Acute Restraint Stress Enhances Prosocial Behavior in Rats via Oxytocin and Fear-Related Circuits

Sheng-Chiang Wang; Chen-Cheng Lin; Chun-Chuan Chen; Yia-Ping Liu

doi:10.31083/JIN33400

Journal of Integrative Neuroscience ›› 2025, Vol. 24 ›› Issue (4) :33400 DOI: 10.31083/JIN33400

Original Research

research-article

Acute Restraint Stress Enhances Prosocial Behavior in Rats via Oxytocin and Fear-Related Circuits

Author information +

History +

PDF (7562KB)

Abstract

Background:

Stress is a critical determinant of social behavior, with oxytocin playing a key role in buffering stress effects and facilitating social bonding. However, the relationship between stress-induced fear and oxytocin-associated sociability remains unclear, particularly in contexts reminiscent of prior stress. This study investigates whether acute restraint stress (ARS) alters anxiety-related behaviors and prosocial choices, and whether these effects can be modulated by pharmacological intervention targeting the oxytocin and corticotropin-releasing hormone (CRH) systems.

Methods:

Sprague-Dawley rats were subjected to ARS and assessed for anxiety-like behavior using the elevated T-maze (ETM) and for prosocial behavior using the social choice test (SCT). The effects of the oxytocin receptor antagonist L-368899 and CRH receptor antagonist antalarmin were evaluated in this paradigm. Plasma corticosterone was checked peripherally and the tissue concentrations of serotonin (5-HT), dopamine (DA), and norepinephrine (NE) were measured in the hippocampus, medial prefrontal cortex (mPFC), and amygdala to assess stress-related neurochemical changes in the fear circuit.

Results:

(i) ARS rats showed a significant increase in prosocial preference compared to control, an effect blocked by L-368899 or antalarmin. (ii) ARS rats exhibited reduced corticosterone levels, together with shorter avoidance latency, and longer escape latency in the ETM. (iii) Neurochemically, ARS rats had decreased DA and increased NE levels in the mPFC, both of which were normalized by L-368899 treatment.

Conclusions:

Oxytocin modulates stress-induced alterations in monoaminergic activity within the mPFC, influencing social choice behavior. These findings provide new insights into the neurobiological mechanisms underlying stress-related sociability and the context-dependent role of oxytocin in fear memory and social behavior.

Graphical abstract

Keywords

anxiety / corticosterone / corticotropin-releasing hormone / fear memory / monoamines / oxytocin / stress / sociability

Cite this article

Download citation ▾

Sheng-Chiang Wang, Chen-Cheng Lin, Chun-Chuan Chen, Yia-Ping Liu. Acute Restraint Stress Enhances Prosocial Behavior in Rats via Oxytocin and Fear-Related Circuits. Journal of Integrative Neuroscience, 2025, 24(4): 33400 DOI:10.31083/JIN33400

登录浏览全文

4963

注册一个新账户忘记密码

1. Introduction

Stress plays an important role in humans’ daily lives; it helped our ancestors develop problem-solving abilities, with which they were able to leave the jungle some 200,000 years ago [1]. However, stress can also affect cognitive and emotional functions, including sociability [2, 3]. In general, stress reduces an individual’s willingness to engage in social activities, while in other situations, it can facilitate prosocial behavior [4]. However, the mechanisms underlying these alternating effects remain unclear. From a neurobiological perspective, at least the upstream and downstream profiles of the hypothalamic–pituitary–adrenal axis (HPA) axis and neural substrates projecting to stress-related brain areas (particularly the hippocampus, amygdala, as well as medial prefrontal cortex) are highly involved, representing an incorporated way to manage stress throughout the peripheral and central components [5, 6, 7, 8]. Oxytocin plays a key role in integrating these mechanisms.

Oxytocin is a neuropeptide produced in the hypothalamus and released from the posterior pituitary gland [9]. Initially identified as a hormone produced by expectant mothers to aid in childbirth, it has been recognized for its multiple biological utilities with a connection to the HPA axis, including the involvement of corticotropin-releasing hormone (CRH), the key to bridging stress management and social behavior [10, 11, 12]. For example, increasing evidence has indicated that oxytocin, colloquially known as the ‘love hormone’, enhances feelings of social bonding [13, 14]. However, it has also been reported to enhance emotional distress, in which oxytocin-induced social behavior may be interpreted as an outcome of conflicting or opposing factors [15, 16]. Diversity in the milieu or contextual environment in which oxytocin may operate to differentially modulate stress-induced psychological outcomes, where appropriate, remains unclear [13]. Furthermore, whether stress/anxiety-related fear memory influences oxytocin-driven prosocial behavior may involve the disruption of neurotransmission across fear memory circuits, including the hippocampus, medial prefrontal cortex (mPFC), as well as amygdala, via a highly area-dependent operating mechanism regulated by oxytocin function requires further investigated [17, 18, 19, 20].

In our previous studies using a rat model of post-traumatic stress disorder (PTSD), we demonstrated that oxytocin successively restored traumatic stress-reduced prosocial contact, whereas CRH was more sensitive to the animals’ anxiety/ambivalence state [20, 21]. However, compared to PTSD, a long-term biological adaptation process, it appears that stress may more commonly trigger quick/reactive effects, as modeled by acute restraint stress (ARS). The ARS is a rodent paradigm of movement constraints that elicits unpleasant reaction [22, 23, 24, 25, 26]; thus it has been used to induce acute stress specific to the inability to escape. Therefore, the objective of the present study was to investigate whether oxytocin-involved social choice is influenced by acute stress, and whether it is related to disturbances in monoamine neurotransmitters, such as serotonin (5-HT), dopamine (DA), and norepinephrine (NE), across different fear circuit areas including the hippocampus, mPFC, as well as amygdala.

In this study, we aimed to fill the significant knowledge gap regarding the role of oxytocin in acutely stressed rats experiencing psychological conflict. These findings may provide novel insights into the relationship between stress and oxytocin-associated prosocial behaviors.

2. Materials and Methods

2.1 Experimental Protocol

Fig. 1 is a schematic diagram of the experimental design for this study. In brief, ARS rats were employed, and their behavioral performance were measured by social choice test (SCT) and elevated-T maze (ETM), referring to prosocial behavior and anxiety activity, respectively. The ARS procedure was employed to mimic real-life stressful psychosocial events [27, 28, 29]. During the ARS, rats were restrained in a ventilated plastic holder with an adjustable top for two hours. Afterward, they were isolated in their home cages for one day. Meanwhile, the rats that did not undergo ARS remained undisturbed in their cages.

Our paradigm of SCT is a three-chamber design which was modified from previous social interaction paradigm [30, 31], to reflect not only rats’ social choice for the chamber placing a holder-restrained conspecific rat, it also effectively examines the effect of fear memory as the experimental rats being restrained in the same holder previously when underwent ARS [20]. ETM provides both behavioral profile of conditioned and non-conditioned anxiety, thus is broadly employed in stress paradigm [32, 33]. Neurochemical assessments included measuring plasma corticosterone levels and analyzing monoamines concentrations in the hippocampus, mPFC, as well as amygdala. The endpoint of the experiment was done by decapitating the rats after they were exposed to 5% isoflurane (#1001936040, Baxter International Inc., Deerfield, IL, USA) vapor until death.

2.2 Drugs and Doses

Oxytocin antagonist (L-368899 hydrochloride, Tocris Bioscience, Bristol, UK) was obtained from Tocris Bioscience, UK, it was dissolved in saline and administered intraperitoneally (i.p.) at a dose of 5 mg per kg, one hour prior to SCT and ETM. The dose of L-368899 was chosen based on previous studies [34, 35]. Corticotropin releasing hormone receptor 1 (CRHR1) antagonist antalarmin was obtained from Sigma-Aldrich, St. Louis, MO, USA (A8727). It was dissolved in 1:10 ratio of Tween 80 (P4780, Sigma-Aldrich, St. Louis, MO, USA)/saline and intraperitoneally administered at 20 mg per kg 1 hour before SCT and ETM. For all groups, drugs were freshly prepared before administration. Each control group received the corresponding vehicle of the drug being tested (saline).

2.3 Animals

We used 24 male and aged 8 weeks Sprague–Dawley (SD) rats in this study, these rats were purchased from BioLASCO Co., Ltd. When the rats arrived at the animal center of National Defense Medical Center, they were randomly assigned to four groups (3 rats in one cages), including control-vehicle (CON-veh), ARS-vehicle (ARS-veh), ARS-L368899, ARS-antalarmin (N = 6), respectively.

The rats were housed under controlled temperature and humidity conditions, with house lights on from 7:00 AM to 7:00 PM at the animal center of National Defense Medical Center. Standard laboratory chow (Ralston Purina, St. Louis, MO, USA) and sterile filtered water were provided ad libitum.

The behavioral tests in this study began at 8:00 AM and were completed by no later than 6:00 PM, and the experiment was conducted at the same time for each rat as much as possible. The animal care committee of NDMC approved the experimental procedures and ethical guidelines (IACUC-17-300). Every effort was made to minimize animal use and to alleviate any potential suffering.

2.4 Locomotor Activity

The locomotor activity was similar to the protocol used in previous study [36], Two hours prior to ETM, the rat was individually placed in a white box (40 cm in width, 40 cm in depth, as well as 20 cm in height) containing 16 squares (10 cm in width and 10 cm in depth for each) and allowed to explore the environment for 5 min. During this period, the number of rears and total line crossings were recorded as indicators of vertical and horizontal activity, respectively.

2.5 SCT

The SCT was used to assess social responses and empathy-like behaviors [30, 31]. It was employed in a non-transparent white acrylic box (SCT box, 60 cm in width, 30 cm in depth, as well as 30 cm in height.) with three chambers: zone 1 (designated as the non- social zone), zone 2 (designated as the center), as well as zone 3 (designated as the social zone). Each SCT trial lasted 300 seconds, during which a non-familiar conspecific rat was placed in a transparent plexiglass restrainer (8.75 cm in width

\times{}

25 cm in depth

\times{}

7.5 cm in height (Harvard Apparatus, Holliston, MA, USA)) positioned in the zone 3, the restrainer was spacious enough to allow the restrained rat to move and turn inside. The restrainer featured several small lateral slits and a larger slit at the rear. Note that the restrained rat and the tested rat were of the same sex and similar in size.

During the initial 3 days, all tested rats were habituated to the SCT box for 10 min daily. On the test day, the tested rat was placed in the center chamber of SCT box (zone 2). The time spent in each zone and the interactions between the two rats were recorded and the social choice-related behavior was evaluated by two senior experimenters who remained blinded to the group assignment throughout the study to ensure unbiased data collection and interpretation. Note that a rat was counted only when all four of its paws were in that zone.

2.6 ETM

The ETM was performed three days after the SCT, similar to the protocol used in previous studies [33, 37], in which the performance of avoidance latency and escape latency are considered to reflect generalized and panic anxiety in human, respectively [38].

The black ETM apparatus featured a 50-cm high T-shaped platform with three equal arms (12 cm in width and 50 cm in depth), a 40 cm-high black walls surrounded the enclosed middle arm and 1 cm-high black barriers surrounded the two open side arms. For the training stage of ETM, we blocked the enclosed middle arm and then placed the rats on the one of the open side arm for 30 min. The test stage was conducted 24 hours after the training stage of ETM, the rats were cautiously placed along the wall at the enclosed arm’s end, and the experimenter maintained a distance of at least 5 meters until each trial was completed. The time spent to leave the arm was recorded (defined as the moment all four paws exited the arm). This process was repeated three times, corresponding to baseline, avoidance 1 latency, and avoidance 2 latency. After the avoidance 2 trial, the rats were positioned at the open arm’s end with their heads facing the center, and the escape latency was recorded as the time taken for all four paws to enter the middle enclosed arm. The intertrial interval (ITI) was set at 180 seconds, with a maximum duration of 300 seconds for each trial. A trial concluded as soon as the rats moved to a different arm. To minimize potential habituation effects, the rats were carefully returned to their home cages immediately after each trial.

2.7 Plasma Corticosterone Level

A 0.5 cc blood samples were collected from the rats’ tail veins between 2:00 PM and 3:00 PM to ensure that corticosterone stays at its relative lower level to avoid the influence from circadian change [39]. The blood samples were quickly mixed with 1 cc heparin sodium. After centrifuging the blood samples at 6000 g for 10 minutes at 4 °C, the supernatants (plasma) were collected and the corticosterone concentration was further assessed by using a corticosterone EIA kit (item number: 501320, Cayman Chemical Company, Ann Arbor, MI, USA). The layout and reagent volumes for the corticosterone EIA kit can be found in Supplementary Fig. 2.

2.8 Tissue Levels of Monoamines in Hippocampus, mPFC, as well as Amygdala

Rats were euthanized via rapid decapitation, and their hippocampus, mPFC, as well as amygdala were rapidly dissected [40]. The process of brain region dissection was carried out on an icy cold plate. Each brain tissue was carefully weighed immediately after dissection. The tissues were then homogenized in 0.2 mL of 7 N perchloric acid (244252, Sigma-Aldrich, St. Louis, MO, USA) and centrifuged at 12,000

\times{}

g at 4 °C for 30 min. The supernatant was then collected and filtered through a 0.22-µm filter. An electrochemical detector HPLC (ECD, LC-4C, BAS, West Lafayette, IN, USA) was used to measure the concentration of tissue 5-HT, DA, as well as NE in the target brain areas with a C18 column (150 mm

\times{}

4.6 mm, 5 µm, HICHROM, Haryana, India) and 1.0 mL per min flow rate. The mobile phase we used contained the following components: NaH₂PO₄

\cdot{}

H₂O (S9638, 100 mM, Sigma-Aldrich, St. Louis, MO, USA), sodium octane sulfonate (O8380, 0.74 mM, Sigma-Aldrich, St. Louis, MO, USA), ethylenediaminetetraacetic acid (E5134, 0.02 mM, Sigma-Aldrich, St. Louis, MO, USA), methanol (34860, 10%, Sigma-Aldrich, St. Louis, MO, USA) and the pH adjusted to 3.0 using H₃PO₄, (695017, Sigma-Aldrich, St. Louis, MO, USA). For standard curve of 5-HT, DA, and NE quantification, see Supplementary Fig. 1.

2.9 Data Analysis

In this study, comparisons between the Control-veh and ARS-veh groups were made using an unpaired t-test. Note that if the data failed to normality or equal variance test, the Mann-Whitney rank sum test (MW test) was applied instead. To analyze differences among the ARS-veh, ARS-L368899, and ARS-antalarmin groups, a one-way analysis of variance (ANOVA) was conducted. A p-value of less than 0.05 was considered indicative of statistical significance. The statistical analyses in this study were carried out with SPSS (version 16.0, IBM Corp., Chicago, IL, USA).

3. Results

For the locomotion activity, unpaired t-test showed no significant difference between Control-veh and ARS-veh (Fig. 2A). Furthermore, one-way ANOVA also revealed no significant difference among the drugs in ARS groups (Fig. 2B).

For the contact time to the social partner, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₁₀₎ = 7.706, p

<

0.001) (Fig. 3A). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,15) = 13.983, p

<

0.001). This difference was driven by the differences observed between ARS-Veh and ARS-L368899 (p = 0.01), and antalarmin (p = 0.01) (Fig. 3B). For the contact number to the social partner, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₁₀₎ = 3.967, p = 0.003) (Fig. 3C). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,15) = 30.688, p

<

0.001). This difference was driven by the differences observed between ARS-Veh and ARS-L368899 (p

<

0.001), and antalarmin (p

<

0.001) (Fig. 3D).

For the duration spent in Zone 1, unpaired t-test showed no significant difference between Control-veh and ARS-veh (Fig. 4A). Furthermore, one-way ANOVA also revealed no significant difference among the drugs in ARS groups (Fig. 4B). For the duration spent in Zone 2, unpaired t-test showed no significant difference between Control-veh and ARS-veh (Fig. 4C). Furthermore, one-way ANOVA further revealed a significant difference among drugs in the ARS groups (F_(2,15) = 4.272, p = 0.034). This difference was driven by the differences observed between ARS-L368899 and ARS- antalarmin (p = 0.041) (Fig. 4D). For the duration spent in Zone 3, unpaired t-test showed no significant difference between Control-veh and ARS-veh (Fig. 4E). Furthermore, one-way ANOVA also revealed no significant difference among the drugs in ARS groups (Fig. 4F).

For the ratio of contact time and contact number to the social partner, unpaired t-test showed no significant difference between Control-veh and ARS-veh (Fig. 5A). Furthermore, one-way ANOVA also revealed no significant difference among the drugs in ARS groups (Fig. 5B). For the ratio of contact time to the social partner and time spent in Zone 3, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₁₀₎ = 6.606, p

<

0.001) (Fig. 5C). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,15) = 7.638, p = 0.005). This difference was driven by the differences observed between ARS-Veh and ARS-L368899 (p = 0.011), and between ARS-Veh and antalarmin (p = 0.011) (Fig. 5D).

For the avoidance 1 latency of ETM, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₁₀₎ = 3.413, p = 0.007) (Fig. 6A). Furthermore, one-way ANOVA further revealed no significant difference among the drugs in ARS groups (Fig. 6B). For the escape latency of ETM, MW test showed a significant difference between Control-veh and ARS-veh (T = 25, p = 0.026) (Fig. 6C). Furthermore, one-way ANOVA revealed a significant difference among the drugs in ARS groups (H₍₃₎ = 6.99, p = 0.03). This difference was driven by a difference observed between ARS-veh and ARS-L368899 (p

<

0.05) (Fig. 6D).

For the concentration of plasma corticosterone, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₈₎ = 3.286, p = 0.011) (Fig. 7A). However, one-way ANOVA revealed no significant difference among the drugs in ARS groups (Fig. 7B).

For the Hippocampus 5-HT level, unpaired t-test showed no significant difference between Control-veh and ARS-veh (Fig. 8A). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,12) = 13.333, p

<

0.001). This difference was driven by differences observed between ARS-Veh and ARS-antalarmin (p = 0.011) and between ARS-L368899 and ARS-antalarmin (p

<

0.001) (Fig. 8B). For the mPFC 5-HT level, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₈₎ = 2.449, p = 0.04) (Fig. 8C). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,12) = 15.176, p

<

0.001). This difference was driven by differences observed between ARS-Veh and ARS-antalarmin (p = 0.026) and between ARS-L368899 and ARS-antalarmin (p

<

0.001) (Fig. 8D). For the amygdala 5-HT level, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₈₎ = 2.629, p = 0.03) (Fig. 8E). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,12) = 31.815, p

<

0.001). This difference was driven by differences observed between ARS-veh and ARS- L368899 (p

<

0.001), and ARS-veh and ARS-antalarmin (p

<

0.001) (Fig. 8F).

For the Hippocampus DA level, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₈₎ = 7.216, p

<

0.001) (Fig. 9A). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,12) = 4.524, p = 0.034). This difference was driven by differences observed between ARS-veh and ARS- L368899 (p = 0.034) (Fig. 9B). For the mPFC DA level, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₈₎ = 2.569, p = 0.033) (Fig. 9C). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,12) = 9.826, p = 0.003). This difference was driven by a difference observed between ARS-veh and - L368899 (p = 0.007), and ARS-L368899 and ARS-antalarmin (p = 0.006) (Fig. 9D). For the amygdala DA level, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₈₎ = 2.54, p = 0.035) (Fig. 9E). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,12) = 13.571, p

<

0.001). This difference was driven by differences observed between ARS-veh and ARS- L368899 (p

<

0.001), and ARS-veh and ARS-antalarmin (p = 0.01) (Fig. 9F).

For the hippocampus NE level, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₈₎ = 2.345, p = 0.047) (Fig. 10A). Furthermore, one-way ANOVA further revealed no significant difference among the drugs in ARS groups (Fig. 10B). For the mPFC NE level, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₈₎ = 7.414, p

<

0.001) (Fig. 10C). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,12) = 33.474, p

<

0.001). This difference was driven by a difference observed between ARS-veh and ARS-L368899 (p

<

0.001), and ARS-veh and ARS-antalarmin (p

<

0.001), (Fig. 10D). For the amygdala NE level, unpaired t-test showed a significant difference between Control-veh and ARS-veh (t₍₈₎ = 4.454, p = 0.003) (Fig. 10E). Furthermore, one-way ANOVA further revealed a significant difference among the drugs in ARS groups (F_(2,12) = 26.984, p

<

0.001). This difference was driven by differences observed between ARS-veh and ARS- L368899 (p = 0.005), ARS-veh and ARS-antalarmin (p

<

0.001), and ARS- L368899 and ARS-antalarmin (p = 0.016) ARS- L368899 (Fig. 10F).

4. Discussion

Social behaviors extend far beyond simply presenting with positive or negative feelings towards others; they may include ambivalent and emotionally mixed feelings in the decision-making process. In the present study, we designed a psychological dilemma for rats that had previously undergone restraint stress (i.e., being placed in a physical no-escape holder), in which they had to decide whether to engage in a prosocial opportunity involving an explicit cue (i.e., the no-escape holder) associated with their fear memories. Using this design, we examined the roles of oxytocin (the so-called ‘love hormone’) and CRH (an anxiety-triggering hormone) in tasks targeting prosocial behavior and anxiety activity, together with the corresponding changes in central monoamines within fear circuits. Overall, our results demonstrated the following: (i) ARS rats chose the chamber with prosocial opportunities more frequently, and this phenomenon was reversed by L-368899 and antalarmin. (ii) ARS rats exhibited lower corticosterone levels, together with shorter avoidance latency and longer escape latency in the ETM, indicating reduced anxiety. (iii) Compared to controls, ARS rats had lower DA levels, but higher NE levels in the mPFC, both of which were reversed by L-368899. The findings of this study are discussed below.

ARS rats showed a higher contact time/number with their partner indicates a prosocial tendency. However, as these rats were previously restrained in the same no-escape holder, the restraint impact on fear memory should also be considered. In other words, choosing a chamber with a social partner represents the outcome of the emotional conflict between fear memory (i.e., being far away from the chamber) and prosocial engagement (i.e., approaching the chamber). Regarding this type of social choice, Ben-Ami Bartal et al. [41] successfully demonstrated the strong urge of rats to free a cage mate trapped in a restrainer using an innovative cage-liberating task design. They considered this an evidence of “empathic concern” in rats. The neural basis of empathy-like behavior involves individuals’ previous experiences of an affective state that the empathy-associated neural network shares (or co-activates), specifically in the context of environmental similarity [42]. This hypothesis is further supported by the corresponding changes in ultrasonic vocalization, an animal communication mechanism, in rats previously experiencing electrical foot shocks while witnessing their conspecific cage undergoing the same shocks [43].

The above argument indicates a complicated relationship between stress and social behavior, specifically regarding how stressed rats express their social needs when fear memory is retrieved. Our oxytocin data may be helpful for interpretation. Oxytocin has been consistently acknowledged for its effect to enhance the feelings of social bonding [13, 14]. Hormones have also been reported to exert a fear-enhancing effect that increases emotional distress [15]. The twofold role of oxytocin appears to be strongly associated with its context-dependent mechanism, particularly when stress is combined with social interactions [42, 44, 45]. In the present study, the oxytocin antagonist L-368899 noticeably reversed the ARS-induced prosocial effect. Together with our previous findings that intranasal oxytocin amended the prosocial deficit in a pharmacologically specific manner in a rodent model of PTSD, indicating a mediating role of oxytocin to prompt social behavior when required [46], these results suggest that oxytocin-strengthened fear memory benefits the prosocial effect in ARS rats, as the required neuronal network is co-activated for contextual similarity with fear memory [42].

The observed anxiety profile in the present study highlights the role of anxiety in terms of its implications for prosocial behavior following acute stress. Overall, we found a lower level of corticosterone in ARS rats, together with a shorter avoidance latency and longer escape latency in the ETM. This raises the possibility that stress does not always trigger individual anxiety; rather, it may function in a positive way to soothe one’s mood or even promote defensive capacity to deal with incoming distress [47]. An alternative explanation could be that re-exposure to the traumatic analog itself may be considered a process for treating stress-induced disturbances and fear memory-associated cortisol abnormalities [48]. In this regard, it is possible that SCT (performed on day 3, one day following ARS) serves as an exposure therapy to soothe the rats’ anxiety tone (tested by ETM on Day 5) and reduce the level of plasma corticosterone (examined on day 6). These effects were reversed by L-368899, supporting the contribution of oxytocin to the anxiolytic effect once the rats were placed again into the context of trauma. In line with our previous finding that oxytocin helps fear extinction, oxytocin antagonism reduced escape latency in the ETM (i.e., heightened panic anxiety) in the present study, supporting the therapeutic role of oxytocin in anxiety disorders and PTSD [49, 50].

Monoaminergic neurotransmitters appeared to exert different effects across fear circuit areas (i.e., the hippocampus, mPFC, as well as amygdala) following ARS. In the present study, 5-HT and DA levels in these brain regions were reduced compared to those of the NE, which increased. In particular, the opposite changes in DA and NE levels in the mPFC were similar to those observed in the PTSD paradigm [8]. This indicates that catecholamines are crucial to regulate expression/suppression of fear. In the mPFC, DA downregulation and NE upregulation could represent a shared yet dissociable stressed neuronal process in both the acute reaction (as in the ARS paradigm) and long-term adaptation (as in the PTSD paradigm) [8, 51]. Overall, these results suggest that ARS-induced DA/NE changes in the mPFC are related to oxytocin-mediated social effects that mediate fear memory [52]. Neurochemical abnormalities can be reversed by the oxytocin antagonist L-368899, which reversed the ARS-induced prosocial effect, supporting the mediating role of oxytocin on mPFC DA transmission, potentially in a DA 1 receptor-dependent manner [53]. In other words, the mediating/buffering role of oxytocin may play a key role in explaining why fear memory facilitates prosocial behavior.

Overall, these results raise an interesting debate regarding whether oxytocin-dependent social behavior is delivered with ease or unease. Antalarmin negated ARS-induced prosocial inclinations, indicating that social needs are enhanced when individuals feel stressed or anxious. However, ARS rats also showed less anxiety, as indicated by lower plasma corticosterone levels, shorter avoidance latency, and longer escape latency in the ETM. This discrepancy highlights a complicated mechanism in which individuals are in conflict between prosocial tendencies and fear memory-associated anxiety, in which time-dependent neuroadaptation may be a key. For example, anxiety levels were increased three weeks after traumatic stress, yet the lower anxiety level found in the present study reflected incomplete neuroadaptation, as it was measured only 4 days after stress. These results have significant clinical implications. Specifically, our L-368899 data suggested that immediate oxytocin administration after stress restores the impaired socioemotional function [54], possibly via a fear circuit DA normalization mechanism, while conversely contributing to maintaining low plasma corticosterone levels, similar to that in PTSD [55]. These findings suggest a dual effect of oxytocin, supporting its potential therapeutic utility in individuals with socioemotional problems, while necessitating caution in those diagnosed with PTSD.

Some limitations must be addressed when interpreting our data. First, the number of rats in each group appeared to be insufficient, and increasing the number of animals should be beneficial for validating the scientific significance. Second, as this study had a single-dose design for L-368899 and antalarmin, the negative findings of their effects on corticosterone should be conservative, as different dosing and timing arrangement were found to disturb the corticosterone level [34]. Finally, we were unable to quantify fear memory, as a conditioned fear memory test was not performed. These concerns should be addressed in a future study involving pharmacologically fully scaling the dose profile of oxytocin and CRH receptors and behaviorally incorporating the Pavlovian fear conditioning test.

5. Conclusions

The present study demonstrated that acute restraint stress mediates anxiety and facilitates prosocial contact in a context-dependent manner involving signaling collaboration between oxytocin and CRH. Our results not only fill the knowledge gap regarding the relationship between stress, anxiety, and sociability, but also highlight the role of oxytocin in fear-related contexts.

Availability of Data and Materials

The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Nesse RM. Evolutionary psychiatry: foundations, progress and challenges. World Psychiatry. 2023; 22: 177–202. https://doi.org/10.1002/wps.21072.

[2]	Bagosi Z, Megyesi K, Ayman J, Rudersdorf H, Ayaz MK, Csabafi K. The role of corticotropin-releasing factor (CRF) and CRF-related peptides in the social behavior of rodents. Biomedicines. 2023; 11: 2217. https://doi.org/10.3390/biomedicines11082217.

[3]	Campeau S, Liberzon I, Morilak D, Ressler K. Stress modulation of cognitive and affective processes. Stress. 2011; 14: 503–519. https://doi.org/10.3109/10253890.2011.596864.

[4]	Sandi C, Haller J. Stress and the social brain: behavioural effects and neurobiological mechanisms. Nature Reviews. Neuroscience. 2015; 16: 290–304. https://doi.org/10.1038/nrn3918.

[5]	Salomé N, Viltart O, Lesage J, Landgraf R, Vieau D, Laborie C. Altered hypothalamo-pituitary-adrenal and sympatho-adrenomedullary activities in rats bred for high anxiety: central and peripheral correlates. Psychoneuroendocrinology. 2006; 31: 724–735. https://doi.org/10.1016/j.psyneuen.2006.02.002.

[6]	Carrasco J, Márquez C, Nadal R, Tobeña A, Fernández-Teruel A, Armario A. Characterization of central and peripheral components of the hypothalamus-pituitary-adrenal axis in the inbred Roman rat strains. Psychoneuroendocrinology. 2008; 33: 437–445. https://doi.org/10.1016/j.psyneuen.2008.01.001.

[7]	Burke AR, Miczek KA. Stress in adolescence and drugs of abuse in rodent models: role of dopamine, CRF, and HPA axis. Psychopharmacology. 2014; 231: 1557–1580. https://doi.org/10.1007/s00213-013-3369-1.

[8]

Lin CC, Tung CS, Lin PH, Huang CL, Liu YP. Traumatic stress causes distinctive effects on fear circuit catecholamines and the fear extinction profile in a rodent model of posttraumatic stress disorder. European Neuropsychopharmacology. 2016; 26: 1484–1495. https://doi.org/10.1016/j.euroneuro.2016.06.004.

[9]	Ludwig M. Dendritic release of vasopressin and oxytocin. Journal of Neuroendocrinology. 1998; 10: 881–895. https://doi.org/10.1046/j.1365-2826.1998.00279.x.

[10]	Bosch OJ, Young LJ. Oxytocin and social relationships: from attachment to bond disruption. Current Topics in Behavioral Neurosciences. 2018; 35: 97–117. https://doi.org/10.1007/7854_2017_10.

[11]	Takahashi T. Sensory stimulation of oxytocin release is associated with stress management and maternal care. Frontiers in Psychology. 2021; 11: 588068. https://doi.org/10.3389/fpsyg.2020.588068.

[12]	de Andrade JS, Viana MB, Abrão RO, Bittencourt JC, Céspedes IC. CRF family peptides are differently altered by acute restraint stress and chronic unpredictable stress. Behavioural Brain Research. 2014; 271: 302–308. https://doi.org/10.1016/j.bbr.2014.06.014.

[13]	Froemke RC, Young LJ. Oxytocin, neural plasticity, and social behavior. Annual Review of Neuroscience. 2021; 44: 359–381. https://doi.org/10.1146/annurev-neuro-102320-102847.

[14]	Walter MH, Abele H, Plappert CF. The role of oxytocin and the effect of stress during childbirth: neurobiological basics and implications for mother and child. Frontiers in Endocrinology. 2021; 12: 742236. https://doi.org/10.3389/fendo.2021.742236.

[15]	Guzmán YF, Tronson NC, Jovasevic V, Sato K, Guedea AL, Mizukami H, et al. Fear-enhancing effects of septal oxytocin receptors. Nature Neuroscience. 2013; 16: 1185–1187. https://doi.org/10.1038/nn.3465.

[16]	Eskandarian S, Vafaei AA, Vaezi GH, Taherian F, Kashefi A, Rashidy-Pour A. Effects of systemic administration of oxytocin on contextual fear extinction in a rat model of post-traumatic stress disorder. Basic and Clinical Neuroscience. 2013; 4: 315–322.

[17]	Bazaz A, Ghanbari A, Vafaei AA, Khaleghian A, Rashidy-Pour A. Oxytocin in dorsal hippocampus facilitates auditory fear memory extinction in rats. Neuropharmacology. 2022; 202: 108844. https://doi.org/10.1016/j.neuropharm.2021.108844.

[18]	Baldi E, Costa A, Rani B, Passani MB, Blandina P, Romano A, et al. Oxytocin and fear memory extinction: possible implications for the therapy of fear disorders? International Journal of Molecular Sciences. 2021; 22: 10000. https://doi.org/10.3390/ijms221810000.

[19]

Lopes-Azevedo S, Fortaleza EAT, Busnardo C, Scopinho AA, Matthiesen M, Antunes-Rodrigues J, et al. The Supraoptic Nucleus of the Hypothalamus Modulates Autonomic, Neuroendocrine, and Behavioral Responses to Acute Restraint Stress in Rats. Neuroendocrinology. 2020; 110: 10–22. https://doi.org/10.1159/000500160.

[20]

Wang SC, Lin CC, Tzeng NS, Tung CS, Liu YP. Effects of oxytocin on prosocial behavior and the associated profiles of oxytocinergic and corticotropin-releasing hormone receptors in a rodent model of posttraumatic stress disorder. Journal of Biomedical Science. 2019; 26: 26. https://doi.org/10.1186/s12929-019-0514-0.

[21]

Barretto-de-Souza L, Benini R, Reis-Silva LL, Crestani CC. Role of CRF₁ and CRF₂ receptors in the lateral hypothalamus in cardiovascular and anxiogenic responses evoked by restraint stress in rats: Evaluation of acute and chronic exposure. Neuropharmacology. 2022; 212: 109061. https://doi.org/10.1016/j.neuropharm.2022.109061.

[22]	Wang B, Yang X, Lu J, Ntim M, Xia M, Kundu S, et al. Two-hour acute restraint stress facilitates escape behavior and learning outcomes through the activation of the Cdk5/GR P S211 pathway in male mice. Experimental Neurology. 2022; 354: 114023. https://doi.org/10.1016/j.expneurol.2022.114023.

[23]	Padovan CM, Guimarães FS. Restraint-induced hypoactivity in an elevated plus-maze. Brazilian Journal of Medical and Biological Research = Revista Brasileira De Pesquisas Medicas E Biologicas. 2000; 33: 79–83. https://doi.org/10.1590/s0100-879x2000000100011.

[24]	Spinieli RL, Cazuza R, Sales AJ, Carolino R, Franci JA, Tajerian M, et al. Acute restraint stress regulates brain DNMT3a and promotes defensive behaviors in male rats. Neuroscience Letters. 2024; 820: 137589. https://doi.org/10.1016/j.neulet.2023.137589.

[25]	Molina P, Andero R, Armario A. Restraint or immobilization: A comparison of methodologies for restricting free movement in rodents and their potential impact on physiology and behavior. Neuroscience and Biobehavioral Reviews. 2023; 151: 105224. https://doi.org/10.1016/j.neubiorev.2023.105224.

[26]	Chaoui N, Anarghou H, Laaroussi M, Essaidi O, Najimi M, Chigr F. Long lasting effect of acute restraint stress on behavior and brain anti-oxidative status. AIMS Neuroscience. 2022; 9: 57–75. https://doi.org/10.3934/Neuroscience.2022005.

[27]	Zhang WJ, Cao WY, Huang YQ, Cui YH, Tu BX, Wang LF, et al. The role of miR-150 in stress-induced anxiety-like behavior in mice. Neurotoxicity Research. 2019; 35: 160–172. https://doi.org/10.1007/s12640-018-9943-x.

[28]	Amin SN, Gamal SM, Esmail RSEN, Aziz TMA, Rashed LA. Cognitive effects of acute restraint stress in male albino rats and the impact of pretreatment with quetiapine versus ghrelin. Journal of Integrative Neuroscience. 2014; 13: 669–692. https://doi.org/10.1142/S0219635214500253.

[29]

Miklos Z, Flynn FW, Lessard A. Stress-induced dendritic internalization and nuclear translocation of the neurokinin-3 (NK3) receptor in vasopressinergic profiles of the rat paraventricular nucleus of the hypothalamus. Brain Research. 2014; 1590: 31–44. https://doi.org/10.1016/j.brainres.2014.09.043.

[30]	Eagle AL, Fitzpatrick CJ, Perrine SA. Single prolonged stress impairs social and object novelty recognition in rats. Behavioural Brain Research. 2013; 256: 591–597. https://doi.org/10.1016/j.bbr.2013.09.014.

[31]	Noble LJ, Gonzalez IJ, Meruva VB, Callahan KA, Belfort BD, Ramanathan KR, et al. Effects of vagus nerve stimulation on extinction of conditioned fear and post-traumatic stress disorder symptoms in rats. Translational Psychiatry. 2017; 7: e1217. https://doi.org/10.1038/tp.2017.191.

[32]	Lin CC, Huang KL, Tung CS, Liu YP. Hyperbaric oxygen therapy restored traumatic stress-induced dysregulation of fear memory and related neurochemical abnormalities. Behavioural Brain Research. 2019; 359: 861–870. https://doi.org/10.1016/j.bbr.2018.07.014.

[33]	Lin CC, Yang CP, Cheng PY, Hsiao M, Liu YP. Escitalopram reversibility of the impacts following chronic stress on central 5-HT profiles - Implications to depression and anxiety. Behavioural Brain Research. 2023; 453: 114613. https://doi.org/10.1016/j.bbr.2023.114613.

[34]	Hodges TE, Eltahir AM, Patel S, Bredewold R, Veenema AH, McCormick CM. Effects of oxytocin receptor antagonism on social function and corticosterone release after adolescent social instability in male rats. Hormones and Behavior. 2019; 116: 104579. https://doi.org/10.1016/j.yhbeh.2019.104579.

[35]	Blitzer DS, Wells TE, Hawley WR. Administration of an oxytocin receptor antagonist attenuates sexual motivation in male rats. Hormones and Behavior. 2017; 94: 33–39. https://doi.org/10.1016/j.yhbeh.2017.06.002.

[36]	Kraeuter AK, Guest PC, Sarnyai Z. The open field test for measuring locomotor activity and anxiety-like behavior. Methods in Molecular Biology. 2019; 1916: 99–103. https://doi.org/10.1007/978-1-4939-8994-2_9.

[37]	László K, Péczely L, Géczi F, Kovács A, Zagoracz O, Ollmann T, et al. The role of D2 dopamine receptors in oxytocin induced place preference and anxiolytic effect. Hormones and Behavior. 2020; 124: 104777. https://doi.org/10.1016/j.yhbeh.2020.104777.

[38]	Viana MB, Tomaz C, Graeff FG. The elevated T-maze: a new animal model of anxiety and memory. Pharmacology, Biochemistry, and Behavior. 1994; 49: 549–554. https://doi.org/10.1016/0091-3057(94)90067-1.

[39]	Liu PY. Rhythms in cortisol mediate sleep and circadian impacts on health. Sleep. 2024; 47: zsae151. https://doi.org/10.1093/sleep/zsae151.

[40]	Paxinos G, Watson C. The rat brain in stereotaxic coordinates. 6th edn. Academic Press: USA. 2008.

[41]	Ben-Ami Bartal I, Decety J, Mason P. Empathy and pro-social behavior in rats. Science. 2011; 334: 1427–1430. https://doi.org/10.1126/science.1210789.

[42]	Bernhardt BC, Singer T. The neural basis of empathy. Annual Review of Neuroscience. 2012; 35: 1–23. https://doi.org/10.1146/annurev-neuro-062111-150536.

[43]	Karwicka W, Wiatrowska M, Kondrakiewicz K, Knapska E, Kursa MB, Hamed A. Relaying aversive ultrasonic alarm calls depends on previous experience. Empathy, Social Buffering, or Panic? Brain Sciences. 2021; 11: 759. https://doi.org/10.3390/brainsci11060759.

[44]	Guzmán YF, Tronson NC, Sato K, Mesic I, Guedea AL, Nishimori K, et al. Role of oxytocin receptors in modulation of fear by social memory. Psychopharmacology. 2014; 231: 2097–2105. https://doi.org/10.1007/s00213-013-3356-6.

[45]	Yamagishi A, Okada M, Masuda M, Sato N. Oxytocin administration modulates rats’ helping behavior depending on social context. Neuroscience Research. 2020; 153: 56–61. https://doi.org/10.1016/j.neures.2019.04.001.

[46]	Crockford C, Deschner T, Wittig RM. The role of oxytocin in sSocial buffering: what do primate studies add? Current Topics in Behavioral Neurosciences. 2018; 35: 155–173. https://doi.org/10.1007/7854_2017_12.

[47]	Danysz W, Kostowski W, Archer T. Some aspects of stress and depression. Progress in Neuro-Psychopharmacology & Biological Psychiatry. 1988; 12: 405–419. https://doi.org/10.1016/0278-5846(88)90101-7.

[48]	Elzinga BM, Schmahl CG, Vermetten E, van Dyck R, Bremner JD. Higher cortisol levels following exposure to traumatic reminders in abuse-related PTSD. Neuropsychopharmacology. 2003; 28: 1656–1665. https://doi.org/10.1038/sj.npp.1300226.

[49]	Lin EJD. Neuropeptides as therapeutic targets in anxiety disorders. Current Pharmaceutical Design. 2012; 18: 5709–5727. https://doi.org/10.2174/138161212803530871.

[50]	Olff M, Langeland W, Witteveen A, Denys D. A psychobiological rationale for oxytocin in the treatment of posttraumatic stress disorder. CNS Spectrums. 2010; 15: 522–530. https://doi.org/10.1017/s109285290000047x.

[51]	Giustino TF, Maren S. The role of the medial prefrontal cortex in the conditioning and extinction of fear. Frontiers in Behavioral Neuroscience. 2015; 9: 298. https://doi.org/10.3389/fnbeh.2015.00298.

[52]	Jang M, Jung T, Jeong Y, Byun Y, Noh J. Oxytocin modulation in the medial prefrontal cortex of pair-exposed rats during fear conditioning. Psychoneuroendocrinology. 2022; 141: 105752. https://doi.org/10.1016/j.psyneuen.2022.105752.

[53]	Li Q, Zhang B, Cao H, Liu W, Guo F, Shen F, et al. Oxytocin Exerts Antidepressant-like effect by potentiating dopaminergic synaptic transmission in the mPFC. Neuropharmacology. 2020; 162: 107836. https://doi.org/10.1016/j.neuropharm.2019.107836.

[54]	Kirsch P. Oxytocin in the socioemotional brain: implications for psychiatric disorders. Dialogues in Clinical Neuroscience. 2015; 17: 463–476. https://doi.org/10.31887/DCNS.2015.17.4/pkirsch.

[55]	Yehuda R. Post-traumatic stress disorder. The New England Journal of Medicine. 2002; 346: 108–114. https://doi.org/10.1056/NEJMra012941.

Funding

National Science and Technology Council(NSTC 112-2410-H-350-001)

Ministry of Science and Technology(MOST 111-2410-H-350-001)

Cheng Hsin General Hospital and National Defense Medical Center(CH-NDMC-110-9)

Cheng Hsin General Hospital and National Defense Medical Center(CH-NDMC-111-09)

PDF (7562KB)

Accesses

Citation

Detail

Sections

Recommended

About the journal

Aims & scope

Editorial board

Abstracting / indexing

Contact us

Browse

Just accepted

All volumes and issues

Collections

Featured articles

Most accessed

Most cited

Authors & reviewers

Online submission

Author guidelines