The role of neuromediators and proteins in genetic and functional organization of animal brain

It was shown that animals that differ in behavioral characteristics (August and Wistar rats) also differ in neurotransmitter and protein metabolism, which can be considered as tests that adequately reflect the functional condition of the central nervous system. These differences are expressed at the level of both subcortical structures (hippocampus and caudate nucleus) and various morphofunctional types of the sensorimotor cortex neurons (layers III and V). Studies on genetically different animals strains have revealed metabolic features that allow determination of individual behavioral features and estimation of individual brain structures in these processes.     

Behavioral and respiratory responses to stressors in multiple populations of three-spined sticklebacks that differ in predation pressure

Individual animals of the same species inhabiting environments which differ in the frequency and magnitude of stressors often exhibit different physiological and behavioral responses to stressors. Here, we compare the respiratory response to confinement stress, and behavioral responses to ecologically relevant challenges among sticklebacks from 11 different populations varying in predation pressure. We found that sticklebacks from high predation populations breathed faster in response to confinement stress and were, on an average, more behaviorally responsive to a pike behind glass compared with sticklebacks from low predation populations. These patterns differ from the results of studies on other species, highlighting the need for a conceptual framework to understand the proximate and ultimate factors shaping variable responses to stressors over developmental and evolutionary time. Moreover, physiological and behavioral responses were integrated with each other, both at the individual and population levels. In general, fish that were more aggressive and bold in the presence of a predator breathed faster, independent of body size. These results are consistent with the growing body of evidence that individuals differ in a suite of physiological and behavioral mechanisms for coping with challenges in the environment.     

Immune links in the system organization of behaviour

The work is devoted to the research of immune mechanisms in self-control of various functional systems of homeostatic and behavioral levels. Distinction of immune mechanisms in rats with different prognostic stress-resistance is established. Immunization of rats by conjugates of various neuromediators with bovine serum albumin selectively changes the animals stress-resistance. Participation cytokines in reactions of a brain's separate neurons and their interaction with a leading neuromediator - norepinephrine is established. Individual changes of pro- and anti-inflammatory cytokines in blood serum are shown in rats with different stress-resistance. There are revealed features of morphological distinctions of immunogenic structures small intestine fabrics in animals with various behavioral activity in the "Open field" test.     

Evaluating cognition and thermal physiology as components of the pace-of-life syndrome

The pace-of-life syndrome (POLS) suggests that behavioral traits are correlated and integrate within a fast–slow physiological continuum. At the fast extreme, individuals having higher metabolic rates are more active, exploratory, and bold with the opposite suite of traits characterizing those at the slow physiological extreme. A recent framework suggests that behavioral types may also differ consistently in their cognitive style. Accordingly, we propose that cognition could be further incorporated into the POLS framework comprised of behavioral and thermal physiological traits. Under this premise, fast behavioral types having high thermal traits are predicted to acquire a novel task faster but at the cost of accuracy while slow behavioral types with low thermal traits would be more attentive, responding to cues at a slower rate leading to higher accuracy and flexibility. This was tested by measuring physiological and behavioral traits in delicate skinks (Lampropholis delicata) and testing their learning ability. Correlations were detected between cognition and behavior but not thermal physiology. Contrary to our predictions, individual positioning along these axes opposed our predicted directions along the fast–slow continuum. Fast lizards preferring lower body temperatures expressed higher activity, exploration, sociality, and boldness levels, and learned the discrimination learning task at a slower rate but made the most errors. Additionally, modelling results indicated that neither thermal physiology, behavior, or their interaction influenced cognitive performance. Although the small number of animals completing the final stages of the learning assays limits the strength of these findings. Thus, we propose that future research involving a greater sample size and number of trials be conducted so as to enhance our understanding into how the integration of cognitive style, behavior, and physiology may influence individual fitness within natural populations.     

The individuality of mice

Mutant mice simulating human CNS disorders are used as models for therapeutic drug development. Drug evaluation requires a coherent correlation between behavioral phenotype and drug status. Variations in behavioral responses could mask such correlations, a problem highlighted by the three-site studies of Crabbe et al. (1999) and Wahlsten et al. (2003a). Factors contributing to variation are considered, focusing on differences between individual animals. Genetic differences due to minisatellite variation suggest that each mouse is genetically distinct. Effects during gestation, including maternal stress, influence later life behavior; while endocrine exchanges between fetus and parent, and between male and female fetuses dependent on intrauterine position, also contribute. Pre and perinatal nutrition and maternal attention also play a role. In adults, endocrine cyclicity in females is a recognized source of behavioral diversity. Notably, there is increasing recognition that groups of wild and laboratory mice have complex social structures, illustrated through consideration of Crowcroft (1966). Dominance status can markedly modify behavior in test paradigms addressing anxiety, locomotion and aggressiveness, to an extent comparable to mutation or drug status. Understanding how such effects amplify the behavioral spectrum displayed by otherwise identical animals will improve testing.     

Improving the precision and accuracy for estimating energy expenditure using the heart rate method

The "heart rate technique" is commonly used to estimate the rate of oxygen consumption (a proxy for energy expenditure) of free-ranging animals. However, a major limitation of this technique is that interindividual variability in the relationship between heart rate (f(H)) and rate of oxygen consumption (Vo2) generates large errors of estimation when the technique is applied to individual free-ranging animals. In this study, we present a new analysis technique that takes advantage of the observation that the f(H) or Vo2 relationships between individuals are frequently parallel and differ only in elevation. This technique offers superior accuracy and precision of Vo2 estimates, reducing the coefficient of variability from 18% to 9% for individual animals in an example application in macaroni penguins. This approach enables application of the heart rate technique to deduce the energetic strategies of individual animals.     

Lactation does not alter the long-term stability of individual differences in behavior of laboratory mice on the elevated plus maze

Individual consistency over time in behavioral responses to challenging situations is usually regarded as an indication of the existence of animal personality types. Although such consistency has been found in a variety of species, information about long-term stability is scanty, in particular across different life history stages, for example reproductive and non-reproductive periods, which have the potential to affect substantially the behavioral responses of animals. In our study of adult female laboratory mice, we explored the stability of behavioral responses across a 43-day period by successively testing the animals on an elevated plus maze. We tested two groups, one group that had offspring during the first two tests but not during the last test, and another group that only had offspring during the last test. We found clear evidence of individual consistency over time by means of positive significant correlations across the different tests: animals that spent more time in the closed arms and those that entered the open arms more often during the first test also tended to do so during the second test—when still in the same reproductive state, and also during the third test—when in a different reproductive state. In addition, females of the two groups did not differ overall in their responses, although we found a significant increase in the frequency and duration of presumed anxiety-related behavior during the course of the experiment, contradicting the notion that habituation effects should attenuate the challenge of the test situation. In conclusion, our study strongly suggests the existence of stable personality types in female laboratory mice, even across different reproductive stages.     

Involvement of serotoninergic brain structures in the mechanisms of neurotensin effect on passive avoidance in rats

The purpose of the research was to reveal the features of neurotensin (administered in substantia nigra or dorsal raphe nucleus) effect on recall of passive avoidance reactions in rats. It was shown that the effect of neurotensin injected into the substantia nigra was characterized by a sharp reduction of passive avoidance reactions. On the contrary, injection of the substance in the dorsal raphe nucleus led to an intensification of these reactions and delay of their extinction. The effects of microinjections of serotonin 1A receptor agonist, 8-hydroxy-dipropylaminotetralin (8-OH-DPAT), into the mentioned brain structures was similar to that of neurotensin. Changes in the content of serotonin and its metabolite 5- hydroxyindoleacetic acid (5-HIAA) in the caudate nucleus corresponded to various behavioral effects. The conclusion was made that neurotensin effect on the passive avoidance behavior is related to regulation of emotional state of animals mediated by its action on the function of the serotoninergic brain structures.     

Stress coping styles and singing behavior in the short-tailed singing mouse (Scotinomys teguina)

Stress coping styles have been characterized as a proactive/reactive dichotomy in laboratory and domesticated animals. In this study, we examined the prevalence of proactive/reactive stress coping styles in wild-caught short-tailed singing mice (Scotinomys teguina). We compared stress responses to spontaneous singing, a social and reproductive behavior that characterizes this species. To establish proactive/reactive profiles for singing mice, we measured exploratory and anxiety behavior using an open-field behavioral test. We examined correlations between open-field behaviors and fecal corticosterone (CORT) metabolites, baseline plasma CORT, and stress-induced CORT. Mice with proactive behavioral responses in the open-field had higher fecal CORT titers than reactive males, but did not differ in baseline or stress-induced plasma CORT. We suggest that individual differences in CORT metabolism may contribute to this surprising pattern. Males that sang in the open-field were behaviorally proactive and had lower stress-induced CORT, indicating a link between stress responses and singing in this species. Overall, the data demonstrate that singing mice offer an interesting model for exploring how stress reactivity can shape social behaviors.     

Transient changes in nucleus accumbens amino acid concentrations correlate with individual responsivity to the predator fox odor 2,5-dihydro-2,4,5-trimethylthiazoline

Predator odors elicit fear and defensive behavioral responses in rats, but a wide range of individual responsivity exists. The aim of this study was to examine whether individual differences in behavioral responsivity correlate with differences in amino acid neurotransmission to a predator fox odor, 2,5-dihydro-2,4,5-trimethylthiazoline (TMT). We investigated the time course of behaviorally evoked amino acid neurotransmitter changes in the nucleus accumbens using on-line microdialysis coupled to capillary electrophoresis with 14-s temporal resolution. One subset of animals (high responders) showed a large, biphasic increase in amino acids, such as glutamate and GABA, which lasted about 3 min. These neurochemical changes were highly correlated with increases in locomotion and burrowing, but lagged behind the behavioral changes by 2 min. A second subset of rats (low responders) showed neither behavioral activation nor changes in amino acid neurotransmission. As a positive control, rats were subjected to tail pinch, which evoked transient changes in amino acids in all animals. Cocaine (2 mg/kg, i.v.) increased locomotion but not amino acid levels. This work demonstrates that rapid and transient increases in amino acid neurotransmitters correlate with behavioral reactivity to salient stimuli.     

Individual behavioral characteristics and extent of stress-induced gastric ulceration in rats.

Individual rats differ amongst themselves with respect to both behavior and the extent of stress-induced gastric ulceration, even though they have been treated identically, are from the same stock, age, etc. The relationship between behavior and ulcer susceptibility is of interest in its own right, and is reminiscent of the extensive body of literature on personality characteristics and disease risk in humans. In the Sprague-Dawley rat, we have found that animals react differentially to the introduction of new stimuli in a previously learned Lashley-maze, and that the increase in latency is negatively related to attack frequency in a classic intruder test. Furthermore, we have found a negative correlation between attack latency in the intruder test and the amount of gastric ulceration induced by restraint-in-water stress. We have further found highly significant relationships between the responses of otherwise untreated animals to a simple startle test and the extent of gastric ulceration induced by restraint-in water stress. We believe that greater notice should be taken of the individual animal's behavioral profile for three reasons. First, prior behavioral screening may be a useful method for reducing error variance. Second, physiological and neuroendocrinological differences between high susceptible and low susceptible individuals are of interest in understanding the psychobiology of stress ulcerations both in animals and humans. Finally, an understanding of the etiology of these individual differences may cast light on links between behavior patterns and stress pathology.     

Displays of individually-typological features of animals and the person at a choice of strategy of goal-direction behavior

In work the hypothesis according to which different forms of goal-directed behavior develop depending on the basis of the undervaluation/supervaluation of reinforcement by brain abilities at the conditions of its achievement uncertainty. From these positions such opposite biological characteristics of the subject, as impulsiveness/self-control, care/propensity to risk on which basis there are individually typological features in behavior of the person and animals are considered. In the article, our experimental data on animals and the persons by behavioral techniques and results of last years on research of neural networks of animal cortical and subcortical brain structures depending on the strategy in choice behavior are also analyzed.     

Morpho-functional study of the brain of animals with different types of individual resistance to hypoxia

The experiments on white rats have shown that animals with distinct tolerance to hypoxia were characterized by individual metabolic changes in phylogenetically different brain structures. Adaptation to hypoxia in animals with high tolerance was associated with metabolic changes in the reticular formation and in animals with low tolerance with changes in the cerebral cortex. The experiments have shown that white rats with distinct individual tolerance to hypoxia are characterized by an inherent level of plastic metabolism in different brain structures. A correlation between brain tissue metabolism and individual tolerance of animals to hypoxia is suggested.     

The Adaptive Behavior of the White Whales <Emphasis Type="Italic">Delphinapterus leucas</Emphasis> (Pallas, 1776) in the Southern Herd of the White Sea under Conditions of the Local Habitat During the Breeding Season

Research on a southern herd of white (beluga) whales conducted during the summer seasons of 2003–2006 in the southeastern part of the Onega Bay revealed the specific behavioral features that allow white whales to sustain their habitation in the local hydrological conditions. It has been shown that once the white whales occur in some areas of habitation with complicated hydrological conditions, the animals develop an entire complex of behavioral adaptations that provide their comfort and their successful reproduction in the habitat.     

Behavioral plasticity mitigates the effect of warming on white‐tailed deer

Climate change is expected to create novel environments in which extant species cannot persist, therefore leading to the loss of them and their associated ecological functions within the ecosystem. However, animals may employ behavioral mechanisms in response to warming that could allow them to maintain their functional roles in an ecosystem despite changed temperatures. Specifically, animals may shift their activity in space or time to make use of thermal heterogeneity on the landscape. However, few studies consider the role of behavioral plasticity and spatial or temporal heterogeneity in mitigating the effects of climate change. We conducted experiments to evaluate the potential importance of behavior in mediating the net effects of warming on white‐tailed deer (Odocoileus virginianus). We used shade structures to manipulate the thermal environment around feeding stations to monitor deer feeding activity and measure total consumption. In individual experiments where deer only had access to unshaded feeders, deer fed less during the day but compensated by increasing feeding during times when temperature was lower. In group experiments where deer had access to both shaded and unshaded feeders, deer often fed during the day but disproportionally preferred the cooler, shaded feeders. Our results suggest that deer can capitalize on temporal and spatial heterogeneity in the thermal environment to meet nutritional and thermal requirements, demonstrating the importance of behavioral plasticity when predicting the net effects of climate change.     

Significance of individual resistance to hypoxia for the correction of the brain trauma sequelae

In rats, the individual sensitivity to hypoxia plays an prominent role for recovery of animals after mechanic brain injury. Enthomerzol (25 mg/kg intraperitoneally) for three days after brain injury decreased behavioral disorders in rats with different resistance to acute hypoxia, recovered structure of individual behavior, prevented metabolic disorders in brain. Therefore, antihypoxant ethomerzol is effective as a drug against hypoxia due to brain injury.     

The brain catecholamines during domestication of the silver fox Vulpes fulvus

Studies have been made on the content of catecholamines (noradrenaline and dopamine) as well as metabolites of dopamine (3,4-dihydroxyphenylacetic and homovanillic acids) in the brain structures of silver foxes which differ in their handling reactions. The level of noradrenaline was found to be significantly higher in the anterior hypothalamus of domesticated animals; no differences in noradrenaline content were found in the frontal cortex, hippocamp, posterior hypothalamus and midbrain in animals from aggressive and domesticated groups. Dopamine content was higher in the tuberculum olfactorium of domesticated animals, being lower in the striatum and n. accumbens. Metabolite level remained unaffected which is presumably due to changes in dopamine synthesis in the investigated structures. It was concluded that domestication of animals favours the specimens with an altered state of catecholaminergic system of the brain.     

The neuroteratogenicity of procarbazine in the rat: behavioral, morphological, and neurochemical aspects

Pregnant female Sprague-Dawley rats were treated from day 12 through day 15 of gestation with procarbazine, an antineoplastic drug, and their offspring were subjected to tests of locomotor development and behavior. Treatment levels ranged from 0.5 mg/kg/day, a dose that produced no abnormalities, to 10 mg/kg/day, a dose that caused a marked micrencephaly in the absence of other teratological changes. Despite marked morphological brain changes, preweaning locomotor development, as assessed by open-field swimming activity and vertical grid climbing, was normal in all offspring. Post-weaning passive avoidance learning and retention were also normal. Groups that had been treated prenatally with teratogenic doses (5.0 and 10.0 mg/kg/day) displayed less rearing behavior in the open field, while ambulation in the periphery of the open field arena was unaffected. Groups treated with subteratogenic doses (0.5 and 1.0 mg/kg/day) did not differ from control. In addition to the behavioral studies, sodium-dependent high-affinity choline uptake and choline acetyltransferase activity (CAT) were measured (per mg protein) in the cortex and hippocampus of animals that had been exposed prenatally to either teratogenic or subteratogenic doses of procarbazine. In spite of a substantial reduction in size of both brain structures in the group receiving a teratogenic dose, choline uptake and CAT did not differ from control.     

An extremely low frequency magnetic field increases unconditioned larval movement of the common cutworm,Spodoptera litura: A novel model for a magnetoreceptive neurobehavioral study

One of the most interesting features of magnetic field (MF) responsiveness in animals is the signal transduction mechanism from sensing MF to behavior. To develop a model system for understanding the process, we performed a preliminary behavioral assay using an insect, the common cutworm, Spodoptera litura (Fabricius). In contrast to sham exposure, a continuous 60 Hz oscillating MF (0.2 mT) induced a significant increase in movement in third instar larvae: the MF‐induced movement was longer in total duration and had an earlier onset than movement from sham exposure. Not surprisingly, the movement duration of the group test was notably higher than that of the individual test, suggesting that the individual test is more favorable for assessing the MF effect on movement. Considering the simplicity of the experimental operation and obvious non‐conditioned responsiveness to the MF, this model might be suitable for studying magnetoreception and following the signal transduction mechanism between neurons and behavior.     

Spatiotemporal analysis of simultaneous single-unit activity in the dragonfly

Continuous neural spiking records were obtained from the mesothoracic ganglion of the dragonfly. For analysis the 12 s records of all 58 discriminated cells were “tracked” across three continuous behavioral states: pre-flight, flight and post-flight. The recorded spike amplitudes and angles (widths) for each cell were used to construct a simple map of individual cell positions relative to each other within the ganglion. Individual cell activity patterns were then characterized both with respect to neighboring cell locations and patterns of cell spiking observed across three behavioral states. The results indicated that this technique for constructing a “neighboring cell map” effectively reflects the known histological features of the ganglionic cell architecture. The gross firing histories of individual cells were found to correspond to the overall spike patterns of neighboring ganglionic cells as opposed to more distal cells. Such relationships suggest that the physical layout of this ganglionic network may help to determine or bias individual cell firing histories that occur during different behavioral states in the dragonfly.