Serotonin and Central Mechanisms Underlying Motor Control

The review considers in a historical aspect the published data on the role of serotonin in brain activity, as well as on the structure and organization of neuronal projections of serotonergic nuclei. In addition, information on the facilitatory and inhibitory effects of serotonin on neurons of various brain regions under both in vivo and in vitro conditions is presented. General characteristics of the main types of central serotonin receptors are also given. It is emphasized that such receptors form a heterogeneous group, and this is the reason for the diversity of the effects when agonists and antagonists are applied. Regularities characteristic of changes in the activity of serotonergic system over the sleep-wakefulness cycle are also analyzed in this review; data on the involvement of serotonin in motor control are cited. Possible reasons for the complexity and multiplicity of the effects evoked by serotonin at different levels of the CNS and within various neuronal structures in the course of motor behavior are discussed.     

Purinergic Mechanisms of Adaptation of Different Types of Motor Units under Conditions of Allergic Reorganization

Biophysics - A role for presynaptic signaling was found in the processes of adaptation to allergies during isometric contractions of mouse EDL (fast) and soleus (slow) muscles evoked by electrical...     

Rethinking Motor Lateralization: Specialized but Complementary Mechanisms for Motor Control of Each Arm

Motor lateralization in humans has primarily been characterized as “handedness”, resulting in the view that one arm-hemisphere system is specialized for all aspects of movement while the other is simply a weaker analogue. We have proposed an alternative view that motor lateralization reflects proficiency of each arm for complementary functions that arises from a specialization of each hemisphere for distinct movement control mechanisms. However, before this idea of hemispheric specialization can be accepted, it is necessary to precisely identify these distinct, lateralized mechanisms. Here we show in right-handers that dominant arm movements rely on predictive mechanisms that anticipate and account for the dynamic properties of the arm, while the non-dominant arm optimizes positional stability by specifying impedance around equilibrium positions. In a targeted-reaching paradigm, we covertly and occasionally shifted the hand starting location either orthogonal to or collinear with a particular direction of movement. On trials on which the start positions were shifted orthogonally, we did not notice any strong interlimb differences. However, on trials on which start positions were shifted orthogonally, the dominant arm largely maintained the direction and straightness of its trajectory, while the non-dominant arm deviated towards the previously learned goal position, consistent with the hypothesized control specialization of each arm-hemisphere system. These results bring together two competing theories about mechanisms of movement control, and suggest that they coexist in the brain in different hemispheres. These findings also question the traditional view of handedness, because specialized mechanisms for each arm-hemisphere system were identified within a group of right-handers. It is likely that such hemispheric specialization emerged to accommodate increasing motor complexity during evolution.     

Electrophysiological Mechanisms of Adaptation Processes

A systemic analysis of the relationships between electrophysiological parameters of the cardiovascular and respiratory systems during adaptation processes has been performed in order to study some electrophysiological mechanisms of stress. Studies were performed in subjects with various circulatory disorders and in healthy subjects at rest and during exercise; in skilled and apprentice workers at an electronics plant; and in students under examination stress. It is demonstrated that determining the set of parameters of the integrated cardiac–respiratory–hemodynamic system is necessary but not sufficient for diagnosing stress and its individual stages. The main characteristic is the degree of harmony in the ratios between these parameters, i.e., the balance of relationships between subsystems; the ratios thereby serve as new diagnostic signs of the functional state of the body. A resonance–wave model of stress is proposed. This model forms a basis for the assessment of stress during its development, with the stages of strain and overstrain being regarded as stages of the positive dynamics of adaptation syndrome provided that self-regulation is preserved during the progress of these stages, i.e., resonance is formed. In the case of disharmonic ratios between electrophysiological parameters and imbalance of their relationships, the stages of adaptation processes differ in the degree of deviation from invariant ratios between parameters.     

植物对逆境交叉适应的分子机制

交叉适应(cross-adaptation)是植物应答复合逆境的主要表现形式,它涉及环境刺激、信号转导、基因表达及细胞代谢调节等.为明确交叉适应的分子机制,本文从活性氧、激素、促细胞分裂原激活性蛋白激酶等方面进行了综述,以深入系统地阐明植物对逆境的响应,为作物抗逆栽培提供经济、高效的途径.     

Neurosensory Mechanisms of Space Adaptation Syndrome

The results of studies on oculomotor reactions, both spontaneous and induced by visual and vestibular stimuli, that were performed during missions of Russian orbital complexes are described. It is demonstrated that abnormal sensorimotor reactions (spontaneous nystagmus; disturbance of the tracking function of the eyes; and decrease and increase in the tonic and dynamic vestibular excitability, respectively) are appropriate reactions of sensory systems during weightlessness. Abnormal sensorimotor reactions during spaceflights are individualized with respect to the strength, pattern of expression, time of development, and duration and dynamics of adaptation processes. Periods of adaptation (the initial, disintegration, and adaptation periods and alternation of compensation and decompensation periods) of sensorimotor functions to the conditions of weightlessness are determined. The possible mechanisms of neurosensory disturbances are described. These are otolith deafferentation, channel–otolith conflict, interlabyrinth asymmetry, intersensory mismatch, sensory deprivation, and suppression of vestibular afferent signals inadequate to new conditions.     

Analysis of Mechanisms Underlying Adaptation Processes

A system of elementary adaptation mechanisms is presented. The adaptations are considered as transients to a new homeostatic condition induced by an environmental change. We propose to distinguish adaptation mechanisms not directly related to gene expression (changes in the rate of synthesis and degradation of proteins, protein–ligand interactions, changes in viscosity of the membrane lipids) and the mechanisms relying on gene expression (changes in expression of already functioning genes, expression of new genes, mutations). Most of these mechanisms have phenotypic nature and just one (mutations) is genotypic. By the nature and time pattern of the environmental influence the adaptation processes can be divided into four types: phenotypic adaptations under rapidly (A) or gradually (B) alternating environmental factors, genotypic adaptations induced by an instant change (mutation) (C), and step adaptational changes (several or many mutations) (D). We propose a model based on a (second-order) linear differential equation qualitatively describing all four types of the adaptation processes.     

冲突适应的神经振荡机制

靶刺激和干扰刺激的不一致性会造成人类的行为冲突.特别地,连续的冲突情境能诱发大脑对冲突的适应.然而,目前的研究结果还不能清楚地阐释冲突适应的认知和神经机制.为了考察冲突适应的神经振荡过程,采用冲突观察实验范式,记录了15个健康成人被试在完成字母Flanker任务时的行为和脑电数据.对EEG数据进行时频分析,结果揭示了冲突适应的神经振荡机制.在观察任务中,对于不一致条件,α频带（9~13 Hz,480~980 ms）在左前额叶和中前区展现了显著的事件相关异步性（ERD）;对于一致条件,α频带在这些区域展现了显著的事件相关同步性（ERS）.在反应任务中,θ频带（6~8 Hz,50~1000 ms）的ERS在左前额叶和中前区表现为iI〈cI,反映了冲突适应.这些结果表明,冲突能诱发特定频带范围内大脑能量的调整,从而使大脑对冲突进行有效的控制.     

Molecular Mechanisms of Stress Adaptation in Plant Natural Populations

Recent advances in studies of genetic variation at protein and DNA levels in plant natural populations and its relationship with environmental changes were reviewed with special reference to the works on the wild barley ( Hordeum spontaneum C. Koch.). On one side, adaptation was shown in statistic data, on the other side, the fact that a considerable part of genetic variation does exist within populations (subpopulations) under same ecological condition indicated its maintainability of neutral or near-neutral mutations in natural populations. The researches on adaptive populations of plants, especially on wild soybean ( Glycine soja Sieb. et Zucc.) mainly conducted in author's laboratory, have shown that the most part of molecular variation within and among populations can not be explained by selection particularly as far as the individual uniqueness was concerned. There are some data shown that adaptation may be caused by accumulation of a few near-neutral mutations. Recent publications on molecular mechanisms of morphological evolution has been received special attention to elucidate the discrepancy between molecular evolution and morphological adaptive evolution. A frame on the unified evolution theory has been built. Finally some related viewpoints of philosophy were discussed.     

The Control of the Controller: Molecular Mechanisms for Robust Perfect Adaptation and Temperature Compensation

Organisms have the property to adapt to a changing environment and keep certain components within a cell regulated at the same level (homeostasis). “Perfect adaptation” describes an organism's response to an external stepwise perturbation by regulating some of its variables/components precisely to their original preperturbation values. Numerous examples of perfect adaptation/homeostasis have been found, as for example, in bacterial chemotaxis, photoreceptor responses, MAP kinase activities, or in metal-ion homeostasis. Two concepts have evolved to explain how perfect adaptation may be understood: In one approach (robust perfect adaptation), the adaptation is a network property, which is mostly, but not entirely, independent of rate constant values; in the other approach (nonrobust perfect adaptation), a fine-tuning of rate constant values is needed. Here we identify two classes of robust molecular homeostatic mechanisms, which compensate for environmental variations in a controlled variable's inflow or outflow fluxes, and allow for the presence of robust temperature compensation. These two classes of homeostatic mechanisms arise due to the fact that concentrations must have positive values. We show that the concept of integral control (or integral feedback), which leads to robust homeostasis, is associated with a control species that has to work under zero-order flux conditions and does not necessarily require the presence of a physico-chemical feedback structure. There are interesting links between the two identified classes of homeostatic mechanisms and molecular mechanisms found in mammalian iron and calcium homeostasis, indicating that homeostatic mechanisms may underlie similar molecular control structures.     

Role of Glutamate in the Mechanisms of Adaptation of the System of Respiratory Control in Rats to Intermittent Hypoxia

In experiments on Wistar rats, we studied the role of changes in the state of glutamatergic transmission in the course of adaptation of the system of respiratory control to intermittent hypoxia. The volume/temporal parameters of respiration were estimated according to characteristics of EMG activity (amplitude, integral intensity of EMG discharges) recorded from the diaphragmatic muscle. Changes in EMG activity of the diaphragm induced by acute hypoxia (breathing a 12% О₂-containing gas mixture) were estimated before and after of a 14-day-long course of intermittent hypoxia trainings and before and after inductions of a blocker of NMDA receptors, МK-801. The results prove that the glutamatergic transmitter system is significantly involved in the reaction of the respiratory system to presentation of a hypoxic stimulus within all stages of formation of the ventilatory response, both before and after the action of intermittent hypoxia. Blocking of NMDA receptors under conditions of adaptation to intermittent hypoxia exerted a more intense influence on the amplitude of respiratory EMG discharges of the diaphragm than on their frequency.     

Environmental Consistency Determines the Rate of Motor Adaptation

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Neural and Photochemical Mechanisms of Visual Adaptation in the Rat

The effects of light adaptation on the increment threshold, rhodopsin content, and dark adaptation have been studied in the rat eye over a wide range of intensities. The electroretinogram threshold was used as a measure of eye sensitivity. With adapting intensities greater than 1.5 log units above the absolute ERG threshold, the increment threshold rises linearly with increasing adapting intensity. With 5 minutes of light adaptation, the rhodopsin content of the eye is not measurably reduced until the adapting intensity is greater than 5 log units above the ERG threshold. Dark adaptation is rapid (i.e., completed in 5 to 10 minutes) until the eye is adapted to lights strong enough to bleach a measurable fraction of the rhodopsin. After brighter light adaptations, dark adaptation consists of two parts, an initial rapid phase followed by a slow component. The extent of slow adaptation depends on the fraction of rhodopsin bleached. If all the rhodopsin in the eye is bleached, the slow fall of threshold extends over 5 log units and takes 2 to 3 hours to complete. The fall of ERG threshold during the slow phase of adaptation occurs in parallel with the regeneration of rhodopsin. The slow component of dark adaptation is related to the bleaching and resynthesis of rhodopsin; the fast component of adaptation is considered to be neural adaptation.     

Motor Adaptive Remodeling Speeds Up Bacterial Chemotactic Adaptation

Bacterial chemotaxis is a canonical system for the study of signal transduction. One of the hallmarks of this system is its robust adaptive behavior. However, how fast the system adapts remains controversial. The adaptation time measured at the level of the kinase activity was tens of seconds, whereas that measured at the level of the flagellar motor was <10 s. The flagellar motor was recently shown to exhibit adaptive remodeling, its main physiological function being to provide a robust match between the chemoreceptor output and the motor input, whereas its adaptation timescale was thought to be too slow to contribute much to the overall adaptation timescale of the chemotaxis system. Here, through theoretical modeling of the motor adaptive remodeling and experimental tests, we show that this motor adaptation contributes significantly to speeding up the overall chemotactic adaptation, thereby resolving the previous inconsistency.     

深海细菌及其适压机制

深海是以高压为主要特征的极端环境。在深海中适压生活的细菌在分类上多属于蛋白细菌(Pro-teobacteria)类群的γ分支。深海细菌对高压的适应可表现为嗜压或耐压,其适压的机制包括细胞膜脂成分中不饱和脂肪酸的增加,此外,细菌细胞的呼吸链系统也与耐压有关。     

Between-Trial Forgetting Due to Interference and Time in Motor Adaptation

Learning a motor task with temporally spaced presentations or with other tasks intermixed between presentations reduces performance during training, but can enhance retention post training. These two effects are known as the spacing and contextual interference effect, respectively. Here, we aimed at testing a unifying hypothesis of the spacing and contextual interference effects in visuomotor adaptation, according to which forgetting between trials due to either spaced presentations or interference by another task will promote between-trial forgetting, which will depress performance during acquisition, but will promote retention. We first performed an experiment with three visuomotor adaptation conditions: a short inter-trial-interval (ITI) condition (SHORT-ITI); a long ITI condition (LONG-ITI); and an alternating condition with two alternated opposite tasks (ALT), with the same single-task ITI as in LONG-ITI. In the SHORT-ITI condition, there was fastest increase in performance during training and largest immediate forgetting in the retention tests. In contrast, in the ALT condition, there was slowest increase in performance during training and little immediate forgetting in the retention tests. Compared to these two conditions, in the LONG-ITI, we found intermediate increase in performance during training and intermediate immediate forgetting. To account for these results, we fitted to the data six possible adaptation models with one or two time scales, and with interference in the fast, or in the slow, or in both time scales. Model comparison confirmed that two time scales and some degree of interferences in either time scale are needed to account for our experimental results. In summary, our results suggest that retention following adaptation is modulated by the degree of between-trial forgetting, which is due to time-based decay in single adaptation task and interferences in multiple adaptation tasks.     

Motor control: Mechanisms of motor equivalence in handwriting

Handwriting is a classic example of how the details of movement can be scale and plane invariant: letter forms reflecting personal style are unchanged, whether one is writing on a piece of paper, on a blackboard or in the sand using the foot. Recent research points to a role for the parietal cortex in such motor equivalence.