Effects of social isolation and crowding upon active-avoidance performance in the rat

A novel escapable social interaction test reveals that social behavior and mPFC activation during an escapable social encounter are altered by post-weaning social isolation and are dependent on the aggressiveness of the stimulus rat

Post-weaning social isolation (PSI) has been shown to increase aggressive behavior and alter medial prefrontal cortex (mPFC) function in social species such as rats. Here we developed a novel escapable social interaction test (ESIT) allowing for the quantification of escape and social behaviors in addition to mPFC activation in response to an aggressive or nonaggressive stimulus rat. Male rats were exposed to 3 weeks of PSI (ISO) or group (GRP) housing, and exposed to 3 trials, with either no trial, all trials, or the last trial only with a stimulus rat. Analysis of social behaviors indicated that ISO rats spent less time in the escape chamber and more time engaged in social interaction, aggressive grooming, and boxing than did GRP rats. Interestingly, during the third trial all rats engaged in more of the quantified social behaviors and spent less time escaping in response to aggressive but not nonaggressive stimulus rats. Rats exposed to nonaggressive stimulus rats on the third trial had greater c-fos and ARC immunoreactivity in the mPFC than those exposed to an aggressive stimulus rat. Conversely, a social encounter produced an increase in large PSD-95 punctae in the mPFC independently of trial number, but only in ISO rats exposed to an aggressive stimulus rat. The results presented here demonstrate that PSI increases interaction time and aggressive behaviors during escapable social interaction, and that the aggressiveness of the stimulus rat in a social encounter is an important component of behavioral and neural outcomes for both isolation and group-reared rats.

Neonatal handling (resilience) attenuates water-avoidance stress induced enhancement of chronic mechanical hyperalgesia in the rat

Chronic stress is well known to exacerbate pain. We tested the hypothesis that neonatal handling, which induces resilience to the negative impact of stress by increasing the quality and quantity of maternal care, attenuates the mechanical hyperalgesia produced by water-avoidance stress in the adult rat. Neonatal male rats underwent the handling protocol on postnatal days 2-9, weaned at 21 days and tested for muscle mechanical nociceptive threshold at postnatal days 50-75. Decrease in mechanical nociceptive threshold in skeletal muscle in adult rats, produced by exposure to water-avoidance stress, was significantly attenuated by neonatal handling. Neonatal handling also attenuated the mechanical hyperalgesia produced by intramuscular administration of the pronociceptive inflammatory mediator, prostaglandin E2 in rats exposed as adults to water-avoidance stress. Neonatal handling, which induces a smaller corticosterone response in adult rats exposed to a stressor as well as changes in central nervous system neurotransmitter systems, attenuates mechanical hyperalgesia produced by water-avoidance stress and enhanced prostaglandin hyperalgesia in adult animals.

Ameliorative effects of brief daily periods of social interaction on isolation-induced behavioral and hormonal alterations

The present study investigated the effects of brief daily periods of social interaction on social-isolation-induced behavioral and hormonal alterations and deficits. Adult male Wistar rats were allocated to one of three housing conditions: 1) social housing (two per cage); 2) social isolation (one per cage); or partial social isolation (one per cage with access to another male rat for 60 min/day). After 14 days in these different housing conditions, the animals were subjected to various behavioral tests, including sucrose preference test, acoustic startle response, two-way active shuttle avoidance, pre-pulse inhibition, open field, cooperation learning task, and levels of corticosterone. Results revealed that social isolation had a substantial impact on rats' performance on most behavioral tests as well as on their corticosterone levels. Importantly, however, the results clearly demonstrate that allowing otherwise isolated animals to have a brief (60 min) daily social contact with another rat to a great extent abolishes or ameliorates most of the isolation-induced behavioral and hormonal alterations. Hence, providing isolated animals with brief daily periods of social contact may be used as a "preventive treatment" in order to protect them from the deleterious effects of isolation.

Social isolation prevents exercise-induced proliferation of hippocampal progenitor cells in female rats

Social isolation negatively affects the behavior and health of laboratory rats. Recently, it has been found that social isolation retards exercise-induced neurogenesis in the hippocampal dentate gyrus (DG) of male rats (Stranahan et al. (2006) Nat Neurosci 9:526-533). Since male and female rats react differently to housing changes and exercise opportunities, we investigated whether social isolation would also suppress the exercise-dependent increase in proliferation of dentate gyrus progenitor cells in females. Accordingly, female rats were housed either alone (isolated) or in groups (social) with (exercise) or without (sedentary) the opportunity to run in an exercise wheel. Proliferating progenitor cells were labeled with bromodeoxyuridine (BrdU). As expected, exercise increased the number of BrdU+ cells in socially housed animals. However, isolation prevented this running-induced increase. Our results expand upon previous findings by showing that the female brain is also susceptible to the suppressive effect of social isolation on exercise-induced neurogenesis.

The effects of individual housing on mice and rats: a review

Isolating an animal refers to the situation where the animal is physically fully demarcated from conspecifics without physical, visual, olfactory and auditory contact. Animals housed in separate cages in the same room are, although deprived of physical and visual contact, still in olfactory and auditory contact, and thus not totally isolated. During the fifties and sixties several studies claimed to show physiological and behavioural differences between individually and group housed rats and mice. The so-called ‘Isolation Syndrome’ characterised by changes in corticosterone levels, metabolism, growth, and behaviour was introduced, rather as a model for psychoneurosis than through any concern for animal welfare. Today, it is often stated as common knowledge in laboratory animal science textbooks that individual housing as well as isolation of rats and mice has an effect on physiology and behaviour. It is, however, unclear whether this effect actually impairs animal welfare.

The aim of this paper is to analyse studies on individual housing of mice and rats to evaluate whether there is documented proof that individual housing affects welfare, and, alternatively whether it is possible to house these animals individually without negative impact on welfare, eg by providing special housing improvements.

A range of studies have shown that individual housing or isolation has effects on corticosterone, the open field behaviour, barbiturate sleeping time and the metabolism of different pharmaceuticals in the animals. However, this review of 37 studies in rats and 17 studies in mice showed divergence in test results difficult to explain, as many studies lacked basal information about the study, eg information on genetic strains and housing conditions, such as bedding, enrichment and cage sizes. Furthermore, test and control groups most frequently differed in cage sizes and stocking densities, and behavioural tests differed in ways which may very well explain the differences in results. Overall, there seemed to be an effect of individual housing, although it may be small, and it seems reasonable to assume that, through making small changes in the procedures and housing environments, the effects can be minimised or even eliminated. More well-controlled and standardised studies are needed to give more specific answers to the questions this issue poses.

Effect of intrauterine position on sex differences in the gabaergic system and behavior of rats

In multiparous species such as the rat (in this case the albino Wistar strain), steroid influence during fetal growth is affected by the relative intrauterine position of male and female fetuses and is stronger when the potential effects of contiguity and caudal position are combined. The effect of intrauterine position on gonadal steroid levels in neonatal and adult animals was examined using radioimmunoassay techniques. Since the organizing effect of prenatal steroids may influence the postnatal GABA content, HPLC was used to determine the gabaergic content in several hypothalamic and limbic areas in the adult rat. The effects of intrauterine position on adaptive behavior were examined by recording exploratory behavior (using the corridor and hole board tests) and intraspecific aggression (induced by isolation). Female pups influenced by males during development produced more testosterone. In adult males, those that developed closer to the cervix (and with no influence from other fetuses) produced more testosterone and less estradiol. The same animals also produced more hypothalamic GABA and showed greater exploratory capacity. No significant differences were seen between any experimental groups with respect to aggression. These results show increased variability between males with respect to adult exploratory behavior, and in the neurochemical and endocrine systems involved, due to intrauterine position during development. The effect of this physiological phenomenon on the structure of rodent populations is discussed.

Sex differences in behavioral and neurochemical profiles after chronic stress: role of housing conditions

This experiment sought to identify the extent housing conditions can differentially enhance or dampen the effects chronic restraint stress has on exploration and object memory in male and female rats. Subjects were either pair- or singly housed during stress (21 days of 6-h restraint) and maintained under those conditions during poststress behavior testing (7 days). Neurochemical analysis of neural tissue was accomplished by HPLC with electrochemical detection. Interactions between stress and housing conditions were found across both sexes. Stress was associated with less activity in the center of the forced open-field in both sexes. Stress also decreased the latency for males to enter the free open-field to female levels. Object recognition was greatly impaired in double-housed males but unaffected by stress or housing in females. Object location memory was impaired in stressed males if they were singly housed, and females performed as well as control males only if they were stressed. Both sexes generally showed increased in hippocampal (CA3) norepinephrine levels in their respective stress groups. Singly housed subjects had higher CA1 serotonin levels compared to double-housed subjects, whereas in the prefrontal cortex, a general sex difference was found with females having higher levels of serotonin and dopamine metabolites. These results show that stress affects limbic neurochemistry across sex, although only males exhibit stress-dependent decrements in object memory. Housing condition also has a profound effect on neurochemistry and male performance on object recognition. Thus, housing condition is a critical variable for male models of stress that can influence the extent the stress manipulation affects behavior. The differences observed across sex are further discussed in the context of behavioral inhibition.

Ethanol inhibition of NMDA currents in acutely dissociated medial septum/diagonal band neurons from ethanol dependent rats

The effect of acutely applied ethanol and the impact of chronic ethanol treatment, sufficient to induce tolerance and physical dependence, on N-methyl-D-aspartate (NMDA) receptor function were studied in acutely isolated neurons from the medial septum/diagonal band (MS/DB) of adult rats using whole cell, patch-clamp electrophysiology. There was a small positive correlation for capacitance and current amplitude activated by 100 microM NMDA for all groups. Also, cell membrane capacitance was significantly smaller for Ethanol Dependent (approximately 80-84%) than either Naive or Control cells. Therefore NMDA-activated responses were normalized for capacitance (current density, pA/pF) across all three groups. NMDA-activated (30-1000 microM) responses were significantly larger in cells from Control and Ethanol Dependent rats relative to those from Naives. In addition, estimated maximal responses were significantly larger for Ethanol Dependent cells, compared to either Control or Naive, respectively, while EC50s and slopes were not significantly different. Acute 60 mM ethanol significantly inhibited responses to 100 microM NMDA in all three groups, however, mean ethanol inhibition was 12-25% smaller after ethanol dependence. There was no evidence of acute tolerance to ethanol inhibition for any group, but examination of patterns of inhibition for individual neurons showed a few cells were resistant to ethanol or exhibited progressive loss of ethanol inhibition. These results suggest that NMDA receptor function in acutely isolated MS/DB neurons is increased following in vivo chronic ethanol treatment, and shows resistance to acute ethanol inhibition suggesting NMDA receptor-mediated cellular tolerance.