Research article

The effect of BLA GABA(A) receptors in anxiolytic-like effect and aversive memory deficit induced by ACPA

Katayoon Kangarlu-Haghighi1, Shahrbanoo Oryan1, Mohammad Nasehi2, Mohammad-Reza Zarrindast2[*],3,4,5

1Department of Biology, Science and Research Branch, Islamic Azad University, Tehran, Iran

2Cognitive and Neuroscience Research Center (CNRC), Medical Genomics Research Center and School of Advanced Sciences in Medicine, Islamic Azad University, Tehran Medical Sciences Branch, Tehran, Iran

3Department of Pharmacology School of Medicine, Tehran University of Medical Sciences, Tehran, Iran

4Iranian National Center for Addiction Studies, Tehran University of Medical Sciences, Tehran, Iran

5School of Cognitive Sciences, Institute for Research in Fundamental Sciences (IPM), Tehran, Iran

EXCLI J 2015;14:Doc613

 

Abstract

The roles of GABAergic receptors of the Basolateral amygdala (BLA) in the cannabinoid CB1 receptor agonist (arachydonilcyclopropylamide; ACPA)-induced anxiolytic-like effect and aversive memory deficit in adult male mice were examined in elevated plus-maze task. Results showed that pre-test intra-peritoneal injection of ACPA induced anxiolytic-like effect (at dose of 0.05 mg/kg) and aversive memory deficit (at doses of 0.025 and 0.05 mg/kg). The results revealed that Pre-test intra-BLA infusion of muscimol (GABAA receptor agonist; at doses of 0.1 and 0.2 µg/mouse) or bicuculline (GABAA receptor antagonist; at all doses) impaired and did not alter aversive memory, respectively. All previous GABA agents did not have any effects on anxiety-like behaviors. Interestingly, pretreatment with a sub-threshold dose of muscimol (0.025 µg/mouse) and bicuculline (0.025 µg/mouse) did not alter anxiolytic-like behaviors induced by ACPA, while both drugs restored ACPA-induced amnesia. Moreover, muscimol or bicuculline increased and decreased ACPA-induced locomotor activity, respectively. Finally the data may indicate that BLA GABAA receptors have critical and different roles in anxiolytic-like effect, aversive memory deficit and locomotor activity induced by ACPA.

Keywords: ACPA, GABA, anxiety, memory, amygdala

Introduction

Cannabis sativa (Marijuana) is commonly used all over the world. The plant extract composes of almost 70 cannabinoid compounds (Burns, 2006[11]). Various researches have shown that the administration of marijuana affects various cognitive and non-cognitive behaviors including impairment of spatial (Uchida et al., 2012[71]; Wise et al., 2009[79]) and non-spatial learning and memory, anxiety-like behaviors, mood, locomotor, and euphoria experience both in animal models and human subjects (Burgdorf et al., 2011[10]; Kilmer et al., 2011[34]; King et al., 2002[35]; Pacula, 2011[58]). Some reports revealed that the endogenous cannabinoid system is critically linked to the extinction of aversive memories (Marsicano et al., 2002[44]). Endocannabinoids are thought to be retrograde messengers released by neurons to modulate release of neurotransmitters (Kreitzer and Regehr, 2001[37]; Nicolle et al., 2001[55]; Ohno-Shosaku et al., 2001[56]; Wilson and Mogil, 2001[78]). Three main cannabinoid receptors have been identified so far as CB1, CB2, and CB3 (non-CB1 and -CB2), which are engaged in cannabinoids' functions (Mackiewicz et al., 2006[41]; Ryberg et al., 2008[67]). CB1 receptors are plentifully expressed in the central nervous system regions such as the hippocampus, amygdala, cerebellum and cortex (Davies et al., 2002[18]; Pertwee and Ross, 2002[61]; Wilson et al., 2002[77]). CB2 receptors mostly are expressed peripherally rather than in brain tissues. It is believed that neuropsychological functions of endocannabinoids are related to CB1 receptors. CB1 is mainly expressed in the amygdala (Katona et al., 2001[33]; McDonald and Mascagni, 2001[45]), an essential part and component of the limbic circuitry. The amygdala is an integral part in controlling the emotional behavior such as conditioned fear, anxiety (McKernan and Shinnick-Gallagher, 1997[47]), and pain perception (Gauriau and Bernard, 2002[23]; Paulson et al., 2002[59]).

Amygdala nuclei mainly are classified into the three groups:

1. the deep or basolateral group, which includes the lateral nucleus, the basal nucleus, and accessory basal nucleus used as auxiliary and helping nucleus;

2. the superficial or cortical-like group, which consists of cortical nuclei and nucleus of the lateral olfactory tract; and

3. the centromedial group composed of the medial and central nuclei (Faber and Sah, 2003[21]; Sah and Lopez De Armentia, 2003[68]).

It has been proven that CB1 cannabinoid receptors are expressed at high levels in the BLA amygdala nuclei (Herring et al., 2003[29]; Marsicano et al., 2002[44]). Expression of the CB1 protein is limited to a definite and noticeable subpopulation of GABAergic interneurons corresponding to large cholecystokinin-positive cells (Jazi et al., 2009[31]). In-depth and comprehensive analysis has shown that CB1 receptors exist presynaptically on cholecystokinin-positive axon terminals, which establish symmetrical GABAergic synapses with their postsynaptic targets (Azad et al., 2003[5]; Katona et al., 2001[33]). In the mammals brain, γ-aminobutyric acid (GABA) is the most abundant inhibitory neurotransmitter (Nicoll et al., 1990[54]), working by means of different receptor types: the ionotropic GABAA and GABAC receptors (both of which activate Cl currents) and the metabotropic GABAB receptor (G protein coupled receptor). The present study, in accordance with the above mentioned data, was designed to examine the role of BLA GABAergic (GABAA receptors) system on the ACPA (selective CB1 cannabinoid receptor agonist), which causes emotional amnesia in the EPM test-retest protocol in mice.

Materials and Methods

Animals

Male albino NMRI (Institute Pasture, Iran) mice weighting 27-30 g (9-10 week old), were applied. The animals were kept under a 12/12-h light-dark cycle, with light beginning at 0700 h and at a controlled temperature (22 ± 2 c). They had free access to food and water. The animals were housed 10 per cage (45 cm × 30 cm × 15 cm). Eight animals were used in each experiment. Each animal was only used once. All procedures in this investigation are in accordance with the guide for the Care and Use of Laboratory Animals as adopted by the Ethics Committee of Faculty of Science, Tehran University (357: November 2000).

Drugs

Ketamine and xylazine (Alfasan Chemical Co., Woerden, Holland) were applied for animal anesthesia. Muscimol (GABAA receptor agonist), bicuculline (GABAA receptor antagonist) and ACPA (CB1 cannabinoid receptor agonist) have been used in this study that purchased from Tocris, Bristol, UK). All drugs were dissolved in sterile 0.9 % saline, just before the experiment, except for bicuculline. Bicuculline was dissolved in 1 drop of glacial acetic acid using a Hamilton microsyringe, then made up to a volume of 5 ml with sterile 0.9 % saline and then diluted to the required volume. Muscimol and bicuculline were administered into the BLA of amygdala at volume of 0.6 µl/ mouse (0.3 µl/site). The control animals received saline or vehicle. The timing of drugs administration was defined as per our pilot results and the previous studies (Chegini et al., 2014[15]; Yousefi et al., 2013[81]).

Surgical procedures and microinjections

All surgical procedures were organized under ketamine-xylazine (100 mg/kg ketamine-5 mg/kg xylazine) anesthesia. Cannulae were implanted with bilateral 27-gauge stainless steel cannulas into either the BLA of amygdala. Drugs were injected into the amygdala (coordinates from bregma as follows: AP = -0.7 mm, ML = ± 2.7, DV = 3. 8 (Paxinos and Franklin, 2001[60]). Skull cap was made from dental acrylic. Finally, stainless steel wires were inserted with plastic caps into each cannula to prevent any debris from entering the brain and to maintain patency of the hollow metal cylinder. The injecting needle extended 1 mm beyond the tip of the cannulas, reflecting the ultimate desired depth of the apparatus and the actual depth the infusion needle reached during antagonist or buffer infusion. Following surgery all animals were allowed 1 week to recover from surgery and get cleared from anesthetics effect. For drug infusion, animals were gently restrained in hand and the stylets were removed from the guide cannulae and replaced by 27-gauge injection needles. Each injection unit was connected by polyethylene tubing to a 1 µl Hamilton syringe. The forward movement of a small air bubble inside the polyethylene tubing interposed among the upper end of needle and the microsyringe was taken as evidence of drug flow. The injection needles were left in place for an additional 60 s to allow diffusion after which the stylets were reinserted into the guide cannulae (Ebrahimi-ghiri et al., 2012[20]; Nasehi et al., 2012[52]; Zarrindast et al., 2011[84]).

Apparatus and behavioral testing

We applied a wooden elevated plus-maze (EPM) apparatus set up 50 cm above the floor which included two oppositely positioned open-arms (50 × 10 cm) and two enclosed arms (50 × 10 × 40 cm), surrounded by1cm high Plexiglas ledge so that to prevent falls. The junction area of the four arms (central platform) measured 10 × 10 cm (Carobrez and Bertoglio, 2005[13]; Zarrindast et al., 2010[83], 2011[85]). The EPM test is used to assess anxiety and memory processes in rodent models of CNS disorders.

Findings demonstrate that aversive learning and memory may be studied at the same time as anxiety in rodents exposed to the EPM test/retest. Animals retested in the EPM avoid exploring the open spaces, displaying a clear enclosed arm preference with a low percentage of entries and time spent in the open arms relative to their respective level on testing. The aversive and fear-inductor nature of the open arms represents a useful tool for the study of aversively motivated learning processes in the EPM. For example, learning and memory have been studied in the EPM through avoidance to open-arms in the retest session. The different analysis indicated that this response of further avoidance to open-arms is gradually acquired throughout testing, and is thought to reflect the retrieval of the aversive memory related to the initial EPM exploration (Chegini et al., 2014[15]; Valizadegan et al., 2013[73]).

Mice were left undisturbed to the testing room 1 hour prior to the test so that to adapt to the testing environment. The mice were individually placed in the center of the maze facing a closed arm and allowed 5 min of free exploration. Experiments were under a low light (40-lux), during the day phase, between 9:00 and 14:00 h. During this 5 min, the percentage of open arm time and open arm entries were calculated as follows:

These behaviors were recorded by a video camera while a monitor and a computer-recording system were installed in an adjacent room. Raw data were used to manually calculate these behaviors. Experiments were performed by someone blind to doses of drugs and statistical results.

Experimental design

Experiment 1: Effect of pretest microinjections of muscimol and bicuculline on open-arm exploratory-like behaviors

To substantiate that the microinjection of drugs into BLA involves in anxiety, the drug infusion took place before EPM testing. In the present experiment nine groups of animals received saline (0.6 µl/mouse, 3 groups), vehicle (0.6 µl/mouse, 3 groups), muscimol (0.025, 0.05, 0.1, and 0.2 µg/ mouse) or bicuculline (0.025, 0.05, 0.1, 0.2 and 0.4 µg/mouse), 5 min. before testing. In order to investigate possible after-effect intra-BLA drugs effects on aversive learning during test day to aversive memory in retest day, treated groups were retested in the EPM 24 h later un-drugged.

Experiment 2: Effect of pretest microinjections of ACPA on open-arm exploratory-like behaviors

To provide information on the impact of ACPA on anxiety, the drug infusion happened before EPM testing. In this experiment 4 groups of animals received saline (10 ml/kg, i.p.) and ACPA (0.0125, 0.025, and 0.05 mg/kg, i.p.) 15 minutes before testing. To inquire possible carry-over drug effects on aversive learning, treated groups were retested in the EPM 24 h later un-drugged.

Experiment 3: Effect of pretest microinjections of muscimol and bicuculline on open-arm exploratory-like behaviors induced by ACPA

To supply evidence that possible interaction of GABAA BLA receptors with exploratory-like behaviors induced by ACPA, the drugs infusion were made before EPM testing for anxiety-like behavior assessment. In these experiments the animals received saline (0.6 µl/mouse, 4 groups), sub-threshold dose of muscimol (0.025 µg/mouse, 4 groups) and bicuculline (0.025 µg/mouse, 4 groups) intra-BLA, 5 min before testing. Furthermore, these animals also received saline (10 ml/kg, i.p.) and sub-threshold and effective doses of ACPA (0.0125, 0.025 and, 0.05 mg/kg, i.p.) 15 min before testing. In order to look into the possible side-effects of intra-BLA drugs on aversive learning, treated groups were retested in the EPM 24 h later un-drugged.

Verification of cannulae placements

After the completion of the experimental sessions, each animal was eliminated with an overdose of chloroform. Animals received intra-BLA injection of ink (0.3 l/side; 1 % aquatic methylene blue solution). The brains were then removed and fixed in a 10 % formalin solution for 10 days before sectioning. Sections were analyzed to find out the location of the cannulae aimed for bilateral BLA. The cannulae placements were checked by using the atlas of Paxinos and Franklin (2001[60]). Data which were obtained from animals with injection into the specified sites, outside these regions were not taken into the consideration for the analysis.

Statistical analysis

Given the normality of distribution and the homogeneity of variance, the results were statistically evaluated using the repeated measure and two-way analysis of variance (ANOVA), in which mean ± S.E.M was employed for the comparison of outcomes between experimental groups and their corresponding controls. Where F-value was significant, one-way analysis of variance (ANOVA) and post-hoc analysis (Tukey's test) were performed. Differences with P < 0.05 between groups were considered statistically significant.

Results

Histology

For the statistical analyses, we included the data only from animals with correct cannulae implants (320 animals). 27 animals with incorrectly positioned cannulae tips were excluded.

Effect of pretest microinjections of muscimol into BLA on open-arm exploratory-like behaviors

Repeated measure and post-hoc analysis demonstrated that intra-BLA injection of muscimol at dose 0.1 and 0.2 µg/mouse increased %OAT (Figure 1(Fig. 1); Panel 2A) and %CAE (Figure 1(Fig. 1); Panel 2B) but not CAE (Figure 1(Fig. 1); Panel 2C) in the retest day, while these interventions did not alter all behaviors in the test day (Figure 1(Fig. 1); Panels 1A, 1B and 1C). In conclusion, the data uncovered that muscimol did not induce any effect on anxiety behaviors, while impaired aversive memory acquisition. All the experimental repeated measure results are summarized in the Table 1(Tab. 1).

Effect of pretest microinjections of bicuculline into BLA on open-arm exploratory-like behaviors

Repeated measure and post-hoc analysis demonstrated that intra-BLA injection of bicuculline at dose 0.4 µg/mouse decreased CAE (Figure 1(Fig. 1); Panel 4C) but did not alter %OAT (Figure 1(Fig. 1); Panel 4A) and %CAE (Figure 1(Fig. 1); Panel 4B) in the retest day. The interventions did not alter any behaviors in the test day (Figure 1(Fig. 1); Panels 3A, 3B and 3C). In conclusion, the data showed that bicuculline did not induce any effect on anxiety behaviors and aversive memory acquired. All the experimental repeated measure results are summarized in the Table 1(Tab. 1).

Effect of pretest intraperitoneal injections of ACPA on open-arm exploratory-like behaviors

Repeated measure and post-hoc showed that intraperitoneal injection of ACPA at the highest dose (0.05 mg/kg) increased %OAT (Figure 2(Fig. 2); Panel 1A) and %CAE (Figure 2(Fig. 2); Panel 1B) but not CAE (Figure 2(Fig. 2); Panel 1C) in the test day. The same interventions in the retest day showed that ACPA increased %OAT (Figure 2(Fig. 2); panel 2A at doses 0.025 and 0.05 mg/kg) and %CAE (Figure 2(Fig. 2); Panel 2B at dose 0.05 mg/kg) but not CAE (Figure 2(Fig. 2); Panel 2C). In conclusion, the data demonstrated that ACPA induced anxiolytic-like effect and impaired aversive memory acquisition. All the experimental repeated measure results are summarized in the Table 2(Tab. 2).

Effect of pretest microinjections of muscimol and bicuculline on open-arm exploratory-like behaviors induced by ACPA

Two-way ANOVA and post-hoc analysis showed that pretest intra-BLA injection of sub-threshold dose of muscimol (0.025 µg/ mouse) or bicuculline (0.025 µg/mouse) potentiated %OAT (Figure 2(Fig. 2) Panel 4A for muscimol and Figure 2(Fig. 2) Panel 6A for bicuculline) and %OAE (Figure 2(Fig. 2) Panel 4B for muscimol and Figure 2(Fig. 2) Panel 6B for bicuculline) induced by ACPA in the retest day. The interventions showed that muscimol and bicuculline did not %OAT (Figure 2(Fig. 2) Panel 3A for muscimol and Figure 2(Fig. 2) Panel 5A for bicuculline) and %OAE (Figure 2(Fig. 2) Panel 3B for muscimol and Figure 2(Fig. 2) Panel 5B for bicuculline) induced by ACPA in the test day. Interesting data showed co-administration of muscimol or bicuculline with ACPA decreesed and increased respectively, locomotor activity both test and retest days (Figure 2(Fig. 2) Panel 3C and 4C for muscimol and Figure 2(Fig. 2) Panel 5C and 6C for bicuculline). Finally, the data revealed that the main effect of muscimol and bicuculline is on ACPA-induced locomotor activity rather than anxiety and aversive memory. All the experimental repeated measure results are summarized in the Table 2(Tab. 2).

Discussion

It has been presumed that in the events which are connected to the feelings and emotions, the amygdala (a major brain region) regulates hippocampal formation activity for driving information recording to cortical areas. For instance, BLA activation into inactivation situation (i.e. damage) change memory from the event in favor of the essential part to visual details (Adolphs et al., 2001[2], 2005[3]; Canli et al., 2000[12]), thus, it seems that amygdala and the hippocampal system jointly play a critical role in the emotional memory improvement (Dolcos et al., 2004[19]). Moreover, emotional situation including aversion and fear, may improve or may weaken memory formation (McGaugh, 2004[46]). Since the existing animal models of learning and memory have a limited ability to detect the effect of drugs on anxiety and fear memory, as measured by these models, the exact subject matter and points may be misinterpreted and misunderstood. Therefore, elevated plus maze (EPM) task is an attempt to assess the effects of drugs on anxiety, learning, and memory happening at the same time in rodents (Asth et al., 2012[4]). The justification for utilizing the EPM in testing anxiety relies on the natural tendency of animals to avoid dangerous situation when they face height and open spaces (Chegini et al., 2014[15]; Zarrindast et al., 2010[82]).

Effect of ACPA on open-arm exploratory behaviors in native mice subjected to the EPM

The present results show that, intra-peritoneal infusion of selective CB1 cannabinoid receptor agonist, ACPA, make anxiolytic-like behaviors appear in the EPM. Moreover, anxiolytic effects of ACPA revealed in retest day. These results propose an impairment of aversive memory acquisition on testing presented itself in ACPA-treated groups. Meanwhile, the drug did not alter locomotor activity in the test and retest days. It has been showed that cannabinoids have several effects on the cognitive and non-cognitive behaviors such as short-term memory deficit, mood alterations, increased body awareness, decreased attention, sleepiness and discoordination (Court, 1998[17]; Heishman et al., 1997[28]). In terms of anxiety-like behaviors, it appears that the effects of cannabinoid agonists on this phenomenon are complex and often contradictory and conflicting in both humans and animals. In the anxiety animal model these agents induced dose-dependent regulation which seems the animal is strongly affected by environmental context. For instance, low doses of nabilone (Onaivi et al., 1990[57]), CP55, 940 (Marco et al., 2004[43]) and Delta9-tetrahydrocannabinol (Berrendero and Maldonado, 2002[8]) as CB1 cannabinoid receptor agonists induced anxiolytic-like effects in the EPM and light-dark tasks. On the other hand, the CB1 knockout mice also showed an anxiogenic-like behavior in the EPM and social interaction task (Haller et al., 2002[25]; Uriguen et al., 2004[72]). A recent study reported that cannabinoid agonists at high and low doses induced opposite effects on cognitive behaviors (Moreira and Wotjak, 2010[49]). For instance, high and low doses of these compounds induced anxiogenic- and anxiolytic-like behaviors, respectively. The effects can be blocked by CB1 cannabinoid antagonists (Haller et al., 2007[26]).

A large body of evidence shows that the endocannabinoidergic system plays a crucial role in physiological mechanisms of learning and memory (Lichtman et al., 2002[40]; Marsicano et al., 2002[44]). For example, systemic injections of Δ9-THC, anandamide or intra-hippocampal injections of WIN55212-2 impair memory acquisition, consolidation, and recall in rodents (Costanzi et al., 2004[16]; Mishima et al., 2001[48]; Nasehi et al., 2010[51]). In terms of emotional memory, several brain regions including hippocampus, amygdala, and cortex with high density of CB1 receptor expression have critical role in emotional behavior regulation (Viveros et al., 2005[75]). It seems that the endocannabinoidergic system plays a major role in aversive memory extinction (Marsicano et al., 2002[44]). CB1 cannabinoid receptors are one of the major receptors in the emotional learning and memory and its neural plasticity process (Laviolette and Grace, 2006[39]; Marsicano et al., 2002[44]) and they have high expression in BLA and medial prefrontal cortex (mPFC) (McDonald and Mascagni, 2001[45]).

Effect of BLA GABAA agents on open-arm exploratory behaviors

The results showed that intra-BLA infusion of muscimol and bicuculline did not alter anxiety-like behaviors. Interestedly, further analyses showed that muscimol impaired memory formation and locomotor activity. A large number of studies have reported that amygdale plays an important role in anxiety-like behaviors (Roozendaal et al., 2009[64]); specifically amygdale BLA nucleus (Wang et al., 2011[76]). The amygdale BLA and lateral nucleus receives GABAergic neuron input from the raphe nucleus (Smith and Porrino, 2008[69]). This system and its receptors are involved in the regulation of cognitive and non-cognitive behaviors including anxiety-like behaviors, emotional memory, locomotor activity, attention, biorhythms, food intake and body temperature (Abrams et al., 2005[1]; Bonn et al., 2013[9]; Holmes, 2008[30]; Kriegebaum et al., 2010[38]). GABA is the major inhibitory neurotransmitter in the mammals CNS, including the brain stem. The GABA induces most of its effects through activation of either GABAA or GABAB receptors. Synaptically released GABA activates postsynaptic GABAB receptors, which increase the membrane permeability to chloride, evoking a hyper-polarizing inhibitory postsynaptic current (IPSC). Inside the synapse, the concentration of GABA to a relatively high level (milimolar range) is increased by synaptic release (Cathala et al., 2005[14]; Farrant and Nusser, 2005[22]). The short current which is named as “phasic” inhibition happens as a result of the synaptic release of GABA from presynaptic terminals. But new detailed examinations have revealed that GABA released from presynaptic terminals can escape, or spillover, from the synaptic cleft, or there may be a spillover of GABA from the synaptic cleft, leading to activations of the receptors either at the synapse or distant from it (Cathala et al., 2005[14]; Farrant and Nusser, 2005[22]). On the contrary our results two previous studies showed that GABAA receptor activation induced anxiolytic-like behaviors (Naseri et al., 2014[53]; Rezayat et al., 2005[63]), Many drugs such as benzodiazepines, barbiturates and alcohols seem to elicits their effects via GABAA receptors, (Morrow, 1995[50]). GABAA receptors are ligand-gated heterooligomeric complexes comprising distinct subunits. Pharmacological studies have highlighted the crucial role of the GABAergic system in the regulation of anxiety. For instance, using pentylenetetrazole (a GABAA receptors blocking agent) is shown to induce anxiety-like effects. On the contrary, using benzodiazepines (with increasing effect on GABAergic transmission) induce anxiolytic-like effect (Kalueff and Nutt, 1997[32]). The data from bicuculline-included experiments may suggest that under normal conditions, the BLA GABAA receptors are not necessary for the anxiety-like behaviors and aversive memory formation. Some other studies have reported similar effects of intra-CA1 bicuculline on memory retention (Chegini et al., 2014[15]; Zarrindast et al., 2002[82]), spatial change and non-spatial novelty detection (Yousefi et al., 2013[81]).

Effect of BLA GABAergic system on open-arm exploratory behavior induced by ACPA

The data uncovered that muscimol and bicuculline did not alter anxiolytic-like behaviors induced by ACPA, while both drugs restored ACPA-induced amnesia. Interestingly muscimol or bicuculline increased and decreased ACPA-induced locomotor activity, respectively. This mainly showed that there is a dealing mechanism between anxiety and cannabinoid level, to the extent that anxiety events increased endocannabinoid tone level for the reduction of anxiety phenomenon, for instance, the increase of anandamide following a foot shock after hearing in the amygdale (Marsicano et al., 2002[44]). Moreover, the contribution of amygdale endocannabinoids in the extinction of aversive memories has been also proposed (Azad et al., 2004[6]). It has been reported that in stressful stimuli, as well as rewarding experiences, mediate changes in the expression level of the CB1 receptor specifically in GABAergic terminals (Rossi et al., 2008[65]; Yamodo et al., 2010[80]). It is well worth considering that, the stress-mediated regulation of the GABAergic CB1 receptor has been postulated as a compensatory mechanism needed to restore the balance between GABAergic and glutamatergic neurotransmission in emotional homeostasis (Ruehle et al., 2012[66]). CB1 cannabinoid receptors are expressed in GABAergic terminals of the amygdale (Haring et al., 2007[27]). Thus, the endocannabinoidergic system can modulate GABAergic transmission through regulating the activity of afferents into GABA producing neurons (Haj-Dahmane and Shen, 2005[24]), and through directly modulating the functions of a subset of GABAergic neurons (Haring et al., 2007[27]). In the connection of cannabinoidergic and GABAergic systems interactions, some reports have mentioned that cannabinoids and their receptor agonists such as anandamide and ACPA inhibit the uptake of GABA into the cortical synaptosomes and this may happen through reducing the activity of the uptake energy source Na+/K+-ATPase (Steffens and Feuerstein, 2004[70]). Thus, using of cannabinoid receptor agonist, blocks respective transporters and finally increases GABA level in different brain regions (Köfalvi, 2007[36]). In vivo study showed GABAA receptors have a critical role in modulation effect of cannabinoid (Beinfeld and Connolly, 2001[7]). For example it showed that blocked of GABAA receptors by bicuculline completely restored Δ9-THC-induced deficits in both the Morris water maze working-memory task and an alternation T-maze task (Varvel et al., 2005[74]). However a study showed that microinjection of the GABAA agonist muscimol into the central nucleus of the amygdala but not into the BLA nucleus of the amygdala, reduced the antinociceptive effects of systemic WIN55, 212-2 (Manning et al., 2003[42]), Rea and et al. (2013[62]) demonstrated that CB1 receptors in the BLA facilitate the expression of fear-conditioned analgesia, through a mechanism which is likely to involve the modulation of GABAA signaling.

Conclusion

In conclusion, the findings of the present study proposed that ACPA induced anxiolytic-like effect and aversive memory deficit. Furthermore, muscimol and bicuculline did not and restored anxiolytic-like effect and aversive memory deficit by ACPA, respectively. Moreover, muscimol or bicuculline increased and decreased locomotion by ACPA, respectively. It seems that the main effect of GABAA in ACPA-induced behaviors is on locomotor activity rather than anxiety and aversive memory behaviors.

Acknowledgements

The authors thank the Iran National Science Foundation (INSF) for providing the financial support for the project.

Conflicts of interest

There are no conflicts of interest.

 

References

1. Abrams JK, Johnson PL, Hay-Schmidt A, Mikkelsen JD, Shekhar A, Lowry CA. Serotonergic systems associated with arousal and vigilance behaviors following administration of anxiogenic drugs. Neuro-science. 2005;133:983-97.
2. Adolphs R, Denburg NL, Tranel D. The amygdala's role in long-term declarative memory for gist and detail. Behav Neurosci. 2001;115:983-92.
3. Adolphs R, Tranel D, Buchanan TW. Amygdala damage impairs emotional memory for gist but not details of complex stimuli. Nat Neurosci. 2005;8:512-8.
4. Asth L, Lobao-Soares B, Andre E, Soares Vde P, Gavioli EC. The elevated T-maze task as an animal model to simultaneously investigate the effects of drugs on long-term memory and anxiety in mice. Brain Res Bull. 2012;87:526-33.
5. Azad SC, Eder M, Marsicano G, Lutz B, Zieglgansberger W, Rammes G. Activation of the cannabinoid receptor type. 1 decreases glutamatergic and GABAergic synaptic transmission in the lateral amygdala of the mouse. Learn Mem. 2003;10:116-28.
6. Azad SC, Monory K, Marsicano G, Cravatt BF, Lutz B, Zieglgansberger W, et al. Circuitry for associative plasticity in the amygdala involves endocannabinoid signaling. J Neurosci. 2004;24:9953-61.
7. Beinfeld MC, Connolly K. Activation of CB1 cannabinoid receptors in rat hippocampal slices inhibits potassium-evoked cholecystokinin release, a possible mechanism contributing to the spatial memory defects produced by cannabinoids. Neurosci Lett. 2001;301:69-71.
8. Berrendero F, Maldonado R. Involvement of the opioid system in the anxiolytic-like effects induced by Delta(9)-tetrahydrocannabinol. Psychopharmacology (Berl). 2002;163:111-7.
9. Bonn M, Schmitt A, Lesch KP, Van Bockstaele EJ, Asan E. Serotonergic innervation and serotonin receptor expression of NPY-producing neurons in the rat lateral and basolateral amygdaloid nuclei. Brain Struct Funct. 2013;218:421-35.
10. Burgdorf J, Zhang XL, Weiss C, Matthews E, Disterhoft JF, Stanton PK, et al. The N-methyl-D-aspartate receptor modulator GLYX-13 enhances learning and memory, in young adult and learning impaired aging rats. Neurobiol Aging. 2011;32:698-706.
11. Burns JW. Arousal of negative emotions and symptom-specific reactivity in chronic low back pain patients. Emotion. 2006;6:309-19.
12. Canli T, Zhao Z, Brewer J, Gabrieli JD, Cahill L. Event-related activation in the human amygdala associates with later memory for individual emotional experience. J Neurosci. 2000;20:RC99.
13. Carobrez AP, Bertoglio LJ. Ethological and temporal analyses of anxiety-like behavior: the elevated plus-maze model 20 years on. Neurosci Biobehav Rev. 2005;29:1193-205.
14. Cathala L, Holderith NB, Nusser Z, DiGregorio DA, Cull-Candy SG. Changes in synaptic structure underlie the developmental speeding of AMPA receptor-mediated EPSCs. Nat Neurosci. 2005;8:1310-8.
15. Chegini HR, Nasehi M, Zarrindast MR. Differential role of the basolateral amygdala 5-HT3 and 5-HT4 serotonin receptors upon ACPA-induced anxiolytic-like behaviors and emotional memory deficit in mice. Behav Brain Res. 2014;261:114-26.
16. Costanzi M, Battaglia M, Rossi-Arnaud C, Cestari V, Castellano C. Effects of anandamide and morphine combinations on memory consolidation in cd1 mice: involvement of dopaminergic mechanisms. Neurobiol Learn Mem. 2004;81:144-9.
17. Court JM. Cannabis and brain function. J Paediatr Child Health. 1998;34:1-5.
18. Davies DC, Martinez-Garcia F, Lanuza E, Novejarque A. Striato-amygdaloid transition area lesions reduce the duration of tonic immobility in the lizard Podarcis hispanica. Brain Res Bull. 2002;57:537-41.
19. Dolcos F, LaBar KS, Cabeza R. Interaction between the amygdala and the medial temporal lobe memory system predicts better memory for emotional events. Neuron. 2004;42:855-63.
20. Ebrahimi-ghiri M, Nasehi M, Rostami P, Mohseni-Kouchesfehani H, Zarrindast MR. The effect of cholestasis on rewarding and exploratory behaviors induced by opioidergic and dopaminergic agents in mice. Arch Iran Med. 2012;15:617-24.
21. Faber ES, Sah P. Ca2+-activated K+ (BK) channel inactivation contributes to spike broadening during repetitive firing in the rat lateral amygdala. J Physiol. 2003;552:483-97.
22. Farrant M, Nusser Z. Variations on an inhibitory theme: phasic and tonic activation of GABA(A) receptors. Nat Rev Neurosci. 2005;6:215-29.
23. Gauriau C, Bernard JF. Pain pathways and parabrachial circuits in the rat. Exp Physiol. 2002;87:251-8.
24. Haj-Dahmane S, Shen RY. The wake-promoting peptide orexin-B inhibits glutamatergic transmission to dorsal raphe nucleus serotonin neurons through retrograde endocannabinoid signaling. J Neurosci. 2005;25:896-905.
25. Haller J, Bakos N, Szirmay M, Ledent C, Freund TF. The effects of genetic and pharmacological blockade of the CB1 cannabinoid receptor on anxiety. Eur J Neurosci. 2002;16:1395-8.
26. Haller J, Matyas F, Soproni K, Varga B, Barsy B, Nemeth B, et al. Correlated species differences in the effects of cannabinoid ligands on anxiety and on GABAergic and glutamatergic synaptic transmission. Eur J Neurosci. 2007;25:2445-56.
27. Haring M, Marsicano G, Lutz B, Monory K. Identification of the cannabinoid receptor type. 1 in serotonergic cells of raphe nuclei in mice. Neuroscience. 2007;146:1212-9.
28. Heishman SJ, Arasteh K, Stitzer ML. Comparative effects of alcohol and marijuana on mood, memory, and performance. Pharmacol Biochem Behav. 1997;58:93-101.
29. Herring D, Huang R, Singh M, Robinson LC, Dillon GH, Leidenheimer NJ. Constitutive GABAA receptor endocytosis is dynamin-mediated and dependent on a dileucine AP2 adaptin-binding motif within the beta. 2 subunit of the receptor. J Biol Chem. 2003;278:24046-52.
30. Holmes A. Genetic variation in cortico-amygdala serotonin function and risk for stress-related disease. Neurosci Biobehav Rev. 2008;32:1293-314.
31. Jazi R, Lalonde R, Qian S, Strazielle C. Regional brain evaluation of acetylcholinesterase activity in PS1/A246E transgenic mice. Neurosci Res. 2009;63:106-14.
32. Kalueff A, Nutt DJ. Role of GABA inmemory and anxiety. Depress Anx. 1997;4:100-10.
33. Katona I, Rancz EA, Acsady L, Ledent C, Mackie K, Hajos N, et al. Distribution of CB1 cannabinoid receptors in the amygdala and their role in the control of GABAergic transmission. J Neurosci. 2001;21:9506-18.
34. Kilmer B, Caulkins J, Pacula R, Reuter P. Bringing perspective to illicit markets: estimating the size of the U.S. marijuana market. Drug Alcohol Depend. 2011;119:153-60.
35. King JA, Burgess N, Hartley T, Vargha-Khadem F, O'Keefe J. Human hippocampus and viewpoint dependence in spatial memory. Hippocampus. 2002;12:811-20.
36. Köfalvi A. Cannabinoids and the brain. New York: Springer, 2007.
37. Kreitzer AC, Regehr WG. Retrograde inhibition of presynaptic calcium influx by endogenous cannabinoids at excitatory synapses onto Purkinje cells. Neuron. 2001;29:717-27.
38. Kriegebaum C, Gutknecht L, Schmitt A, Lesch KP, Reif A. [Serotonin now: Part. 1. Neurobiology and developmental genetics]. Fortschr Neurol Psychiatr. 2010;78:319-31.
39. Laviolette SR, Grace AA. The roles of cannabinoid and dopamine receptor systems in neural emotional learning circuits: implications for schizophrenia and addiction. Cell Mol Life Sci. 2006;63:1597-613.
40. Lichtman AH, Varvel SA, Martin BR. Endocannabinoids in cognition and dependence. Prostaglandins Leukot Essent Fatty Acids. 2002;66:269-85.
41. Mackiewicz KL, Sarinopoulos I, Cleven KL, Nitschke JB. The effect of anticipation and the specificity of sex differences for amygdala and hippocampus function in emotional memory. Proc Natl Acad Sci U S A. 2006;103:14200-5.
42. Manning BH, Martin WJ, Meng ID. The rodent amygdala contributes to the production of cannabinoid-induced antinociception. Neuroscience. 2003;120:1157-70.
43. Marco EM, Perez-Alvarez L, Borcel E, Rubio M, Guaza C, Ambrosio E, et al. Involvement of 5-HT1A receptors in behavioural effects of the cannabinoid receptor agonist CP 55,940 in male rats. Behav Pharmacol. 2004;15:21-7.
44. Marsicano G, Wotjak CT, Azad SC, Bisogno T, Rammes G, Cascio MG, et al. The endogenous cannabinoid system controls extinction of aversive memories. Nature. 2002;418:530-4.
45. McDonald AJ, Mascagni F. Localization of the CB1 type cannabinoid receptor in the rat basolateral amygdala: high concentrations in a subpopulation of cholecystokinin-containing interneurons. Neuroscience. 2001;107:641-52.
46. McGaugh JL. The amygdala modulates the consolidation of memories of emotionally arousing experiences. Annu Rev Neurosci. 2004;27:1-28.
47. McKernan MG, Shinnick-Gallagher P. Fear conditioning induces a lasting potentiation of synaptic currents in vitro. Nature. 1997;390:607-11.
48. Mishima K, Egashira N, Hirosawa N, Fujii M, Matsumoto Y, Iwasaki K, et al. Characteristics of learning and memory impairment induced by delta9-tetrahydrocannabinol in rats. Jap J Pharmacol. 2001;87:297-308.
49. Moreira FA, Wotjak CT. Cannabinoids and anxiety. Curr Top Behav Neurosci. 2010;2:429-50.
50. Morrow AL. Regulation of GABAA receptor function and gene expression in the central nervous system. Int Rev Neurobiol. 1995;38:1-41.
51. Nasehi M, Piri M, Jamali-Raeufy N, Zarrindast MR. Influence of intracerebral administration of NO agents in dorsal hippocampus (CA1) on cannabinoid state-dependent memory in the step-down passive avoidance test. Physiol Behav. 2010;100:297-304.
52. Nasehi M, Sharifi S, Zarrindast MR. Involvement of the cholinergic system of CA1 on harmane-induced amnesia in the step-down passive avoidance test. J Psychopharmacol. 2012;26:1151-61.
53. Naseri MH, Hesami-Tackallou S, Torabi-Nami M, Zarrindast MR, Nasehi M. Involvement of the CA1 GABAA receptors in MK-801-induced anxiolytic-like effects: an isobologram analysis. Behav Pharmacol. 2014;25:197-205.
54. Nicoll RA, Malenka RC, Kauer JA. Functional comparison of neurotransmitter receptor subtypes in mammalian central nervous system. Physiol Rev. 1990;70:513-65.
55. Nicolle MM, Gallagher M, McKinney M. Visualization of muscarinic receptor-mediated phosphoinositide turnover in the hippocampus of young and aged, learning-impaired Long Evans rats. Hippocampus. 2001;11:741-6.
56. Ohno-Shosaku T, Maejima T, Kano M. Endogenous cannabinoids mediate retrograde signals from depolarized postsynaptic neurons to presynaptic terminals. Neuron. 2001;29:729-38.
57. Onaivi ES, Green MR, Martin BR. Pharmacological characterization of cannabinoids in the elevated plus maze. J Pharmacol Exp Ther. 1990;253:1002-9.
58. Pacula RL. Substance use and recessions: what can be learned from economic analyses of alcohol? Int J Drug Policy. 2011;22:326-34.
59. Paulson PE, Casey KL, Morrow TJ. Long-term changes in behavior and regional cerebral blood flow associated with painful peripheral mononeuropathy in the rat. Pain. 2002;95:31-40.
60. Paxinos G, Franklin KBJ. The mouse brain in stereotaxic coordinates. 2nd ed. New York: Academic Press, 2001.
61. Pertwee RG, Ross RA. Cannabinoid receptors and their ligands. Prostaglandins Leukot Essent Fatty Acids. 2002;66:101-21.
62. Rea K, Olango WM, Harhen B, Kerr DM, Galligan R, Fitzgerald S, et al. Evidence for a role of GABAergic and glutamatergic signalling in the basolateral amygdala in endocannabinoid-mediated fear-conditioned analgesia in rats. Pain. 2013;154:576-85.
63. Rezayat M, Roohbakhsh A, Zarrindast MR, Massoudi R, Djahanguiri B. Cholecystokinin and GABA interaction in the dorsal hippocampus of rats in the elevated plus-maze test of anxiety. Physiol Behav. 2005;84:775-82.
64. Roozendaal B, McEwen BS, Chattarji S. Stress, memory and the amygdala. Nat Rev Neurosci. 2009;10:423-33.
65. Rossi S, De Chiara V, Musella A, Kusayanagi H, Mataluni G, Bernardi G, et al. Chronic psychoemotional stress impairs cannabinoid-receptor-mediated control of GABA transmission in the striatum. J Neurosci. 2008;28:7284-92.
66. Ruehle S, Rey AA, Remmers F, Lutz B. The endocannabinoid system in anxiety, fear memory and habituation. J Psychopharmacol. 2012;26:23-39.
67. Ryberg AT, Warfvinge G, Axelsson L, Soukup O, Gotrick B, Tobin G. Expression of muscarinic receptor subtypes in salivary glands of rats, sheep and man. Arch Oral Biol. 2008;53:66-74.
68. Sah P, Lopez De Armentia M. Excitatory synaptic transmission in the lateral and central amygdala. Ann N Y Acad Sci. 2003;985:67-77.
69. Smith HR, Porrino LJ. The comparative distributions of the monoamine transporters in the rodent, monkey, and human amygdala. Brain Struct Funct. 2008;213:73-91.
70. Steffens M, Feuerstein TJ. Receptor-independent depression of DA and 5-HT uptake by cannabinoids in rat neocortex--involvement of Na(+)/K(+)-ATPase. Neurochem Int. 2004;44:529-38.
71. Uchida N, Takasaki K, Sakata Y, Nogami A, Oishi H, Watanabe T, et al. Cholinergic involvement and synaptic dynamin. 1 expression in yokukansan-mediated improvement of spatial memory in a rat model of early Alzheimer's Disease. Phytother Res. 2012.
72. Uriguen L, Perez-Rial S, Ledent C, Palomo T, Manzanares J. Impaired action of anxiolytic drugs in mice deficient in cannabinoid CB1 receptors. Neuropharmacology. 2004;46:966-73.
73. Valizadegan F, Oryan S, Nasehi M, Zarrindast MR. Interaction between morphine and noradrenergic system of basolateral amygdala on anxiety and memory in the elevated plus-maze test based on a test-retest paradigm. Arch Iran Med. 2013;16:281-7.
74. Varvel SA, Anum E, Niyuhire F, Wise LE, Lichtman AH. Delta(9)-THC-induced cognitive deficits in mice are reversed by the GABA(A) antagonist bicuculline. Psychopharmacology. 2005;178:317-27.
75. Viveros MP, Marco EM, File SE. Endocannabinoid system and stress and anxiety responses. Pharmacol Biochem Behav. 2005;81:331-42.
76. Wang DV, Wang F, Liu J, Zhang L, Wang Z, Lin L. Neurons in the amygdala with response-selectivity for anxiety in two ethologically based tests. PloS One. 2011;6:e18739.
77. Wilson MA, Mascagni F, McDonald AJ. Sex differences in delta opioid receptor immunoreactivity in rat medial amygdala. Neurosci Lett. 2002;328:160-4.
78. Wilson SG, Mogil JS. Measuring pain in the (knockout) mouse: big challenges in a small mammal. Behav Brain Res. 2001;125:65-73.
79. Wise LE, Thorpe AJ, Lichtman AH. Hippocampal CB(1) receptors mediate the memory impairing effects of Delta(9)-tetrahydrocannabinol. Neuropsychopharmacology. 2009;34:2072-80.
80. Yamodo IH, Chiara DC, Cohen JB, Miller KW. Conformational changes in the nicotinic acetylcholine receptor during gating and desensitization. Biochemistry. 2010;49:156-65.
81. Yousefi B, Farjad M, Nasehi M, Zarrindast MR. Involvement of the CA1 GABAA receptors in ACPA-induced impairment of spatial and non-spatial novelty detection in mice. Neurobiol Learn Mem. 2013;100:32-40.
82. Zarrindast MR, Bakhsha A, Rostami P, Shafaghi B. Effects of intrahippocampal injection of GABAergic drugs on memory retention of passive avoidance learning in rats. J Psychopharmacol. 2002;16:313-9.
83. Zarrindast MR, Naghdi-Sedeh N, Nasehi M, Sahraei H, Bahrami F, Asadi F. The effects of dopaminergic drugs in the ventral hippocampus of rats in the nicotine-induced anxiogenic-like response. Neurosci Lett. 2010;475:156-60.
84. Zarrindast MR, Nasehi M, Khansari M, Bananej M. Influence of nitric oxide agents in the rat amygdala on anxiogenic-like effect induced by histamine. Neurosci Lett. 2011;489:38-42.
85. Zarrindast MR, Nasehi M, Piri M, Heidari N. Effects of cholinergic system of dorsal hippocampus of rats on MK-801 induced anxiolytic-like behavior. Neurosci Lett. 2011;505:65-70.
 
 

Figure 1: Open-arms exploratory behavior following pretest microinjections of muscimol (Panels 1 and 2) and bicuculline (Panels 3 and 4) into BLA. After 24 h, all groups were retested in the EPM un-drugged. %OAT (A); %OAE (B) and CAE (C). Values are expressed as mean±S.E.M (n=8 in each group).

**P < 0.05 different from respective saline group in the panel 1. +P < 0.05, ++P < 0.01 and +++P < 0.001 different from control saline group in Panel 2. ψ < 0.05 different from the saline group in the Panel 4.

Figure 2: Panels 3 and 4 for muscimol and Panels 5 and 6 for bicuculline show the effect of intra-BLA pre-testing injection of sub-threshold dose muscimol and bicuculline on open-arms exploratory-like behavior induced by both sub-threshold and effective doses of ACPA. After 24 h, all groups were retested in the EPM un-drugged which showed by %OAT (A), %OAE (B) and CAE (C). Values are expressed as mean±S.E.M (n = 8 in each group).

*P < 0.05 and **P < 0.01 different from saline group in the Panel 1. ψψψP < 0.001 different from saline group in Panel 2. For panels 3 φφ < 0.01 and φφφ < 0.001 are compared to respective group in the Panel 1, while δ < 0.05, δδ < 0.01 and δδδ < 0.001 are compared to the respective group in the Panel 2.

 

Table 1: The table describes repeated measure analysis with P values for the effect of GABAA agonist and antagonist on exploratory-like behaviors.

Table 2: Repeated measure analysis with P values for the effect of ACPA by itself and two-way ANOVA results for the effect of GABAA agonist and antagonist on exploratory-like behaviors induced by ACPA.

[*] Corresponding Author:

Mohammad-Reza Zarrindast, Department of Pharmacology, School of Medicine, Tehran University of Medical Sciences, Tehran, Iran, P. O. Box 13145-784, Tel: +9821-66402569, Fax: +9821-66402569, eMail: zarinmr@ams.ac.ir