Role of aversively motivated behavior in the olfactory bulbectomy syndrome.

The aim of the present studies was to determine the extent to which changes in defensive behaviors could account for some of the behavioral effects of bilateral olfactory bulbectomy (OBX) in rats. Four tests of aversively-motivated behavior were conducted in bulbectomized and sham-operated rats: activity in a dimly lit or brightly lit open field, passive avoidance, foot shock-induced freezing, and defensive withdrawal. OBX reduced the duration of immobility in the open field. Bulbectomized rats exhibited less freezing in response to foot shock than sham-operated rats. In the defensive-withdrawal test, bulbectomized rats made more transitions into and spent less time inside the covered enclosure than sham-operated rats. The experiments thus reveal two novel paradigms for assessing the behavioral effects of OBX. The results also suggest that deficits in aversively-motivated behavior, specifically defensive freezing, may comprehensively explain the putative "hyperactivity" and "passive-avoidance learning deficits" widely associated with the OBX behavioral syndrome.     

Olfactory bulbectomy induces rapid and stable changes in basal and stress-induced locomotor activity,heart rate and body temperature responses in the home cage

Background: Olfactory bulbectomy (OBX) in rats causes several behavioral and neurochemical changes. However, the extent and onset of physiological and behavioral changes induced after bulbectomy have been little examined. Methods: Male Sprague–Dawley rats received telemetric implants. Before and immediately after OBX surgery, basal and stress-induced heart rate, body temperature, and locomotor activity were measured in the home cage in sham (n=9) and OBX animals (n=11). Stress was induced using novel cage stress or witness stress. Results: Bulbectomized animals differed physiologically and behaviorally from shams. Nocturnally, OBX animals were significantly more active compared with shams, had a higher core body temperature and displayed a decreased heart rate variability. During the light period, OBX animals had a significantly lower basal heart rate and a reduced heart rate variability. These effects became apparent 2–3 days after OBX surgery, and were stable over time. After witness stress, OBX animals showed smaller autonomic (body temperature and heart rate) responses compared with shams, but showed no difference in locomotor responses. In contrast, novel cage stress led to increased locomotor responses in OBX rats compared with sham rats, while no differences were found in autonomic responses. Conclusion: Removal of the olfactory bulbs results in rapid, stable and persistent changes in basal locomotor activity, body temperature, heart rate and heart rate variability. Although the sleep–wake cycle of these parameters is not altered, increases in circadian amplitude are apparent within 3 days after surgery. This indicates that physiological changes in the OBX rat are the immediate result of olfactory bulb removal. Further, stress responsivity in OBX rats depends on stressor intensity. Bulbectomized rats display smaller temperature and heart rate responses to less intense witness stress compared with sham rats. Increased locomotor responses to more intense novel cage stress are present in the home cage as well as the open field. The present study shows that olfactory bulbectomy has rapid and persistent influence on basal and stress-induced physiological parameters.     

Evaluation of exploration and risk assessment in pre-weaning mice using the novel cage test

Exploration and risk behaviour (risk assessment/risk taking) are critical to enable mice to cope with novel situations and gain control over their environment. Evaluation of those behaviours would therefore be a useful part of early phenotypic characterization of genetically modified mice, allowing early detection of behavioural phenotypes that require special attention and/or are of scientific interest. This study aimed to evaluate exploration and risk behaviour in pre-weaning mice using the novel cage test, which consists in exploration of a novel, clean, Makrolon type III cage. The results of this test were compared with those obtained in more complex and established tests to which the same mice were subjected as adolescents and young adults. Mice of two inbred strains (129S6/Bkl, n=10; C57BL/6Bkl, n=10) and one hybrid (B6CBAF1/Bkl, n=10) were used for validation of the test. The animals were tested in the novel cage (at weaning), the open field test (at 5 weeks), and from 9 weeks of age in three other tests: the elevated plus-maze, the concentric square field and the rat exposure test. The novel cage test effectively detected strain differences in pre-weaning mice as regards exploration and risk behaviour and the results were largely consistent with those obtained in the established tests later in life. In all tests 129S6 displayed a low locomotion and high risk assessment, while C57BL/6 and B6CBAF1 showed high locomotion and exploration. In addition high levels of risk taking were observed in C57BL/6. The novel cage test is rapid, requires no special equipment and is as discriminatory as more complex tests in detecting strain/genotype differences. This suggests that the novel cage test is a valuable tool for evaluation of exploration, risk assessment and risk taking in juvenile mice.     

Features of the Genetically Defined Anxiety in Mice

The behaviors of male mice of the C57BL/6J (C57), CBA/Lac (CBA) and BALB/c (BALB) strains have been studied in the plus-maze and open field tests for estimation of state anxiety in the stressful novel conditions, and in the cubic box test (exploration of novel cubic box) and the partition test (behavioral reactivity to the unfamiliar partner in the neighboring compartment) for estimation of trait anxiety in the unstressful familiar conditions of the home cage. Plus-maze data suggest that C57 mice are the more anxious than CBA and BALB ones. However, it was revealed the opposite rank order in the open field. The study on the effect of pre-testing in the one of test on the behavior in the other test revealed active behavioral strategy in C57 mice in any situations. The plus-maze behavior of CBA mice was affected to a much lesser extent than in C57 ones after pre-testing in the open field, but expressed changes were observed in open field behavior of CBA mice after pre-testing in the plus-maze. BALB mice displayed low-reactive behavior after any pre-testing exposure under the state anxiety-provoking conditions. Familiar environment revealed a higher level of trait anxiety in C57 than males of other two strains: CBA and BALB mice willingly explore unfamiliar partner and cubic box while C57 mice avoid its. Mainly genetically inherent state anxiety in CBA mice and trait anxiety in C57 mice has been suggested. Lowest state and trait indices of anxiety were revealed in BALB mice in these conditions.     

Evidence that electrolytic median raphe lesions increase locomotion but not exploration

Electrolytic lesions of the median raphe nucleus were found to increase locomotion but decrease rearing in the open field. Additionally, these lesions reduced the amount of time that rats spent sniffing at a novel object placed in the open field on their first encounter with it. In a test of exploratory behavior in a T-maze, median raphe lesions eliminated the preference for entering a novel arm displayed by sham operated animals. These results suggest that, although median raphe lesions increase locomotion, they may actually decrease exploration.     

Differences in Measures of Exploration and Fear in MHC-Congenic C57BL/6J and B6-H-2K Mice

MHC-congenic mice prefer to mate with mice of different MHC types and are able to discriminate between MHC-congenic mice by their urine odors, but nothing is known about behavioral differences among MHC-congenic mice. The present experiments examine the strain and sex differences in MHC-congenic C57BL/6J and B6-H-2K mice with respect to exploration and fear motivated behaviors in the elevated plus maze, the elevated zero maze, and the open field. In the elevated plus maze and elevated zero maze, C57BL/6J mice spent more time in the open areas than B6-H-2K mice, suggesting that they were less fearful and more exploratory. No sex differences for exploration were found but male mice defecated more than females in the elevated plus maze. In the open field there were no significant strain or sex differences in measures of exploration or fear. There were no strain differences in the investigation of a novel object placed into the open field, but males investigated the novel object more than females. These results indicate that there are differences in exploratory and fear behavior in MHC-congenic mice that may contribute to mate preferences and that behavioral differences in these mice might be further examined advantageously.     

Home cage activity and activity-based measures of anxiety in 129P3/J, 129X1/SvJ and C57BL/6J mice

We investigated the home cage activity and emotional behavior in mouse strains used as background for many studies of altered genes [C57BL/6J (B6, n=20), 129X1/SvJ (X1, n=20) and 129P3/J (P3, n=19)]. In their home cages, X1 and P3 mice exhibited less locomotion than did B6 mice, and the X1 mice showed significantly greater rearing than B6 and P3 mice did. A battery of three tests conducted in an open field (open field, emergence and novel object) revealed strain rankings of B6>X1>P3 or B6>X1=P3 in most activity variables. Significant correlations were found between home cage activity and activity in each of three tests, but not in all observation periods. Strain rankings on the elevated zero maze test were B6=X1>P3 in the number of stretched-attend body postures (SAPS) during the initial 6-min exposure for naive mice. Naive and nonnaive mice showed significantly different behaviors on the elevated zero maze. The results suggest that rankings on anxiety are P3>X1>B6 and that B6 mice have greater exploration in a novel environment compared with X1 and P3 mice. However, anxiety-like behaviors differed among strains in open-field-based tests and in the zero maze, and testing experience impacted performance on the zero maze. The findings illustrate that test variations and experience can influence performance and suggest the need for the consideration of how these factors interact with background strains in assessing gene-altered mice.     

Spontaneous Stereotypy in an Animal Model of Down Syndrome: Ts65Dn Mice

Stereotyped behaviors (e.g., body rocking) occur at high rates in individuals with mental retardation (e.g., Down syndrome). To determine if spontaneous stereotypy occurs in a murine model of Down syndrome, the home cage behavior of Ts65Dn and control mice was monitored during the dark cycle. Motor activity was further assessed in novel automated test chambers, with acoustic startle and rotor rod paradigms providing additional environmental challenges. Spontaneous stereotypy (repetitive jumping and cage top twirling) was observed in the home cage in approximately half of the Ts65Dn mice, compared with approximately 10% of diploid controls. Repetitive jumping was observed exclusively in the Ts65Dn mice. In the open field, although no differences were found between Ts65Dn and control mice, stereotypic Ts65Dn mice exhibited significantly less locomotor activity and rearing relative to control and nonstereotypic Ts65Dn mice. Ts65Dn mice attained significantly lower rotor rod speeds but did not differ from controls in the amplitude of the acoustic startle response. These environmental challenges did not increase stereotypy over home cage rates but induced stereotypy in two additional animals. The Ts65Dn model may aid in identifying genes associated with the development and expression of stereotypy.     

Object recognition memory is conserved in Ts1Cje,a mouse model of Down syndrome

Ts1Cje and Ts65Dn are genetic mouse models of Down syndrome (DS). Like individuals with DS, these mice exhibit various hallmarks of hippocampal pathology, and deficits in hippocampal-based, declarative learning and memory tasks. Both spatial navigation and novel object recognition, two prototypical domains of declarative memory function, have been strongly characterized in the Ts65Dn DS model. Indeed, Ts65Dn mice show navigation problems in the Morris water maze, impaired alternation in a T-maze, and deficient working and reference memory in the radial arm maze task. They, likewise, show an inability to detect object novelty over time. In contrast to the Ts65Dn model, hippocampal-dependent cognition has been less well characterized in Ts1Cje. Although Ts1Cje mice have been found to exhibit spatial difficulties in the Morris water maze and reduced spontaneous alternation, their ability to process object-based information has never been examined. Here, we report that Ts1Cje mice perform normally in short-term and long-term novel object recognition tasks. The ability of Ts1Cje mice to detect object novelty, unlike Ts65Dn, may point to differences in the extent of hippocampal pathology in the two DS mouse models.     

Absence of SHATI/Nat8l reduces social interaction in mice

We previously identified a novel molecule “Shati/Nat8l” from the nucleus accumbens of mice. However, the physiological roles of the SHATI protein are not clear. To investigate the effect of SHATI on the central nervous system and behavior, we studied knockout mice of this protein. We carried out various behavior tests using Shati-knockout mice. Shati-knockout mice did not differ from wild type mice in learning and memory. In the open field test, Shati-knockout mice did not differ from wild-type mice in time of stay in the outer, middle and center areas. On the other hand, Shati-knockout mice showed increases in rearing and grooming time in the open field test, and exploration time of novel objects. These results suggested that knockout of the Shati gene may increase exploration in specific circumstances. Interestingly, the Shati-knockout mice avoided social interaction with unfamiliar mice out of their home cage, although there was no difference in social interaction in their home cage compared with wild type mice. Lack of the Shati gene increased brain-derived neurotrophic factor (BDNF) mRNA in the prefrontal cortex and hippocampus, and decreased glial cell line-derived neurotrophic factor (GDNF) mRNA in the striatum and hippocampus, and lipopolysaccharides-induced TNF-α factor (LITAF) mRNA in the striatum. Since these factors play important roles in behavior, alteration of expression of these factors may be related to the induction of exploration and reduction of social interaction in Shati-knockout mice.     

Social stress in mice: gender differences and effects of estrous cycle and social dominance.

A large discrepancy in the possibility of inducing social stress in the two genders exists. Since generalizations of findings from one sex to the other appear not to be valid, reliable models of social stress in females are needed. We examined the effects of social context in the housing environment, as a possible source of stress, on exploration and anxiety in male and female mice, taking into account the estrous phase for females and the social status for males as additional variables. Mice housed individually or with siblings were tested in a free-exploratory paradigm of anxiety (where test animals have a choice to stay in their home cage or to explore an open field, OF). Individually housed females did not leave their home cage for long periods, explored less the unfamiliar area and displayed higher risk assessment, a behavioral profile suggestive of lower propensity for exploration and higher level of anxiety compared with group-housed females. Individually housed males tended to show an opposite profile. Proestrus mice were less sensitive to the decrease of exploratory propensity induced by individually housing compared to estrus and diestrus mice. Social dominants and social subordinates in sibling groups did not differ in their exploratory responses to the OF. Different housing procedures, as means to provide different social environment, may differentially induce mild social stress in male and female mice.     

"Isolation stress" revisited: isolation-rearing effects depend on animal care methods

Early reports of enhanced behavioral reactivity in isolation-reared rats attributed this syndrome to "isolation stress." In the studies reported here, this "isolation stress syndrome" was reliably obtained in adult rats reared from weaning in individual hanging metal cages. Such isolates showed behavioral and adrenocortical symptoms of profound fear during open-field testing, unlike group-housed controls or littermate isolates reared singly in plastic cages. Animals in hanging metal cages are never touched by human caretakers, whereas rats reared in plastic cages are picked up and put in clean cages twice weekly. Handling hanging-cage isolates twice weekly to model the handling associated with cage changes completely protected against this syndrome. Further, there was no hormonal, neurochemical or anatomical evidence of chronic stress even in hanging-cage isolates. Littermates housed in social groupings (three rats per plastic cage) also froze and defecated in the open field at rates comparable to hanging-cage isolates if they were the first animals to be tested from their social group cage. It is probable that odor cues from familiar cagemates in the open field protected socially reared animals tested subsequently from the same cage from this syndrome. It is concluded that isolates are not chronically stressed, and that rearing effects are the result of a complex interaction between prior handling, social experience and test conditions.     

Behavioral consequences of minimal traumatic brain injury in mice

Victims of minor traumatic brain injury (mTBI), who show no clear morphological brain defects, frequently manifest cognitive, behavioral and emotional difficulties that can be long-lasting. In this paper we present a modified weight drop model used to deliver a closed head minimal traumatic brain injury to mice, which closely mimics real-life injuries and the symptoms observed in mTBI patients. Our choice of impact force does not produce structural damage to the brain and its surrounding tissue (as examined by MRI), any skull fracture, no edema and no evident damage to the blood-brain barrier (BBB). Moreover, our mTBI mice show no abnormal behavior on recovering from the weight drop, or any change in other brain functions such as reflexes, balance, exploration, strength, locomotor activity and swim speed. Since our mTBI model does not produce neurological, motor or sensory damage to the mice, it allows the direct evaluation of mTBI sequelae on the mice behavior and cognitive abilities. Using a variety of cognitive and behavioral tests (Morris water maze, staircase test, passive avoidance test, water T-maze, hot palate, elevated plus maze and forced swimming test) we assessed the short- and long-term sequelae induced by our model. Our results indicate that our closed head mTBI cause profound and long-lasting, irreversible learning and memory impairments, accompanied by a depressive-like behavior in mice that are evident even 90 days post injury. Our results indicate that the closed head mTBI model presented here may be useful in the development of novel therapeutic approaches, such as neuroprotective agents, for mTBI.     

Selective Breeding for Increased Home Cage Physical Activity in Collaborative Cross and Hsd:ICR Mice

Selective breeding experiments for increased wheel running and open field behavior have identified genetic and neurobiological factors associated with increased voluntary physical activity in mice, but no previous study has directly selected for increased distance traveled in the home cage. Therefore, within-family selection was applied to increase home cage activity as measured by continuous video tracking using two different starting populations, G2:F1 Collaborative Cross (CC) and Hsd:ICR mice. Genetic correlations with distance traveled on running wheels and in the open field were evaluated by mid-parent offspring regression. A significant response to selection was observed in CC but not Hsd:ICR. Wheel running was heritable in both populations but not significantly genetically correlated with home cage activity. Open field was not heritable in either population. We conclude that different genes and neural circuits influence physical activity in the home cage as compared to wheel running or open field. Selective breeding for home cage activity in CC mice warrants further exploration.     

Low amplitude entrainment of mice and the impact of circadian phase on behavior tests

A tremendous increase in the use of genetically engineered mice as experimental animals has led to increased scrutiny of mouse models generally and mouse behavioral paradigms specifically. Although mice are nocturnal, for practical reasons, most experimental procedures, including behavioral studies, are conducted during their inactive, sleep phase. Accumulating evidence indicates that myriad behavioral, cellular and biochemical processes fluctuate with circadian rhythmicity; however, time of day at which experiments are conducted is rarely controlled. The impact of circadian phase on the reliability of experimental results has received little attention and the present data are conflicting. This study addressed two questions. First, will laboratory mice in a typical animal care facility entrain to a low amplitude light cycle using bright/dim rather than light/dark cycles? A positive answer will make reversing photocycle easy to implement in any facility as dim light suitable for animal husbandry and behavioral testing can substitute for darkness during work hours. By monitoring home cage wheel running, we examined the effectiveness of a dim/bright photocycle as a zeitgeiber. We found that mice subjected to dim/bright photocycles effectively entrained such that their subjective night and activity onset coincided with the beginning of the dim light period, suggesting a potential strategy for standardization and management of circadian phase in nocturnal animals. In a second experiment, we asked what effect circadian phase has on behavioral performance in commonly used mouse behavioral tests. We found no main effect of circadian phase on outcome in open field activity, elevated plus maze emotionality, water maze spatial memory, novel object exploration and hyperactivity in response to amphetamine; however, we observed occasional interactions between circadian phase and both strain and sex that were neither consistent nor systematic. These data suggest that the tests examined here are relatively impervious to circadian phase. In general, testing mice during their active phase is more suitable for behavioral studies; a reversed dim/bright photocycle potentially offers one practical strategy for managing rodents' circadian cycles.     

Separating the effects of shelter from additional cage enhancements for group-housed BALB/cJ mice

Enrichment studies with rodents have demonstrated that cage enhancements can improve animal welfare and performance on common behavioral measures, but few studies have compared more than one type of enrichment or controlled for confounds, and some have revealed undesirable effects including increased aggression. We compared effects on male (n=51) and female (n=52) BALB/cJ mice of three common additions to a standard home cage: shelter, shelter+running wheel, and shelter+novel objects. Mice in all conditions lived in standard sized cages with 3-4 mice per cage. Males evidenced significant condition effects. Shelter increased longevity and maintained low levels of aggression. Adding a running wheel increased aggression over shelter alone, changed behavior in the elevated plus (EP) and open field (OF), and maintained the improved longevity seen in all shelter conditions. Novel objects impacted behavioral measures compared to the standard condition. An Igloo shelter without running wheel creates a very different home cage environment than the same shelter with the running wheel attached. Shelter, with positive impact on animal welfare, minimal effects on some common behavioral measures, and some positive effects on test variance, warrants consideration for routine inclusion with group-housed BALB/cJ males.     

Differential genetic regulation of motor activity and anxiety-related behaviors in mice using an automated home cage task

Traditional behavioral tests, such as the open field test, measure an animal's responsiveness to a novel environment. However, it is generally difficult to assess whether the behavioral response obtained from these tests relates to the expression level of motor activity and/or to avoidance of anxiogenic areas. Here, an automated home cage environment for mice was designed to obtain independent measures of motor activity levels and of sheltered feeding preference during three consecutive days. Chronic treatment with the anxiolytic drug chlordiazepoxide (5 and 10 mg/kg/day) in C57BL/6J mice reduced sheltered feeding preference without altering motor activity levels. Furthermore, two distinct chromosome substitution strains, derived from C57BL/6J (host strain) and A/J (donor strain) inbred strains, expressed either increased sheltering preference in females (chromosome 15) or reduced motor activity levels in females and males (chromosome 1) when compared to C57BL/6J. Longitudinal behavioral monitoring revealed that these phenotypic differences maintained after adaptation to the home cage. Thus, by using new automated behavioral phenotyping approaches, behavior can be dissociated into distinct behavioral domains (e.g., anxiety-related and motor activity domains) with different underlying genetic origin and pharmacological responsiveness.     

Housing influences exploration and social interaction of control and DSP-4-treated rats.

Exploratory behavior and social interaction were investigated in rats that were reared in different social environments following neonatal injection with either water vehicle or the norepinephrine neurotoxin, DSP-4. At weaning, they were placed in a familiar or novel bedding type and were housed in either vehicle control-only, DSP-4-only, or mixed vehicle control and DSP-4 groups for 10 days. They were then observed in three different situations: the home cage, the cage of an unfamiliar rat, and an open field. Compared to rats housed in vehicle control-only or DSP-4-only groups, rats housed in mixed DSP-4 and vehicle control groups showed elevated exploration behavior in the home cage. Also, rats housed in mixed groups in the familiar bedding, but not the novel one, showed abnormally low levels of rearing in an open field test and reduced social interaction with unfamiliar rats. The implications of these results for a new animal model of anxiety are discussed.     

Behavioral phenotyping of mice in pharmacological and toxicological research

The evaluation of behavioral effects is an important component for the in vivo screening of drugs or potentially toxic compounds in mice. Ideally, such screening should be composed of monitoring general health, sensory functions, and motor abilities, right before specific behavioral domains are tested. A rational strategy in the design and procedure of testing as well as an effective composition of different well-established and reproducible behavioral tests can minimize the risk of false positive and false negative results in drug screening. In the present review we describe such basic considerations in planning experiments, selecting strains of mice, and propose groups of behavioral tasks suitable for a reliable detection of differences in specific behavioral domains in mice. Screening of general health and neurophysiologic functions (reflexes, sensory abilities) and motor function (pole test, wire hang test, beam walking, rotarod, accelerod, and footprint) as well as specific hypothesis-guided testing in the behavioral domains of learning and memory (water maze, radial maze, conditioned fear, and avoidance tasks), emotionality (open field, hole board, elevated plus maze, and object exploration), nociception (tail flick, hot plate), psychiatric-like conditions (porsolt swim test, acoustic startle response, and prepulse inhibition), and aggression (isolation-induced aggression, spontaneous aggression, and territorial aggression) are described in further detail. This review is designed to describe a general approach, which increases reliability of behavioral screening. Furthermore, it provides an overview on a selection of specific procedures suitable for but not limited to behavioral screening in pharmacology and toxicology.     

Dopamine overflow is increased in olfactory bulbectomized rats: an in vivo microdialysis study

Olfactory bulbectomy (OBX) in rats produces behavioral, physiological, and neurochemical changes that resemble symptoms of depression in humans. The procedure thus serves as a rodent model of affective disorder. Many of the behavioral effects of OBX resemble psychomotor agitation. The possible role of dysregulation of ventral striatal dopamine (DA) systems in this phenomenon was investigated. Basal levels of DA, norepinephrine (NE), homovanillic acid, dihydroxyphenylacetic acid, and 5-hydroxyindoleacetic acid were examined in the striatum of OBX and sham-operated controls using in vivo microdialysis. OBX rats exhibited significantly higher basal DA levels (192%) and lower NE levels (12%) than sham-operated controls. Locomotor activity in response to novelty and footshock stress was elevated in OBX rats. The finding of higher DA levels in striatum may explain this "agitation-like" behavior, a commonly observed phenomenon in the OBX model.