Abstract
Decreased medial prefrontal cortex (mPFC) neuronal activity is associated with social defeat-induced depression- and anxiety-like behaviors in mice. However, the molecular mechanisms underlying the decreased mPFC activity and its prodepressant role remain unknown. We show here that induction of the transcription factor ΔFosB in mPFC, specifically in the prelimbic (PrL) area, mediates susceptibility to stress. ΔFosB induction in PrL occurred selectively in susceptible mice after chronic social defeat stress, and overexpression of ΔFosB in this region, but not in the nearby infralimbic (IL) area, enhanced stress susceptibility. ΔFosB produced these effects partly through induction of the cholecystokinin (CCK)-B receptor: CCKB blockade in mPFC induces a resilient phenotype, whereas CCK administration into mPFC mimics the anxiogenic- and depressant-like effects of social stress. We previously found that optogenetic stimulation of mPFC neurons in susceptible mice reverses several behavioral abnormalities seen after chronic social defeat stress. Therefore, we hypothesized that optogenetic stimulation of cortical projections would rescue the pathological effects of CCK in mPFC. After CCK infusion in mPFC, we optogenetically stimulated mPFC projections to basolateral amygdala or nucleus accumbens, two subcortical structures involved in mood regulation. Stimulation of corticoamygdala projections blocked the anxiogenic effect of CCK, although no effect was observed on other symptoms of social defeat. Conversely, stimulation of corticoaccumbens projections reversed CCK-induced social avoidance and sucrose preference deficits but not anxiogenic-like effects. Together, these results indicate that social stress-induced behavioral deficits are mediated partly by molecular adaptations in mPFC involving ΔFosB and CCK through cortical projections to distinct subcortical targets.
Introduction
Several anatomically and functionally interconnected limbic brain regions, including medial prefrontal cortex (mPFC), hippocampus, amygdala, and nucleus accumbens (NAc), are implicated in mediating key symptoms of depression and anxiety (Bremner, 1999; Drevets, 2001; Keedwell et al., 2005; Mayberg et al., 2005; Bremner, 2006, 2007; Krishnan and Nestler, 2008; Feder et al., 2009). For example, the absence of cortical feedback to amygdala is correlated with dysphoric emotions and reverts to normal levels upon successful treatment. The antidepressant effects of deep brain stimulation of subgenual cingulate cortex, an area of mPFC, are associated with restoration of both cortical and subcortical brain activity to normal levels (Mayberg et al., 2005; Nahas et al., 2010). Similarly, deep brain stimulation of NAc is antidepressant and anxiolytic and correlates with altered metabolism in NAc, amygdala, and mPFC (Schlaepfer et al., 2008; Bewernick et al., 2010; Grubert et al., 2011). These data support a neural network hypothesis of mood disorders in which antidepressant treatments, regardless of mechanisms, normalize activity in both underactive cortical and overactive subcortical circuits (Kennedy et al., 2001; Mayberg et al., 2005; Kennedy and Giacobbe, 2007; Fales et al., 2008; Fales et al., 2009; Leistedt and Linkowski, 2013).
Animal models involving chronic exposure to physical or psychological stress impair the structure and function of neurons in mPFC (Radley et al., 2006), amygdala (Akirav and Maroun, 2007), hippocampus (Surget et al., 2011), and NAc (Vialou et al., 2010; Christoffel et al., 2011). Chronic social defeat stress, an ethologically valid model of depression (Berton et al., 2006), decreases mPFC neuronal activity as inferred from reduced expression of Zif268 and c-Fos (Covington et al., 2005; Covington et al., 2010). Furthermore, optogenetic stimulation of mPFC reverses these deficits and exerts antidepressant-like effects (Covington et al., 2010), confirming the importance of mPFC in mood-related phenomena. The rodent mPFC, as in primates, controls emotional behavior in part through projections to basolateral amygdala (BLA) and NAc (Vogt et al., 1992; Barbas and Blatt, 1995; Heidbreder and Groenewegen, 2003). Nevertheless, the molecular mechanisms that mediate this role of mPFC remain unknown.
The present study focused initially on ΔFosB, a stable transcription factor that is induced in NAc by chronic social defeat stress where it opposes stress susceptibility (Vialou et al., 2010). We performed brain-wide mapping of ΔFosB induction after defeat stress and found, similar to earlier studies (Perrotti et al., 2004; Nikulina et al., 2008; Lehmann and Herkenham, 2011), robust induction in mPFC. Surprisingly, we found that such ΔFosB induction in mPFC promotes stress susceptibility. We identified the cholecystokinin (CCK)-B receptor as a molecular target of ΔFosB in mPFC, where CCKergic neurotransmission has been implicated in both anxiogenic and depressogenic effects of social stress (Becker et al., 2001, 2008). We found that CCK activity in mPFC is both necessary and sufficient for the anxiety- and depression-like effects of social stress. Moreover, by use of optogenetic approaches, we demonstrate specific actions of CCK in mPFC subcircuits: CCK in mPFC-BLA projections mediates anxiety symptoms, whereas CCK in mPFC-NAc projections mediates depression symptoms.
Materials and Methods
Experiment 1: brain-wide mapping of ΔFosB induction by chronic social defeat stress.
Eight-week-old C57BL/6J male mice were subjected to chronic social defeat stress for 10 consecutive days as described previously (Berton et al., 2006; Krishnan et al., 2007; Vialou et al., 2010) (see Table 1; Fig. 1A). Briefly, each mouse was exposed to an unfamiliar, aggressive male CD1 retired breeder mouse for 5 min per day. After direct interaction with the CD1 aggressor (5 min), animals were placed in an adjacent compartment of the same cage for the next 24 h with sensory, but not physical, contact. Control animals were housed in equivalent cages but with members of the same strain. Social interaction tests were performed 24 h after the final day of defeat. Social avoidance to an unfamiliar CD1 male mouse was assessed according to published protocols. The time spent in the “interaction zone” (an 8-cm-wide corridor surrounding the cage) was measured. Segregation of defeated mice into susceptible and resilient subpopulations was performed as described previously (Krishnan et al., 2007; Vialou et al., 2010). Because the majority of control mice spend more time interacting with a social target than with an empty target enclosure, an interaction ratio of 100 (equal time spent in the interaction zone in the presence vs absence of a social target) is used as a cutoff: mice with scores <100 are labeled as “susceptible,” and those with scores ≥100 as “resilient.” Extensive behavioral, biochemical, and electrophysiological analyses support the validity of these distinct susceptible and resilient subpopulations (Krishnan et al., 2007; Wilkinson et al., 2009; Vialou et al., 2010).
Right after the social interaction test, mice were anesthetized and perfused intracardially with 4% paraformaldehyde/PBS. Cell counts for ΔFosB+ neurons in NAc were performed as described previously (Vialou et al., 2010). Brains were cryoprotected with 30% sucrose and coronal sections (30 μm) were cut on a freezing microtome and processed for immunohistochemistry. Free-floating sections were preincubated in a blocking buffer containing 0.3% Triton and 3% normal goat serum. ΔFosB was detected using rabbit polyclonal antibodies raised against the N-terminal portion of the protein (1/1000 Santa Cruz Biotechnology, catalog #sc-48) in the same buffer, then processed with biotinylated goat anti-rabbit IgG antibodies and avidin–biotin peroxidase complex method with DAB as a substrate (Vector Laboratories). Diaminobenzidine incubation times were kept constant for all conditions (100 s). Slices were mounted, dehydrated, and coverslipped. ΔFosB-immunopositive cells showed a specific brown staining in the nucleus and were quantified by an observer blind to the treatment conditions using a microscope (20× magnification). Three selected brain sections spanning each brain area were chosen per mouse for quantification. Anatomical segregation of each brain region was performed by comparing the section with the Paxinos mouse brain atlas. Conditions for immunohistochemistry were optimized to reduce background levels to the minimum allowing the correct identification of ΔFosB-positive cells. Mean values were calculated for each animal and considered as an individual observation for statistical analysis. Although the antibody used recognizes both ΔFosB and full-length FosB, we know by Western blotting that only ΔFosB is detectable under the conditions studied (Perrotti et al., 2004; Vialou et al., 2010).
Experiment 2: identification of social stress-induced ΔFosB neuronal phenotype in mPFC.
To examine expression of ΔFosB in cortical GABAergic neurons, we used tissues from GAD2-tdTomato mice exposed to chronic social defeat stress and stained for ΔFosB as described above (see Fig. 1B). Mice were generated by breeding knockin GAD2-Cre mice (Gad2tm2(cre)Zjh/J; JAX stock number 010802) (Taniguchi et al., 2011) with (B6.Cg-Gt(ROSA)26Sortm9(CAG-tdTomato)Hze/J; JAX stock number 007908) that carry floxed-stop controlled tdTomato (RFP variant).
Experiment 3: behavioral effects of ΔFosB overexpression in the prelimbic (PrL) and infralimbic (IL) cortex.
Stereotaxic surgery was performed on adult male mice (8 weeks) to inject HSV-ΔFosB-GFP or HSV-GFP into the PrL or IL regions of mPFC. Briefly, mice were anesthetized using a mixture of ketamine (10 mg/kg) and xylazine (1 mg/kg), and the following stereotaxic coordinates were used for viral delivery for PrL: 1.8 mm (anterior/posterior), 0.65 mm (lateral), −2.2 mm (dorsal/ventral); and for IL: 1.9 mm (anterior/posterior), 0.75 mm (lateral), −2.8 mm (dorsal/ventral) at an angle of 10° from the midline (relative to bregma). A total of 0.5 μl of purified virus was delivered bilaterally over a 5 min period (0.1 μl/min) followed by 5 min of rest. Viral injection sites were confirmed using standard histological methods (see Fig. 1C). Although it is not possible to selectively target PrL versus IL in mice with perfect accuracy, the data in Figure 1C illustrate that it is very feasible to predominantly target one region or the other. Indeed, the distinct behavioral effects obtained from targeting the two regions (see Results) substantiate this approach. The first batch of mice was used exclusively in a submaximal social defeat experiment (see Fig. 1D). Three days after surgery, mice were subjected to two consecutive defeats on the same day and then tested for social interaction 24 h later. This submaximal defeat procedure has been validated previously to reveal prosusceptibility phenotypes following genetic manipulations (Krishnan et al., 2007; Vialou et al., 2010).
A second batch of mice was used to test for basal anxiety- and depressive-like behaviors (see Fig. 1E–J). A day after the surgery, mice were habituated with a 1% (w/v) sucrose solution. The following day, mice could choose between a water bottle and a 1% sucrose solution bottle, switched daily. Sucrose solution intake for 24 h was measured during the fourth and fifth day after surgery and expressed as a percentage of the total amount of liquid ingested. Mice were tested in the open-field (day 3), elevated plus maze (day 4), social interaction (day 5 morning), and forced swim (day 5 afternoon) tests based on published protocols (Vialou et al., 2010). We have found that, with this order of testing, results on subsequent tests are not affected by previous ones (Krishnan et al., 2007). The activity of mice in the open field was recorded for 5 min using a videotracking system (Ethovision) under red light conditions. The elevated plus maze consisted of two straight intersecting runways positioned 60 cm above the floor and divided into two open and two enclosed arms. Mice were individually placed at the center of the maze and allowed to freely explore each arm for a period of 5 min. In the open-field and elevated plus maze tests, time spent in the center and open arms, respectively, was used as an inverse index of anxiety-related responses. A one day forced swim test was conducted for a period of 5 min. Increased time of immobility during the forced swim test was interpreted as a prodepression-like behavior. This 1 day test has been used extensively in mice and validated as a measure of predictive validity, in that antidepressant drugs reduce immobility times.
Finally, a separate group of mice were injected intra-mOFC with HSV-ΔFosB and tested for social interaction after a submaximal defeat (see Fig. 1K).
HSV vectors were obtained from Rachael Neve (Massachusetts Institute of Technology). The genes of interest (ΔFosB and GFP) are under a CMV promoter. These vectors have been extensively validated in prior publications (e.g., Maze et al., 2010).
Experiment 4: effects of chronic social stress on CCKB receptor levels in mPFC.
At 24 h after the social interaction test, brains were quickly removed and serially sliced, and mPFC was rapidly dissected and frozen on dry ice (see Fig. 2A,B). RNA isolation, qPCR, and data analysis were performed as described previously (Maze et al., 2010; Vialou et al., 2010). RNA was isolated with TriZol reagent (Invitrogen) and was further purified with RNAeasy micro kits from QIAGEN. All RNA samples were determined to have 260/280 and 260/230 values ≥1.8. Reverse transcription was performed using iScript (Bio-Rad). qPCR using SYBR Green (Quanta) was performed with an Applied Biosystems 7900HT RT PCR system with the following cycle parameters: 2 min at 95°C; 40 cycles of 95°C for 15 s, 59°C for 30 s, and 72°C for 33 s; and graded heating to 95°C to generate dissociation curves for confirmation of single PCR products. Data were analyzed by comparing Ct values of the treatment condition (susceptible or resilient vs control mice, or HSV-ΔFosB vs HSV-GFP) with the ΔΔCt method (Tsankova et al., 2006). qPCR primers are as follows: ΔFosB, forward, AGGCAGAGCTGGAGTCGGAGAT and reverse, GCCGAGGACTTGAACTTCACTCG; CCKB, forward, ACCCTTTATGCGGTGATCTTTC and reverse, ATGAGCACGTTTCCGCCAA; CCK, forward, AGCGCGATACATCCAGCAG and reverse, ACGATGGGTATTCGTAGTCCTC; GAPDH, forward, AGGTCGGTGTGAACGGATTTG and reverse, TGTAGACCATGTAGTTGAGGTCA.
Experiment 5: effects of ΔFosB on CCKB receptor and cFos levels.
Mice were injected intra-PrL with HSV-ΔFosB. At 72 h after surgery, at the peak of viral overexpression, injection sites were dissected under a fluorescent microscope (see Fig. 2C). RNA isolation, qPCR, and data analysis were performed as described above. qPCR primers are as follows: c-fos, forward, AATCCGAAGGGAACGGAATAAGA and reverse, TGCAACGCAGACTTCTCATCT.
Experiment 6: effects of ΔFosB blockade on stress-induced CCKB receptor levels and resilience.
Adult mice were injected bilaterally with HSV-GFP or HSV-ΔJunD into PrL (see Fig. 2D–F). ΔJunD is an N-terminal truncated mutant of JunD that acts as a dominant-negative antagonist of ΔFosB. Mice were subjected to social defeat twice daily for 5 d. This accelerated social defeat protocol, shortened to coincide with the period of maximal HSV transgene expression, has been used previously and shown to induce maximal levels of social avoidance (Covington et al., 2011). At 24 h after the last stress episode, mice were decapitated without anesthesia to avoid effects of anesthetics on neuronal protein levels. Infected tissue was removed in PBS-containing protease (Roche) and phosphatase (Sigma-Aldrich) inhibitors using a 15 gauge punch and immediately frozen on dry ice. Samples were homogenized by light sonication in modified RIPA buffer: 10 mm Tris base, 150 mm sodium chloride, 1 mm EDTA, 0.1% SDS, 1% Triton X-100, 1% sodium deoxycholate, pH 7.4, and protease and phosphatase inhibitors as above. After addition of Laemmli's buffer, proteins were separated on 4–15% polyacrylamaide gradient gels (Criterion System; Bio-Rad), and Western blotting was performed using the Odyssey system (Li-Cor) according to the protocols of the manufacturer. Membranes were blotted with CCKB receptor antibody (1/1000, Acris, catalog #AP01421PU-N). Another group of mice were injected with AAV-ΔJunD or AAV-GFP in PrL and then, 5 weeks after surgery to allow maximal transgene expression, the mice were submitted to the submaximal defeat protocol. They were tested for social interaction 24 h after the last defeat.
Experiment 7: effects of intra-mPFC CI-988, a CCKB antagonist, on social stress-induced social avoidance and anhedonia.
Bilateral cannula (1.0 mm cannula to cannula distance, 1.8 mm anterior, injector −2.2 mm dorsal/ventral) targeting mPFC were implanted in susceptible mice (see Fig. 2G,H). A week after surgery, 10 ng of CI-988 was infused directly into mPFC, targeting primarily PrL. Mice were then tested for their social interaction behavior. Sucrose preference was measured for the remaining 24 h. CI-988 (Tocris Bioscience) was dissolved in saline, aliquoted, and frozen. Final dilution was prepared on the day of the experiment. An additional experiment was performed in susceptible mice with CI-988 administered intraperitoneally (2 mg/kg) 30 min before the social interaction test.
Experiment 8: effects of CCKB agonist on susceptibility to social stress and reversal by optogenetic stimulation of mPFC projections to BLA or NAc.
AAV-CaMKII-ChR2-EYFP or AAV-CaMKII-EYFP was injected into the right mPFC, again targeting primarily PrL (see Fig. 3A–G). Five weeks later, optic fibers were implanted in right NAc (1.4 anterior/posterior, 2.6 lateral, −4.7 dorsal/ventral at an angle of 25° from the midline) or BLA (−1.6 anterior/posterior, 3.1 lateral, −4.7 dorsal/ventral with no angle from the midline). During the same surgical procedure bilateral cannula were implanted into mPFC (see above). Cannulae and fibers were secured to the skull with dental cement. Mice were then allowed 1 week to recover before the start of the behavioral experiments. Mice were subjected to submaximal defeat, then tested 24 h later for social interaction, directly followed by elevated plus maze and for sucrose preference for the remaining 24 h. At 30 min before the social interaction test, half the mice were infused with CCK-8 (10 ng) into mPFC while the other half received vehicle (saline). Mice were tested in pairs (a vehicle- and a CCK-8-treated mouse, with AAV-GFP or AAV-ChR2). CCK-8 (Sigma) was dissolved in saline, aliquoted, and frozen. Final dilution was prepared the day of the experiment.
Optical stimulations were performed according to published protocols (Covington et al., 2010). Optical fibers (Thor Laboratories) were chronically implanted and connected via a FC/PC adaptor to a 473 nm blue laser diode (Crystal Lasers, BCL-473–050-M). A stimulator (Agilent, #33220A) was used to generate blue light pulses. During all stimulations, 40 ms bursts of 100 Hz (9.9 ms spike width) blue light pulses were delivered every 3 s to terminal regions in BLA or NAc over the duration of the social interaction test only, to mimic a burst-like pattern of cortical activity. The intensity of the optic fiber light was verified before each use, using a light sensor (Thor Laboratories, S130A), and light intensity was ∼15 mW. This stimulation protocol, which was validated electrophysiologically previously (Covington et al., 2010), did not induce seizures based on behavioral observations and the absence of c-Fos expression outside of optogenetically stimulated regions (Covington et al., 2010).
Experiment 9: effects of CCKB agonist on mPFC neuronal activity as measured by c-Fos mRNA levels.
Bilateral cannulae were implanted on adult mice targeting the mPFC (see Fig. 3H). After a week of rest, mice were subjected to submaximal defeat and infused with CCK-8 24 h later. mPFC punches were taken 30 min after the drug infusion, and samples prepared for mRNA analysis as described above.
Animal housing.
Eight-week-old C57BL/6J male mice (The Jackson Laboratory) were used. All mice were habituated to the animal facility for at least 1 week before experimental manipulations and were maintained at 23°C–25°C on a 12 h light/dark cycle (lights on at 7:00 A.M.) with ad libitum access to food and water. Experiments were conducted in accordance with guidelines of the Society for Neuroscience and the Institutional Animal Care and Use Committee at Icahn School of Medicine at Mount Sinai.
Statistical analyses.
Data displayed are expressed as mean ± SEM (represented as error bars). One-way ANOVAs were used to compare means between control, susceptible, and resilient mice in immunohistochemical, biochemical, and behavioral analyses. One-way ANOVAs were used to compare means between GFP-controls and ΔFosB overexpression in PrL or IL in the open-field, elevated plus maze, forced swim, and sucrose preference tests. Two-way ANOVAs were used to compare means between GFP-controls, ΔFosB-PrL, and ΔFosB-IL in the social interaction test. Two-way ANOVAs were used to compare CCK-8 effects with or without optogenetic stimulation in all behavioral experiments, as well as the effect of ΔFosB overexpression or CI-988 infusion on social avoidance. When appropriate, post hoc analyses were conducted using a Bonferroni post hoc test. Student's t tests were used to compare means for the effect of CI-988 infusion on sucrose preference and forced swim tests, and of CCK-8 on c-Fos mRNA levels. Differences between experimental conditions were considered statistically significant when p ≤ 0.05.
Results
Brain-wide mapping of ΔFosB induction by chronic social defeat stress
We first investigated ΔFosB induction by immunohistochemistry in control, susceptible, and resilient mice, after a course of chronic (10 d) social defeat stress, with a focus on forebrain and midbrain regions implicated previously in stress responses. Animals were analyzed 24 h after the last defeat episode. Chronic social stress induces ΔFosB in numerous brain areas with distinct patterns observed between resilient and susceptible mice. As shown in Table 1 and Figure 1A, IL, BLA, dentate gyrus of hippocampus, dorsal striatum, and NAc core showed preferential activation in resilient mice; such results in NAc are consistent with published findings (Vialou et al., 2010). In striking contrast, susceptible mice showed greater induction in PrL, lateral septum, and bed nucleus of stria terminalis. Several brain regions showed comparable ΔFosB induction in susceptible and resilient mice; these included orbitofrontal cortex (OFC, another area of PFC), NAc shell, dorsal raphé, and periaqueducal gray (PAG).
To identify the neuronal subtype displaying ΔFosB induction in cortical regions, GAD2-tdTomato mice were subjected to chronic social defeat stress. ΔFosB immunoreactivity in susceptible mice was undetectable in GABAergic neurons (Fig. 1B), which confirms earlier findings of specific induction of ΔFosB in cortical pyramidal neurons after other forms of chronic stress (Perrotti et al., 2004). In nondefeated control mice, baseline ΔFosB levels across brain regions were similar to those reported in previous studies (Perrotti et al., 2004, 2008) with much higher basal levels in the NAc and dorsal striatum compared with any other region, with the one exception of dentate gyrus, which displayed levels comparable with those in striatal regions (Table 1).
ΔFosB in mPFC promotes susceptibility to stress
To follow-up these findings, we focused on PrL because we had shown previously that optogenetic activation of this region exerted antidepressant-like effects in the social defeat paradigm (Covington et al., 2010). To test the functional consequences of ΔFosB induction in this brain region, we virally overexpressed ΔFosB in PrL of control mice (Fig. 1C) and subjected them to a submaximal course of social defeat stress, which does not induce social avoidance in normal animals. Mice overexpressing ΔFosB in PrL were more susceptible to social defeat than GFP-injected control mice in that they showed social avoidance behavior after submaximal social defeat (interaction, F(2,38) = 2.847, p > 0.05, main effect of virus, F(2,38) = 6.013, p < 0.05; Bonferroni post test t = 2.447, p < 0.05) (Fig. 1D). These mice also showed increased immobility in a 1 day forced swim test (F(2,31) = 6.448, p < 0.05; Bonferroni post test t = 3.518, p < 0.05) (Fig. 1E), an effect opposite to that produced by antidepressant drugs. In contrast, ΔFosB overexpression in PrL did not alter several baseline measures of anxiety-like behavior, sucrose preference, social interaction, or locomotor activity (Fig. 1F–J). Together, these findings support the hypothesis that the selective induction of ΔFosB in PrL of susceptible mice contributes to vulnerability to stress and its deleterious consequences. In contrast, ΔFosB overexpression in another region of mPFC, IL, had no effect on baseline emotional behaviors or on responses to social defeat stress (Fig. 1D–J), whereas ΔFosB overexpression in medial OFC trended toward promoting resilience to chronic social defeat, although this effect did not reach statistical significance (interaction, F(1,31) = 1.741, p > 0.05, main effect of interaction time, F(1,31) = 14.170, p < 0.05; Bonferroni post test t = 3.860, p < 0.05 within GFP group; t = 1.960, p < 0.05 within ΔFosB group; effect of virus, t = 2.447, p < 0.05) (Fig. 1K).
ΔFosB promotes CCKB induction in mPFC
A large body of evidence supports the notion that CCK, an abundant neuropeptide in brain, plays an essential role in neurobiological mechanisms of stress and anxiety (Rotzinger and Vaccarino, 2003). In particular, release of CCK in mPFC during social stress in rats is associated with anxiety-related behaviors (Becker et al., 2001). Although the involvement of CCK in human depression remains unclear, recent evidence points to its role in social defeat-induced depression-like behavior in rats (Becker et al., 2008). We thus hypothesized that alterations in levels of CCK or its CCKB (also known as CCK2) receptor in mPFC might contribute to differences between susceptible and resilient mice. At 48 h after the final defeat episode, CCKB mRNA levels were decreased in mPFC of resilient mice only (F(2,18) = 8.084, p < 0.01; Bonferroni post test, t = 3.104, p < 0.05 vs control; t = 5.113, p < 0.01 vs susceptible) (Fig. 2A). No difference was observed in CCK mRNA levels in either susceptible or resilient mice (data not shown). We observed an increase in ΔFosB mRNA levels only in susceptible mice consistent with the protein data reported above (F(2,18) = 5.246, p < 0.01; Bonferroni post test t = 3.336, p < 0.05 vs susceptible; t test t(12) = 2.138, p < 0.05 vs control) (Fig. 2B). Because ΔFosB regulates the transcription of numerous genes (McClung and Nestler, 2003; Winstanley et al., 2007), we considered the possibility that it might regulate CCKB mRNA expression. To address this question, we first overexpressed ΔFosB in PrL and found that this manipulation upregulates CCKB mRNA levels in this region (t(12) = 2.012, p < 0.05 vs GFP) (Fig. 2C). Interestingly, we also found a decrease in c-Fos mRNA levels after ΔFosB overexpression (t(11) = 3.382, p < 0.01) (Fig. 2C). These findings further suggest that ΔFosB induction in PrL of susceptible mice is an active mechanism of susceptibility by preventing the suppression of CCKB seen in resilient mice.
To further strengthen these observations, we overexpressed ΔJunD, a ΔFosB binding partner that lacks its transactivation domain and thereby acts as a dominant negative antagonist, and determined its effect on stress-induced CCKB expression. We confirmed that chronic social defeat stress increased CCKB protein levels in PrL of susceptible mice (t test t(12) = 2.289, p < 0.05 vs control) (Fig. 2D,E). Moreover, such induction was completely blocked by ΔJunD overexpression in this region (F(2,20) = 6.306, p < 0.01, Bonferroni post test t = 3.615, p < 0.01) (Fig. 2D,E), supporting the hypothesis that ΔFosB mediates stress-induced CCKB expression. Furthermore, blockade of ΔFosB activity in PrL, via local ΔJunD expression, also promoted resilience to defeat stress (t test t(16) = 2.114, p = 0.05 vs control) (Fig. 2F). The mechanism underlying the downregulation of CCKB in resilient mice remains to be elucidated.
Role of CCKB in resilience and susceptibility to stress
To directly test the role of CCKB regulation in PrL in mediating susceptibility versus resilience, we infused the selective CCKB receptor antagonist CI-988 (10 ng) directly into this brain region of susceptible mice. CI-988 effectively antagonizes CCKB receptors in vivo because it exhibits nanomolar affinity and high selectivity for the CCKB receptor subtype (Noble et al., 1999). Blockade of CCKB activity strongly increased social interaction (Fig. 2G) (interaction, F(1,20) = 7.795, p < 0.05; drug F(1,20) = 5.38, p < 0.05, Bonferroni post test t = 3.615, p < 0.01). CI-988 infusion also reversed the deficit in sucrose preference observed in susceptible mice (t(8) = 2.681, p < 0.05) (Fig. 2H). Both behavioral results indicate that blockade of CCK action in PrL exerts potent antidepressant-like effects. Interestingly, when administered intraperitoneally, CI-988 was ineffective in reversing social avoidance (data not shown).
To test the converse, that activation of CCKB in PrL could mediate the social avoidance and decreased sucrose preference induced by chronic social defeat stress, we examined the effect of local infusion of CCK-8 (10 ng), the predominant form of CCK in brain, on depression- and anxiety-related behaviors. The dose of the drug was chosen based on previous results in the literature (De Witte et al., 1987; Rotzinger and Vaccarino, 2003; Zanoveli et al., 2004). Mice were exposed to submaximal social defeat stress 24 h before behavioral testing (Fig. 3A). CCK-8, infused 30 min before testing, was sufficient to induce social avoidance in the social interaction test as well as a decrease in time spent in the open arms in the elevated plus maze (SI: BLA, interaction, F(1,22) = 0.79, p > 0.05; main effect of drug, F(1,22) = 11.75, p < 0.05; Bonferroni post test t = 2.957, p < 0.05; NAc: interaction, F(1,26) = 6.688, p < 0.05, Bonferroni post test t = 2.816, p < 0.05; EPM: BLA, interaction, F(1,22) = 8.0, p < 0.01; Bonferroni post test t = 2.509, p < 0.05 drug effect; t = 2.528, p < 0.05 virus effect; NAc, t test t(17) = 1.961; p < 0.05 drug effect within eYFP group) (Fig. 3B–E, left). No differences were observed in sucrose preference (Fig. 3F,G, left). Finally, CCK-8 infusion had no effect on the behavior (social interaction and elevated plus maze) of naive nondefeated mice in these assays (data not shown). These results demonstrate that the ΔFosB-mediated increase in CCKB activity in PrL of susceptible mice, compared with resilient mice, contributes to some of the stress-induced behavioral deficits exhibited by these animals.
Blockade of CCK-induced susceptibility to stress by activation of cortical projections to BLA versus NAc
Decreased mPFC neural activity correlates with depression-like behaviors in mice, with optogenetic stimulation of mPFC neurons of susceptible mice producing antidepressant-like effects (Covington et al., 2010). We thus hypothesized that CCK might act in PrL by inhibiting neuronal activity and thereby causing depression-like behavior. Consistent with this hypothesis, we observed a decrease in c-Fos mRNA levels in PrL in response to CCK infusion into this brain region (t(13) = 2.235, p < 0.05) (Fig. 3H).
We next hypothesized that optogenetic stimulation of mPFC exerts its antidepressant actions by opposing the effects of CCK on neuronal activity. In testing this hypothesis, we investigated the subcortical structures mediating the anxiogenic- and prodepression-like effects of CCK. Pyramidal neurons of the mPFC project heavily to the NAc and BLA, two limbic structures implicated in behavioral responses to stress. Altered activity of both brain regions has been shown to play an essential role in the expression of anxiety- and depression-like behaviors (Vialou et al., 2010; Tye et al., 2011). We therefore tested whether stimulation of glutamatergic projections from PrL to NAc or to BLA would oppose the deleterious effects of CCK microinfusion into PrL (Fig. 3A). We injected AAV-CaMKII-ChR2-EYFP, or AAV-CaMKII-EYFP as a control, into PrL. The CaMKII promoter is known to target viral expression to glutamatergic pyramidal neurons in cortical regions. We then allowed sufficient time (6 weeks) for the transgenes to be transported to the nerve terminals of these pyramidal neurons in NAc and BLA (Fig. 3I). Mice received submaximal social defeat; 24 h later, we infused CCK-8 into PrL and, 30 min after that, social interaction was measured during optogenetic stimulation of glutamatergic terminals in NAc or BLA. Immediately after the social interaction test, mice were evaluated in the elevated plus maze to assess anxiety-related behavior and then for sucrose preference to assess anhedonia.
Optogenetic stimulation of PrL glutamatergic projections to NAc fully reversed the social avoidance induced by intra-PrL CCK-8 (interaction, F(1,26) = 6.688, p < 0.05, no drug effect in ChR2 group) (Fig. 3C). In contrast, such PrL to NAc stimulation had no effect on anxiety-like behavior as measured in the elevated plus maze (Fig. 3E); however, such stimulation increased sucrose preference compared with unstimulated mice (interaction, F(1,20) = 5.77, p < 0.05; Bonferroni post test t = 2.998, p < 0.05 stimulation effect within CCK-8 treated animals) (Fig. 3G).
A very different behavioral pattern was seen with optogenetic stimulation of PrL glutamatergic projections to BLA. Such stimulation did not prevent the social avoidance induced by intra-PrL CCK-8 infusion (interaction, F(1,22) = 0.79, p > 0.05; main effect of drug, F(1,22) = 11.75, p < 0.05; no effect in stimulated group, t test t(12) = 2.054, p < 0.05) (Fig. 3B). However, stimulation of BLA afferents exerted an anxiolytic-like effect as indicated by increased time spent in the open arms of the elevated plus maze (interaction, F(1,22) = 8.0, p < 0.01; Bonferroni post test t = 2.528, p < 0.05 virus effect within CCK-8 treated groups) (Fig. 3D). Stimulation of glutamatergic projections to BLA had no significant effect on sucrose preference (interaction, F(1,22) = 2.08, p > 0.05) (Fig. 3F).
Discussion
Results of the present study provide evidence of molecular adaptations occurring in PrL that underlie susceptibility to social stress. We show induction of ΔFosB in this mPFC subregion after chronic social defeat stress, where ΔFosB overexpression promotes stress susceptibility. We identified the CCKB receptor as one target gene regulated by ΔFosB in PrL, apparently inducing CCKB protein in susceptible mice and preventing the downregulation of CCKB expression that occurs selectively in resilient mice. We showed further that infusion of a CCK agonist into PrL promotes depression- and anxiety-like behavioral abnormalities in response to social stress, whereas blockade of CCKB receptor activity in this region of susceptible mice blocks these effects. We next used optogenetic tools to identify the microcircuitry involved in the proanxiety- vs prodepression-like actions of CCK in PrL. Although cortico-NAc glutamatergic projections mediate reward deficits evidenced by social avoidance and reduced sucrose preference, this microcircuit does not influence the anxiogenic effects of CCK infused into PrL. Conversely, cortical projections to BLA mediate the manifestation of anxiety-related behaviors but have no effect on social stress-induced social avoidance or sucrose preference deficits. Together, these data show that alterations in PrL function after chronic social defeat stress mediate numerous behavioral deficits via specific subcortical projections.
ΔFosB: mapping a limbic stress network and role in mPFC
ΔFosB immunohistochemistry identifies neurons affected by chronic stress with single-cell resolution and has been used for mapping stress-regulated neuronal circuitry (Perrotti et al., 2004; Nikulina et al., 2008; Lehmann and Herkenham, 2011). We used this methodology to show that chronic social defeat stress induces ΔFosB in several brain areas with distinct patterns between resilient and susceptible groups, with some regions showing induction in resilient mice only, others in susceptible mice only, and still others under both conditions (Table 1). Previous work demonstrated that ΔFosB induction in NAc or ventral PAG promotes resilience to chronic stress and contributes to antidepressant responses (Berton et al., 2007; Vialou et al., 2010).
Induction of ΔFosB in PrL of susceptible mice, coupled with previous findings that optogenetic stimulation of this region exerts antidepressant effects (Covington et al., 2010), prompted us to study the influence of ΔFosB in this cortical region. Opposite to findings in NAc and ventral PAG, we found that ΔFosB in PrL promotes susceptibility to chronic social defeat stress and produces a prodepression-like effect in the forced swim test, without affecting anxiety-like behavior or sucrose preference. In contrast to PrL, we found no effect of ΔFosB overexpression in the nearby IL. A recent study found elevated levels of ΔFosB in IL in resilient mice and implicated this subregion in resilience to social stress (Lehmann and Herkenham, 2011). Further studies are thus needed to address differential roles for these two mPFC subregions, which have been shown to produce opposite effects in other behavioral domains (Sierra-Mercado et al., 2011; Burgos-Robles et al., 2013; Richard and Berridge, 2013). We previously reported that depressed humans display lower levels of ΔFosB in NAc examined postmortem (Vialou et al., 2010), whereas higher levels of ΔFosB have been shown in dorsolateral PFC (Brodmann area 46) of depressed humans (Teyssier et al., 2011). Other cortical regions were not examined in the latter study. In any event, these findings together support region-specific abnormalities in ΔFosB expression in human depression, where the transcription factor exerts very different effects on stress vulnerability. It would be interesting in future studies to examine the influence of ΔFosB in numerous other brain regions where it is induced (Table 1) on stress responses.
One mechanism by which ΔFosB induction in PrL might contribute to depression-like behavior is via suppression of PrL activity. ΔFosB has been shown to suppress AMPA glutamate responses, and c-Fos expression, in NAc medium spiny neurons (Renthal et al., 2008; Vialou et al., 2010; Grueter et al., 2013). Likewise, we found a decrease in c-Fos expression after ΔFosB overexpression in PrL. Thus, ΔFosB induction in PrL could be responsible for reduced neuronal activity seen in this region after chronic social defeat stress. Such decreased tone of PrL over its subcortical targets, such as BLA and NAc, would be expected to enhance fear expression and the inability to extinguish emotional responses to stress (Fales et al., 2008, 2009). Moreover, mPFC lesions induce sensitized stress responses and deficits in fear extinction (Holson, 1986; Silva et al., 1986; Diorio et al., 1993; Milad and Quirk, 2002), suggesting that stress-induced impairment of mPFC, mediated partly via ΔFosB induction, could contribute to depression and other stress-related disorders (Choi et al., 2012).
Role of CCK in stress vulnerability
We provide evidence that the CCKB receptor is a target of ΔFosB, such that ΔFosB induction in PrL of susceptible mice only is one mechanism through which ΔFosB exerts its prodepression-like effects in this region. Although the specific actions of CCK in mPFC circuitry remain unclear, in rodents CCK is localized within GABAergic interneurons (Somogyi et al., 1984). It is thought to suppress the activity of cortical pyramidal neurons by enhancing local GABA release and acting directly on CCKB receptors expressed by pyramidal neurons (Yaksh et al., 1987; Benoliel et al., 1992; Pérez de la Mora et al., 1993; Gallopin et al., 2006). Thus, CCKergic neurotransmission could contribute to the reduced PrL activity noted above.
CCK is an anxiogenic agent, with systemic administration of CCKB agonists inducing panic attacks in healthy volunteers. Patients predisposed to panic attacks become hypersensitized after CCK exposure (de Montigny, 1989; Bradwejn et al., 1991). Several studies have confirmed CCK's anxiogenic effects in rodents (Rotzinger and Vaccarino, 2003). CCK release in mPFC during defeat stress in rats is associated with anxiety-related behaviors (Becker et al., 2001); PrL and IL subregions were not differentiated in this study. More recently, systemic, chronic blockade of CCKB with CI-988 exerted antidepressant-like effects in rats (Becker et al., 2008). CI-988 normalized immobility time in the forced swim test. It also prevented hypothalamic-pituitary-adrenal axis hyperactivity, reduced hippocampal volume and cell proliferation, and reduced sucrose preference normally evoked by social defeat. Here, we confirm these results by showing an antidepressant-like effect of CI-988 infused into PrL of susceptible mice, although a single systemic injection did not mimic this effect.
In addition to the acute actions of CCK in PrL, we identified decreased levels of CCKB mRNA in resilient mice, which could be a molecular adaptation underlying resilience. Indeed, alterations in CCKergic tone, specifically CCKB levels, constitute an important mechanism for the expression of anxiety. Transgenic mice overexpressing CCKB in forebrain show heightened anxiety and fear responses (Chen et al., 2006). Our finding of altered CCKB levels between resilient and susceptible mice might contribute to the phenotypic differences in anxiety and depressive-like behavior. Here, we demonstrate the PrL as a critical anatomical substrate for the anxiogenic and prodepressant effects of CCK in the context of social stress. Nevertheless, several other brain regions are involved in CCK's behavioral actions, including BLA, hippocampus, NAc, and PAG (De Witte et al., 1987; Belcheva et al., 1994; Noble and Roques, 1999; Zanoveli et al., 2004; Rezayat et al., 2005). Also, we found an increase in CCKB protein levels, but not mRNA levels, in mPFC of susceptible animals. These findings underscore that, although mRNA levels often correlate with protein levels, this is not necessarily the case (Gygi et al., 1999).
Our optogenetic experiments demonstrate that increasing activity of glutamatergic projections from PrL to NAc or to BLA antagonizes the effects of CCK in PrL. Further studies are needed to establish that this effect of optogenetic stimulation is mediated by the same PrL neurons that are controlled by CCK. Interestingly, our data reveal distinct roles of these two microcircuits in mediating different domains of behavioral abnormalities. The cortico-NAc projection controls anhedonia and reward; the fact that it regulates social avoidance confirms that this symptom is more a reflection of decreased motivation and reward for social behavior and not of increased social anxiety. This conclusion is consistent with the inability of benzodiazepines to correct this abnormality (Berton et al., 2006), and with the recent demonstration that mPFC stimulation of NAc increases reward and motivation for drugs of abuse (Britt et al., 2012). In contrast, the cortico-BLA projection controls anxiety-related symptoms, consistent with a large literature in rodents and humans (see above).
In conclusion, results of the present study identify a pattern of limbic brain regions implicated in susceptible and resilient animals, and demonstrate alterations in PrL that promote susceptibility. These alterations involve induction of ΔFosB and its induction of the CCKB receptor. In contrast, blockade of CCK actions in PrL promotes antidepressant- and anxiolytic-like effects. We also establish the subcortical targets of these cortical pyramidal neurons that mediate these actions, with a cortico-NAc circuit essential for depression-related behaviors, and a cortico-BLA circuit essential for anxiety-related behaviors. Whereas clinical studies of CCKB antagonists in depressed patients in the 1990s did not yield promising results, the present findings suggest the value of revisiting the therapeutic potential of such agents in subsets of patients exposed to high levels of stress.
Footnotes
This work was supported by the National Institute of Mental Health (E.J.N.) and the Brain & Behavior Research Foundation National Alliance for Research on Schizophrenia and Depression Young Investigator Award to V.V.
The authors declare no competing financial interests.
- Correspondence should be addressed to Dr. Eric J. Nestler, Fishberg Department of Neuroscience and Friedman Brain Institute, Icahn School of Medicine at Mount Sinai, One Gustave L. Levy Place, Box 1065, New York, NY 10029-6574. eric.nestler{at}mssm.edu