Effect of an enkephalin-like tetrapeptide on the food instrumental behavior of rats

An enkephalin-like tetrapeptide (subcutaneous, intraperitoneal and intraventricular injections) disturbs the goal-oriented food instrumental behavior of rats by decreasing the number of adequately performed instrumental reactions. In addition to these disorders, intraventricular microinjections entail an increase in the number of inadequate, incomplete behavioral reactions. Besides, injection of the tetrapeptide evokes specific disorders of motor activity, which manifest in the occurrence in rats of stretches, "duck-like step", motor stereotypy, arching of the tail, changes in the tone of abdominal muscles, etc. The tetrapeptide effects described were not inhibited by narcan, remaining unchanged for 3.5-5 months following a single injection of the tetrapeptide.     

Emotional reactions to odours in Parkinson's disease A clinical application of ethological methods

The behavioral reactions of 24 Parkinson patients to six kinds of odours were analyzed in relation to the subjective assessments of the odours. The reactions of the patients were normal in character, but reduced in intensity for two of the six odours. This was attributed primarily not to motor retardation but to impaired subjective perception.     

Reproduction of the electrophysiologic correlates of a conditioned defense reflex following electroconvulsive activity]

Acute and chronic experiments on cats have shown the possibility of obtaining in one session conditioned EEG-responses and vegetative changes as well as conditioned motor reactions time-locked to the moment of the unconditioned pain stimulation omitted during testing. Electro-convulsive stimulation directly after elaboration prevents the appearance of conditioned motor reactions, while conditioned EEG and vegetative changes are retained after electric seizures. A conclusion has been drawn that the emotional component of conditioned reactions is not subjected to the amnestic effect of electro-convulsive action.     

Behavioral Activity and Anxiety of Rats under Open Field Conditions in the Norm and after Parenteral Introductions of Xenogenic Cerebrospinal Fluid

We studied the effects of injections of xenogenic cerebrospinal fluid (CSF) on behavioral phenomena in rats under open field conditions. Parenteral introduction of xenogenic liquor in adult male and female rats resulted in appreciable changes in the indices of spontaneous motor activity in the open field. Single and double CSF injections promoted intensification of motor and orientational/research activity followed by inhibition of the respective behavioral manifestations. Repeated CSF injections were accompanied by a gradual decrease in the behavioral activity of rats. In males and females, these changes were nearly synchronous. Injections of CSF also influenced the seasonal dynamics of behavioral phenomena in rats and cyclic changes in the activity of females during the estrous cycle. In the whole, CSF injections exerted more powerful effects than the action of main natural biological regulators (photoperiod and sex cycle). The presence of significant amounts of biologically active substances in the liquor, which are responsible for complex effects on links of the neuroendocrine regulatory system of recipients, is the probable basis of the revealed effects.     

Experimental informational neuroses in dogs as sequelae of overloading short-term memory

In conditions of overloaded function of short-term memory, studied by the method of delayed reactions, with a prolonged deficit of time allotted for realization of the function, the animals exhibit substantial disturbances of higher nervous activity which by their etiological character belong to the group of informational neuroses. Appearance of the neurosis is preceded by a number of complex behavioral and vegetative changes reflecting activation of powerful compensatory mechanisms of the brain activity, aimed at elimating the time deficit and other neurotizing factors of the surroundings. Experimental neurosis caused by overloading the function of short-term memory is characterized by a severe course and is attended with motor and somatic disturbances as well as by memory and emotional disorders.     

The hypothalamo-hypophysial system of the lemming Dicrostonyx torquatus Pallas. IV. Influence of experimental animal cooling on the ultrastructure of the hypothalamo-posthypophysial neurosecretory system

The reaction of the hypothalamo-hypophysial neurosecretory system (HHNS) of lemmings to cold (+4 degrees C) was studied by the method of electron microscopy. The animals were kept in cages with nest, but with no wheel to allow running; in cages with a wheel, but with no nest; in cages with no nest and no wheel. No changes in the HHNS reaction were revealed under cold stimulation, if the animals were not deprived of motor activity (running in a wheel), or could hide in a nest. In case of no nest and restricted motor activity exposition to low temperature led to a progressive activation of neurosecretory cells of the supraoptic and paraventricular nuclei, and finally to their exhaustion and degeneration. The intensity of the HHNS reaction to cold is shown to depend on the initial state of the system which varies according to the stages of population cycle. The present study gives grounds to put forward the hypothesis that the adaptation of the Dicrostonyx torquatus Pallas to cold is made possible due to maximal utilization of ecological conditions and behavioral reactions.     

Understanding the neural control of ingestive behaviors: helping to separate cause from effect with dehydration-associated anorexia

Eating and drinking are motivated behaviors that are made up of coordinated sets of neuroendocrine, autonomic, and behavioral motor events. Although the spinal cord, hindbrain, and hypothalamus contain the motor neurons and circuitry sufficient to maintain the reflex parts of these motor events, inputs from the telencephalon are required to furnish the behavioral components with a motivated (goal-directed) character. Each of these motor events derives from the complex interaction of a variety of sensory inputs with groups of neural networks whose components are distributed throughout the brain and collectively support motor expression and coordination. At a first approximation based on a variety of data, these networks can be divided into three groups: networks that stimulate, those that inhibit, and those that disinhibit motor functions. A fourth contributor is the circadian timing signal that originates in the hypothalamic suprachiasmatic nucleus and provides the temporal anchor for the expression of all behaviors. This article discusses the nature of these networks using neuroanatomical (tract-tracing and neuropeptide in situ hybridization), endocrine, and behavioral evidence from a variety of experimental models. A persistent problem when studying the control of food intake from a neural systems perspective has been the difficulty in separating those neuronal changes that result in hunger from those that are as a consequence of eating. To address this problem, dehydration-associated anorexia is presented as a particularly useful experimental model because it can be used to distinguish between neural mechanisms underlying anorexia and those changes that occur as a consequence of anorexia. The article concludes by highlighting the potential role of neuropeptidergic action in the operation of these networks, using forebrain neuropeptidergic innervation of the parabrachial nucleus as an example.     

Transformation of conditioned responses of the tonic type

A reversal of signal meaning of stimuli signalling experimental situation was performed on dogs with conditioned defensive motor reflexes to clicks: clicks and electro-cutaneous stimulation were stopped, and the animals were started to be given food in the same experimental situation. Reversal of conditioned defensive tonic stimuli to alimentary ones led to a complex of behavioral and electrographic reactions. Isolated click tests showed that signals of experimental situation considerably affect a fully-elaborated defensive motor reflex. At the same time the preparatory role of certain situational elements may be specialized with regard to the components of the conditioned reflex, in particular to the local flexor reaction.     

Brain Activation in Motor Sequence Learning Is Related to the Level of Native Cortical Excitability

Cortical excitability may be subject to changes through training and learning. Motor training can increase cortical excitability in motor cortex, and facilitation of motor cortical excitability has been shown to be positively correlated with improvements in performance in simple motor tasks. Thus cortical excitability may tentatively be considered as a marker of learning and use-dependent plasticity. Previous studies focused on changes in cortical excitability brought about by learning processes, however, the relation between native levels of cortical excitability on the one hand and brain activation and behavioral parameters on the other is as yet unknown. In the present study we investigated the role of differential native motor cortical excitability for learning a motor sequencing task with regard to post-training changes in excitability, behavioral performance and involvement of brain regions. Our motor task required our participants to reproduce and improvise over a pre-learned motor sequence. Over both task conditions, participants with low cortical excitability (CElo) showed significantly higher BOLD activation in task-relevant brain regions than participants with high cortical excitability (CEhi). In contrast, CElo and CEhi groups did not exhibit differences in percentage of correct responses and improvisation level. Moreover, cortical excitability did not change significantly after learning and training in either group, with the exception of a significant decrease in facilitatory excitability in the CEhi group. The present data suggest that the native, unmanipulated level of cortical excitability is related to brain activation intensity, but not to performance quality. The higher BOLD mean signal intensity during the motor task might reflect a compensatory mechanism in CElo participants.     

In vitro classical conditioning of a gill withdrawal reflex in Aplysia: neural correlates and possible neural mechanisms

An in vitro preparation consisting of the siphon, mantle, gill, and abdominal ganglion undergoes classical conditioning when a weak tactile stimulus (CS) applied to the siphon is paired with a strong tactile stimulus to the gill (UCS). When the stimuli are paired, the CS comes to evoke a gill withdrawal reflex (GWR) which increases in amplitude with training. Only when the stimuli are paired in a classical conditioning paradigm does the CS come to evoke a GWR. With classical conditioning training there is an alteration in the synaptic efficacy between central sensory neurons and central gill motor neurons. Moreover, these changes can be observed in sensory neurons not activated by the CS. The changes observed, as evidence by the number of action potentials evoked in the gill motor neuron do not completely parallel the observed behavioral changes. It is suggested that in addition to changes in the synaptic efficacy at the sensory-motor neuron synapse, other changes in neuronal activity occur at other loci which lead to the observed behavioral changes.     

Effects of urocortin 2 and 3 on motor activity and food intake in rats

Urocortin 2 (Ucn 2) and Ucn 3 are new members of the corticotropin-releasing factor (CRF) family and bind selectively to the CRF type 2 receptor (CRF2). The effects of these peptides on behavioral changes induced by CRF were examined in rats. In a familiar environment, intracerebroventricular injection of Ucn 2 attenuated the stimulatory effect of CRF on motor activity, although it alone produced no effect. Ucn 3 suppressed motor activity and attenuated the stimulatory effect of CRF. In an open field, CRF decreased locomotion and rearing but increased grooming behavior. Ucn 2 attenuated the inhibition of locomotor activity induced by CRF without affecting other activities, such as rearing or grooming behavior. Ucn 3 had no effect on the behavioral changes induced by CRF, although it alone decreased locomotion and rearing in a manner similar to CRF. Ucn 2 was thus found to have an antagonistic effect on bi-directional motor activation induced by CRF, while Ucn 3 had a suppressive effect on motor activity. Both Ucn 2 and Ucn 3 suppressed food intake in freely-fed rats, but not immediately after injection. These results suggest that the CRF2 receptor is involved in motor suppressive effects as well as anxiolytic and anorectic effects of Ucn 2 and Ucn 3.     

Characteristics of cortical responses to electrostimulation of the internal geniculate body during formation of a defensive conditioned reflex]

During elaboration of a classical defensive conditioned reflex the dogs exhibited a dependence of the changes in amplitude and configuration of evoked potentials (EP) to electrical stimulation of the medial geniculate body (MGB), a conditioned stimulus, on the nature of effector manifestation of the conditioned reflex: the late components were the most depressed at multiple phasic reactions and not infrequently increased and became complicated at single and short motor reactions as well as at their incidental absence. The primary oscillations, while mostly remaining unchanged, were depressed in the case of conditioned reactions attended with a general motor restlessness. A difference has been revealed during conditioning in the EP changes to electrical stimulation of MGB and to an adequate peripheral stimulation. It has been assumed that EP changes during conditioned activity are determined by the relationship between the levels of tonic and phasic cortical activation.     

The spike reactions of the motor cortex neurons of old rabbits to specific stimuli

Spike reactions of motor cortex neurons to tactile and electrocutaneous stimulation of a forelimb were studied in aged (6-7-year old) rabbits. As compared with young adult animals, the neuronal reactions to afferent stimuli were rarely recorded in the motor cortex of aged rabbits (66.7 and 50%, respectively). The activation manifested in increasing firing rate over its spontaneous level was less intensive than in young animals. The neuronal reactions of aged animals were characterized by the slower activation with longer latencies and slower development of spike responses. The parameters of slow activation could be partly corrected by the iontophoretic application of acetylcholine to the soma region. Neuronal inhibition recorded in the motor cortex of aged rabbits was not markedly changed compared to inhibition reactions in young animals. It is suggested that impairment of the functional state of dendrites in aging is responsible for the changes observed.     

Effects of cold and heat on behavior and cerebellar function in goldfish

Summary A similar sequence of behavioral effects was observed for either cooling or heating; most effects occurred on changing temperature of entire fish or of only the cerebellum. On moderate heating or cooling, fish are hyperexcitable, spontaneously hyperactive; on further heating or cooling swimming is uncoordinated; when the subcerebellar structures are heated or cooled, equilibrium is disturbed; on further heating or cooling coma and respiratory failure ensue. Critical temperatures are modifiable by acclimation. The behavioral effects of cerebellectomy are additive with temperature effects on motor centers.Electrical activity of Purkinje neurons changes in the same thermal ranges as behavior. Inhibition via cerebellar interneurons is most sensitive and can be modified by acclimation. Ongoing activity increases with warming up to a blocking temperature; interspike interval histograms show pattern changes during warming. Activation via mossy fibers-granule cells is more sensitive than that via climbing fibers, and antidromic impulses are most resistant.A neuronal model based on inhibitory actions of Purkinje neurons on motor centers and parallel feedback excitatory pathways can explain both behavioral and electrical observations.     

Fundamental motor patterns of the mammalian fetus.

Techniques that permit direct observation of fetuses in vivo recently have expanded our understanding of prenatal behavioral development in mammals. Although fetal motor activity seems to lack the dynamic, goal-directed character of postnatal behavior, the dimensions that define behavioral organization after birth are applicable to the movements expressed by fetuses. Fetal activity exhibits temporal, sequential, and spatial organization that emerges between the inception of movement and term. Fetal rodents, for example, exhibit coordinated motor patterns antecedent to postnatal righting, locomotion, suckling, maternal-infant communication and grooming behavior, while other action patterns appear to be functional adaptations to the intrauterine niche. Fetuses also are behaviorally responsive to sensory stimulation and changes in environmental conditions in utero. Expression of these behavioral properties emphasizes continuity between prenatal and postnatal life while implying an adaptive role for behavior before birth.     

多巴胺信号系统在衰老引起的行为和认知能力退化中的作用

衰老是生物体随时间推移各项生理功能逐渐发生改变的自然现象。动物的衰老伴随着行为和认知能力的降低,因此研究动物行为和认知功能退化的分子神经机制对于提高老年群体的生活质量具有重要意义。近年来,随着正电子发射断层扫描技术和功能性核磁共振脑成像技术在神经生物学上的广泛运用,越来越多证据表明多巴胺系统功能在衰老过程中显著降低,并且这是人类和动物行为和认知功能退化的重要原因。本文将概述自然衰老过程中多巴胺信号系统功能变化及机制和其在动物行为和认知退化中的作用等方面研究进展。     

Consideration of Proprioception and Neuromuscular Integration in Crustacean Locomotion

Recent work on sensory, motor and behavioral aspects of walkingin a variety of decapod Crustacea is discussed and compared.In these studies there has been considerable emphasis on modificationsof the motor program by variations imposed experimentally totest its capabilities and by naturally occurring variationsin environmental conditions which challenge the integrated system.The roles of sensory structures in signalling such changes arediscussed as well as the integrative capabilities of neuromuscularsystems in adaptive responses.     

EEG correlation and impulse activity of neuronal populations of individual structures of the cat brain during elaboration and reproduction of motor and alimentary reactions in instrumental conditioned reflexes]

Stable changes in EEG and spike activity of neuronal populations in different brain formations were studied on models of instrumental conditioned reflexes: motor and motor alimentary. A depencence has been established of the EEG amplitude-frequency parameters in the motor and striate cortical zones and the hippocampus on definite changes of unit spike activity in these areas. Simultaneous recording of the EEG and the spike activity of neuronal populations helps to elucidate the neurophysiological nature of individual rhythms of bio-electrical activity. Learned animals exhibit a stable reproduction of the spatial-temporal EEG patterns and motor alimentary reactions when automatic presentation of reinforcement is changed over to an arbitrary one.     

Effect of fenamin and haloperidol on conditioned activity of neurons of the motor cortex and striopallidal system

The activity of neurones in the motor cortex, caudate nucleus, putamen and globus pallidus was studied during elaboration of motor conditioned reflexes to time in rabbits, treated with 1-amphetamine and haloperidol. Mechanisms of reproduction of cells trace activity in the reflex to time at the omission of trials, reacted to 1-amphetamine by increasing the intensity of reactions in the motor cortex and inactivation in putamen cells. The curve of dynamics of intensity changes of trace discharges in the course of a series of trials omissions remained unaltered only in motor cortex; in the other structures it significantly differed from the norm of intact animals. Haloperidol depressed the mechanisms of reproduction of trace reactions of the globus pallidus cells, and made them almost fully inactive in the motor cortex; the putamen neurones reacted to haloperidol by an increase of trace reactions intensity. Against the background of the animal chronic 1-amphetamine intoxication, haloperidol normalized the dynamics and intensity of trace activity. "Therapeutic" effect of haloperidol was most distinctly expressed in the motor cortex and putamen cells, less--in the caudate nucleus and was completely absent in the globus pallidus.     

Repeated Cocaine Alters Glutamate Receptor Subunit Levels in the Nucleus Accumbens and Ventral Tegmental Area of Rats that Develop Behavioral Sensitization

Increased glutamate transmission in the nucleus accumbens and ventral tegmental area has been proposed as a mechanism underlying sensitized behavioral responses to repeated cocaine administration. GluR1, GluR2/3, and NMDAR1 subunits of glutamate receptors were quantified from immunoblots in these brain nuclei in rats at 24 h and 3 weeks after discontinuing 1 week of daily cocaine injections. Motor behavior was monitored after the first and last injections of daily cocaine, and those rats that showed >20% increase in motor activity after the last compared with the first injection were considered to have developed behavioral sensitization. The subjects that developed behavioral sensitization showed a significant increase in GluR1 levels in the nucleus accumbens at 3 weeks but not at 24 h of withdrawal. Conversely, sensitized animals showed a significant increase in NMDAR1 and GluR1 levels in the ventral tegmental area at 1 day but not at 3 weeks of withdrawal. None of these increases occurred in the rats exposed to daily cocaine that did not develop behavioral sensitization (<20% increase in motor activity), and no changes were measured in the level of GluR2/3 in any treatment group. The functional importance of the increases in glutamate receptor subunit levels is suggested by the fact that the changes were present only in rats that developed behavioral sensitization to repeated cocaine administration.