Probability analysis of elements of rat behavior after sudden and signalled interruption of food reinforcement

Probability analysis was carried out of the appearance of single elements of rats behaviour in the process of extinction of a conditioned alimentary motor reflex. The dynamics of effector behavioural components at a sudden cessation of reinforcement (usual schedule of extinction) was compared with cessation of reinforcement signalled by a previously differentiated signal and with reinforcement cessation preceded by a stimulus initially unknown to the animal. If the reinforcement cessation is signalled by a previously differentiated (negative) stimulus, in response to its action the animals "loose the aim", what is revealed in a rapid complete reduction of all elements of the goal-directed alimentary behaviour. Obviously differentiation signal actualises the memory trace of "nonreinforcement" which was formed in the previous negative experience of the animal; this is revealed in accelerated inhibition of the alimentary motor reflex under extinction.     

Neurophysiological and neurotransmitter mechanisms of behavior inhibition in normal and pathological conditions

The data concerning neurophysiological and neurotransmitter mechanisms of two principal kinds of inhibition of behavior is carried out: the inborn genetically determined inhibition and that developed in the course of training. On the basis of the experiments performed by the author and the literature on general neurophysiology the conclusion is made that development of inhibition of behavior during training (i.e. internal inhibition, including "latent inhibition") is determined by the relative strengthening of inhibitory hyperpolarization processes either locally (in a conditioned stimulus analyzer) or globally in the brain cortex and other brain structures during intensification of the inhibitory state (profound inhibition of a reflex and sleep). The main neurotransmitter in development of internal inhibition is gamma-aminobutyric acid. Inhibition of behavior without preliminary training arises either during the action of superstrong stimuli, (exceeding the maximum value inhibition) or during interaction of two and more active systems. A stronger one of these two systems suppresses another one (external inhibition, dominant inhibition, "freezing", "prepulse inhibition", etc.). These kinds of inhibition develop on the background of EEG activation, which suggests participation in their realization of reticular structures and corresponding neurotransmitters (acetylcholine, noradrenalin, dopamine and serotonin). Behavior pathology causes a break of the balanced interaction between the excitation and inhibition in the central nervous system. This affects both genetically determined forms of behavior inhibition and the learned internal inhibition.     

Extinction of a passive avoidance response of mice with a depressive-like state

The analysis of a behaviour and memory of mice with depressive state is conducted. The mice with "behavioral despair" obtained by forced swimming and mice with submissive stereotype generated by 20 confrontations were used. They were characterized by increased anxiety and reduced exploratory activity in tests of the elevated plus-maze and light/dark apparatus. It is shown that for want of behavioral differences in manifestation of a depressive state the process of extinction was opposite. Mice with "behavioral despair" revealed retention of a high level of memory trace retrieval down to the 21st day of testing reflecting essential delay of extinction. Submissive mice displayed fast extinction begining with the 5th day of testing.     

Retention of memory traces in rats subjected to 10-minute clinical death procedure

Retention of memory traces was tested on the 12th day after 10-min clinical death (CD) produced by the total cessation of blood circulation in Albino rats previously trained for operant food conditioning in a multiple alternative maze. It was found that the structure of memory trace (sequence of operant actions in the maze), motivation activity and habit organization after the resuscitation were completely preserved in all rats independently of the number of the memory traces formed. Short-term negative changes were revealed only in the character of habit realization: the efficiency and reproduction parameters such as "readiness", mobilization activity, and stability of habit realization had lower values during 2-3 sessions. The rate of their recovery after the CD depended on rat's initial motivation state: the higher was the initial motivation, the faster recovered all the reproduction parameters. It is suggested that the observed negative changes in habit realization were nonspecific and were provoked by the CD-induced hyperexcitability of rats.     

Interplay between Affect and Arousal in Recognition Memory

Background

Emotional states linked to arousal and mood are known to affect the efficiency of cognitive performance. However, the extent to which memory processes may be affected by arousal, mood or their interaction is poorly understood.

Methodology/Principal Findings

Following a study phase of abstract shapes, we altered the emotional state of participants by means of exposure to music that varied in both mood and arousal dimensions, leading to four different emotional states: (i) positive mood-high arousal; (ii) positive mood-low arousal; (iii) negative mood-high arousal; (iv) negative mood-low arousal. Following the emotional induction, participants performed a memory recognition test. Critically, there was an interaction between mood and arousal on recognition performance. Memory was enhanced in the positive mood-high arousal and in the negative mood-low arousal states, relative to the other emotional conditions.

Conclusions/Significance

Neither mood nor arousal alone but their interaction appears most critical to understanding the emotional enhancement of memory.     

Proton dependence of the partial reactions of the sodium-proton exchanger in renal brush border membranes.

The pre-steady state time dependence of Na+ accumulation by the Na(+)-H+ exchanger in renal brush border membrane vesicles was investigated at 0 degree C by a manual mixing technique using amiloride to quench the reaction. Dilution of acid-loaded (pHi 5.7) vesicles into an alkaline medium (pHo 7.7) containing 1 mM 22Na+ produced a time course of amiloride-sensitive Na+ uptake that consisted of three distinct phases: 1) a lag, 2) a monoexponential "burst," and 3) a linear or steady state phase. Experiments testing for the presence of 22Na+ backflux, residual Na+ binding to the membrane, and hysteresis were negative, lending support to the hypothesis that the burst phase corresponds to Na+ translocation during the initial turnover of Na(+)-H+ exchanger. Lowering the internal pH increased the amount of na+ uptake in each of the phases without affecting the apparent burst rate, whereas lowering the external pH inhibited Na+ uptake while increasing the duration of the lag phase. The pattern of inhibition produced by external H+ was of the simple competitive type, indicating that Na+ and H+ share a common binding site. Steady state Na+ uptake showed a sigmoidal dependence on internal pH (Hill coefficient = 1.67), consistent with the presence of an internal allosteric H+ activation site. Alkaline loading conditions (pHi 7.7), which favor desaturation of the internal H+ binding sites, completely abolished Na+ uptake in the steady state. In contrast, Na+ accumulation during the burst phase was reduced to 25% of an acid-loaded (pHi 5.7) control. The persistence of the burst phase and the disappearance of steady state Na+ uptake under alkaline loading conditions suggest that recycling of the H(+)-loaded exchanger is a late event in the transport cycle that follows Na+ translocation (ping-pong mechanism) and controls the steady state rate of Na+ accumulation. Activation of the recycling step involves sequential binding of H+ to the allosteric and transport sites, thus accounting for the cooperative dependence of steady state Na+ uptake on the internal [H+].     

自传体记忆与阈下抑郁关系的神经机制研究

情绪对记忆的影响是十分重要的,记忆与情绪存在很多的相互作用,主要包括积极和消极两方面。本文从神经机制的角度论述了自传体记忆与情绪的关系,不同情绪状况的自传体记忆的大脑神经机制特征,积极情绪状况下,记忆效果比较好;但消极情绪状态下,记忆效果比较差。其次,自传体记忆是关于个人自己生活事件的记忆;阈下抑郁一般指的是具有抑郁症状,但达不到抑郁诊断标准的个体。阈下抑郁作为一种常见的消极情绪状况对于记忆的影响也是很明显的,尤其是对于自传体记忆的干扰具有明显的情绪一致性效应,既消极情感的视角看待所有的自传体记忆。本文重点分析了阈下抑郁对自传体记忆影响的神经机制,包括脑成像、脑损伤以及临床研究方面的研究现状。最后对相关研究的不足和未来的展望做出了述评。     

An algebraic model of an associative noise-like coding memory

A mathematical model of an associative memory is presented, sharing with the optical holography memory systems the properties which establish an analogy with biological memory. This memory system-developed from Gabor's model of memoryis based on a noise-like coding of the information by which it realizes a distributed, damage-tolerant, equipotential storage through simultaneous state changes of discrete substratum elements. Each two associated items being stored are coded by each other by means of two noise-like patterns obtained from them through a randomizing preprocessing. The algebraic braic transformations operating the information storage and retrieval are matrix-vector products involving Toeplitz type matrices. Several noise-like coded memory traces are superimposed on a common substratum without crosstalk interference; moreover, extraneous noise added to these memory traces does not injure the stored information. The main performances shown by this memory model are: i) the selective, complete recovering of stored information from incomplete keys, both mixed with extraneous information and translated from the position learnt; ii) a dynamic recollection where the information just recovered acts as a new key for a sequential retrieval process; iii) context-dependent responses. The hypothesis that the information is stored in the nervous system through a noise-like coding is suggested. The model has been simulated on a digital computer using bidimensional images.     

Influence of body mass, age, and maturation on specific oxygen consumption in a freshwater cichlid fish, Cichlasoma nigrofasciatum (Günther, 1869)

The oxygen consumption of a freshwater convict cichlid (Cichlasoma nigrofasciatum) was determined throughout the fish development from age 74 days to 403 days, covering the period before and after maturation. The specific oxygen consumption decreases with increasing age. The decrease in metabolic rate appears rather in distinct phases. A small increase in the average specific metabolic rate (mainly from the bigger fish) around age 200 days suggests an involvement of internal changes in the fish during a transition period from "young" state to "mature" state. The relationship between the specific oxygen consumption and body mass is determined by maturation and age. Before reaching maturation (before age 200 days) the correlation between specific oxygen consumption and body mass is negative for "young" fish of the same age. After age 200 days, no correlation between both parameters could be found. We suggest from this study that both factors "age" and "size" of the organism have to be considered for determining the metabolism, especially in fish. This study indicates that even in fish, which retain a continuous growing capability until they die, the decrease in the specific oxygen consumption is related to the aging process.     

Synaptic mechanisms underlying pheromonal memory in vomeronasal system

When female mice are mated, they form a memory of the pheromonal signal of the male with which they mated. Our research objective was to determine the neural mechanisms underlying learning and memory by employing a convenient model of pheromone-induced olfactory memory (pheromonal memory). Formation of pheromonal memory depends on the association between mating and exposure to pheromones. Synaptic plasticity involving this memory occurs in the accessory olfactory bulb (AOB), depending on vaginocervical stimulation at mating. The vaginocervical stimulation at mating reduces the dendrodendritic feedback inhibition of principal neurons (mitral/tufted (MT) cells) in the AOB and enhances their cell activity. The enhancement of activity induces on these plastic changes in dendrodendritic synapses, which in turn enhance GABA-mediated inhibition of MT cell activity. This "self-inhibition" of MT cells activity in response to pheromonal signals of the partner can disrupt its signals at the AOB thereby preventing the signals from reaching the central brain. The formation and maintenance of pheromonal memory is based on this inhibition mechanism.     

Block of sodium channels by internal mono- and divalent guanidinium analogues. Modulation by sodium ion concentration.

We have investigated the block of squid axon sodium channels by mono- and divalent guanidinium analogues. The action of these compounds on steady state sodium currents was independent of the presence or absence of the normal inactivation process. Block by both mono- and divalent analogues was voltage-dependent, but was a steeper function of potential for divalent molecules. The voltage-dependence could not, in general, be reproduced by a simple model based on Boltzmann's equation. Inhibition of steady state currents by guanidinium ions with 50 mM internal sodium was reasonably well described by a 1:1 drug/channel binding function. Increasing the internal sodium ion concentration increased both the degree and voltage-dependence of current inhibition. This is in sharp contrast to the decrease in inactivation caused by internal sodium. Changes in the external sodium concentration had very little effect on drug block. These results are consistent with a model of the sodium channel as a multi-ion pore. Only a small increase in block can be produced by increased internal sodium in a three-barrier two-site model, but a four-barrier three-site model can reproduce these experimental findings. The implications of these results for physical models of inactivation are discussed.     

Contribution of GABA receptors in extinction of memory trace in norm and depressive-like state

The dependence of activation and blockade of GABA receptors influences on extinction of passive avoidance response from a type of receptors and initial psychoemotional state of mice is shown. The activation of GABAA receptors by muscimol disrupted extinction in norm and did not influence on delay of this process at mice with "behavioral despair". The activation of GABAB receptors by baclofen accelerated extinction of fair memory at mice with depressive-like state. The blockade of GABAA receptors by bicuculline was ineffective in modification of extinction. The blockade of GABAB receptors by phaclofen promoted retention of fear expression at intact mice and facilitation of extinction at "depressive" mice.     

Affective State Influences Retrieval-Induced Forgetting for Integrated Knowledge

Background

Selectively testing parts of learned materials can impair later memory for nontested materials. Research has shown that such retrieval-induced forgetting occurs for low-integrated materials but may be prevented for high-integrated materials. However, previous research has neglected one factor that is ubiquitous in real-life testing: affective state.

Methodology/Principal Findings

We investigated whether affect influences the resistance of integrated materials to retrieval-induced forgetting by inducing neutral, positive, or negative affect immediately before selectively testing previously learned textbook passages containing interrelated facts and concepts. As negative affect is known to promote a detail-oriented local processing style, we hypothesized that experiencing negative affect during testing may decrease the protective effects of integration and lead to reoccurrence of forgetting. By contrast, as positive affect is known to promote a relation-oriented global processing style, we hypothesized that experiencing positive affect may support effects of integration and prevent forgetting. Our findings are consistent with these predictions. No subsequent forgetting occurred when testing memories for integrated text materials in affectively neutral and positive states, whereas forgetting occurred when testing in negative states. A correlation analysis showed that forgetting decreased with higher positive affect, with participants experiencing high positive affect even showing facilitation instead of forgetting.

Conclusions/Significance

These findings indicate that affect can moderate the memory consequences of test taking and suggest that educators should use testing as a tool to improve memory with care.     

Cognitive Behavioral Performance of Untreated Depressed Patients with Mild Depressive Symptoms

This study evaluated the working memory performance of 18 patients experiencing their first onset of mild depression without treatment and 18 healthy matched controls. The results demonstrated that working memory impairment in patients with mild depression occurred when memorizing the position of a picture but not when memorizing the pictures themselves. There was no significant difference between the two groups in the emotional impact on the working memory, indicating that the attenuation of spatial working memory was not affected by negative emotion; however, cognitive control selectively affected spatial working memory. In addition, the accuracy of spatial working memory in the depressed patients was not significantly reduced, but the reaction time was significantly extended compared with the healthy controls. This finding indicated that there was no damage to memory encoding and function maintenance in the patients but rather only impaired memory retrieval, suggesting that the extent of damage to the working memory system and cognitive control abilities was associated with the corresponding depressive symptoms. The development of mild to severe depressive symptoms may be accompanied by spatial working memory damage from the impaired memory retrieval function extending to memory encoding and memory retention impairments. In addition, the impaired cognitive control began with an inadequate capacity to automatically process internal negative emotions and further extended to impairment of the ability to regulate and suppress external emotions. The results of the mood-congruent study showed that the memory of patients with mild symptoms of depression was associated with a mood-congruent memory effect, demonstrating that mood-congruent memory was a typical feature of depression, regardless of the severity of depression. This study provided important information for understanding the development of cognitive dysfunction.     

Selective attention and memory: evoked potentials in visual and auditory verbal competition

The brain mechanisms of the selective verbal attention were studied using evoked potential (EP) technique. It was shown that the late "cognitive" EP components (400-800 ms) related to memory function were more positive to the words presented via a relevant sensory channel and more negative to irrelevant words. The hypothesis is advanced that words delivered via two competing sensory channels, such as visual and auditory, are perceived, i.e., the subject sees and hears them. However, irrelevant signals are not stored in episodic memory due to the active inhibition of the information transmission to the hippocampal structures.     

A Model of Visuospatial Working Memory in Prefrontal Cortex: Recurrent Network and Cellular Bistability

We report a computer simulation of the visuospatial delayed-response experiments of Funahashi et al. (1989), using a firing-rate model that combines intrinsic cellular bistability with the recurrent local network architecture of the neocortex. In our model, the visuospatial working memory is stored in the form of a continuum of network activity profiles that coexist with a spontaneous activity state. These neuronal firing patterns provide a population code for the cue position in a graded manner. We show that neuronal persistent activity and tuning curves of delay-period activity (memory fields) can be generated by an excitatory feedback circuit and recurrent synaptic inhibition. However, if the memory fields are constructed solely by network mechanisms, noise may induce a random drift over time in the encoded cue position, so that the working memory storage becomes unreliable. Furthermore, a distraction stimulus presented during the delay period produces a systematic shift in the encoded cue position. We found that the working memory performance can be rendered robust against noise and distraction stimuli if single neurons are endowed with cellular bistability (presumably due to intrinsic ion channel mechanisms) that is conditional and realized only with sustained synaptic inputs from the recurrent network. We discuss how cellular bistability at the single cell level may be detected by analysis of spike trains recorded during delay-period activity and how local modulation of intrinsic cell properties and/or synaptic transmission can alter the memory fields of individual neurons in the prefrontal cortex.     

Lymphoma models for B-cell activation and tolerance. VII. Pathways in anti-Ig-mediated growth inhibition and its reversal

WEHI-231, CH33, and CH31 are B-cell lymphomas that are inhibited in their growth by crosslinking of surface Ig receptors during early G1. This "negative signaling" process can be prevented or reversed under certain conditions. In the present paper, we use a cell synchronization procedure to demonstrate that activation of protein kinase C (PKC) is not involved in the negative signal for growth, but rather that PKC activation prevents growth inhibition when present early in the cell cycle. Indeed, the prevention of negative signaling is only accomplished by active phorbol esters. Moreover, phorbol esters and a calcium ionophore fail to deliver a negative signal under conditions in which anti-Ig can significantly prevent cell cycle progression into S phase, thereby ruling out synergy between PKC and calcium in growth inhibition. Whether phorbol esters reverse negative signaling by preventing internalization of the immune complex or phosphorylation of a critical intracellular protein is discussed.     

Inhibition of pre-mRNA splicing by antisense RNA in vitro: effect of RNA containing sequences complementary to introns

The objective of the experiments described in this paper was to test the potential of antisense RNAs complementary to the internal portion of an intron to inhibit the splicing process and to determine the mechanism of such inhibition. The results obtained indicate that RNA fragments complementary to the internal portion of an intron can effectively inhibit the splicing of pre-mRNA. Inhibition was observed only with antisense RNA complementary to pre-mRNA suggesting that the inhibitory effect was due to the formation of a hybrid with the corresponding portion of the pre-mRNA's intron. The observed inhibition was not due to interference with possible intron elements essential for the splicing process, for the deletion of the sequences complementary to inhibitory antisense RNA from the corresponding pre-mRNA molecule did not affect the efficiency of a splicing reaction, and the addition of antisense RNA to pre-mRNA mutants carrying such deletions did not result in any inhibition. Our results indicate that the observed inhibition is a function of the length of the antisense RNA expressed as a fraction of an intron with which it interacts when antisense RNA is modified by incorporation of a "hinge" element, it loses its inhibitory potential suggesting that the inhibitory effect is probably due to limitation of conformational flexibility of an intron.