The acoustic startle reflex as a tool for assessment of odor environment effects on affective states in laboratory mice.

Apart from self and conspecific odors, odors from other species also influence the affective states in laboratory mice (Mus musculus musculus) in their home cages and during experimental procedures, possibly inducing confusion and inconsistency in experimental data. Thus, it is important to detect the types of animal odors associated with housing, husbandry, and laboratory practice that can arouse different types of affective changes in mice. Here, we aimed to test the effectiveness of the acoustic startle reflex (ASR) in detecting changes in the affective states of laboratory mice due to animal-derived-odor as it has a non-zero baseline, and can be enhanced or attenuated by positive or negative affective shifts, respectively. We used ASR to examine the affective changes in mice that were induced by bedding odors and an alarm pheromone. The odor of bedding obtained from the mice' home cages significantly attenuated the ASR, suggesting positive affective shifts in the test mice, whereas that from bedding obtained from rat cages significantly enhanced the ASR, suggesting negative affective shifts. No significant changes in ASR were observed in mice presented with the odor of bedding obtained from cages of unfamiliar conspecifics. In contrast, there was significant ASR enhancement in mice exposed to volatile components of alarm pheromones trapped in water, suggesting negative affective shifts. Thus, our findings show that ASR may be a valuable tool in assessing the effects of odors on the affective states in laboratory mice.

Dietary ratio of protein to carbohydrate induces plastic responses in the gastrointestinal tract of mice.

Some vertebrates change the size of their digestive system in response to quantity and fibre content of ingested food, but the effects of dietary nutrients on gut structure remain poorly understood. Here we investigate how the protein to carbohydrate ratio of diets affects the mass of the gastrointestinal tract in mice. We fed 6-week-old male mice one of five isocaloric diets differing only in protein to carbohydrate ratio (the "no-choice" treatments), while a further four treatment groups received nutritionally complementary food pairings from which they could self-select a diet (the "choice" treatments). After 32 days, we measured the resulting dry mass of stomachs, intestines, caeca and colons. In the no-choice treatments, the stomachs were heavier in the mice fed diets containing more protein and less carbohydrate, indicating that larger stomachs may be needed for efficient digestion of the protein-rich food. In contrast, intestines, caeca and colons were heavier when diets contained more carbohydrates and less protein. This response may function to increase the digestive rate of carbohydrates when the dietary content of this macronutrient increases, but it may also indicate a compensatory response to increase amino acid uptake from a protein-deficient food. Mice in the choice treatments self-selected a diet with a protein to carbohydrate ratio of 0.46, and had gut dimensions similar to the expectation derived from no-choice treatments for this diet composition. Our results provide an example of plasticity in the differential allocation of resources to organ function, which is triggered by variation in resource quality.

Sugar and fat conditioned flavor preferences in C57BL/6J and 129 mice: oral and postoral interactions.

C57BL/6J (B6) mice consume more sugar and fat solutions than do 129 mice in 24-h preference tests. Previous studies have attributed this observation to strain differences in taste responsiveness to these nutrients. We tested the hypothesis that differences in postingestive responsiveness contribute to the strain differences. In experiment 1, B6 and 129 mice were trained to associate consumption of a flavored solution (CS+) with intragastric (IG) infusions of 16% sucrose and a different flavored solution (CS-) with IG water infusions (22 h/day). They were then retrained with new flavors paired with IG infusions of 5.6% soybean oil and water. Although both strains developed preferences for the nutrient-paired CS+ solutions, the B6 mice displayed significantly stronger preferences. The B6 mice consumed more CS+ during training, which may have contributed to their enhanced preference. In a second experiment, training intakes were equated by giving B6 and 129 mice "isosweet" CS solutions prepared with different amounts of sucrose and saccharin. The B6 and 129 mice consumed more of the sugar- or fat-paired CS+ than the water-paired CS- during training. The two strains also displayed equally strong preferences for the CS+ over CS- in choice tests, indicating that they had similar postingestive responsiveness to the sucrose and soybean oil. We propose that B6 mice consume more sugar and fat than 129 mice because their stronger orosensory response stimulates greater intake, which leads to greater stimulation of postingestive nutrient detectors and further enhancement of consumption.

Inbred mouse strain differences in the establishment of long-term fear memory.

Studies describing variations in fear-related memory in inbred mouse strains typically focus upon 24 h retention. As a consequence, little is known about strain differences in the establishment of longer lasting memories of aversive events. In the present study, male mice from the strains A/Ibg, AKR/J, BALB/cByJ, CBA/J, C3H/HeIbg, C57BL/6J, DBA/2J, LP/J, SJL/J and 129/SvevTac were tested 24 h, 14, or 60 days after contextual and auditory-cued fear conditioning. Consistent with previous data, 24 h after conditioning these strains exhibited substantial variation in levels of memory for the context and the auditory cue as measured by freezing scores. Sixty days after training, most strains exhibited some forgetting of the context and auditory cue, and again there was significant strain variation. Strain rankings at 60-day retention were similar to that at 24 h with a significant genetic correlation between freezing values for the two time periods. Fourteen days following training, nearly all strains exhibited generalized freezing, a behavioral phenotype originally observed in C57BL/6 but not DBA/2 mice. These data confirm that cognitive differences exist between several popular inbred mouse strains during 24 h contextual fear recall. In addition, they extend these differences into retention time frames longer than those typically used and reveal several unique learning profiles of mouse strains that may be useful in furthering our understanding of how memories are formed. Emotionally arousing situations are often recalled a great deal of time after an event. Therefore, a more complete picture of the biochemical and genetic underpinnings of learning and memory will benefit from studies using time points that assess time points beyond 24 h retention. The utility of the 14-day hyper responsiveness phenotype as a potential model for fear-related psychopathology is also discussed.

The strain-specific involvement of nucleus accumbens in latent inhibition might depend on differences in processing configural- and cue-based information between C57BL/6 and DBA mice.

Latent inhibition (LI) consists of decreased associative strength between an elemental stimulus (CS: tone) paired with an unconditioned stimulus (US: footshock) following non-reinforced pre-exposure to the tone. In view of the differences shown by C57BL/6 (C57) and DBA/2 (DBA) mice in processing elemental vs. configural stimuli, the present experiments were designed (1) to assess whether these differences were likely to interfere with the capability of each strain to show LI, and (2) to verify the extent to which lesions of the nucleus accumbens, which have been reported to enhance attention towards contextual stimuli under certain conditions, might interfere with the development of LI. C57 and DBA mice with Nacc or sham lesions were given two periods (4 or 7 days) of pre-exposure to a CS (tone) then subjected to two CS-US pairings given on a single day. On the day after, freezing to the tone was examined in each group. Results show that, following the shorter period of pre-exposure, LI developed in sham-lesioned DBA but did not in sham-lesioned C57. Nacc lesions, however, were found (1) to block LI in DBA but (2) to promote LI in C57. After the longer period of pre-exposure LI was observed in both strain and lesion conditions. In general, these results confirm that strain differences in processing the tone as a single elemental cue (DBA) or, alternatively, as a part of a contextual configural stimulus (C57) can interfere with the development of LI. In addition, they indicate that Nacc lesions, that are susceptible to increase attention to the background, might modify the salience of the tone and produce opposite effect on LI according to the strain specialisation to show elemental or configural responding.

The effect of genotype on sensitivity to electroacupuncture analgesia.

Individual differences in sensitivity to pain and analgesia are well appreciated, and increasing evidence has pointed towards a role of inherited genetic factors in explaining some proportion of such variability. It has long been known by practitioners of acupuncture, an ancient modality of analgesia, that some patients are 'responders' and others 'non-responders.' The present research was aimed at defining the inherited genetic influence on acupuncture analgesia in the mouse, using 10 common inbred strains. Two pairs of metallic needles were inserted into acupoints ST 36 and SP 6, fixed in situ and then connected to the output channel of an electric pulse generator. Electroacupuncture (EA) parameters were set as constant current output (intensity: 1.0-1.5-2.0 mA, 10 min each; frequency: 2 or 100 Hz) with alteration of a positive and negative square wave, 0.3 ms in pulse width. Tail-flick latencies evoked by radiant heat were measured before, during and after EA stimulation. Narrow-sense heritability estimates of 2 and 100 Hz EA were 0.37 and 0.16, respectively. We found that the C57BL/10 strain was the most sensitive, and the SM strain was the least sensitive to both 2 and 100 Hz EA. However, the relative sensitivities of other strains to these two EA frequencies suggested some genetic dissociation between them as well. These results demonstrate a role of inherited genetic factors in EA sensitivity in the mouse, although the low-to-moderate heritability estimates suggest that environmental factors may be of greater importance in predicting who will benefit from this analgesic modality.

On the relationships of high-frequency hearing loss and cochlear pathology to the acoustic startle response (ASR) and prepulse inhibition of the ASR in the BXD recombinant inbred series.

The measurement of the acoustic startle response (ASR) and prepulse inhibition (PPI) of the ASR in many inbred strains of mice, including C57BL/6 and DBA/2, may be complicated by age-related high-frequency hearing loss (HFHL) and the associated cochlear pathology. Willott and Erway (1998) have recently reported on the age-related changes of the acoustic brain response in the BXD recombinant inbred (RI) series. Based on these data, the RI series was divided into three groups: juvenile-, intermediate-, and adult-onset HFHL. Each of these groups was tested using paradigms which varied the frequency or intensity of the auditory startle and prepulse stimuli. The results obtained in adolescent mice (6-8 weeks) demonstrate that ASR performance is independent of HFHL; there was no group-dependent decline in the ASR amplitudes for high-frequency stimuli. The expected effect of HFHL on PPI is to increase the salience of the still-audible tones. In response to a white-noise prepulse stimulus, the PPI in the juvenile-onset group (which shows marked HFHL at 6 weeks) was similar to that in the adult-onset group. However, when the prepulse stimulus was a pure tone, the juvenile group showed a decrease in salience across all frequencies tested (5-20 kHz). The data point out the need for carefully constructing auditory tasks in the BXD RI series, to avoid the confounding effects of HFHL.

Inbred mouse strains differ in the regulation of startle and prepulse inhibition of the startle response.

The startle response and adaptability of the startle response (prepulse inhibition and habituation) have been observed in animals. The studies reported here screened 8 inbred mouse strains to determine whether genetic factors influence these behaviors. Strain differences were found in both the sensitivity to acoustic startle and the magnitude of both the auditory and tactile startle as well as the magnitude of prepulse inhibition (PPI) of both tactile and acoustic startle. Neither the 2 startle responses nor the 2 forms of PPI were significantly correlated with one another, suggesting that different genes regulate these 2 forms of startle and PPI. Acoustic-acoustic PPI was significantly correlated, however, with hippocampal auditory gating (TC ratio) suggesting an overlap in the genes that regulate these 2 forms of sensory gating.

Strain-dependent differences in vertebral bone mass, serum osteocalcin, and calcitonin in calcium-replete and -deficient mice.

The effects of dietary calcium intake on vertebral bone mass, composition, and turnover (calcium deposition and resorption) were determined in 10- and 14-week-old C57BL/6 (small) and SENCAR (large) mice. Total vertebral mass, percent ash, calcium, magnesium, and phosphorus were higher in SENCAR mice than in C57BL/6 mice at 10 weeks of age and after being fed 0.02% or 0.6% dietary calcium for 4 additional weeks. Relative calcium deposition was higher in C57BL/6 than in SENCAR mice, while relative calcium resorption was similar in both strains. The rate of resorption was higher in mice fed 0.02% dietary calcium than in those fed 0.6% dietary calcium. Thus, C57BL/6 mice gained vertebral calcium, while it remained unchanged or declined in SENCAR mice under conditions of both calcium depletion and calcium repletion. Serum osteocalcin (an index of bone formation) was higher in C57BL/6 mice than in SENCAR mice. Mathematically significant correlations between osteocalcin levels and vertebral calcium resorption and the net vertebral calcium loss were observed only in SENCAR mice. The serum calcitonin concentration was correlated with the amount of vertebral calcium resorbed in SENCAR mice, but not in C57BL/6 mice. Thus, vertebral resorption and formation are more tightly coupled in 10- to 14-week-old SENCAR mice than in C57BL/6 mice. In addition, remodeling appears to dominate vertebral calcium dynamics in SENCAR mice, while growth dominates in C57BL/6 mice during this period. Rodents have frequently been dismissed as potential models of bone aging based on the expectation that continued growth, rather than remodeling, dominates skeletal dynamics. These data clearly demonstrate that increases in body mass ("growth") are not invariably associated with continued vertebral growth. In this murine model, both heredity and dietary calcium intake modulate vertebral bone mass, turnover dynamics, and composition at sexual maturity. These differences in the development and regulation of vertebral bone mass in small C57BL/6 and large SENCAR mice suggest that animal, as well as clinical, models provide useful insights into the cellular and hormonal mechanisms of somatotype-dependent vertebral growth.

[Biological characteristics of 3 new substrains of laboratory mice used in evaluating the quality of pertussis vaccines]. / Biologicheskie kharakteristiki trekh novykh sublinii laboratornykh myshei, ispol'zuemykh pri otsenki kachestva kokliushnykh vaktsin.

NFR/NM, NFS/NM inbred mice and M : CFLP random bred mice have been shown to possess immunobiological properties making them suitable for the evaluation of the quality of pertussis vaccines and for their standardization. NFS/NM mice are highly sensitive to the histamine-sensitizing factor, while M : CFLP mice are sensitive to the lienotoxic factor of pertussis vaccines. All these substrains of mice have sufficient fertility for their breeding under the conditions of a commercial breeding establishment.

Dietary enrichment with the polyunsaturated fatty acid eicosapentaenoic acid prevents proteinuria and prolongs survival in NZB x NZW F1 mice.

Prostaglandins and related compounds are active mediators of inflammation, but data concerning their role in the pathogenesis of the glomerulonephritis of New Zealand Black x New Zealand White (NZB x NZW) F1 mice are conflicting. Dietary eicosapentaenoic acid (EPA, C20:5), a fatty acid analogue of arachidonic acid (C20:4), has been shown to impair platelet aggregation in humans, apparently through inhibition of the synthesis of prostaglandins and thromboxanes from arachidonic acid. We report here the effects of a diet high in EPA on the development of renal disease and survival in female NZB x NZW F1 mice. Animals from 4--5 wk of age were fed diets containing 25% lipid, supplied either as beef tallow or menhaden oil, with fatty acid analysis of less than 0.05 and 14.4% EPA, respectively. In the first experiment, by 13.5 mo of age, mice on the beef tallow diet had all (9/9) developed proteinuria and the majority (6/9) had died, with renal histologic examination revealing severe glomerulonephritis. In contrast, none of 10 menhaden oil-fed animals had developed proteinuria, and all were alive at this time (P less than 0.005 for both proteinuria and survival). In a second experiment using 50 mice in each dietary group, 56% of the beef tallow group vs. none of the menhaden oil group had developed proteinuria at 9 mo of age (P less than 0.005). Native DNA binding at 6 mo of age was 23.9 +/- 14.7 vs. 10.1 +/- 9.7% in the beef and menhaden oil groups, respectively (P less than 0.01). Weights were similar in all groups, and there was no evidence of essential fatty acid deficiency in any group. These results demonstrate that a diet high in EPA protects NZB x NZW F1 mice from the development of glomerulonephritis.

Hypothalamic self-stimulation and operant activity in the mottled mutant mouse.

Some behavioural effects of the mottled mutation were studied in the variegated heterozygote female. In mutants, compared to normals, operant activity was increased, whereas hypothalamic self-stimulation was always decreased. These results are discussed relative to the excepted central catecholaminergic disturbances resulting from the mutant gene.