Your search keyword '"SYSBIO"' showing total 191 results

1. The Glycerophospho Metabolome and Its Influence on Amino Acid Homeostasis Revealed by Brain Metabolomics of GDE1(−/−) Mice

Author

Kopp, Florian, Komatsu, Toru, Nomura, Daniel K., Trauger, Sunia A., Thomas, Jason R., Siuzdak, Gary, Simon, Gabriel M., and Cravatt, Benjamin F.

Subjects

*METABOLITES, *HOMEOSTASIS, *AMINO acids, *LABORATORY mice, *BRAIN, *EUKARYOTIC cells

Abstract

Summary: GDE1 is a mammalian glycerophosphodiesterase (GDE) implicated by in vitro studies in the regulation of glycerophophoinositol (GroPIns) and possibly other glycerophospho (GroP) metabolites. Here, we show using untargeted metabolomics that GroPIns is profoundly (>20-fold) elevated in brain tissue from GDE1(−/−) mice. Furthermore, two additional GroP metabolites not previously identified in eukaryotic cells, glycerophosphoserine (GroPSer) and glycerophosphoglycerate (GroPGate), were also highly elevated in GDE1(−/−) brains. Enzyme assays with synthetic GroP metabolites confirmed that GroPSer and GroPGate are direct substrates of GDE1. Interestingly, our metabolomic profiles also revealed that serine (both L-and D-) levels were significantly reduced in brains of GDE1(−/−) mice. These findings designate GroPSer as a previously unappreciated reservoir for free serine in the nervous system and suggest that GDE1, through recycling serine from GroPSer, may impact D-serine-dependent neural signaling processes in vivo. [ABSTRACT FROM AUTHOR]

Published

2010

2. A Conserved Switch in Sensory Processing Prepares Developing Neocortex for Vision

Author

Colonnese, Matthew T., Kaminska, Anna, Minlebaev, Marat, Milh, Mathieu, Bloem, Bernard, Lescure, Sandra, Moriette, Guy, Chiron, Catherine, Ben-Ari, Yehezkel, and Khazipov, Rustem

Subjects

*SENSORY neurons, *NEOCORTEX, *VISUAL cortex, *BIOLOGICAL neural networks, *LABORATORY rodents, *MATURATION (Psychology), *RETINAL (Visual pigment)

Abstract

Summary: Developing cortex generates endogenous activity that modulates the formation of functional units, but how this activity is altered to support mature function is poorly understood. Using recordings from the visual cortex of preterm human infants and neonatal rats, we report a “bursting” period of visual responsiveness during which the weak retinal output is amplified by endogenous network oscillations, enabling a primitive form of vision. This period ends shortly before delivery in humans and eye opening in rodents with an abrupt switch to the mature visual response. The switch is causally linked to the emergence of an activated state of continuous cortical activity dependent on the ascending neuromodulatory systems involved in arousal. This switch is sensory system specific but experience independent and also involves maturation of retinal processing. Thus, the early development of visual processing is governed by a conserved, intrinsic program that switches thalamocortical response properties in anticipation of patterned vision. [ABSTRACT FROM AUTHOR]

Published

2010

3. Oscillations and Filtering Networks Support Flexible Routing of Information

Author

Akam, Thomas and Kullmann, Dimitri M.

Subjects

*OSCILLATIONS, *BIOLOGICAL neural networks, *CELLULAR signal transduction, *HUMAN information processing, *NEURAL circuitry, *INTERNEURONS

Abstract

Summary: The mammalian brain exhibits profuse interregional connectivity. How information flow is rapidly and flexibly switched among connected areas remains poorly understood. Task-dependent changes in the power and interregion coherence of network oscillations suggest that such oscillations play a role in signal routing. We show that switching one of several convergent pathways from an asynchronous to an oscillatory state allows accurate selective transmission of population-coded information, which can be extracted even when other convergent pathways fire asynchronously at comparable rates. We further show that the band-pass filtering required to perform this information extraction can be implemented in a simple spiking network model with a single feed-forward interneuron layer. This constitutes a mechanism for flexible signal routing in neural circuits, which exploits sparsely synchronized network oscillations and temporal filtering by feed-forward inhibition. Video Abstract: Display Omitted [ABSTRACT FROM AUTHOR]

Published

2010

4. A Parcellation Scheme for Human Left Lateral Parietal Cortex

Author

Nelson, Steven M., Cohen, Alexander L., Power, Jonathan D., Wig, Gagan S., Miezin, Francis M., Wheeler, Mark E., Velanova, Katerina, Donaldson, David I., Phillips, Jeffrey S., Schlaggar, Bradley L., and Petersen, Steven E.

Subjects

*PARIETAL lobe, *BRAIN imaging, *BRAIN mapping, *MEMORY, *MAGNETIC resonance imaging of the brain, *BIOLOGICAL neural networks

Abstract

Summary: The parietal lobe has long been viewed as a collection of architectonic and functional subdivisions. Though much parietal research has focused on mechanisms of visuospatial attention and control-related processes, more recent functional neuroimaging studies of memory retrieval have reported greater activity in left lateral parietal cortex (LLPC) when items are correctly identified as previously studied (“old”) versus unstudied (“new”). These studies have suggested functional divisions within LLPC that may provide distinct contributions toward recognition memory judgments. Here, we define regions within LLPC by developing a parcellation scheme that integrates data from resting-state functional connectivity MRI and functional MRI. This combined approach results in a 6-fold parcellation of LLPC based on the presence (or absence) of memory-retrieval-related activity, dissociations in the profile of task-evoked time courses, and membership in large-scale brain networks. This parcellation should serve as a roadmap for future investigations aimed at understanding LLPC function. [Copyright &y& Elsevier]

Published

2010

5. Adaptation to Stimulus Statistics in the Perception and Neural Representation of Auditory Space

Author

Dahmen, Johannes C., Keating, Peter, Nodal, Fernando R., Schulz, Andreas L., and King, Andrew J.

Subjects

*PHYSIOLOGICAL adaptation, *AUDITORY perception, *BIOLOGICAL neural networks, *INTERNEURONS, *GAUSSIAN distribution, *SPATIAL behavior, *CELLULAR signal transduction

Abstract

Summary: Sensory systems are known to adapt their coding strategies to the statistics of their environment, but little is still known about the perceptual implications of such adjustments. We investigated how auditory spatial processing adapts to stimulus statistics by presenting human listeners and anesthetized ferrets with noise sequences in which interaural level differences (ILD) rapidly fluctuated according to a Gaussian distribution. The mean of the distribution biased the perceived laterality of a subsequent stimulus, whereas the distribution''s variance changed the listeners'' spatial sensitivity. The responses of neurons in the inferior colliculus changed in line with these perceptual phenomena. Their ILD preference adjusted to match the stimulus distribution mean, resulting in large shifts in rate-ILD functions, while their gain adapted to the stimulus variance, producing pronounced changes in neural sensitivity. Our findings suggest that processing of auditory space is geared toward emphasizing relative spatial differences rather than the accurate representation of absolute position. [Copyright &y& Elsevier]

Published

2010

6. Multimodal Integration in Granule Cells as a Basis for Associative Plasticity and Sensory Prediction in a Cerebellum-like Circuit

Author

Sawtell, Nathaniel B.

Subjects

*SENSORIMOTOR integration, *NEURAL physiology, *NEUROPLASTICITY, *CEREBELLUM, *NEURAL circuitry, *PURKINJE cells

Abstract

Summary: The recoding of diverse sensory and motor signals by granule cells (GCs) is probably critical for the function of cerebellar circuits, yet the nature of these transformations and their significance for cerebellar information processing remain poorly understood. In cerebellum-like structures in fish, anti-Hebbian plasticity at parallel fiber synapses generates “negative images” that act to cancel predictable patterns of electrosensory input. Here I test the hypothesis that GCs enhance the capacity of Purkinje-like cells to generate specific negative images by selectively encoding combinations of sensory and motor signals. Using in vivo whole-cell recordings, I show (1) that a subset of GCs integrate sensory and motor signals conveyed by distinct mossy fiber classes and (2) that Purkinje-like cells exhibit plastic changes specific to the combinations of signals that individual GCs encode. Consistent with influential theories of cerebellar function, these findings suggest that selective GC output enhances the capacity of Purkinje-like cells to acquire selectivity through associative plasticity. [Copyright &y& Elsevier]

Published

2010

7. The Temporal Structures and Functional Significance of Scale-free Brain Activity

Author

He, Biyu J., Zempel, John M., Snyder, Abraham Z., and Raichle, Marcus E.

Subjects

*BRAIN physiology, *ELECTROPHYSIOLOGY, *BRAIN function localization, *TASK performance, *VISUAL cortex, *COGNITION

Abstract

Summary: Scale-free dynamics, with a power spectrum following P ∝f −β, are an intrinsic feature of many complex processes in nature. In neural systems, scale-free activity is often neglected in electrophysiological research. Here, we investigate scale-free dynamics in human brain and show that it contains extensive nested frequencies, with the phase of lower frequencies modulating the amplitude of higher frequencies in an upward progression across the frequency spectrum. The functional significance of scale-free brain activity is indicated by task performance modulation and regional variation, with β being larger in default network and visual cortex and smaller in hippocampus and cerebellum. The precise patterns of nested frequencies in the brain differ from other scale-free dynamics in nature, such as earth seismic waves and stock market fluctuations, suggesting system-specific generative mechanisms. Our findings reveal robust temporal structures and behavioral significance of scale-free brain activity and should motivate future study on its physiological mechanisms and cognitive implications. [Copyright &y& Elsevier]

Published

2010

8. Divisive Normalization in Olfactory Population Codes

Author

Olsen, Shawn R., Bhandawat, Vikas, and Wilson, Rachel I.

Subjects

*NEURAL physiology, *EYE, *OLFACTORY receptors, *CELLULAR signal transduction, *DROSOPHILA, *CELL populations

Abstract

Summary: In many regions of the visual system, the activity of a neuron is normalized by the activity of other neurons in the same region. Here we show that a similar normalization occurs during olfactory processing in the Drosophila antennal lobe. We exploit the orderly anatomy of this circuit to independently manipulate feedforward and lateral input to second-order projection neurons (PNs). Lateral inhibition increases the level of feedforward input needed to drive PNs to saturation, and this normalization scales with the total activity of the olfactory receptor neuron (ORN) population. Increasing total ORN activity also makes PN responses more transient. Strikingly, a model with just two variables (feedforward and total ORN activity) accurately predicts PN odor responses. Finally, we show that discrimination by a linear decoder is facilitated by two complementary transformations: the saturating transformation intrinsic to each processing channel boosts weak signals, while normalization helps equalize responses to different stimuli. Video Abstract: Display Omitted [Copyright &y& Elsevier]

Published

2010

9. Preceding Inhibition Silences Layer 6 Neurons in Auditory Cortex

Author

Zhou, Yi, Liu, Bao-hua, Wu, Guangying K., Kim, Young-Joo, Xiao, Zhongju, Tao, Huizhong W., and Zhang, Li I.

Subjects

*NEURONS, *AUDITORY cortex, *NEURAL circuitry, *NEURAL transmission, *LABORATORY rats, *SILENCE

Abstract

Summary: A canonical feedforward circuit is proposed to underlie sensory cortical responses with balanced excitation and inhibition in layer 4 (L4). However, in another input layer, L6, sensory responses and the underlying synaptic circuits remain largely unclear. Here, cell-attached recordings in rat primary auditory cortex revealed that for the majority of L6 excitatory neurons, tonal stimuli did not drive spike responses, but suppressed spontaneous firings. Whole-cell recordings further revealed that the silencing resulted from tone-evoked strong inhibition arriving earlier than excitation. This pattern of inputs can be attributed to a parallel feedforward circuit with both excitatory and inhibitory inputs disynaptically relayed. In contrast, in the other neurons directly driven by thalamic input, stimuli evoked excitation preceding relatively weak inhibition, resulting in robust spike responses. Thus, the dichotomy of L6 response properties arises from two distinct patterns of excitatory-inhibitory interplay. The parallel circuit module generating preceding inhibition may provide a gating mechanism for conditional corticothalamic feedback. [Copyright &y& Elsevier]

Published

2010

10. Spike-Time-Dependent Plasticity and Heterosynaptic Competition Organize Networks to Produce Long Scale-Free Sequences of Neural Activity

Author

Fiete, Ila R., Senn, Walter, Wang, Claude Z.H., and Hahnloser, Richard H.R.

Subjects

*NEUROPLASTICITY, *NEURAL transmission, *BIOLOGICAL neural networks, *NEURONS, *CELLULAR signal transduction, *COGNITION

Abstract

Summary: Sequential neural activity patterns are as ubiquitous as the outputs they drive, which include motor gestures and sequential cognitive processes. Neural sequences are long, compared to the activation durations of participating neurons, and sequence coding is sparse. Numerous studies demonstrate that spike-time-dependent plasticity (STDP), the primary known mechanism for temporal order learning in neurons, cannot organize networks to generate long sequences, raising the question of how such networks are formed. We show that heterosynaptic competition within single neurons, when combined with STDP, organizes networks to generate long unary activity sequences even without sequential training inputs. The network produces a diversity of sequences with a power law length distribution and exponent −1, independent of cellular time constants. We show evidence for a similar distribution of sequence lengths in the recorded premotor song activity of songbirds. These results suggest that neural sequences may be shaped by synaptic constraints and network circuitry rather than cellular time constants. [Copyright &y& Elsevier]

Published

2010

11. Discrimination of Vibrotactile Stimuli in the Rat Whisker System: Behavior and Neurometrics

Author

Gerdjikov, Todor V., Bergner, Caroline G., Stüttgen, Maik C., Waiblinger, Christian, and Schwarz, Cornelius

Subjects

*BRAIN stimulation, *WHISKERS, *LABORATORY rats, *RAT behavior, *NEURONS, *RETINAL ganglion cells, *CELLULAR signal transduction, *PSYCHOPHYSICS

Abstract

Summary: Understanding the neural code underlying perception requires the mapping of physical stimulus parameters to both psychophysical decisions and neuronal responses. Here, we employed a novel psychophysical task in head-fixed rats to measure discriminability of vibrotactile whisker deflections. Rats could discriminate 90 Hz from 60 Hz pulsatile stimuli if stimulus intensity covaried with frequency. To pin down the physical parameters used by the rats to discriminate these vibrations, we manipulated stimulus amplitude to arrive at pairs of nondiscriminable stimuli. We found that vibrations matched in intensity (measured as mean absolute velocity), but differing in frequency, were no longer discriminable. Recordings of trigeminal ganglion neurons revealed that the distribution of neurometric sensitivities based on spike counts, but not interspike intervals, matched the rats'' inability to discriminate intensity-matched stimuli. In conclusion, we suggest that stimulus mean absolute velocity, encoded in primary afferent spike counts, plays a prominent role for whisker-mediated perception. [Copyright &y& Elsevier]

Published

2010

12. Nonoverlapping Sets of Synapses Drive On Responses and Off Responses in Auditory Cortex

Author

Scholl, Ben, Gao, Xiang, and Wehr, Michael

Subjects

*SYNAPSES, *AUDITORY cortex physiology, *NEURAL physiology, *NEURAL circuitry, *NEUROBIOLOGY, *SENSORY neurons

Abstract

Summary: Neurons in visual, somatosensory, and auditory cortex can respond to the termination as well as the onset of a sensory stimulus. In auditory cortex, these off responses may underlie the ability of the auditory system to use sound offsets as cues for perceptual grouping. Off responses have been widely proposed to arise from postinhibitory rebound, but this hypothesis has never been directly tested. We used in vivo whole-cell recordings to measure the synaptic inhibition evoked by sound onset. We find that inhibition is invariably transient, indicating that off responses are not caused by postinhibitory rebound in auditory cortical neurons. Instead, on and off responses appear to be driven by distinct sets of synapses, because they have distinct frequency tuning and different excitatory-inhibitory balance. Furthermore, an on-on sequence causes complete forward suppression, whereas an off-on sequence causes no suppression at all. We conclude that on and off responses are driven by largely nonoverlapping sets of synaptic inputs. [Copyright &y& Elsevier]

Published

2010

13. Imaging the Human Medial Temporal Lobe with High-Resolution fMRI

Author

Carr, Valerie A., Rissman, Jesse, and Wagner, Anthony D.

Subjects

*TEMPORAL lobe, *MAGNETIC resonance imaging, *HIPPOCAMPUS (Brain), *NEURAL circuitry, *CELLULAR signal transduction, *NEUROPHYSIOLOGY

Abstract

High-resolution functional MRI (hr-fMRI) affords unique leverage on the functional properties of human medial temporal lobe (MTL) substructures. We review initial hr-fMRI efforts to delineate (1) encoding and retrieval processes within the hippocampal circuit, (2) hippocampal subfield contributions to pattern separation and pattern completion, and (3) the representational capabilities of distinct MTL subregions. Extant data reveal functional heterogeneity within human MTL and highlight the promise of hr-fMRI for bridging human, animal, and computational approaches to understanding MTL function. [Copyright &y& Elsevier]

Published

2010

14. Synaptic and Network Mechanisms of Sparse and Reliable Visual Cortical Activity during Nonclassical Receptive Field Stimulation

Author

Haider, Bilal, Krause, Matthew R., Duque, Alvaro, Yu, Yuguo, Touryan, Jonathan, Mazer, James A., and McCormick, David A.

Subjects

*VISUAL fields, *VISUAL perception, *PYRAMIDAL tract, *VISUAL cortex, *NEURAL circuitry

Abstract

Summary: During natural vision, the entire visual field is stimulated by images rich in spatiotemporal structure. Although many visual system studies restrict stimuli to the classical receptive field (CRF), it is known that costimulation of the CRF and the surrounding nonclassical receptive field (nCRF) increases neuronal response sparseness. The cellular and network mechanisms underlying increased response sparseness remain largely unexplored. Here we show that combined CRF + nCRF stimulation increases the sparseness, reliability, and precision of spiking and membrane potential responses in classical regular spiking (RSC) pyramidal neurons of cat primary visual cortex. Conversely, fast-spiking interneurons exhibit increased activity and decreased selectivity during CRF + nCRF stimulation. The increased sparseness and reliability of RSC neuron spiking is associated with increased inhibitory barrages and narrower visually evoked synaptic potentials. Our experimental observations were replicated with a simple computational model, suggesting that network interactions among neuronal subtypes ultimately sharpen recurrent excitation, producing specific and reliable visual responses. [Copyright &y& Elsevier]

Published

2010

15. Rewarded Outcomes Enhance Reactivation of Experience in the Hippocampus

Author

Singer, Annabelle C. and Frank, Loren M.

Subjects

*HIPPOCAMPUS (Brain), *REWARD (Psychology), *LABORATORY rats, *BRAIN function localization, *PHYSIOLOGICAL aspects of memory, *BRAIN physiology

Abstract

Summary: Remembering experiences that lead to reward is essential for survival. The hippocampus is required for forming and storing memories of events and places, but the mechanisms that associate specific experiences with rewarding outcomes are not understood. Event memory storage is thought to depend on the reactivation of previous experiences during hippocampal sharp wave ripples (SWRs). We used a sequence switching task that allowed us to examine the interaction between SWRs and reward. We compared SWR activity after animals traversed spatial trajectories and either received or did not receive a reward. Here, we show that rat hippocampal CA3 principal cells are significantly more active during SWRs following receipt of reward. This SWR activity was further enhanced during learning and reactivated coherent elements of the paths associated with the reward location. This enhanced reactivation in response to reward could be a mechanism to bind rewarding outcomes to the experiences that precede them. [Copyright &y& Elsevier]

Published

2009

16. The Neural Circuitry of a Broken Promise

Author

Baumgartner, Thomas, Fischbacher, Urs, Feierabend, Anja, Lutz, Kai, and Fehr, Ernst

Subjects

*NEURAL circuitry, *PROMISES, *NEUROPSYCHOLOGY, *BRAIN function localization, *AMYGDALOID body, *BIOLOGICAL neural networks, *FRONTAL lobe, *BRAIN physiology

Abstract

Summary: Promises are one of the oldest human-specific psychological mechanisms fostering cooperation and trust. Here, we study the neural underpinnings of promise keeping and promise breaking. Subjects first make a promise decision (promise stage), then they anticipate whether the promise affects the interaction partner''s decision (anticipation stage) and are subsequently free to keep or break the promise (decision stage). Findings revealed that the breaking of the promise is associated with increased activation in the DLPFC, ACC, and amygdala, suggesting that the dishonest act involves an emotional conflict due to the suppression of the honest response. Moreover, the breach of the promise can be predicted by a perfidious brain activity pattern (anterior insula, ACC, inferior frontal gyrus) during the promise and anticipation stage, indicating that brain measurements may reveal malevolent intentions before dishonest or deceitful acts are actually committed. [Copyright &y& Elsevier]

Published

2009

17. Using a Compound Gain Field to Compute a Reach Plan

Author

Chang, Steve W.C., Papadimitriou, Charalampos, and Snyder, Lawrence H.

Subjects

*NEURAL physiology, *EYE-hand coordination, *BRAIN function localization, *PARIETAL lobe, *BIOLOGICAL neural networks, *GAZE, *NEURAL circuitry

Abstract

Summary: A gain field, the scaling of a tuned neuronal response by a postural signal, may help support neuronal computation. Here, we characterize eye and hand position gain fields in the parietal reach region (PRR). Eye and hand gain fields in individual PRR neurons are similar in magnitude but opposite in sign to one another. This systematic arrangement produces a compound gain field that is proportional to the distance between gaze location and initial hand position. As a result, the visual response to a target for an upcoming reach is scaled by the initial gaze-to-hand distance. Such a scaling is similar to what would be predicted in a neural network that mediates between eye- and hand-centered representations of target location. This systematic arrangement supports a role of PRR in visually guided reaching and provides strong evidence that gain fields are used for neural computations. [Copyright &y& Elsevier]

Published

2009

18. Primitives for Motor Adaptation Reflect Correlated Neural Tuning to Position and Velocity

Author

Sing, Gary C., Joiner, Wilsaan M., Nanayakkara, Thrishantha, Brayanov, Jordan B., and Smith, Maurice A.

Subjects

*MOTOR cortex, *PHYSIOLOGICAL adaptation, *NEURAL physiology, *BRAIN function localization, *BODY movement, *NEURAL stimulation

Abstract

Summary: The motor commands required to control voluntary movements under various environmental conditions may be formed by adaptively combining a fixed set of motor primitives. Since this motor output must contend with state-dependent physical dynamics during movement, these primitives are thought to depend on the position and velocity of motion. Using a recently developed “error-clamp” technique, we measured the fine temporal structure of changes in motor output during adaptation. Interestingly, these measurements reveal that motor primitives echo a key feature of the neural coding of limb motion—correlated tuning to position and velocity. We show that this correlated tuning explains why initial stages of motor learning are often rapid and stereotyped, whereas later stages are slower and stimulus specific. With our new understanding of these primitives, we design dynamic environments that are intrinsically the easiest or most difficult to learn, suggesting a theoretical basis for the rational design of improved procedures for motor training and rehabilitation. [Copyright &y& Elsevier]

Published

2009

19. Temperature Entrainment of Drosophila's Circadian Clock Involves the Gene nocte and Signaling from Peripheral Sensory Tissues to the Brain

Author

Sehadova, Hana, Glaser, Franz T., Gentile, Carla, Simoni, Alekos, Giesecke, Astrid, Albert, Joerg T., and Stanewsky, Ralf

Subjects

*MECHANORECEPTORS, *DROSOPHILA, *CIRCADIAN rhythms, *LUCIFERASES, *NEURONS, *BRAIN

Abstract

Summary: Circadian clocks are synchronized by the natural day/night and temperature cycles. Our previous work demonstrated that synchronization by temperature is a tissue autonomous process, similar to synchronization by light. We show here that this is indeed the case, with the important exception of the brain. Using luciferase imaging we demonstrate that brain clock neurons depend on signals from peripheral tissues in order to be synchronized by temperature. Reducing the function of the gene nocte in chordotonal organs changes their structure and function and dramatically interferes with temperature synchronization of behavioral activity. Other mutants known to affect the function of these sensory organs also interfere with temperature synchronization, demonstrating the importance of nocte in this process and identifying the chordotonal organs as relevant sensory structures. Our work reveals surprising and important mechanistic differences between light- and temperature-synchronization and advances our understanding of how clock resetting is accomplished in nature. [Copyright &y& Elsevier]

Published

2009

20. Cortical Firing and Sleep Homeostasis

Author

Vyazovskiy, Vladyslav V., Olcese, Umberto, Lazimy, Yaniv M., Faraguna, Ugo, Esser, Steve K., Williams, Justin C., Cirelli, Chiara, and Tononi, Giulio

Subjects

*SLEEP-wake cycle, *HOMEOSTASIS, *CEREBRAL cortex, *WAKEFULNESS, *NEURAL stem cells, *INTERNEURONS, *CENTRAL nervous system

Abstract

Summary: The need to sleep grows with the duration of wakefulness and dissipates with time spent asleep, a process called sleep homeostasis. What are the consequences of staying awake on brain cells, and why is sleep needed? Surprisingly, we do not know whether the firing of cortical neurons is affected by how long an animal has been awake or asleep. Here, we found that after sustained wakefulness cortical neurons fire at higher frequencies in all behavioral states. During early NREM sleep after sustained wakefulness, periods of population activity (ON) are short, frequent, and associated with synchronous firing, while periods of neuronal silence are long and frequent. After sustained sleep, firing rates and synchrony decrease, while the duration of ON periods increases. Changes in firing patterns in NREM sleep correlate with changes in slow-wave activity, a marker of sleep homeostasis. Thus, the systematic increase of firing during wakefulness is counterbalanced by staying asleep. [Copyright &y& Elsevier]

Published

2009

21. Spatial Attention Decorrelates Intrinsic Activity Fluctuations in Macaque Area V4

Author

Mitchell, Jude F., Sundberg, Kristy A., and Reynolds, John H.

Subjects

*ATTENTION, *CENTRAL nervous system, *CEREBRAL cortex, *NEUROTRANSMITTER receptors, *SPATIAL behavior, *CELLULAR signal transduction

Abstract

Summary: Attention typically amplifies neuronal responses evoked by task-relevant stimuli while attenuating responses to task-irrelevant distracters. In this context, visual distracters constitute an external source of noise that is diminished to improve attended signal quality. Activity that is internal to the cortex itself, stimulus-independent ongoing correlated fluctuations in firing, might also act as task-irrelevant noise. To examine this, we recorded from area V4 of macaques performing an attention-demanding task. The firing of neurons to identically repeated stimuli was highly variable. Much of this variability originates from ongoing low-frequency (<5 Hz) fluctuations in rate correlated across the neuronal population. When attention is directed to a stimulus inside a neuron''s receptive field, these correlated fluctuations in rate are reduced. This attention-dependent reduction of ongoing cortical activity improves the signal-to-noise ratio of pooled neural signals substantially more than attention-dependent increases in firing rate. [Copyright &y& Elsevier]

Published

2009

22. Intention, Action Planning, and Decision Making in Parietal-Frontal Circuits

Author

Andersen, Richard A. and Cui, He

Subjects

*NEURAL circuitry, *PARIETAL lobe, *SENSORIMOTOR cortex, *NEUROPHYSIOLOGY, *DECISION making, *BRAIN physiology, *HIGHER nervous activity

Abstract

The posterior parietal cortex and frontal cortical areas to which it connects are responsible for sensorimotor transformations. This review covers new research on four components of this transformation process: planning, decision making, forward state estimation, and relative-coordinate representations. These sensorimotor functions can be harnessed for neural prosthetic operations by decoding intended goals (planning) and trajectories (forward state estimation) of movements as well as higher cortical functions related to decision making and potentially the coordination of multiple body parts (relative-coordinate representations). [Copyright &y& Elsevier]

Published

2009

23. Motor Learning Is Optimally Tuned to the Properties of Motor Noise

Author

van Beers, Robert J.

Subjects

*MOTOR learning, *PHYSIOLOGICAL effects of noise, *BRAIN function localization, *PSYCHOLOGY of movement, *NEUROPHYSIOLOGY, *PSYCHOLOGY of learning

Abstract

Summary: In motor learning, our brain uses movement errors to adjust planning of future movements. This process has traditionally been studied by examining how motor planning is adjusted in response to visuomotor or dynamic perturbations. Here, I show that the learning strategy can be better identified from the statistics of movements made in the absence of perturbations. The strategy identified this way differs from the learning mechanism assumed in mainstream models for motor learning. Crucial for this strategy is that motor noise arises partly centrally, in movement planning, and partly peripherally, in movement execution. Corrections are made by modification of central planning signals from the previous movement, which include the effects of planning but not execution noise. The size of the corrections is such that the movement variability is minimized. This physiologically plausible strategy is optimally tuned to the properties of motor noise, and likely underlies learning in many motor tasks. [Copyright &y& Elsevier]

Published

2009

24. GABAB Receptor Activation Inhibits Neuronal Excitability and Spatial Learning in the Entorhinal Cortex by Activating TREK-2 K+ Channels

Author

Deng, Pan-Yue, Xiao, Zhaoyang, Yang, Chuanxiu, Rojanathammanee, Lalida, Grisanti, Laurel, Watt, John, Geiger, Jonathan D., Liu, Rugao, Porter, James E., and Lei, Saobo

Subjects

*GABA, *CELL receptors, *EXCITATION (Physiology), *NEURAL physiology, *PHYSIOLOGICAL aspects of learning, *CEREBRAL cortex, *ION channels, *HIPPOCAMPUS (Brain)

Abstract

Summary: The entorhinal cortex (EC) is regarded as the gateway to the hippocampus and thus is essential for learning and memory. Whereas the EC expresses a high density of GABAB receptors, the functions of these receptors in this region remain unexplored. Here, we examined the effects of GABAB receptor activation on neuronal excitability in the EC and spatial learning. Application of baclofen, a specific GABAB receptor agonist, inhibited significantly neuronal excitability in the EC. GABAB receptor-mediated inhibition in the EC was mediated via activating TREK-2, a type of two-pore domain K+ channels, and required the functions of inhibitory G proteins and protein kinase A pathway. Depression of neuronal excitability in the EC underlies GABAB receptor-mediated inhibition of spatial learning as assessed by Morris water maze. Our study indicates that GABAB receptors exert a tight control over spatial learning by modulating neuronal excitability in the EC. [Copyright &y& Elsevier]

Published

2009

25. Midbrain Dopamine Neurons Signal Preference for Advance Information about Upcoming Rewards

Author

Bromberg-Martin, Ethan S. and Hikosaka, Okihide

Subjects

*MESENCEPHALON, *DOPAMINERGIC neurons, *CELLULAR signal transduction, *PREFERENCES (Philosophy), *REWARD (Psychology), *MACAQUE behavior, *LABORATORY monkeys, *INFORMATION-seeking behavior

Abstract

Summary: The desire to know what the future holds is a powerful motivator in everyday life, but it is unknown how this desire is created by neurons in the brain. Here we show that when macaque monkeys are offered a water reward of variable magnitude, they seek advance information about its size. Furthermore, the same midbrain dopamine neurons that signal the expected amount of water also signal the expectation of information, in a manner that is correlated with the strength of the animal''s preference. Our data show that single dopamine neurons process both primitive and cognitive rewards, and suggest that current theories of reward-seeking must be revised to include information-seeking. [Copyright &y& Elsevier]

Published

2009

26. How Green Is the Grass on the Other Side? Frontopolar Cortex and the Evidence in Favor of Alternative Courses of Action

Author

Boorman, Erie D., Behrens, Timothy E.J., Woolrich, Mark W., and Rushworth, Matthew F.S.

Subjects

*FRONTAL lobe, *NEUROPSYCHIATRY, *ADAPTABILITY (Personality), *GOAL (Psychology), *HUMAN behavior, *CHOICE (Psychology), *BRAIN function localization, *MAGNETIC resonance imaging, *PHYSIOLOGY

Abstract

Summary: Behavioral flexibility is the hallmark of goal-directed behavior. Whereas a great deal is known about the neural substrates of behavioral adjustment when it is explicitly cued by features of the external environment, little is known about how we adapt our behavior when such changes are made on the basis of uncertain evidence. Using a Bayesian reinforcement-learning model and fMRI, we show that frontopolar cortex (FPC) tracks the relative advantage in favor of switching to a foregone alternative when choices are made voluntarily. Changes in FPC functional connectivity occur when subjects finally decide to switch to the alternative behavior. Moreover, interindividual variation in the FPC signal predicts interindividual differences in effectively adapting behavior. By contrast, ventromedial prefrontal cortex (vmPFC) encodes the relative value of the current decision. Collectively, these findings reveal complementary prefrontal computations essential for promoting short- and long-term behavioral flexibility. [Copyright &y& Elsevier]

Published

2009

27. Inhibitory Plasticity in a Lateral Band Improves Cortical Detection of Natural Vocalizations

Author

Galindo-Leon, Edgar E., Lin, Frank G., and Liu, Robert C.

Subjects

*NEUROPLASTICITY, *EXCITATION (Physiology), *AUDITORY cortex, *SENSORY stimulation, *HUMAN information processing, *LABORATORY mice, *ELECTROPHYSIOLOGY, *AUDITORY evoked response

Abstract

Summary: The interplay between excitation and inhibition in the auditory cortex is crucial for the processing of acoustic stimuli. However, the precise role that inhibition plays in the distributed cortical encoding of natural vocalizations has not been well studied. We recorded single units (SUs) and local field potentials (LFPs) in the awake mouse auditory cortex while presenting pup isolation calls to animals that either do (mothers) or do not (virgins) recognize the sounds as behaviorally relevant. In both groups, we observed substantial call-evoked inhibition. However, in mothers this was earlier, longer, stronger, and more stereotyped compared to virgins. This difference was most apparent for recording sites tuned to tone frequencies lower than the pup calls'' high-ultrasonic frequency range. We hypothesize that this auditory cortical inhibitory plasticity improves pup call detection in a relatively specific manner by increasing the contrast between call-evoked responses arising from high-ultrasonic and lateral frequency neural populations. [Copyright &y& Elsevier]

Published

2009

28. Instantaneous Modulation of Gamma Oscillation Frequency by Balancing Excitation with Inhibition

Author

Atallah, Bassam V. and Scanziani, Massimo

Subjects

*NEURAL physiology, *ELECTRIC stimulation, *LABORATORY rats, *HIPPOCAMPUS (Brain), *EXCITATION (Physiology), *OSCILLATIONS, *SYNAPSES

Abstract

Summary: Neurons recruited for local computations exhibit rhythmic activity at gamma frequencies. The amplitude and frequency of these oscillations are continuously modulated depending on stimulus and behavioral state. This modulation is believed to crucially control information flow across cortical areas. Here we report that in the rat hippocampus gamma oscillation amplitude and frequency vary rapidly, from one cycle to the next. Strikingly, the amplitude of one oscillation predicts the interval to the next. Using in vivo and in vitro whole-cell recordings, we identify the underlying mechanism. We show that cycle-by-cycle fluctuations in amplitude reflect changes in synaptic excitation spanning over an order of magnitude. Despite these rapid variations, synaptic excitation is immediately and proportionally counterbalanced by inhibition. These rapid adjustments in inhibition instantaneously modulate oscillation frequency. So, by rapidly balancing excitation with inhibition, the hippocampal network is able to swiftly modulate gamma oscillations over a wide band of frequencies. [Copyright &y& Elsevier]

Published

2009

29. Neurodegenerative Diseases Target Large-Scale Human Brain Networks

Author

Seeley, William W., Crawford, Richard K., Zhou, Juan, Miller, Bruce L., and Greicius, Michael D.

Subjects

*NEURODEGENERATION, *BIOLOGICAL neural networks, *DEVELOPMENTAL neurobiology, *BRAIN imaging, *NEURAL circuitry, *NEUROPHYSIOLOGY

Abstract

Summary: During development, the healthy human brain constructs a host of large-scale, distributed, function-critical neural networks. Neurodegenerative diseases have been thought to target these systems, but this hypothesis has not been systematically tested in living humans. We used network-sensitive neuroimaging methods to show that five different neurodegenerative syndromes cause circumscribed atrophy within five distinct, healthy, human intrinsic functional connectivity networks. We further discovered a direct link between intrinsic connectivity and gray matter structure. Across healthy individuals, nodes within each functional network exhibited tightly correlated gray matter volumes. The findings suggest that human neural networks can be defined by synchronous baseline activity, a unified corticotrophic fate, and selective vulnerability to neurodegenerative illness. Future studies may clarify how these complex systems are assembled during development and undermined by disease. [Copyright &y& Elsevier]

Published

2009

30. Rewards Evoke Learning of Unconsciously Processed Visual Stimuli in Adult Humans

Author

Seitz, Aaron R., Kim, Dongho, and Watanabe, Takeo

Subjects

*PERCEPTUAL learning, *REWARD (Psychology), *PSYCHOLOGY of adults, *VISUAL learning, *NEURONS, *AWARENESS

Abstract

Summary: The study of human learning is complicated by the myriad of processing elements involved in conducting any behavioral task. In the case of visual perceptual learning, there has been significant controversy regarding the task processes that guide the formation of this learning. However, there is a developing consensus that top-down, task-related factors are required for such learning to take place. Here we challenge this idea by use of a novel procedure in which human participants, who were deprived of food and water, passively viewed visual stimuli while receiving occasional drops of water as rewards. Visual orientation stimuli, which were temporally paired with the liquid rewards, were viewed monocularly and rendered imperceptible by continuously flashing contour-rich patterns to the other eye. Results show that visual learning can be formed in human adults through stimulus-reward pairing in the absence of a task and without awareness of the stimulus presentation or reward contingencies. [Copyright &y& Elsevier]

Published

2009

31. State-Dependent Spike-Timing Relationships between Hippocampal and Prefrontal Circuits during Sleep

Author

Wierzynski, Casimir M., Lubenov, Evgueniy V., Gu, Ming, and Siapas, Athanassios G.

Subjects

*HIPPOCAMPUS (Brain), *PREFRONTAL cortex, *NEURAL circuitry, *SLEEP behavior in animals, *CELL communication, *NEUROPLASTICITY, *SLOW wave sleep, *RAPID eye movement sleep

Abstract

Summary: Cortico-hippocampal interactions during sleep are believed to reorganize neural circuits in support of memory consolidation. However, spike-timing relationships across cortico-hippocampal networks—key determinants of synaptic changes—are poorly understood. Here we show that cells in prefrontal cortex fire consistently within 100 ms after hippocampal cells in naturally sleeping animals. This provides evidence at the single cell-pair level for highly consistent directional interactions between these areas within the window of plasticity. Moreover, these interactions are state dependent: they are driven by hippocampal sharp-wave/ripple (SWR) bursts in slow-wave sleep (SWS) and are sharply reduced during REM sleep. Finally, prefrontal responses are nonlinear: as the strength of hippocampal bursts rises, short-latency prefrontal responses are augmented by increased spindle band activity and a secondary peak ∼100 ms later. These findings suggest that SWR events are atomic units of hippocampal-prefrontal communication during SWS and that the coupling between these areas is highly attenuated during REM sleep. [Copyright &y& Elsevier]

Published

2009

32. Synapses with Inhibitory Neurons Differentiate Anterior Cingulate from Dorsolateral Prefrontal Pathways Associated with Cognitive Control

Author

Medalla, Maria and Barbas, Helen

Subjects

*SYNAPSES, *CHEMICAL inhibitors, *CEREBRAL cortex, *PREFRONTAL cortex, *CELLULAR signal transduction, *COGNITIVE ability, *SENSORY stimulation, *SCHIZOPHRENIA

Abstract

Summary: The primate dorsolateral prefrontal cortex (DLPFC) and anterior cingulate cortex (ACC) focus attention on relevant signals and suppress noise in cognitive tasks. However, their synaptic interactions and unique roles in cognitive control are unknown. We report that two distinct pathways to DLPFC area 9, one from the neighboring area 46 and the other from the functionally distinct ACC, similarly innervate excitatory neurons associated with selecting relevant stimuli. However, ACC has more prevalent and larger synapses with inhibitory neurons and preferentially innervates calbindin inhibitory neurons, which reduce noise by inhibiting excitatory neurons. In contrast, area 46 mostly innervates calretinin inhibitory neurons, which disinhibit excitatory neurons. These synaptic specializations suggest that ACC has a greater impact in reducing noise in dorsolateral areas during challenging cognitive tasks involving conflict, error, or reversing decisions, mechanisms that are disrupted in schizophrenia. These observations highlight the unique roles of the DLPFC and ACC in cognitive control. [Copyright &y& Elsevier]

Published

2009

33. Similarity Effect and Optimal Control of Multiple-Choice Decision Making

Author

Furman, Moran and Wang, Xiao-Jing

Subjects

*DECISION making, *NEUROPHYSIOLOGY, *LABORATORY monkeys, *NEURAL circuitry, *NEUROSCIENCES, *SIMULATION methods & models

Abstract

Summary: Decision making with several choice options is central to cognition. To elucidate the neural mechanisms of such decisions, we investigated a recurrent cortical circuit model in which fluctuating spiking neural dynamics underlie trial-by-trial stochastic decisions. The model encodes a continuous analog stimulus feature and is thus applicable to multiple-choice decisions. Importantly, the continuous network captures similarity between alternatives and possible overlaps in their neural representation. Model simulations accounted for behavioral as well as single-unit neurophysiological data from a recent monkey experiment and revealed testable predictions about the patterns of error rate as a function of the similarity between the correct and actual choices. We also found that the similarity and number of options affect speed and accuracy of responses. A mechanism is proposed for flexible control of speed-accuracy tradeoff, based on a simple top-down signal to the decision circuit that may vary nonmonotonically with the number of choice alternatives. [Copyright &y& Elsevier]

Published

2008

34. Value-Based Modulations in Human Visual Cortex

Author

Serences, John T.

Subjects

*VISUAL cortex, *COGNITIVE psychology, *AFFERENT pathways, *MAGNETIC resonance imaging, *MOTOR neurons, *DECISION making, *NEUROPHYSIOLOGY

Abstract

Summary: Economists and cognitive psychologists have long known that prior rewards bias decision making in favor of options with high expected value. Accordingly, value modulates the activity of sensorimotor neurons involved in initiating movements toward one of two competing decision alternatives. However, little is known about how value influences the acquisition and representation of incoming sensory information or about the neural mechanisms that track the relative value of each available stimulus to guide behavior. Here, fMRI revealed value-related modulations throughout spatially selective areas of the human visual system in the absence of overt saccadic responses (including in V1). These modulations were primarily associated with the reward history of each stimulus and not to self-reported estimates of stimulus value. Finally, subregions of frontal and parietal cortex represent the differential value of competing alternatives and may provide signals to bias spatially selective visual areas in favor of more valuable stimuli. [Copyright &y& Elsevier]

Published

2008

35. Genomic Anatomy of the Hippocampus

Author

Thompson, Carol L., Pathak, Sayan D., Jeromin, Andreas, Ng, Lydia L., MacPherson, Cameron R., Mortrud, Marty T., Cusick, Allison, Riley, Zackery L., Sunkin, Susan M., Bernard, Amy, Puchalski, Ralph B., Gage, Fred H., Jones, Allan R., Bajic, Vladimir B., Hawrylycz, Michael J., and Lein, Ed S.

Subjects

*GENOMICS, *HIPPOCAMPUS (Brain), *IN situ hybridization, *ELECTROPHYSIOLOGY, *MEDICAL imaging systems, *MOLECULAR genetics, *NEURONS, *MOLECULAR neurobiology

Abstract

Summary: Availability of genome-scale in situ hybridization data allows systematic analysis of genetic neuroanatomical architecture. Within the hippocampus, electrophysiology and lesion and imaging studies demonstrate functional heterogeneity along the septotemporal axis, although precise underlying circuitry and molecular substrates remain uncharacterized. Application of unbiased statistical component analyses to genome-scale hippocampal gene expression data revealed robust septotemporal molecular heterogeneity, leading to the identification of a large cohort of genes with robust regionalized hippocampal expression. Manual mapping of heterogeneous CA3 pyramidal neuron expression patterns demonstrates an unexpectedly complex molecular parcellation into a relatively coherent set of nine expression domains in the septal/temporal and proximal/distal axes with reciprocal, nonoverlapping boundaries. Unique combinatorial profiles of adhesion molecules within these domains suggest corresponding differential connectivity, which is demonstrated for CA3 projections to the lateral septum using retrograde labeling. This complex, discrete molecular architecture provides a novel paradigm for predicting functional differentiation across the full septotemporal extent of the hippocampus. [Copyright &y& Elsevier]

Published

2008

36. The Globus Pallidus Sends Reward-Related Signals to the Lateral Habenula

Author

Hong, Simon and Hikosaka, Okihide

Subjects

*NEURAL transmission, *GLOBUS pallidus, *BASAL ganglia, *NEURONS, *LIMBIC system, *LABORATORY monkeys, *BRAIN stem, *DOPAMINERGIC mechanisms

Abstract

Summary: As a major output station of the basal ganglia, the globus pallidus internal segment (GPi) projects to the thalamus and brainstem nuclei thereby controlling motor behavior. A less well known fact is that the GPi also projects to the lateral habenula (LHb) which is often associated with the limbic system. Using the monkey performing a saccade task with positionally biased reward outcomes, we found that antidromically identified LHb-projecting neurons were distributed mainly in the dorsal and ventral borders of the GPi and that their activity was strongly modulated by expected reward outcomes. A majority of them were excited by the no-reward-predicting target and inhibited by the reward-predicting target. These reward-dependent modulations were similar to those in LHb neurons but started earlier than those in LHb neurons. These results suggest that GPi may initiate reward-related signals through its effects on the LHb, which then influences the dopaminergic and serotonergic systems. [Copyright &y& Elsevier]

Published

2008

37. Neuronal Synchronization along the Dorsal Visual Pathway Reflects the Focus of Spatial Attention

Author

Siegel, Markus, Donner, Tobias H., Oostenveld, Robert, Fries, Pascal, and Engel, Andreas K.

Subjects

*VISUAL pathways, *SYNCHRONIZATION, *SPATIAL ability, *NEURONS, *MAGNETOENCEPHALOGRAPHY, *VISUAL cortex, *PREFRONTAL cortex, *ATTENTION

Abstract

Summary: Oscillatory neuronal synchronization, within and between cortical areas, may mediate the selection of attended visual stimuli. However, it remains unclear at and between which processing stages visuospatial attention modulates oscillatory synchronization in the human brain. We thus combined magnetoencephalography (MEG) in a spatially cued motion discrimination task with source-reconstruction techniques and characterized attentional effects on neuronal synchronization across key stages of the human dorsal visual pathway. We found that visuospatial attention modulated oscillatory synchronization between visual, parietal, and prefrontal cortex in a spatially selective fashion. Furthermore, synchronized activity within these stages was selectively modulated by attention, but with markedly distinct spectral signatures and stimulus dependence between regions. Our data indicate that regionally specific oscillatory synchronization at most stages of the human dorsal visual pathway may enhance the processing of attended visual stimuli and suggest that attentional selection is mediated by frequency-specific synchronization between prefrontal, parietal, and early visual cortex. [Copyright &y& Elsevier]

Published

2008

38. Cystatin C-Cathepsin B Axis Regulates Amyloid Beta Levels and Associated Neuronal Deficits in an Animal Model of Alzheimer's Disease

Author

Sun, Binggui, Zhou, Yungui, Halabisky, Brian, Lo, Iris, Cho, Seo-Hyun, Mueller-Steiner, Sarah, Devidze, Nino, Wang, Xin, Grubb, Anders, and Gan, Li

Subjects

*CYSTATINS, *CYSTEINE proteinase inhibitors, *AMYLOID beta-protein, *ALZHEIMER'S disease

Abstract

Summary: Impaired degradation of amyloid beta (Aβ) peptides could lead to Aβ accumulation, an early trigger of Alzheimer''s disease (AD). How Aβ-degrading enzymes are regulated remains largely unknown. Cystatin C (CysC, CST3) is an endogenous inhibitor of cysteine proteases, including cathepsin B (CatB), a recently discovered Aβ-degrading enzyme. A CST3 polymorphism is associated with an increased risk of late-onset sporadic AD. Here, we identified CysC as the key inhibitor of CatB-induced Aβ degradation in vivo. Genetic ablation of CST3 in hAPP-J20 mice significantly lowered soluble Aβ levels, the relative abundance of Aβ1-42, and plaque load. CysC removal also attenuated Aβ-associated cognitive deficits and behavioral abnormalities and restored synaptic plasticity in the hippocampus. Importantly, the beneficial effects of CysC reduction were abolished on a CatB null background, providing direct evidence that CysC regulates soluble Aβ and Aβ-associated neuronal deficits through inhibiting CatB-induced Aβ degradation. [Copyright &y& Elsevier]

Published

2008

39. Integrating Memories in the Human Brain: Hippocampal-Midbrain Encoding of Overlapping Events

Author

Shohamy, Daphna and Wagner, Anthony D.

Subjects

*MEMORY, *GENERALIZATION, *HIPPOCAMPUS (Brain), *MESENCEPHALON

Abstract

Summary: Decisions are often guided by generalizing from past experiences. Fundamental questions remain regarding the cognitive and neural mechanisms by which generalization takes place. Prior data suggest that generalization may stem from inference-based processes at the time of generalization. By contrast, generalization may emerge from mnemonic processes occurring while premise events are encoded. Here, participants engaged in a two-phase learning and generalization task, wherein they learned a series of overlapping associations and subsequently generalized what they learned to novel stimulus combinations. Functional MRI revealed that successful generalization was associated with coupled changes in learning-phase activity in the hippocampus and midbrain (ventral tegmental area/substantia nigra). These findings provide evidence for generalization based on integrative encoding, whereby overlapping past events are integrated into a linked mnemonic representation. Hippocampal-midbrain interactions support the dynamic integration of experiences, providing a powerful mechanism for building a rich associative history that extends beyond individual events. [Copyright &y& Elsevier]

Published

2008

40. Inducible and Selective Erasure of Memories in the Mouse Brain via Chemical-Genetic Manipulation

Author

Cao, Xiaohua, Wang, Huimin, Mei, Bing, An, Shuming, Yin, Liang, Wang, L. Phillip, and Tsien, Joe Z.

Subjects

*MEMORY, *BRAIN, *BIOCHEMICAL genetics, *LABORATORY mice

Abstract

Summary: Rapid and selective erasures of certain types of memories in the brain would be desirable under certain clinical circumstances. By employing an inducible and reversible chemical-genetic technique, we find that transient αCaMKII overexpression at the time of recall impairs the retrieval of both newly formed one-hour object recognition memory and fear memories, as well as 1-month-old fear memories. Systematic analyses suggest that excessive αCaMKII activity-induced recall deficits are not caused by disrupting the retrieval access to the stored information but are, rather, due to the active erasure of the stored memories. Further experiments show that the recall-induced erasure of fear memories is highly restricted to the memory being retrieved while leaving other memories intact. Therefore, our study reveals a molecular genetic paradigm through which a given memory, such as new or old fear memory, can be rapidly and specifically erased in a controlled and inducible manner in the brain. [Copyright &y& Elsevier]

Published

2008

41. Fine Discrimination Training Alters the Causal Contribution of Macaque Area MT to Depth Perception

Author

Chowdhury, Syed A. and DeAngelis, Gregory C.

Subjects

*NEUROPLASTICITY, *NEURONS, *VISUAL perception, *LABORATORY monkeys

Abstract

Summary: When a new perceptual task is learned, plasticity occurs in the brain to mediate improvements in performance with training. How do these changes affect the neural substrates of previously learned tasks? We addressed this question by examining the effect of fine discrimination training on the causal contribution of area MT to coarse depth discrimination. When monkeys are trained to discriminate between two coarse absolute disparities (near versus far) embedded in noise, reversible inactivation of area MT devastates performance. In contrast, after animals are trained to discriminate fine differences in relative disparity, MT inactivation no longer impairs coarse depth discrimination. This effect does not result from changes in the disparity tuning of MT neurons, suggesting plasticity in the flow of disparity signals to decision circuitry. These findings show that the contribution of particular brain area to task performance can change dramatically as a result of learning new tasks. [Copyright &y& Elsevier]

Published

2008

42. Frequency-Independent Synaptic Transmission Supports a Linear Vestibular Behavior

Author

Bagnall, Martha W., McElvain, Lauren E., Faulstich, Michael, and du Lac, Sascha

Subjects

*NEURAL transmission, *VESTIBULAR nuclei, *NEURONS, *NEUROPHYSIOLOGY

Abstract

Summary: The vestibular system is responsible for transforming head motion into precise eye, head, and body movements that rapidly stabilize gaze and posture. How do central excitatory synapses mediate behavioral outputs accurately matched to sensory inputs over a wide dynamic range? Here we demonstrate that vestibular afferent synapses in vitro express frequency-independent transmission that spans their in vivo dynamic range (5–150 spikes/s). As a result, the synaptic charge transfer per unit time is linearly related to vestibular afferent activity in both projection and intrinsic neurons of the vestibular nuclei. Neither postsynaptic glutamate receptor desensitization nor saturation affect the relative amplitude or frequency-independence of steady-state transmission. Finally, we show that vestibular nucleus neurons can transduce synaptic inputs into linear changes in firing rate output without relying on one-to-one calyceal transmission. These data provide a physiological basis for the remarkable linearity of vestibular reflexes. [Copyright &y& Elsevier]

Published

2008

43. Basolateral Amygdala Neurons Facilitate Reward-Seeking Behavior by Exciting Nucleus Accumbens Neurons

Author

Ambroggi, Frederic, Ishikawa, Akinori, Fields, Howard L., and Nicola, Saleem M.

Subjects

*AMYGDALOID body, *NUCLEUS accumbens, *DOPAMINE, *NEURONS

Abstract

Summary: Both the nucleus accumbens (NAc) and basolateral amygdala (BLA) contribute to learned behavioral choice. Neurons in both structures that encode reward-predictive cues may underlie the decision to respond to such cues, but the neural circuits by which the BLA influences reward-seeking behavior have not been established. Here, we test the hypothesis that the BLA drives NAc neuronal responses to reward-predictive cues. First, using a disconnection experiment, we show that the BLA and dopamine projections to the NAc interact to promote the reward-seeking behavioral response. Next, we demonstrate that BLA neuronal responses to cues precede those of NAc neurons and that cue-evoked excitation of NAc neurons depends on BLA input. These results indicate that BLA input is required for dopamine to enhance the cue-evoked firing of NAc neurons and that this enhanced firing promotes reward-seeking behavior. [Copyright &y& Elsevier]

Published

2008

44. Cellular Mechanisms Underlying Stimulus-Dependent Gain Modulation in Primary Visual Cortex Neurons In Vivo

Author

Cardin, Jessica A., Palmer, Larry A., and Contreras, Diego

Subjects

*NERVOUS system, *VISUAL cortex, *NEUROSCIENCES, *ORGANS (Anatomy)

Abstract

Summary: Gain modulation is a widespread neuronal phenomenon that modifies response amplitude without changing selectivity. Computational and in vitro studies have proposed cellular mechanisms of gain modulation based on the postsynaptic effects of background synaptic activation, but these mechanisms have not been studied in vivo. Here, we used intracellular recordings from cat primary visual cortex to measure neuronal gain while changing background synaptic activity with visual stimulation. We found that increases in the membrane fluctuations associated with increases in synaptic input do not obligatorily result in gain modulation in vivo. However, visual stimuli that evoked sustained changes in resting membrane potential, input resistance, and membrane fluctuations robustly modulated neuronal gain. The magnitude of gain modulation depended critically on the spatiotemporal properties of the visual stimulus. Gain modulation in vivo may thus be determined on a moment-to-moment basis by sensory context and the consequent dynamics of synaptic activation. [Copyright &y& Elsevier]

Published

2008

45. Neural Antecedents of the Endowment Effect

Author

Knutson, Brian, Wimmer, G. Elliott, Rick, Scott, Hollon, Nick G., Prelec, Drazen, and Loewenstein, George

Subjects

*DIAGNOSTIC imaging, *FRONTAL lobe, *PREFRONTAL cortex, *NUCLEUS accumbens

Abstract

Summary: The “endowment effect” refers to the tendency to place greater value on items that one owns—an anomaly that violates the reference-independence assumption of rational choice theories. We investigated neural antecedents of the endowment effect in an event-related functional magnetic resonance imaging (fMRI) study. During scanning, 24 subjects considered six products paired with 18 different prices under buying, choosing, or selling conditions. Subjects showed greater nucleus accumbens (NAcc) activation for preferred products across buy and sell conditions combined, but greater mesial prefrontal cortex (MPFC) activation in response to low prices when buying versus selling. During selling, right insular activation for preferred products predicted individual differences in susceptibility to the endowment effect. These findings are consistent with a reference-dependent account in which ownership increases value by enhancing the salience of the possible loss of preferred products. [Copyright &y& Elsevier]

Published

2008

46. Oxytocin Shapes the Neural Circuitry of Trust and Trust Adaptation in Humans

Author

Baumgartner, Thomas, Heinrichs, Markus, Vonlanthen, Aline, Fischbacher, Urs, and Fehr, Ernst

Subjects

*NEURAL circuitry, *NERVOUS system, *OXYTOCIN, *PITUITARY hormones

Abstract

Summary: Trust and betrayal of trust are ubiquitous in human societies. Recent behavioral evidence shows that the neuropeptide oxytocin increases trust among humans, thus offering a unique chance of gaining a deeper understanding of the neural mechanisms underlying trust and the adaptation to breach of trust. We examined the neural circuitry of trusting behavior by combining the intranasal, double-blind, administration of oxytocin with fMRI. We find that subjects in the oxytocin group show no change in their trusting behavior after they learned that their trust had been breached several times while subjects receiving placebo decrease their trust. This difference in trust adaptation is associated with a specific reduction in activation in the amygdala, the midbrain regions, and the dorsal striatum in subjects receiving oxytocin, suggesting that neural systems mediating fear processing (amygdala and midbrain regions) and behavioral adaptations to feedback information (dorsal striatum) modulate oxytocin''s effect on trust. These findings may help to develop deeper insights into mental disorders such as social phobia and autism, which are characterized by persistent fear or avoidance of social interactions. [Copyright &y& Elsevier]

Published

2008

47. Value Representations in the Primate Striatum during Matching Behavior

Author

Lau, Brian and Glimcher, Paul W.

Subjects

*PRIMATES, *MONKEYS, *NERVOUS system, *NEURONS, *EYE movements

Abstract

Summary: Choosing the most valuable course of action requires knowing the outcomes associated with the available alternatives. The striatum may be important for representing the values of actions. We examined this in monkeys performing an oculomotor choice task. The activity of phasically active neurons (PANs) in the striatum covaried with two classes of information: action-values and chosen-values. Action-value PANs were correlated with value estimates for one of the available actions, and these signals were frequently observed before movement execution. Chosen-value PANs were correlated with the value of the action that had been chosen, and these signals were primarily observed later in the task, immediately before or persistently after movement execution. These populations may serve distinct functions mediated by the striatum: some PANs may participate in choice by encoding the values of the available actions, while other PANs may participate in evaluative updating by encoding the reward value of chosen actions. [Copyright &y& Elsevier]

Published

2008

48. Transient Induced Gamma-Band Response in EEG as a Manifestation of Miniature Saccades

Author

Yuval-Greenberg, Shlomit, Tomer, Orr, Keren, Alon S., Nelken, Israel, and Deouell, Leon Y.

Subjects

*GAMMA (Electronic computer system), *ELECTROENCEPHALOGRAPHY, *SACCADIC eye movements, *SCALP, *OSCILLATIONS

Abstract

Summary: The induced gamma-band EEG response (iGBR) recorded on the scalp is widely assumed to reflect synchronous neural oscillation associated with object representation, attention, memory, and consciousness. The most commonly reported EEG iGBR is a broadband transient increase in power at the gamma range ∼200–300 ms following stimulus onset. A conspicuous feature of this iGBR is the trial-to-trial poststimulus latency variability, which has been insufficiently addressed. Here, we show, using single-trial analysis of concomitant EEG and eye tracking, that this iGBR is tightly time locked to the onset of involuntary miniature eye movements and reflects a saccadic “spike potential.” The time course of the iGBR is related to an increase in the rate of saccades following a period of poststimulus saccadic inhibition. Thus, whereas neuronal gamma-band oscillations were shown conclusively with other methods, the broadband transient iGBR recorded by scalp EEG reflects properties of miniature saccade dynamics rather than neuronal oscillations. [Copyright &y& Elsevier]

Published

2008

49. Cortical Mechanisms of Smooth Eye Movements Revealed by Dynamic Covariations of Neural and Behavioral Responses

Author

Schoppik, David, Nagel, Katherine I., and Lisberger, Stephen G.

Subjects

*EYE movements, *NEURONS, *CEREBRAL cortex, *NERVOUS system

Abstract

Summary: Neural activity in the frontal eye fields controls smooth pursuit eye movements, but the relationship between single neuron responses, cortical population responses, and eye movements is not well understood. We describe an approach to dynamically link trial-to-trial fluctuations in neural responses to parallel variations in pursuit and demonstrate that individual neurons predict eye velocity fluctuations at particular moments during the course of behavior, while the population of neurons collectively tiles the entire duration of the movement. The analysis also reveals the strength of correlations in the eye movement predictions derived from pairs of simultaneously recorded neurons and suggests a simple model of cortical processing. These findings constrain the primate cortical code for movement, suggesting that either a few neurons are sufficient to drive pursuit at any given time or that many neurons operate collectively at each moment with remarkably little variation added to motor command signals downstream from the cortex. [Copyright &y& Elsevier]

Published

2008

50. Lateral Sharpening of Cortical Frequency Tuning by Approximately Balanced Inhibition

Author

Wu, Guangying K., Arbuckle, Robert, Liu, Bao-hua, Tao, Huizhong W., and Zhang, Li I.

Subjects

*NEURONS, *NERVOUS system, *CELLS, *TEMPORAL lobe

Abstract

Summary: Cortical inhibition plays an important role in shaping neuronal processing. The underlying synaptic mechanisms remain controversial. Here, in vivo whole-cell recordings from neurons in the rat primary auditory cortex revealed that the frequency tuning curve of inhibitory input was broader than that of excitatory input. This results in relatively stronger inhibition in frequency domains flanking the preferred frequencies of the cell and a significant sharpening of the frequency tuning of membrane responses. The less selective inhibition can be attributed to a broader bandwidth and lower threshold of spike tonal receptive field of fast-spike inhibitory neurons than nearby excitatory neurons, although both types of neurons receive similar ranges of excitatory input and are organized into the same tonotopic map. Thus, the balance between excitation and inhibition is only approximate, and intracortical inhibition with high sensitivity and low selectivity can laterally sharpen the frequency tuning of neurons, ensuring their highly selective representation. [Copyright &y& Elsevier]

Published

2008