Corticosterone and prolactin do not mediate alarm pheromone effect in the rat

The role of neuroinflammation in the release of aversive odor cues from footshock-stressed rats: Implications for the neural mechanism of alarm pheromone

Stressed animals have been known to release aversive chemosignals toward which conspecifics show avoidance-like responses. The present studies assessed whether inflammatory cytokine responses provoked by footshock stress modulate odor signals released from male rats. Male rats were exposed to 30min of intermittent footshock (60 shocks, 1.0mA, 100ms each, variable ITI of 30s) or remained in their home cages as non-stressed controls. Real time RT-PCR analysis of brain tissues indicated that footshock increased the pro-inflammatory cytokine, IL-1β and hnCRH as well as c-fos mRNA expressions in the paraventricular nucleus, and the bed nucleus of the stria terminalis, and increased plasma corticosterone levels. Soiled bedding collected from rats exposed to 30-min, but not 5-min, of footshock elicited a differential response, as expressed by decreased sniffing and increased avoidance in male test subjects. Soiled bedding from rats given corticosterone injection (s.c. 1.25 or 3.75mg/ml) 3h before bedding collection evoked no avoidance response in odor-recipients. Furthermore, ICV infusion of the anti-inflammatory cytokine IL-10 (20 or 200ng) into the stimulus animals 30-min before a 30-min footshock session, had no effect on plasma corticosterone levels in the stimulus animals, but attenuated the release of aversive odor as indicated by dose-dependently diminished avoidance in odor-recipient rats. These results demonstrated that stressed rats release odorant cues that cause other rats to move away from the source of the signal. Such stress-induced chemosignals may be mediated by inflammatory cytokine responses in the brain.

Sickness-related odor communication signals as determinants of social behavior in rat: a role for inflammatory processes

Infected animals are avoided by conspecifics, suggesting that the inflammatory cascade may play a significant role in odor communication. Injection of male rats with the bacterial mimetic, lipopolysaccharide (LPS, 100 microg/kg, i.p.), decreased investigation through a wire-mesh partition between healthy male partners. This avoidance response was observed in adult males in response to soiled bedding collected from sick rats, regardless of whether LPS was injected peripherally (100 microg/kg, i.p.) or centrally (0.25 or 2.5 microg, icv). The release of sickness-related odor cues was dose-dependently blocked by icv infusion of the anti-inflammatory cytokine, interleukin-10 (IL-10; 20 or 200 ng), and reproduced by icv infusion of pro-inflammatory cytokine, IL-1beta (5 or 50 ng). Subcutaneous pretreatment with either estradiol benzoate (20 microg/kg) or testosterone propionate (50 or 500 microg/kg) to adult males that were administered LPS inhibited release of aversive odor cues, but these hormones alone did not influence odor properties. Importantly, the avoidance response to sickness-related odor was not associated with changes in plasma corticosterone, testosterone, or IL-6 levels of odor donors. However, plasma IL-1beta concentrations of sick animals was in fact predictive of aversive responses in conspecifics, suggesting that the inflammatory cascade, but not plasma steroid hormones, is likely to mediate aversive properties in odor that functions to signal illness state to conspecifics.

Enhancement of the acoustic startle reflex by an alarm pheromone in male rats

Recently, we reported that an alarm pheromone released from the perianal region of male rats aggravated stress-induced hyperthermia and increased defensive and risk assessment behaviors in recipient male rats. Based on these results, we hypothesized that the primary effect of the alarm pheromone is to increase anxiety; however, there is still no clear evidence for this pheromone effect. Therefore, we examined this issue by assessing the effect of the alarm pheromone on the acoustic startle reflex (ASR), which is a useful index for studying negative emotions such as anxiety in rats. The alarm pheromone enhanced the ASR for 105-dB auditory stimuli, but not for those of 90 and 120 dB, when these three intensities of sound were used randomly. The same results were obtained when one of these three intensities was used repeatedly. In addition, pretreatment with diazepam (i.p.) at doses of 0.7 and 2.0 mg/kg suppressed the ASR of the pheromone recipients, whereas the lower dose (0.2 mg/kg) slightly attenuated the pheromone effect and the control injection (vehicle) had no effect. These results indicate that the alarm pheromone enhances the ASR by increasing anxiety in recipient rats, suggesting that the primary effect of the alarm pheromone is to increase the anxiety level.

Circannual changes in the duration of the immobility response of rats in the forced swim test

Separate groups of male rats were tested in the forced swim test on the third Tuesday of each mo for 14 mo. A distinct pattern was observable in their immobility response such that animals were most immobile during the winter months (Dec-Mar) and least immobile during the summer months (June-Sept). Bicarbonate-carbon dioxide levels were significantly correlated with immobility times (r = 0.48), as were glucose (r = 0.34) and phosphorus (r = -0.33) levels, whereas corticosterone and testosterone levels were not significantly correlated with immobility. These results indicate that there is a circannual rhythm in the floating behavior of rats in the forced swim test.

Physical activity does not account for the physiological response to forced swim testing

Two experiments were conducted to examine physiological variables associated with the immobility response in the forced swim test. The first study compared the effects of water immersion, treadmill running, and foot shock, and showed that the time-related pattern of reactions to these three conditions, especially those involving lactate, glucose, anion gap (a measure of metabolic acidosis), and carbon dioxide differed significantly. The second study examined the role of food deprivation, and showed that this manipulation does not affect the behavior or physiological response of rats to testing. These results indicate that the physiological changes occurring during the forced swim are not simply due to increased physical activity or stress.

A further analysis of physiological changes in rats in the forced swim test

Rats were tested in the forced swim test in 35 or 20 cm of water or in an open field to evaluate the effects of different intensities of stress on blood gases, electrolytes, and metabolic indices, compared to nontested controls. Animals tested in the open field did not differ from controls on any measure. Immersion in deep water resulted in a greater mixed metabolic and respiratory acidemia (low pH, low bicarbonate, high pCO2), higher glucose and higher lactate levels than immersion in shallow water which in turn resulted in greater metabolic acidemia (low pH, low bicarbonate), and higher glucose and lactate levels than occurred in open field or control animals. In contrast to immersion in deep water, immersion in shallow water resulted in an initial hypocapnia followed by a hypercapnia. Immersion in deep water also resulted in higher potassium levels, lower bicarbonate and total carbon dioxide levels, and a higher anion gap than immersion in shallow water, testing in the open field, or in controls. In a second study, lactate infusion resulted in a metabolic alkalemia (increased pH and bicarbonate levels) and an increase in total carbon dioxide levels. These results indicate that test parameters from forced swim testing (e.g., water depth) can significantly affect the rat's physiological response to testing. The effects of forced swim testing are not simply due to general stress; and the physiological changes seen in conjunction with forced swim testing (e.g., acidemia) are not due to lactate alone.

Alpha-adrenergic receptors mediate imipramine/alarm substance-induced reaction in rats

The mechanism of adverse imipramine-induced reactions (jitteriness, convulsions) was investigated by precipitating such reactions in rats with three injections (IP) of imipramine (5-40 mg/kg) at 24, 5, and 1 h before testing, and comparing their occurrence with comparable treatments using specific noradrenergic and serotonergic reuptake inhibitors [nortriptyline (10 or 30 mg/kg, IP), citalopram (0.5-5.0 mg/kg, IP)]. This initial study indicated that these reactions were mediated by imipramine's noradrenergic effects. Subsequent combinations of imipramine and an alpha 2 agonist (clonidine, 5 mg/kg) and antagonist (yohimbine, 2 mg/kg), and a beta-adrenergic antagonist (propranolol, 2 or 5 mg/kg) (all administered IP 0.5 h after the last injection of imipramine) suggested imipramine's adverse effects were mediated by alpha 2 receptors. The possible involvement of the locus ceruleus in these effects was considered.

Behavioral and physiological effects of different water depths in the forced swim test

Rats were immersed for 15 min in a forced swim test in cylinders filled with water to a depth of 20 or 35 cm. The following day, they were reimmersed for a 5-min test period at one of these two depths. Water immersion, regardless of water depth, resulted in increased serum lactate and corticosterone levels, reduced serum carbon dioxide and potassium levels, a metabolic acidosis, and an increase in the phosphorus/potassium ratio. Testing at the greater water depth resulted in lower immobility times, higher lactate and lower carbon dioxide levels, a greater metabolic acidosis, and a higher phosphorus/potassium ratio than testing at the shallower depth. Water depth did not significantly affect corticosterone or potassium responses. None of the interactions between day 1 and day 2 depth was significant. The correlation between immobility time and corticosterone was very low, whereas the correlation with lactate, carbon dioxide, anion gap, and the phosphorus/potassium ratio were high. The inference from these results is water depth at time of testing affects the rat's behavioral and physiological reactions in the forced swim test and prior exposure to water at any depth does not.

Ontogeny of immobility and response to alarm substance in the forced swim test

The ontogeny of immobility in the forced swim test and the response to alarm substance were determined in rats. Immobility, defined as floating vertically in water, making only those minimal movements necessary to keep the head above water, emerged at 21 days of age and stabilized beginning at 26 days (< or = 10% variation from the mean time of the previous day). Males and females did not differ in maturation of this response. The reaction to alarm substance was discernible when animals were 24 days of age. Again, males and females were not significantly different in ontogeny of this response.

Effects of water immersion stress on convulsions induced by pentylenetetrazol

Increasing durations of water immersion stress were associated with increased serum corticosterone levels, decreased severity of pentylenetetrazol-induced convulsions, and increased latencies to convulse in rats. The results were interpreted in terms of the effects of stress and pentylenetetrazol's actions on GABAergic mechanisms.

Physiological correlates of the forced swim test in rats

Rats were tested in the forced swim test to evaluate the effects of duration of exposure (0, 5, 15, or 25 min), and water temperature (0, 35, 30, 25, or 20 degrees C), on a variety of physiological measures. Serum corticosterone, glucose, lactate, phosphorus levels, and the anion gap (a measure of acid-base status) were increased significantly, whereas carbon dioxide and potassium levels were consistently decreased by testing, as was the potassium/phosphorus ratio; creatinine, triglycerides, and magnesium were not altered significantly in any study. Effects on prolactin, amylase, lipase, cholesterol, alkaline phosphatase, sodium, and chloride were inconsistent. Levels of serum corticosterone were increased at each duration of testing, and the increments were significantly higher than the previous duration. Corticosterone levels were also increased in proportion to decreasing water temperature, but the increments were not significantly different from the previous or following temperatures. Glucose levels were increased at every duration and at every water temperature with the exception of the coldest water temperature. Lactate and phosphorus levels and the anion gap were all increased, whereas carbon dioxide levels decreased after 5 min of immersion. Potassium levels did not decrease until some time after 5 min of testing. Immobility times were marginally correlated with corticosterone levels (r = -0.38) but were highly correlated with serum carbon dioxide (r = 0.59), potassium (r = 0.67), and phosphorus levels (r = -0.73); the correlation between immobility times and the ratio of potassium/phosphorus was 0.82. The potassium/phosphorus ratio accounted for 67% of the variance in immobility. These high correlations were interpreted in terms of acid-base changes associated with testing.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of chronic forced swimming and exposure to alarm substance: physiological and behavioral consequences

Rats tested for 7 consecutive days in the forced swim test in fresh water were more immobile than those tested in soiled water on all days. Animals in both water conditions increased their immobility times slightly over days, but animals tested in soiled water, which presumably contained an alarm substance, never attained the immobility times of those tested in fresh water. When animals were switched between fresh and soiled water, they behaved exactly like animals in the water condition to which they were switched. Prior inescapable forced swimming in either water condition affected subsequent escape in a Morris water maze, but more so for animals tested only in fresh water. A second study corroborated the escape results. Serum corticosterone and relative adrenal weights were increased as a result of forced swimming but escape performance differences could not be attributed to differences in the stress-provoking consequences of the two water conditions.