (Bioseb, Chaville, France). A test session lasted 6 min, during which the time spent immobile and the latency to become immobile were determined (Gria1fl/fl: n=14; Gria15-HT−/−: n=13).
Learned Helplessness
The learned helplessness paradigm is a depression model in which an animal is exposed to unpredictable and uncontrollable stressors (Chourbaji et al, 2006; Chourbaji et al, 2005). See Supplementary Methods for a detailed description of the experimental procedure.
Fear Conditioning
For contextual and cued conditioning, mice were placed into the conditioning chamber and conditioning was performed as described in detail in Supplementary Methods (Strekalova et al, 2003).
Morris Water Maze
The Morris Water Maze is a test for spatial reference memory, in which the animals have to find an escape platform hidden under the surface of opaque water in a circular pool (von Bohlen und Halbach et al, 2006) (see Supplementary Methods for details).
Conditioned Taste Aversion
Conditioned taste aversion (CTA) is a form of classical conditioning, in which mice associate drinking saccharin (conditioned stimulus-CS) with a subsequent unpleasant sensation, that is, nausea (unconditioned stimulus-US) induced by lithium chloride (LiCl) (Balschun et al, 2003; see Supplementary Methods for details).
Hotplate Test
Mice were tested on the Hotplate (ATLab, Vendargues, France) set at 53 °C (+/−0.3 °C) for 45 s (Chourbaji et al, 2008b). Latency to first reaction, that is, licking hind paws or jumping, was assessed (Gria1fl/fl: n=26; Gria15-HT−/−: n=26).
Tail-flick Test
The tail-flick reflex was evoked by a heat stimulus applied via an infrared light source at the underside of the tail in unrestrained mice kept in Plexiglas enclosures (Tappe-Theodor et al, 2007; see Supplementary Methods for details).
Statistical Analysis
Statistical analyses were performed using SigmaPlot 11.0, GraphPad Prism 5 or SPSS 20. Inter-group comparisons were made by Student’s t-tests or Mann–Whitney U-test. Where appropriate, the model was complemented by within subject factors to explore the time-dependence of genotype effects. The parameters of the probe trial of the Morris Water Maze were assessed using a two-way mixed model ANOVA with genotype as between-factor and place as within-factor. Electrophysiological responses to AMPA were analyzed by two-way ANOVA on ranks with genotype and AMPA concentration as the two factors. Significance for all tests was set at p<0.05. Data are presented as mean±standard error (SEM) or median±interquartile range (IQR).
RESULTS
Evidence of 5-HT Neuron-Specific Gria1 Gene Deletion in Adult Gria15-HT−/− Mice
PCR on the samples from dorsal raphe was used to confirm recombination of the loxP-flanked exon 11 of the GLUA1 encoding gene Gria1 in tamoxifen-treated Gria15-HT−/− mice (Supplementary Results and Supplementary Figure S1). Upon verification of raphe nuclei-specific Gria1 recombination, we used double-fluorescence IHC to assess 5-HT neuron-specific recombination efficacy in tamoxifen-treated Gria1fl/fl and Gria15-HT−/− mice (Figure 1). TPH2 antibodies were used to define serotonergic neurons. In Gria15-HT−/− mice, GLUA1 was only present in 13.1% (SEM: ±0.92) of TPH2+ neurons, whereas in Gria1fl/fl controls 90.2% (SEM: ±0.43) of TPH2+ 5-HT neurons also exhibited GLUA1 staining indicating highly efficient Gria1 deletion in 5-HT neurons of Gria15-HT−/− mice (Supplementary Table S1). No differences in recombination efficacy were found between dorsal (mean: 12.9% TPH2+/GLUA1+ neurons, SEM: ±1.8) and median raphe nuclei (mean: 13.1% TPH2+/GLUA1+ neurons, SEM:±0.99) in Gria15-HT−/− mice.
Learning and Memory is Unaltered in Gria15-HT−/− Mice
In the Morris Water Maze (Supplementary Table S2), both Gria1fl/fl and Gria15-HT−/− mice showed decreasing search times and decreasing path length over the 24 training trials (latency: F11,253=8.8, p<0.001; path: F11,253=32.1, p<0.001; velocity: F11,253=1.645, p=0.087). Although Gria15-HT−/− mice had comparable latencies (genotype: ns), there was a trend for reduced distances to reach the platform compared with controls (F1,23=4.2, p=0.053), an effect that was not caused by higher swim speed (genotype: ns). In the probe trial on day 5, both Gria1fl/fl and Gria15-HT−/− mice displayed a significant preference for the target quadrant (F1,22=7.6, p=0.011) as well as an increased number of crossings over the previous platform position (F1,22=15.4, p=0.001). Again, Gria15-HT−/− mice did not differ from controls in reference memory performance as shown by non-significant genotype and interaction effects.
Similarly, in fear conditioning, Gria15-HT−/− mice displayed comparable memory retention in both context and cued version of the test (Supplementary Table S2).
In the conditioned taste aversion test, there was no significant difference in saccharin preference between the sessions conducted 48 h and 14 days after the conditioning session, and Gria15-HT−/− mice did not differ from controls at either time point (Supplementary Table S2).
Altered nociception was excluded as a confounding factor as Gria1fl/fl and Gria15-HT−/− mice did not behave differently on the hotplate and tail-flick test (Supplementary Table S2).
Gria15-HT−/− Mice Display Unaltered Depressive-Like Behavior
In the Tail Suspension Test, latency to become immobile and total immobility times were consistent across the two consecutive test days and Gria15-HT−/− mice did not differ from control mice (Figure 2a and b).
In the Porsolt Forced Swim Test, both genotypes showed reduced latency to become immobile (F1,25=67.7, p<0.001; Figure 2c) and reduced total immobility time (F1,25=13.6, p=0.001; Figure 2d) on the second compared with the first day. Gria15-HT−/− mice did not differ from control mice in terms of latency or total immobility time.
In the Learned Helplessness Paradigm, there was no difference in escape latency or number of failures between Gria1fl/fl and Gria15-HT−/− mice (Figure 2e and f).
Distinct Anxiety Phenotype in Gria15-HT−/− Mice
In the Novel Cage Test, Gria15-HT−/− mice made 20% fewer rearings than controls (p=0.027; Figure 3a).
In the Open Field Test, Gria15-HT−/− mice behaved similarly to controls with respect to locomotion (distance moved, velocity) and spatial activity patterns (time in center, mean distance to walls). During the habituation phase, there were significant time-dependent effects (distance moved: F1,72=178.8, p<0.001; velocity: F1,72=171.8, p<0.001; distance to walls: F1,72=206.3, p<0.001; center time: F1,72=169.2, p<0.001) but no significant differences between genotypes. However, when a novel object was introduced, Gria15-HT−/− mice showed increased latency to approach the novel object (p=0.014; Figure 3b) and a non-significant trend toward a decrease in the number of approaches compared with controls (p=0.062; Figure 3c).
In the Elevated O-Maze, Gria15-HT−/− mice demonstrated a distinct anxiety-like phenotype with increased latency to enter the anxiety-related unsheltered parts (p=0.030; Figure 3d) and decreased number of entries into the unsheltered parts (p=0.008; Figure 3e). Gria15-HT−/− mice also spent less time in the unsheltered parts of the maze (p=0.004; Figure 3f).
In the Dark–Light Box, Gria15-HT−/− mice displayed a similar pattern of anxiety-like behavior with decreased numbers of exits from the dark compartment (p<0.001; Figure 3h) and decreased time spent in the light compartment (p=0.019; Figure 3i). The latency to enter the anxiety-related light compartment also showed a non-significant trend toward an increase in Gria15-HT−/− mice (p=0.065; Figure 3g).
Reduced TPH2 Activity and Expression in the Raphe Nuclei of GRIA15-HT−/− Mice
TPH2 catalyzes the initial and rate-limiting step of 5-HT synthesis from tryptophan to 5-HTP. In Gria15-HT−/− mice, the accumulation of 5-HTP after administration of NSD 1015 was significantly lower (45%) than in controls in the midbrain raphe nuclei (p<0.001) but was unchanged in the projection areas of 5-HT neurons in the hippocampus, striatum, and prefrontal cortex (Table 1). In the same animals and brain regions, the accumulation of the dopamine precursor L-DOPA, reflecting the activity of tyrosine hydroxylase, did not differ between genotypes. In immunoblots of midbrain raphe lysates, we found that TPH2 protein expression was significantly reduced by 14% in Gria15-HT−/− mice compared with controls (p<0.05; Figure 4a and b). Similar to 5-HTP accumulation, TPH2 expression in the projection areas of 5-HT neurons was not decreased.
Reduced Serotonin and Norepinephrine Tissue Levels in the Midbrain Raphe Nuclei of Gria15-HT−/− Mice
Consistent with the reduced TPH2 expression and 5-HTP accumulation in the midbrain of Gria15-HT−/− mice, tissue levels of 5-HT were reduced by 41% relative to controls (p=0.006), while levels of the 5-HT metabolite 5-HIAA were decreased by 33% (p=0.029) (Table 1). In this region, we also found that tissue levels of NE were reduced by 40% in Gria15-HT−/− mice relative to controls (p=0.002). In contrast, in the projection areas of 5-HT neurons, levels of 5-HT and NE, and their metabolites, did not differ between Gria1fl/fl and Gria15-HT−/− mice.
Enhanced AMPA Receptor Mediated Excitation And Attenuated 5-HT1A Autoreceptor-Mediated Inhibition in DRN 5-HT Neurons
Extracellular recordings were made from 73 neurons in the dorsal raphe nuclei of slices from six Gria1fl/fl and six Gria15-HT−/− mice (2–8 neurons per animal). All neurons had broad, biphasic (negative/positive), or triphasic (positive/negative/positive) waveforms (Figure 5a and b) and fired regularly. After examination of the distribution of basal firing rates, five outliers (three from Gria15-HT−/− mice and two from Gria1fl/fl mice) with basal firing rates above 10 Hz were excluded from further analysis. For the remaining cells, there was no difference between groups in the basal firing rate (Median (IQR) 1.78 (1.13–3.88 (34) Gria1fl/fl vs 2.24 (1.38–3.64 (34) Gria15-HT−/−; Mann–Whitney U-test) (Figure 5c). In the majority of neurons, firing was partially inhibited by application of 5-HT (50 μM, 2 min) (Figure 5a and b). The inhibitory effect of 5-HT was significantly smaller in the Gria15-HT−/− group than in the control group (percentage inhibition: 50.6±6.16% (31) Gria1fl/fl vs 23.7±5.6 (33) Gria15-HT−/−; t test p<0.05; Figure 5d). AMPA (1 and 3 μM, 2 min) evoked short-lived, concentration-dependent increases in firing rate in all neurons tested (Figure 5a and b). The excitatory effect of AMPA was significantly greater in the Gria15-HT−/− group than in the control group (Figure 5e). Thus, two-way ANOVA on ranks revealed a significant main effect of AMPA concentration (F1,115=54.1, p<0.001) and a significant main effect of genotype (F1,115=9.9, p=0.002); there was no significant interaction.
5-HT1A-Autoreceptor-Mediated Hypothermia is Unaffected
Injection of the 5-HT1A autoreceptor agonist 8-OH-DPAT elicited a hypothermic response over the following 90 min (F5,65=41.4, p<0.001; Supplementary Figure S2). However, the time-course and magnitude of the response did not differ between genotypes.
DISCUSSION
Here we examined the consequences of a selective tamoxifen-induced conditional deletion of the GLUA1-encoding Gria1 gene in 5-HT neurons of adult mice. Using PCR and immunohistochemistry, we confirmed recombination of floxed Gria1 alleles in the raphe nuclei and loss of GLUA1 protein in the majority of 5-HT neurons in Gria15-HT−/− mice. Behavioral testing revealed that Gria15-HT−/− mice showed increased anxiety-like behavior in the Novel Cage Exploration, Novel Object Exploration, Elevated O-Maze, and Dark-Light Box compared with controls. Biochemical measures demonstrated that Gria15-HT−/− mice had reduced TPH2 expression and activity in the raphe nuclei, and concomitant reductions in tissue levels of 5-HT and its metabolite 5-HIAA, as well as NE. In contrast, there were no differences between controls and Gria15-HT−/− mice in these biochemical measures in the projection areas of 5-HT neurons. The basal firing of 5-HT neurons driven by stimulation of α1-adrenoceptors did not differ between genotypes, but the excitatory effect of AMPA on 5-HT firing was enhanced in the Gria15-HT−/− mice compared with controls. We also found that 5-HT1A autoreceptor-mediated inhibition of 5-HT neuronal firing was attenuated in Gria15-HT−/− mice, but the autoreceptor-mediated hypothermic response to the 5-HT1A agonist 8-OH-DPAT was unaltered.
Evidence for a Selective Loss of GLUA1
Gria1 mRNA has been demonstrated in most neuronal populations of the brain including the ascending raphe nuclei (Gold et al, 1997; Sato et al, 1993), but Gria1 mRNA or GLUA1 protein expression specifically in serotonergic neurons has not, as yet, been confirmed. Here we show that in control mice GLUA1 is present in the overwhelming majority of DRN and MRN neurons, which co-label for TPH2 (and hence are presumed to be 5-HT neurons). GLUA1 was also seen in the neuropil of controls suggesting that GLUA1 is also present in non-5-HT neurons in the midbrain. In Gria15-HT−/− mice, the co-localization of TPH2 and GLUA1 was massively reduced indicating that only a small proportion of 5-HT neurons retained GLUA1 expression.
Behavioral Phenotype
Here we found that mice lacking GLUA1 selectively in 5-HT neurons display a selective anxiety phenotype. Anxiety-like behavior was increased in a number of test paradigms, which rely on the conflict between the animals’ drive to exploratory behavior and their risk avoidance. In contrast, we found no changes in tests of depressive-like behaviors (Porsolt forced swim, learned helplessness) or in measures of hippocampus-dependent (Morris water maze), amygdala-dependent (fear conditioning), and hippocampus-independent (conditioned taste aversion) learning and memory paradigms. Locomotion and nociception were also unaltered.
Mice lacking GLUA1 globally throughout their lifetime display profound impairments in spatial working memory linked to increased long-term memory for novel space (Sanderson and Bannerman, 2012; Sanderson et al, 2011). They also show mild deficits in motor coordination (Bannerman et al, 2004) and massive novelty induced hyperlocomotion (Bannerman et al, 2004; Chourbaji et al, 2008c; Vekovischeva et al, 2001). Global Gria1-knockout mice have also been shown to exhibit increased learned helplessness (Chourbaji et al, 2008c) as well as mania- and schizophrenia-related behavioral abnormalities (Barkus et al, 2012; Fitzgerald et al, 2010; Wiedholz et al, 2008). The involvement of many different GLUA1-deficient neuronal populations probably underlies the observed complex phenotype. Indeed under these circumstances, it is virtually impossible to infer the specific neuronal population responsible for any identified behavioral ‘symptom’. Hence, it is not surprising that complex and conflicting results for anxiety-related behavior have also been reported in global Gria1-knockouts (Barkus et al, 2012). Increased anxiety-like behavior has been shown in the hyponeophagia test (Bannerman et al, 2004), while reduced anxiety-like behavior was found in the elevated plus maze and Dark–Light Box (Fitzgerald et al, 2010; Vekovischeva et al, 2004). This apparent inconsistency could be a result of the impaired short-term habituation and novelty induced hyperlocomotion in global Gria1-knockouts that complicate analysis of anxiety behavior (Barkus et al, 2012; Chourbaji et al, 2008c; Wiedholz et al, 2008).
An explanation for the discrepancy between global and 5-HT neuron-specific Gria1 knockouts is the possibility that a lack of GLUA1 in non-5-HT neurons of global Gria1 knockouts conceals the anxiety-like behavior resulting from a loss of GLUA1 in 5-HT neurons. Alternatively, it may be that developmental adaptive mechanisms tend to offset the effects of a GLUA1 loss in 5-HT neurons. To decipher the contribution of specific neuronal populations to the Gria1-knockout phenotype, other investigators have also turned to the CreERT2/loxP-system to achieve inducible and tissue-specific Gria1-deletions in adult mice (Engblom et al, 2008; Inta et al, 2013; Vogt et al, 2014). Interestingly, the selective deletion of Gria1 in neither dopaminergic neurons nor in forebrain glutamatergic neurons leads to an anxiety phenotype (personal communication Ainhoa Bilbao; (Vogt et al, 2014)) supporting the view, that it is only a Gria1-deletion in 5-HT neurons that induces an anxiety phenotype. The fact that we observed increased anxiety-related behavior in animals with a manipulation of 5-HT neurons is not surprising as this neurotransmitter system has been implicated in the evolution of anxiety (Leonardo and Hen, 2008).
Mechanisms Underlying the Behavioral Phenotype
Activation of AMPA receptors in the DRN increases the firing rate of 5-HT neurons (Gartside et al, 2007) and increases 5-HT release both locally and in terminal regions (Tao and Auerbach, 2000). Using in vitro extracellular electrophysiology, we recorded DRN neurons with broad action potentials and regular, low frequency, firing in the presence of phenylephrine. These presumed 5-HT neurons are similar in firing rate, pattern and action potential shape to phenotypically identified 5-HT neurons (Aghajanian et al, 1983) in the rat and similar to those reported by us previously in the mouse DRN (Ayissi Mbomo et al, 2012). As we have previously observed in rat (Gartside et al, 2007) and mouse (Ayissi Mbomo et al, 2012), all presumed 5-HT neurons showed a concentration-dependent excitatory AMPA response. Our immunohistochemistry confirmed the expression of GLUA1 in virtually all DRN 5-HT neurons of control mice and showed that there was an almost complete loss of GLUA1 in 5-HT neurons of Gria15-HT−/− mice. The fact that the AMPA response was greater in Gria15-HT−/− mice strongly suggests that, in normal animals, the GLUA1 subunit is an important determinant of the AMPA response. However, the fact that, when GLUA1 is lost, AMPA sensitivity of DRN 5-HT neurons was enhanced (rather than abolished) in Gria15HT–/– mice suggests an upregulation of other AMPA receptor subunits or their postranscriptional splice forms and that receptors thus constructed produce a greater response for a given concentration of AMPA. In previous work we observed that AMPA receptor-mediated synaptic responses in the hippocampal CA1 pyramidal cells of global Gria1-knockout mice are preserved indicating that, for synaptic transmission, the missing GluA subunits can be substituted by other AMPA receptor subunits (Zamanillo et al, 1999). Dense expression of both Gria2 and Gria4 subunit mRNA and low Gria3 mRNA expression have been reported previously in the ascending raphe nuclei of the midbrain (Gold et al, 1997; Sato et al, 1993). Thus, we hypothesize the enhanced AMPA response observed in 5-HT neurons lacking GLUA1 is mediated by receptors composed of the remaining subunits, which effectively substitute for GLUA1.
During quiet wake and in animals under anesthesia, AMPA receptors on 5-HT neurons do not appear to be tonically activated (Levine and Jacobs, 1992). However, some evidence suggests that AMPA-mediated glutamatergic tone does drive 5-HT firing during the active dark phase (Tao and Auerbach, 2000). The increase in AMPA receptor sensitivity we found in our Gria15HT–/– mice would be expected to lead to an enhancement of AMPA-driven 5-HT firing activity under such circumstances.
Here, we also determined the impact of 5-HT-specific GLUA1 depletion by measuring biochemical indices of 5-HT neuronal activity. In the midbrain of Gria15HT–/– mice, we found a small but significant decrease in TPH2 expression and a marked decrease in TPH2 activity as demonstrated by reduced 5-HTP accumulation. 5-HT and 5-HIAA levels were also reduced in the midbrain, most likely as a consequence of the diminished TPH2 activity in the same area. Interestingly, there were no changes in TPH2 expression and activity or 5-HT and 5-HIAA levels in terminal regions. While 5-HT synthesis in the cell bodies of 5-HT neurons supplies local 5-HT release in the midbrain, 5-HT released in the projection areas of 5-HT neurons is synthesized in the terminals (Carkaci-Salli et al, 2011; Gutknecht et al, 2009). A dissociation of TPH2 activity in cell body and terminal regions has been reported previously (Browne et al, 2011) suggesting differential regulation of TPH2 for somatodendritic 5-HT release in the raphe nuclei or for axonal/synaptic release in the innervated brain areas.
In addition to the effect of GLUA1 deficiency on the AMPA response, we observed that the response to 5-HT was attenuated in Gria15HT–/– mice. This response has previously been shown to be mediated by 5-HT1A autoreceptors (Fairchild et al, 2003; Johnson et al, 2002), suggesting Gria15HT–/– mice have reduced 5-HT1A autoreceptor sensitivity either via receptor downregulation or desensitization. However, using the behavioral test for 5-HT1A autoreceptor function, the 5-HT1A agonist 8-OHDPAT-induced hypothermia (Goodwin et al, 1985b), we found no changes in 5-HT1A autoreceptor sensitivity. This is in line with observations that 8-OHDPAT-induced hypothermia might be a less sensitive model of 5-HT1A activity than inhibition of 5-HT neuron firing (Fletcher et al, 1993; Kelai et al, 2008). The 5-HT1A autoreceptor is thought to be an important inhibitory regulator of 5-HT firing. The reduced 5-HT synthesis in our Gria15HT–/– mice would be expected to result in reduced local release of 5-HT in the DRN. The reduction in 5-HT1A autoreceptor sensitivity noted in the electrophysiology experiments coupled with reduced 5-HT release would be expected to result in reduced autoinhibition and hence an increased net firing rate of 5-HT neurons. Although changes in 5-HT1A autoreceptor function during development have been associated with increased anxiety behaviors, downregulation of 5-HT1A autoreceptors in adulthood has been shown not to impact on anxiety measures (Donaldson et al, 2013; Richardson-Jones et al, 2011). As we used an inducible system to achieve Gria1 deletion in adult Gria15HT–/– mice, the 5-HT1A autoreceptor desensitization/downregulation observed occurred during adulthood making it unlikely that 5-HT1A autoreceptor alterations are responsible for the observed anxiety phenotype.
Finally, we also examined NE levels and, surprisingly, found a significant decrease in the midbrain region, whereas NE levels were unchanged in all other brain areas examined. The TgTPH2-CreERT2 driver line is 5-HT neuron-specific (Weber et al, 2009) and thus only deletes the Gria1 gene in 5-HT neurons. Hence, this raphe-region-specific NE reduction must be an indirect effect of the GLUA1 loss in 5-HT neurons. Interestingly, mice with a homozygous Tph2 gene deletion reportedly have reduced levels of NE in the raphe nuclei (Gutknecht et al, 2012), suggesting that the reduction in NE might be an indirect consequence of the reduced TPH2 activity we observed.
NE acting through α1-adrenoceptors on 5-HT neurons is thought to be the major drive accounting for the pacemaker activity of 5-HT neurons in vivo in animals under anesthesia or during quiet wake (Baraban and Aghajanian, 1980; Sakai and Crochet, 2000). In our electrophysiology experiments, we found normal α1-adrenoceptor sensitivity suggesting that the observed decrease in NE in the raphe nuclei had not resulted in an increase in postsynaptic receptor sensitivity. The decrease in availability of NE in the DRN in the presence of normosensitive α1-adrenoceptors might be expected to result in reduced tonic firing of 5-HT neurons, at least during some phases of the sleep-wake cycle.
Taken together our biochemical and electrophysiological data suggest that a dysregulation of 5-HT firing underlies the behavioral anxiety-phenotype in Gria15HT–/– mice. 5-HT neuron-specific Gria1 deletion in adult mice results in enhanced AMPA receptor sensitivity and reduced TPH2 activity. Reduced 5-HT1A autoreceptor mediated inhibition and probably reduced α1-adrenoceptor-mediated tonic firing activity in 5-HT neurons are likely consequences of raphe nuclei specific reductions in 5-HT and NE. Our data suggest that Gria1 deletion triggers a combination of changes that alters 5-HT firing via different regulators including AMPA-receptors, α1-adrenoceptors and 5-HT1A autoreceptors that may all have a role in the mediation of anxiety.
FUNDING AND DISCLOSURE
This work was funded by grants from the German Ministry for Education and Research (BMBF, 01GQ1003B) National Bernstein Network for Computational Neuroscience (http://www.gesundheitsforschung-bmbf.de/en/2478.php#Heidelberg) to D.B and P.G. and from the Deutsche Forschungsgemeinschaft (SFB636-TP3) to P.G. S.E.G was the recipient of a Royal Society International Joint Project award. R.L was supported by grants from the Spanisch Ministry of Education and Science (CONSOLIDER CSD2008-00005). The authors declare no conflict of interest.
References
Aghajanian GK, Vandermaelen CP, Andrade R (1983). Intracellular studies on the role of calcium in regulating the activity and reactivity of locus coeruleus neurons in vivo. Brain Res 273: 237–243.
Aguado C, Fernandez-Alacid L, Cabanero MJ, Yanagawa Y, Schilling K, Watanabe M et al (2013). Differential maturation of GIRK2-expressing neurons in the mouse cerebellum. J Chem Neuroanat 47: 79–89.
Ayissi Mbomo R, Gartside S, Ngo Bum E, Njikam N, Okello E, McQuade R (2012). Effect of Mimosa pudica (Linn.) extract on anxiety behaviour and GABAergic regulation of 5-HT neuronal activity in the mouse. J Psychopharmacol 26: 575–583.
Balschun D, Wolfer DP, Gass P, Mantamadiotis T, Welzl H, Schutz G et al (2003). Does cAMP response element-binding protein have a pivotal role in hippocampal synaptic plasticity and hippocampus-dependent memory? J Neurosci 23: 6304–6314.
Bannerman DM, Deacon RM, Brady S, Bruce A, Sprengel R, Seeburg PH et al (2004). A comparison of GluR-A-deficient and wild-type mice on a test battery assessing sensorimotor, affective, and cognitive behaviors. Behav Neurosci 118: 643–647.
Baraban JM, Aghajanian GK (1980). Suppression of firing activity of 5-HT neurons in the dorsal raphe by alpha-adrenoceptor antagonists. Neuropharmacology 19: 355–363.
Barkus C, Feyder M, Graybeal C, Wright T, Wiedholz L, Izquierdo A et al (2012). Do GluA1 knockout mice exhibit behavioral abnormalities relevant to the negative or cognitive symptoms of schizophrenia and schizoaffective disorder? Neuropharmacology 62: 1263–1272.
Berger SM, Weber T, Perreau-Lenz S, Vogt MA, Gartside SE, Maser-Gluth C et al (2012). A functional Tph2 C1473G polymorphism causes an anxiety phenotype via compensatory changes in the serotonergic system. Neuropsychopharmacology 37: 1986–1998.
Browne CA, Clarke G, Dinan TG, Cryan JF (2011). Differential stress-induced alterations in tryptophan hydroxylase activity and serotonin turnover in two inbred mouse strains. Neuropharmacology 60: 683–691.
Carkaci-Salli N, Salli U, Kuntz-Melcavage KL, Pennock MM, Ozgen H, Tekin I et al (2011). TPH2 in the ventral tegmental area of the male rat brain. Brain Res Bull 84: 376–380.
Carver CS, Miller CJ (2006). Relations of serotonin function to personality: current views and a key methodological issue. Psychiatry Res 144: 1–15.
Celada P, Puig MV, Martin-Ruiz R, Casanovas JM, Artigas F (2002). Control of the serotonergic system by the medial prefrontal cortex: potential role in the etiology of PTSD and depressive disorders. Neurotox Res 4: 409–419.
Chourbaji S, Brandwein C, Vogt MA, Dormann C, Gass P (2008a). Evaluation of effects of previous exposure to an acute stressor before testing for depression-like behaviours in mice. Stress 11: 170–175.
Chourbaji S, Brandwein C, Vogt MA, Dormann C, Hellweg R, Gass P (2008b). Nature vs. nurture: can enrichment rescue the behavioural phenotype of BDNF heterozygous mice? Behav Brain Res 192: 254–258.
Chourbaji S, Urani A, Inta I, Sanchis-Segura C, Brandwein C, Zink M et al (2006). IL-6 knockout mice exhibit resistance to stress-induced development of depression-like behaviors. Neurobiol Dis 23: 587–594.
Chourbaji S, Vogt MA, Fumagalli F, Sohr R, Frasca A, Brandwein C et al (2008c). AMPA receptor subunit 1 (GluR-A) knockout mice model the glutamate hypothesis of depression. FASEB J 22: 3129–3134.
Chourbaji S, Zacher C, Sanchis-Segura C, Dormann C, Vollmayr B, Gass P (2005). Learned helplessness: validity and reliability of depressive-like states in mice. Brain Res Brain Res Protoc 16: 70–78.
Cools R, Roberts AC, Robbins TW (2008). Serotoninergic regulation of emotional and behavioural control processes. Trends Cogn Sci 12: 31–40.
Dayan P, Huys QJ (2009). Serotonin in affective control. Annu Rev Neurosci 32: 95–126.
Dingledine R, Borges K, Bowie D, Traynelis SF (1999). The glutamate receptor ion channels. Pharmacol Rev 51: 7–61.
Donaldson ZR, Piel DA, Santos TL, Richardson-Jones J, Leonardo ED, Beck SG et al (2013). Developmental effects of serotonin 1A autoreceptors on anxiety and social behavior. Neuropsychopharmacology 39: 291–302.
Engblom D, Bilbao A, Sanchis-Segura C, Dahan L, Perreau-Lenz S, Balland B et al (2008). Glutamate receptors on dopamine neurons control the persistence of cocaine seeking. Neuron 59: 497–508.
Fairchild G, Leitch MM, Ingram CD (2003). Acute and chronic effects of corticosterone on 5-HT1A receptor-mediated autoinhibition in the rat dorsal raphe nucleus. Neuropharmacology 45: 925–934.
Finger EC, Marsh AA, Buzas B, Kamel N, Rhodes R, Vythilingham M et al (2007). The impact of tryptophan depletion and 5-HTTLPR genotype on passive avoidance and response reversal instrumental learning tasks. Neuropsychopharmacology 32: 206–215.
Fitzgerald PJ, Barkus C, Feyder M, Wiedholz LM, Chen YC, Karlsson RM et al (2010). Does gene deletion of AMPA GluA1 phenocopy features of schizoaffective disorder? Neurobiol Dis 40: 608–621.
Fletcher A, Bill DJ, Bill SJ, Cliffe IA, Dover GM, Forster EA et al (1993). WAY100135: a novel, selective antagonist at presynaptic and postsynaptic 5-HT1A receptors. Eur J Pharmacol 237: 283–291.
Fuss J, Ben Abdallah NM, Hensley FW, Weber KJ, Hellweg R, Gass P (2010). Deletion of running-induced hippocampal neurogenesis by irradiation prevents development of an anxious phenotype in mice. Plos one 5:e12769.
Gartside SE, Cole AJ, Williams AP, McQuade R, Judge SJ (2007). AMPA and NMDA receptor regulation of firing activity in 5-HT neurons of the dorsal and median raphe nuclei. Eur J Neurosci 25: 3001–3008.
Geyer MA, Vollenweider FX (2008). Serotonin research: contributions to understanding psychoses. Trends Pharmacol Sci 29: 445–453.
Gold SJ, Ambros-Ingerson J, Horowitz JR, Lynch G, Gall CM (1997). Stoichiometries of AMPA receptor subunit mRNAs in rat brain fall into discrete categories. J Comp Neurol 385: 491–502.
Goodwin GM, De Souza RJ, Green AR (1985a). The pharmacology of the hypothermic response in mice to 8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT). A model of presynaptic 5-HT1 function. Neuropharmacology 24: 1187–1194.
Goodwin GM, De Souza RJ, Green AR (1985b). Presynaptic serotonin receptor-mediated response in mice attenuated by antidepressant drugs and electroconvulsive shock. Nature 317: 531–533.
Gordon JA, Hen R (2004). Genetic approaches to the study of anxiety. Annu Rev Neurosci 27: 193–222.
Gutknecht L, Araragi N, Merker S, Waider J, Sommerlandt FM, Mlinar B et al (2012). Impacts of brain serotonin deficiency following Tph2 inactivation on development and raphe neuron serotonergic specification. PLoS ONE 7: e43157.
Gutknecht L, Kriegebaum C, Waider J, Schmitt A, Lesch KP (2009). Spatio-temporal expression of tryptophan hydroxylase isoforms in murine and human brain: convergent data from Tph2 knockout mice. Eur Neuropsychopharmacol 19: 266–282.
Hellweg R, Zueger M, Fink K, Hortnagl H, Gass P (2007). Olfactory bulbectomy in mice leads to increased BDNF levels and decreased serotonin turnover in depression-related brain areas. Neurobiol Dis 25: 1–7.
Heninger GR (1997). Serotonin, sex, and psychiatric illness. Proc Natl Acad Sci USA 94: 4823–4824.
Inta D, Vogt MA, Elkin H, Weber T, Lima-Ojeda JM, Schneider M et al (2013). Phenotype of mice with inducible ablation of GluA1 AMPA receptors during late adolescence: relevance for mental disorders. Hippocampus 24: 424–435.
Jacobs BL, Azmitia EC (1992). Structure and function of the brain serotonin system. Physiol Rev 72: 165–229.
Jensen V, Kaiser KM, Borchardt T, Adelmann G, Rozov A, Burnashev N et al (2003). A juvenile form of postsynaptic hippocampal long-term potentiation in mice deficient for the AMPA receptor subunit GluR-A. J Physiol 553: 843–856.
Johnson DA, Gartside SE, Ingram CD (2002). 5-HT1A receptor-mediated autoinhibition does not function at physiological firing rates: evidence from in vitro electrophysiological studies in the rat dorsal raphe nucleus. Neuropharmacology 43: 959–965.
Kelai S, Renoir T, Chouchana L, Saurini F, Hanoun N, Hamon M et al (2008). Chronic voluntary ethanol intake hypersensitizes 5-HT(1A) autoreceptors in C57BL/6J mice. J Neurochem 107: 1660–1670.
Lau T, Schneidt T, Heimann F, Gundelfinger ED, Schloss P (2010). Somatodendritic serotonin release and re-uptake in mouse embryonic stem cell-derived serotonergic neurons. Neurochem Int 57: 969–978.
Leonardo ED, Hen R (2008). Anxiety as a developmental disorder. Neuropsychopharmacology 33: 134–140.
Leone DP, Genoud S, Atanasoski S, Grausenburger R, Berger P, Metzger D et al (2003). Tamoxifen-inducible glia-specific Cre mice for somatic mutagenesis in oligodendrocytes and Schwann cells. Mol Cell Neurosci 22: 430–440.
Levine ES, Jacobs BL (1992). Neurochemical afferents controlling the activity of serotonergic neurons in the dorsal raphe nucleus: microiontophoretic studies in the awake cat. J Neurosci 12: 4037–4044.
Lucki I (1998). The spectrum of behaviors influenced by serotonin. Biol Psychiatry 44: 151–162.
Mann JJ (2003). Neurobiology of suicidal behaviour. Nat Rev Neurosci 4: 819–828.
McIlwain KL, Merriweather MY, Yuva-Paylor LA, Paylor R (2001). The use of behavioral test batteries: effects of training history. Physiol Behav 73: 705–717.
Mori T, Tanaka K, Buffo A, Wurst W, Kuhn R, Gotz M (2006). Inducible gene deletion in astroglia and radial glia—a valuable tool for functional and lineage analysis. Glia 54: 21–34.
Pardo CA, Eberhart CG (2007). The neurobiology of autism. Brain Pathol 17: 434–447.
Richardson-Jones JW, Craige CP, Nguyen TH, Kung HF, Gardier AM, Dranovsky A et al (2011). Serotonin-1A autoreceptors are necessary and sufficient for the normal formation of circuits underlying innate anxiety. J Neurosci 31: 6008–6018.
Rogers RD (2011). The roles of dopamine and serotonin in decision making: evidence from pharmacological experiments in humans. Neuropsychopharmacology 36: 114–132.
Sakai K, Crochet S (2000). Serotonergic dorsal raphe neurons cease firing by disfacilitation during paradoxical sleep. Neuroreport 11: 3237–3241.
Sanderson DJ, Bannerman DM (2012). The role of habituation in hippocampus-dependent spatial working memory tasks: evidence from GluA1 AMPA receptor subunit knockout mice. Hippocampus 22: 981–994.
Sanderson DJ, Good MA, Seeburg PH, Sprengel R, Rawlins JN, Bannerman DM (2008). The role of the GluR-A (GluR1) AMPA receptor subunit in learning and memory. Prog Brain Res 169: 159–178.
Sanderson DJ, Hindley E, Smeaton E, Denny N, Taylor A, Barkus C et al (2011). Deletion of the GluA1 AMPA receptor subunit impairs recency-dependent object recognition memory. Learn Mem 18: 181–190.
Sato K, Kiyama H, Tohyama M (1993). The differential expression patterns of messenger RNAs encoding non-N-methyl-D-aspartate glutamate receptor subunits (GluR1-4) in the rat brain. Neuroscience 52: 515–539.
Strekalova T, Zorner B, Zacher C, Sadovska G, Herdegen T, Gass P (2003). Memory retrieval after contextual fear conditioning induces c-Fos and JunB expression in CA1 hippocampus. Genes Brain Behav 2: 3–10.
Tao R, Auerbach SB (2000). Regulation of serotonin release by GABA and excitatory amino acids. J Psychopharmacol 14: 100–113.
Tappe-Theodor A, Agarwal N, Katona I, Rubino T, Martini L, Swiercz J et al (2007). A molecular basis of analgesic tolerance to cannabinoids. J Neurosci 27: 4165–4177.
Vekovischeva OY, Aitta-Aho T, Echenko O, Kankaanpaa A, Seppala T, Honkanen A et al (2004). Reduced aggression in AMPA-type glutamate receptor GluR-A subunit-deficient mice. Genes Brain Behav 3: 253–265.
Vekovischeva OY, Zamanillo D, Echenko O, Seppala T, Uusi-Oukari M, Honkanen A et al (2001). Morphine-induced dependence and sensitization are altered in mice deficient in AMPA-type glutamate receptor-A subunits. J Neurosci 21: 4451–4459.
Vogt MA, Chourbaji S, Brandwein C, Dormann C, Sprengel R, Gass P (2008). Suitability of tamoxifen-induced mutagenesis for behavioral phenotyping. Exp Neurol 211: 25–33.
Vogt MA, Elkin H, Pfeiffer N, Sprengel R, Gass P, Inta D (2014). Impact of adolescent GluA1 AMPA receptor ablation in forebrain excitatory neurons on behavioural correlates of mood disorders. Eur Arch Psychiatry Clin Neurosci 264: 625–629.
von Bohlen und Halbach O, Zacher C, Gass P, Unsicker K (2006). Age-related alterations in hippocampal spines and deficiencies in spatial memory in mice. J Neurosci Res 83: 525–531.
Weber T, Bohm G, Hermann E, Schutz G, Schonig K, Bartsch D (2009). Inducible gene manipulations in serotonergic neurons. Front Mol Neurosci 2: 24.
Wiedholz LM, Owens WA, Horton RE, Feyder M, Karlsson RM, Hefner K et al (2008). Mice lacking the AMPA GluR1 receptor exhibit striatal hyperdopaminergia and 'schizophrenia-related' behaviors. Mol Psychiatry 13: 631–640.
Zamanillo D, Sprengel R, Hvalby O, Jensen V, Burnashev N, Rozov A et al (1999). Importance of AMPA receptors for hippocampal synaptic plasticity but not for spatial learning. Science 284: 1805–1811.
Zill P, Baghai TC, Zwanzger P, Schule C, Eser D, Rupprecht R et al (2004). SNP and haplotype analysis of a novel tryptophan hydroxylase isoform (TPH2) gene provide evidence for association with major depression. Mol Psychiatry 9: 1030–1036.
Acknowledgements
We kindly thank Professor Rohini Kuner (University Heidelberg) for the help with measurements of the tail flick latency. We kindly thank Lena Wendler and Christiane Brandwein for their help with animal care, revitalization, perfusions, tamoxifen injections, and genotyping.
Author information
Authors and Affiliations
Corresponding author
Additional information
Supplementary Information accompanies the paper on the Neuropsychopharmacology website
Supplementary information
Rights and permissions
About this article
Cite this article
Weber, T., Vogt, M., Gartside, S. et al. Adult AMPA GLUA1 Receptor Subunit Loss in 5-HT Neurons Results in a Specific Anxiety-Phenotype with Evidence for Dysregulation of 5-HT Neuronal Activity. Neuropsychopharmacol 40, 1471–1484 (2015). https://doi.org/10.1038/npp.2014.332
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/npp.2014.332
This article is cited by
-
Generalized and social anxiety disorder interactomes show distinctive overlaps with striosome and matrix interactomes
Scientific Reports (2021)
-
Fetal glucocorticoid receptor (Nr3c1) deficiency alters the landscape of DNA methylation of murine placenta in a sex-dependent manner and is associated to anxiety-like behavior in adulthood
Translational Psychiatry (2019)