Klaus A. Miczek

Essential Roles for the Abl and Arg Tyrosine Kinases in Neurulation

The Abl and Arg tyrosine kinases play fundamental roles in the development and function of the central nervous system. Arg is most abundant in adult mouse brain, especially in synapse-rich regions. arg(-/-) mice develop normally but exhibit multiple behavioral abnormalities, suggesting that arg(-/-) brains suffer from defects in neuronal function. Embryos deficient in both Abl and Arg suffer from defects in neurulation and die before 11 days postcoitum (dpc). Although they divide normally, abl(-/-)arg(-/-) neuroepithelial cells display gross alterations in their actin cytoskeleton. We find that Abl and Arg colocalize with each other and with actin microfilaments at the apical surface of the developing neuroepithelium. Thus, Abl and Arg play essential roles in neurulation and can regulate the structure of the actin cytoskeleton.

Social and neural determinants of aggressive behavior: pharmacotherapeutic targets at serotonin, dopamine and γ-aminobutyric acid systems

Abstract Background and rationale. Aggressive outbursts that result in harm and injury present a major problem for the public health and criminal justice systems, but there are no adequate treatment options. Obstacles at the level of social policy, institutional regulation, and scientific strategy in developing animal models continue to impede the development of specific anti-aggressive agents for emergency and long-term treatments. Objective. To be more relevant to the clinical situation, preclinical aggression research has begun to focus on the neurobiological determinants of escalated aggressive behavior that exceeds species-typical patterns. It is the goal of this review to examine novel pharmacological and molecular tools that target the neural mechanisms for different kinds of aggressive behavior more selectively than previously possible and to outline potential pharmacotherapeutic options. Results and conclusions. (1) The preclinical focus on the behavioral characteristics and determinants of intense aggression promises to be most relevant to the clinical distinction between the proposed impulsive-reactive-hostile-affective subtypes of human aggression and the controlled-proactive-instrumental-predatory subtypes of aggression. The neural circuits for many types of human and animal aggression critically involve serotonin, dopamine and γ-aminobutyric acid (GABA) and specific receptor subtypes. (2) The dynamic changes in frontal cortical serotonin that are triggered by engaging in aggressive behavior imply that serotonergic drug effects are largely determined by the functional state of the receptors at the time of drug treatment. Of the numerous 5-HT receptors currently identified, the 5-HT1B receptors offer a promising target for reducing impulsive aggressive behavior, particularly if the action can be limited to sites in the central nervous system. (3) Aggressive confrontations are salient stressors, both for the aggressor as well as the victim of aggression, that are accompanied by activation of the mesocorticolimbic but not the striatal dopamine system. Dopaminergic manipulations, particularly targeting the D2 receptor family, can influence aggressive behavior in animals and human patients, suggesting that mesocorticolimbic dopamine may have important enabling or permissive functions. (4) GABA is critical in the neurochemical control of aggressive behavior as evidenced by studies that directly modify GABAergic neurotransmission and neurochemical studies that correlate GABA measurements with aggressive behavioral responses in several animal species. The GABAA receptor complex is a mechanism through which certain benzodiazepines and alcohol enhance and inhibit aggressive behaviors. Social and pharmacological experiences decisively determine the effects of GABAergic positive modulators on aggression.

Corticotropin-releasing factor antagonist reduces emotionality in socially defeated rats via direct neurotropic action.

Introduction of a socially naive male rat into the home territory of a resident counterpart results in agonistic interactions, leading to the rapid social defeat of the intruder. Exposure to the aggressive resident produces a stress-response profile consisting of neuroendocrine activation and coping behaviors such as submission. The present studies examined the dependence of these adaptive responses on endogenous brain Corticotropin-Releasing Factor (CRF), a peptide hormone known to coordinate neuronally mediated- and pituitary-adrenal responses to stress. The Elevated Plus-Maze was employed as an animal model of emotionality in which stressors reduce subsequent exploration of open maze arms without walls in favor of enclosed maze arms. A CRF antagonist, alpha-hel CRF9-41, administered intracerebroventricularly (5 and 25 micrograms i.c.v.) immediately post-stress and 5 min prior to maze testing reversed the heightened emotionality produced by the resident exposure stressor. This action paralleled that of an anxiolytic dose of the short-acting benzodiazepine, midazolam (1.5 mg/kg i.p.). Intra-amygdaloid administration of lower doses of the CRF antagonist (125, 250 and 500 ng i.c.) also reversed, dose-dependently, the effect of exposure to an aggressive resident without altering the behavior of unstressed control animals. Further, the enhanced release of ACTH and corticosterone following social conflict was not modified over the short term by the intra-amygdaloid dose of CRF antagonist (250 ng i.c.) which was effective in reversing stress-induced hyper-emotionality. These results suggest that limbic system CRF substrates exert an anxiogenic effect on the exploratory behavior of socially defeated rats via a pituitary-adrenal-independent mechanism.

Aggressive behavioral phenotypes in mice.

Aggressive behavior in male and female mice occurs in conflicts with intruding rivals, most often for the purpose of suppressing the reproductive success of the opponent. The behavioral repertoire of fighting is composed of intricately sequenced bursts of species-typical elements, with the resident displaying offensive and the intruder defensive acts and postures. The probability of occurrence as well as the frequency, duration, temporal and sequential patterns of aggressive behavior can be quantified with ethological methods. Classic selection and strain comparisons show the heritability of aggressive behavior, and point to the influence of several genes, including some of them on the Y chromosome. However, genetic effects on aggressive behavior critically depend upon the background strain, maternal environment and the intruder. These factors are equally important in determining changes in aggressive behavior in mice with a specific gene deletion. While changes in aggression characterize mutant mice involving a variety of genes, no pattern has emerged that links particular gene products (i.e. enzyme, peptide, receptor) to either an increase or a decrease in aggressive behavior, but rather emphasizes polygenic influences. A potentially common mechanism may be some components of the serotonin system, since alterations in 5-HT neurotransmission have been found in several of the KO mice that display unusual aggressive behavior.

Intruder-evoked aggression in isolated and nonisolated mice: Effects of psychomotor stimulants and l-Dopa

Adult male Swiss-Webster mice were housed either singly (isolated) or with a female (nonisolated). Aggressive behavior was evoked by introducing a group-housed male mouse (intruder) into the home cage of the isolated or nonisolated mouse (resident). d-Amphetamine, methamphetamine, methylphenidate, cocaine, and l-dopa decreased attack and threat behavior by resident mice, the isolates requiring 2–4 times higher drug doses for the antiaggressive effects than the nonisolates. d-Amphetamine, methamphetamine, and methylphenidate caused intruder mice to be more frequently attacked by their nontreated resident opponents, to escape more often, to assume the defensive upright posture less, and to move about more often. l-Dopa nonspecifically decreased all elements of agonistic and nonagonistic behavior, while the amphetamines and methylphenidate suppressed attacks, increased escapes, decreased upright postures, and increased nonagonistic locomotion. By contrast, cocaines antiaggressive effects were remarkably specific, i.e., not accompanied by changes in other behavioral elements.

Intraspecies aggression in rats: Effects of d-amphetamine and chlordiazepoxide

Abstractd-Amphetamine sulfate and chlordiazepoxide hydrochloride, administered to either the dominant or subordinate rat, altered several components of fighting behavior in a dose-dependent biphasic manner. Stereotypic sequences of attack, threat, defense, and submission were generated between pairs of previously isolated Sprague-Dawley rats by extinction of a food-reinforced response. Low doses of amphetamine (0.05, 0.1 mg/kg) and chlordiazepoxide (2.5, 5.0 mg/kg) given i.m. to the dominant rat 30 min prior to 15 min tests increased attack bites and leaps and the display of aggressive postures and threats, whereas higher doses of both drugs (0.5, 1.0 mg/kg amphetamine; 20 mg/kg chlordiazepoxide) suppressed attacks and threats. Amphetamine and chlordiazepoxide, administered to the subordinate rat, caused a more prolonged display of submissive-supine and defensive-upright postures; chlordiazepoxide (10.0, 20.0 mg/kg) prolonged immobile crouching whereas amphetamine (0.5, 1.0 mg/kg) greatly reduced this response. Drugged subordinate rats also provoked more attacks and threats by the non-drugged opponents. The multi-response analysis of fighting reveals that various elements of aggressive and defensive-submissive behavior patterns are differentially sensitive to drug action. The results indicate that amphetamine and chlordiazepoxide can facilitate or inhibit attack or defense depending on the dose level and which of the opponents was injected, but do not reverse dominance-subordination relationships.

Long-term impairment of autonomic circadian rhythms after brief intermittent social stress

This experiment was designed to examine the short- and long-term behavioral, cardiovascular, and thermoregulatory responses to brief intermittent agonistic confrontation in rats. The experimental procedure involves resident-intruder confrontations consisting of a 10-min period during which both animals are separated in the home cage of the resident, followed by a brief physical encounter leading to defeat of the intruder and a 10-min period, when the intruder was alone in the home cage of the resident. These 30-min-long confrontations were repeated on 5 consecutive days. Before the first confrontation with a resident, an intruder rats telemetered heart rate and core temperature show a stable circadian rhythm that is entrained by the light cycle. Acutely, the confrontations produce immediate and large tachycardia and hyperthermia in intruders. A decrease in amplitude of the circadian rhythms for heart rate and core temperature, as detected by cosinor analysis, persists for at least 10 days after the last of five daily brief confrontations with the resident. The defensive upright posture is nearly absent during the first exploration of the residents home cage, but is displayed by the intruder for one-third of the available time before and after the fifth defeat. Intermittent brief social stress is sufficient to induce profound changes in defensive behavior and long-lasting depression of circadian rhythmicity that persist for weeks.

Aggression, anxiety and vocalizations in animals: GABAA and 5-HT anxiolytics

A continuing challenge for preclinical research on anxiolytic drugs is to capture the affective dimension that characterizes anxiety and aggression, either in their adaptive forms or when they become of clinical concern. Experimental protocols for the preclinical study of anxiolytic drugs typically involve thesuppression of conditioned or unconditioned social and exploratory behavior (e.g., punished drinking or social interactions) and demonstrate the reversal of this behavioral suppression by drugs acting on the benzodiazepine-GABAA complex. Less frequently, aversive events engenderincreases in conditioned or unconditioned behavior that are reversed by anxiolytic drugs (e.g., fear-potentiated startle). More recently, putative anxiolytics which target 5-HT receptor subtypes produced effects in these traditional protocols that often are not systematic and robust. We propose ethological studies of vocal expressions in rodents and primates during social confrontations, separation from social companions, or exposure to aversive environmental events as promising sources of information on the affective features of behavior. This approach focusses on vocal and other display behavior with clear functional validity and homology. Drugs with anxiolytic effects that act on the benzodiazepine-GABAA receptor complex and on 5-HT1A receptors systematically and potently alter specific vocalizations in rodents and primates in a pharmacologically reversible manner; the specificity of these effects on vocalizations is evident due to the effectiveness of low doses that do not compromise other physiological and behavioral processes. Antagonists at the benzodiazepine receptor reverse the effects of full agonists on vocalizations, particularly when these occur in threatening, startling and distressing contexts. With the development of antagonists at 5-HT receptor subtypes, it can be anticipated that similar receptor-specificity can be established for the effects of 5-HT anxiolytics.

Acquisition of cocaine self-administration after social stress : role of accumbens dopamine

Abstract Exposure to either aversive or rewarding environmental stimuli increases extracellular dopamine (DA) concentrations in terminal areas of the mesocorticolimbic dopamine system. Furthermore, behavioral reactivity to an environmental stressor has been shown to correlate with latency to initiate self-administration of psychomotor stimulant drugs. The present study examined the behavioral and dopaminergic responses of rats to social defeat stress and compared latencies to initiate cocaine self-administration in defeated and non-defeated rats. In vivo microdialysis was used to examine the effects of social defeat stress on DA concentrations in nucleus accumbens of freely-moving rats. During the experimental session, dialysate and video recording samples were collected from previously-defeated and non-defeated “intruder” rats in consecutive phases, while (1) in the home cage, (2) when placed in the empty, soiled cage of a resident rat which had previously defeated them, and (3) when exposed to threat of defeat by the resident. Immediately following threat of defeat, previously-defeated and non-defeated intruders were given the opportunity to self-administer cocaine IV. When exposed to the olfactory cues of an aggressive resident, extracellular DA levels in nucleus accumbens increased to approximately 135% of baseline in previously defeated rats versus 125% of baseline in non-defeated rats. When exposed to social threat by the resident, DA levels further increased to 145% of baseline in previously defeated rats versus 120% in non-defeated rats. Previously defeated rats acquired cocaine self-administration in approximately half the time of non-defeated rats, consistent with the hypothesis that prior stress exposure may induce a cross-sensitization to the rewarding effects of cocaine. These results are consistent with the idea that exposure to stress may induce changes in central dopaminergic activity, which may render an individual more vulnerable to acquiring psychomotor stimulant self-administration.

Accumbal dopamine and serotonin in anticipation of the next aggressive episode in rats

Autonomic and limbic neural activities are linked to aggressive behavior, and it is hypothesized that activities in the cardiovascular and monoaminergic systems play a role in preparing for an aggressive challenge. The objective was to learn about the emergence of monoamine activity in nucleus accumbens before an aggressive confrontation that was omitted at the regular time of occurrence, dissociating the motoric from the aminergic activity. Dopamine, serotonin, heart rate and behavioral activity were monitored before, during and after a single 10‐min confrontation in resident male Long‐Evans rats fitted with a microdialysis probe in the n. accumbens and with a telemetry sender (experiment 1). DA, but not 5‐HT efflux, was confirmed to increase in n. accumbens during and after a single aggressive episode. In aggressive males that confronted an opponent daily for 10 days (experiment 2) heart rate rose 1 h before the regularly scheduled encounter relative to control rats, as measured on day 11 in the absence of any aggression. Concurrently, DA levels increased by 60–70% over baseline levels and 5‐HT levels decreased by 30–35% compared to baseline levels. These changes were sustained over 1 h, and contrasted with no significant changes in DA, 5‐HT, heart rate or behavioral activity in control rats. The rise in mesolimbic DA appears to be significant in anticipating the physiological and behavioral demands of an aggressive episode, and the fall in 5‐HT in its termination, dissociated from the actual execution of the behavior.