Your search keyword '"Phase dynamics"' showing total 69 results

1. Cone photoreceptor classification in the living human eye from photostimulation-induced phase dynamics

Author

Zhang, Furu, Kurokawa, Kazuhiro, Lassoued, Ayoub, Crowell, James A., and Miller, Donald T.

Published

2019

2. Two-phase dynamics of p53 in the DNA damage response

Author

Zhang, Xiao-Peng, Liu, Feng, and Wang, Wei

Published

2011

3. Cone photoreceptor classification in the living human eye from photostimulation-induced phase dynamics.

Author

Furu Zhang, Kazuhiro Kurokawa, Lassoued, Ayoub, Crowell, James A., and Miller, Donald T.

Subjects

*PHOTORECEPTORS, *COLOR vision, *WAVELENGTHS, *DENSITOMETRY, *ELECTRIC stimulation, *OPTICAL coherence tomography

Abstract

Human color vision is achieved by mixing neural signals from cone photoreceptors sensitive to different wavelengths of light. The spatial arrangement and proportion of these spectral types in the retina set fundamental limits on color perception, and abnormal or missing types are responsible for color vision loss. Imaging provides the most direct and quantitative means to study these photoreceptor properties at the cellular scale in the living human retina, but remains challenging. Current methods rely on retinal densitometry to distinguish cone types, a prohibitively slow process. Here, we show that photostimulation-induced optical phase changes occur in cone cells and carry substantial information about spectral type, enabling cones to be differentiated with unprecedented accuracy and efficiency. Moreover, these phase dynamics arise from physiological activity occurring on dramatically different timescales (from milliseconds to seconds) inside the cone outer segment, thus exposing the phototransduction cascade and subsequent downstream effects. We captured these dynamics in cones of subjectswith normal color vision and a deuteranope, and at different macular locations by: (i) marrying adaptive optics to phase-sensitive optical coherence tomography to avoid optical blurring of the eye, (ii) acquiring images at high speed that samples phase dynamics at up to 3 KHz, and (iii) localizing phase changes to the cone outer segment, where photoactivation occurs. Our method should have broad appeal for color vision applications in which the underlying neural processing of photoreceptors is sought and for investigations of retinal diseases that affect cone function. [ABSTRACT FROM AUTHOR]

Published

2019

4. Two-phase dynamics of p53 in the DNA damage response

Author

Wei Wang, Xiao-Peng Zhang, and Feng Liu

Subjects

Cell cycle checkpoint, Time Factors, DNA Repair, DNA damage, DNA repair, Apoptosis, Cell Cycle Proteins, Ataxia Telangiectasia Mutated Proteins, Cell fate determination, Biology, Protein Serine-Threonine Kinases, Negative feedback, Neoplasms, Oscillometry, Serine, Humans, Cell Lineage, Phosphorylation, Positive feedback, Multidisciplinary, Tumor Suppressor Proteins, Models, Theoretical, Genes, p53, Cell biology, DNA-Binding Proteins, Physical Sciences, Signal transduction, Tumor Suppressor Protein p53, DNA Damage, Signal Transduction

Abstract

The tumor suppressor p53 mainly induces cell cycle arrest/DNA repair or apoptosis in the DNA damage response. How to choose between these two outcomes is not fully understood. We proposed a four-module model of the p53 signaling network and associated the network dynamics with cellular outcomes after ionizing radiation. We found that the cellular response is mediated by both the level and posttranslational modifications of p53 and that p53 is activated in a progressive manner. First, p53 is partially activated by primary modifications such as phosphorylation at Ser-15/20 to induce cell cycle arrest, with its level varying in a series of pulses. If the damage cannot be fixed after a critical number of p53 pulses, then p53 is fully activated by further modifications such as phosphorylation at Ser-46 to trigger apoptosis, with its concentration switching to rather high levels. Thus, p53 undergoes a two-phase response in irreparably damaged cells. Such combinations of pulsatile and switch-like behaviors of p53 may represent a flexible and efficient control mode, avoiding the premature apoptosis and promoting the execution of apoptosis. In our model, p53 pulses are recurrently driven by ataxia telangiectasia mutated (ATM) pulses triggered by DNA damage. The p53-Mdm2 and ATM-p53-Wip1 negative feedback loops are responsible for p53 pulses, whereas the switching behavior occurs when the p53-PTEN-Akt-Mdm2 positive feedback loop becomes dominant. Our results suggest that a sequential predominance of distinct feedback loops may elicit multiple-phase dynamical behaviors. This work provides a new mechanism for p53 dynamics and cell fate decision.

Published

2011

5. Two-phase dynamics of p53 in the DNA damage response.

Author

Xiao-Peng Zhang, Feng Liu, and Wei Wang

Subjects

P53 antioncogene, APOPTOSIS, DNA damage, IONIZING radiation, PHOSPHORYLATION, CELL cycle

Abstract

The tumor suppressor p53 mainly induces cell cycle arrest/DNA repair or apoptosis in the DNA damage response. How to choose between these two outcomes is not fully understood. We proposed a four-module model of the p53 signaling network and associated the network dynamics with cellular outcomes after ionizing radiation. We found that the cellular response is mediated by both the level and posttranslational modifications of p53 and that p53 is activated in a progressive manner. First, p53 is partially activated by primary modifications such as phosphorylation at Ser-15/20 to induce cell cycle arrest, with its level varying in a series of pulses. If the damage cannot be fixed after a critical number of p53 pulses, then p53 is fully activated by further modifications such as phosphorylation at Ser-46 to trigger apoptosis, with its concentration switching to rather high levels. Thus, p53 undergoes a two-phase response in irreparably damaged cells: Such combinations of pulsatile and switch-like behaviors of p53 may represent a flexible and efficient control mode, avoiding the premature apoptosis and promoting the execution of apoptosis. In our model, p53 pulses are recurrently driven by ataxia telangiectasia mutated (ATM) pulses triggered by DNA damage. The p53-Mdm2 and ATM-p53-Wip1 negative feedback loops are responsible for p53 pulses, whereas the switching behavior occurs when the p53-PTEN-Akt-Mdm2 positive feedback loop becomes dominant Our results suggest that a sequential predominance of distinct feedback loops may elicit multiple-phase dynamical behaviors. This work provides a new mechanism for p53 dynamics and cell fate decision. [ABSTRACT FROM AUTHOR]

Published

2011

6. Rpd3 regulates single-copy origins independently of the rDNA array by opposing Fkh1-mediated origin stimulation.

Author

Yiwei He, Petrie, Meghan V., Haiyang Zhang, Peace, Jared M., and Aparicio, Oscar M.

Subjects

RECOMBINANT DNA, HISTONE deacetylase, SUPPRESSOR mutation, DELETION mutation, CHROMOSOMES

Abstract

Eukaryotic chromosomes are organized into structural and functional domains with characteristic replication timings, which are thought to contribute to epigenetic programming and genome stability. Differential replication timing results from epigenetic mechanisms that positively and negatively regulate the competition for limiting replication initiation factors. Histone deacetylase Sir2 negatively regulates initiation of the multicopy (∼150) rDNA origins, while Rpd3 histone deacetylase negatively regulates firing of single-copy origins. However, Rpd3’s effect on single-copy origins might derive indirectly from a positive function for Rpd3 in rDNA origin firing shifting the competitive balance. Our quantitative experiments support the idea that origins compete for limiting factors; however, our results show that Rpd3’s effect on single-copy origin is independent of rDNA copy-number and of Sir2’s effects on rDNA origin firing. Whereas RPD3 deletion and SIR2 deletion alter the early S phase dynamics of single copy and rDNA origin firings in opposite fashion, unexpectedly only RPD3 deletion suppresses overall rDNA origin efficiency across S phase. Increased origin activation in rpd3Δ requires Fkh1/2, suggesting that Rpd3 opposes Fkh1/2-origin stimulation, which involves recruitment of Dbf4-dependent kinase (DDK). Indeed, Fkh1 binding increases at Rpd3-regulated origins in rpd3Δ cells in G1, supporting a mechanism whereby Rpd3 influences initiation timing of single-copy origins directly through modulation of Fkh1-origin binding. Genetic suppression of a DBF4 hypomorphic mutation by RPD3 deletion further supports the conclusion that Rpd3 impedes DDK recruitment by Fkh1, revealing a mechanism of Rpd3 in origin regulation. [ABSTRACT FROM AUTHOR]

Published

2022

7. Chemical pumps and flexible sheets spontaneously form self-regulating oscillators in solution.

Author

Manna, Raj Kumar, Shklyaev, Oleg E., and Balazs, Anna C.

Subjects

CARDIAC contraction, SPATIAL behavior, MYOCARDIUM, MYXOMYCETES, MUSCLE contraction, CATALYTIC reforming, FLEXIBLE packaging

Abstract

The synchronization of self-oscillating systems is vital to various biological functions, from the coordinated contraction of heart muscle to the self-organization of slime molds. Through modeling, we design bioinspired materials systems that spontaneously form shape-changing self-oscillators, which communicate to synchronize both their temporal and spatial behavior. Here, catalytic reactions at the bottom of a fluid-filled chamber and on mobile, flexible sheets generate the energy to "pump" the surrounding fluid, which also transports the immersed sheets. The sheets exert a force on the fluid that modifies the flow, which in turn affects the shape and movement of the flexible sheets. This feedback enables a single coated (active) and even an uncoated (passive) sheet to undergo self-oscillation, displaying different oscillatory modes with increases in the catalytic reaction rate. Two sheets (active or passive) introduce excluded volume, steric interactions. This distinctive combination of the hydrodynamic, fluid-structure, and steric interactions causes the sheets to form coupled oscillators, whose motion is synchronized in time and space. We develop a heuristic model that rationalizes this behavior. These coupled self-oscillators exhibit rich and tunable phase dynamics, which depends on the sheets' initial placement, coverage by catalyst and relative size. Moreover, through variations in the reactant concentration, the system can switch between the different oscillatory modes. This breadth of dynamic behavior expands the functionality of the coupled oscillators, enabling soft robots to display a variety of self-sustained, self-regulating moves. [ABSTRACT FROM AUTHOR]

Published

2021

8. Climate forcing controls on carbon terrestrial fluxes during shale weathering.

Author

Stolze, Lucien, Arora, Bhavna, Dwivedi, Dipankar, Steefel, Carl I., Toshiyuki Bandai, Yuxin Wu, and Nico, Peter

Subjects

ENVIRONMENTAL engineering, SHALE, SOIL respiration, WEATHERING, MICROBIAL respiration, SHALE gas industry, ACID mine drainage, ORGANIC foods, RECLAMATION of land

Abstract

Climate influences near-surface biogeochemical processes and thereby determines the partitioning of carbon dioxide (CO2) in shale, and yet the controls on carbon (C) weathering fluxes remain poorly constrained. Using a dataset that characterizes biogeochemical responses to climate forcing in shale regolith, we implement a numerical model that describes the effects of water infiltration events, gas exchange, and temperature fluctuations on soil respiration and mineral weathering at a seasonal timescale. Our modeling approach allows us to quantitatively disentangle the controls of transient climate forcing and biogeochemical mechanisms on C partitioning. We find that ~3% of soil CO2 (1.02 mol C/m²/y) is exported to the subsurface during large infiltration events. Here, net atmospheric CO2 drawdown primarily occurs during spring snowmelt, governs the aqueous C exports (61%), and exceeds the CO2 flux generated by pyrite and petrogenic organic matter oxidation (~0.2 mol C/m²/y). We show that shale CO2 consumption results from the temporal coupling between soil microbial respiration and carbonate weathering. This coupling is driven by the impacts of hydrologic fluctuations on fresh organic matter availability and CO2 transport to the weathering front. Diffusion-limited transport of gases under transient hydrological conditions exerts an important control on CO2(g) egress patterns and thus must be considered when inferring soil CO2 drawdown from the gas phase composition. Our findings emphasize the importance of seasonal climate forcing in shaping the net contribution of shale weathering to terrestrial C fluxes and suggest that warmer conditions could reduce the potential for shale weathering to act as a CO2 sink. [ABSTRACT FROM AUTHOR]

Published

2024

9. How policies and actor strategies affect electric vehicle diffusion and wider sustainability transitions.

Author

Ryghaug, Marianne and Skjølsvold, Tomas Moe

Subjects

ELECTRIC vehicles, ELECTRIC batteries, TRANSFORMATIVE learning, PRESSURE groups, SUSTAINABILITY

Abstract

Implementing electromobility is a central component in the de-carbonization of personal mobility. In recent years, the absolute number of electric vehicles (EVs) and their market share has increased sharply in many countries. This paper focuses on Norway, a pioneer market for EVs that other countries can learn from. The analysis highlights how a combination of local and national policies over a 30-y period, which targeted both industry development and vehicle demand, were important drivers of this development. It also highlights the importance of advocacy groups and strong networks in promoting EVs, as well as changes in user preferences. The paper demonstrates how the EV diffusion has been driven by alignments of multiple processes across different levels, involving interactions between multiple actors and social groups with different interests and views about desirable futures as described by the multi-level perspective (MLP). Building on the MLP, the study of EV diffusion in Norway illustrates how niches are often sustained through demonstrations, experimentation, strategic alliances, and actors securing favorable political and economic conditions. Further, it shows how local or national niches may depend on international regime actors, such as the car manufacturing industry and policies developed abroad. The paper also explores how the introduction of EVs has opened for wider effects, including innovation within production-consumption systems beyond mobility. Based on this analysis, we argue for a nuanced perspective on the relationship between incremental, regime-internal innovation, and wider transformative changes, where the merits of societal learning and experience with battery electricity for transportation are highlighted. [ABSTRACT FROM AUTHOR]

Published

2023

10. Phase separation and molecular ordering of the prion-like domain of the Arabidopsis thermosensory protein EARLY FLOWERING 3.

Author

Hutin, Stephanie, Kumita, Janet R., Strotmann, Vivien I., Dolata, Anika, Ling, Wai Li, Louafi, Nessim, Popov, Anton, Milhiet, Pierre- Emmanuel, Blackledge, Martin, Nanao, Max H., Wigge, Philip A., Stahl, Yvonne, Costa, Luca, Tully, Mark D., and Zubieta, Chloe

Subjects

ARABIDOPSIS proteins, PHASE separation, SMALL-angle X-ray scattering, ATOMIC force microscopy, CONDENSED matter

Abstract

Liquid–liquid phase separation (LLPS) is an important mechanism enabling the dynamic compartmentalization of macromolecules, including complex polymers such as proteins and nucleic acids, and occurs as a function of the physicochemical environment. In the model plant, Arabidopsis thaliana, LLPS by the protein EARLY FLOWERING3 (ELF3) occurs in a temperature-sensitive manner and controls thermoresponsive growth. ELF3 contains a largely unstructured prion-like domain (PrLD) that acts as a driver of LLPS in vivo and in vitro. The PrLD contains a poly-glutamine (polyQ) tract, whose length varies across natural Arabidopsis accessions. Here, we use a combination of biochemical, biophysical, and structural techniques to investigate the dilute and condensed phases of the ELF3 PrLD with varying polyQ lengths. We demonstrate that the dilute phase of the ELF3 PrLD forms a monodisperse higher-order oligomer that does not depend on the presence of the polyQ sequence. This species undergoes LLPS in a pH- and temperature-sensitive manner and the polyQ region of the protein tunes the initial stages of phase separation. The liquid phase rapidly undergoes aging and forms a hydrogel as shown by fluorescence and atomic force microscopies. Furthermore, we demonstrate that the hydrogel assumes a semiordered structure as determined by small-angle X-ray scattering, electron microscopy, and X-ray diffraction. These experiments demonstrate a rich structural landscape for a PrLD protein and provide a framework to describe the structural and biophysical properties of biomolecular condensates. [ABSTRACT FROM AUTHOR]

Published

2023

11. Spontaneous phase coordination and fluid pumping in model ciliary carpets.

Author

Kanale, Anup V., Feng Ling, Hanliang Guo, Fürthauer, Sebastian, and Kansoa, Eva

Subjects

STOKES flow, GENITALIA, CARPETS, CILIA & ciliary motion, FLUIDS

Abstract

Ciliated tissues, such as in the mammalian lungs, brains, and reproductive tracts, are specialized to pump fluid. They generate flows by the collective activity of hundreds of thousands of individual cilia that beat in a striking metachronal wave pattern. Despite progress in analyzing cilia coordination, a general theory that links coordination and fluid pumping in the limit of large arrays of cilia remains lacking. Here, we conduct in silico experiments with thousands of hydrodynamically interacting cilia, and we develop a continuum theory in the limit of infinitely many independently beating cilia by combining tools from active matter and classical Stokes flow. We find, in both simulations and theory, that isotropic and synchronized ciliary states are unstable. Traveling waves emerge regardless of initial conditions, but the characteristics of the wave and net flows depend on cilia and tissue properties. That is, metachronal phase coordination is a stable global attractor in large ciliary carpets, even under finite perturbations to cilia and tissue properties. These results support the notion that functional specificity of ciliated tissues is interlaced with the tissue architecture and cilia beat kinematics and open up the prospect of establishing structure to function maps from cilium-level beat to tissue-level coordination and fluid pumping. [ABSTRACT FROM AUTHOR]

Published

2022

12. Phase tuning of multiple Andreev reflections of Dirac fermions and the Josephson supercurrent in Al–MoTe2–Al junctions.

Author

Zheyi Zhu, Kim, Stephan, Shiming Lei, Schoop, Leslie M., Cava, R. J., and Ong, N. P.

Subjects

ANDREEV reflection, COOPER pair, FERMIONS, SUPERCONDUCTORS, SUPERCONDUCTIVITY

Abstract

When an electron is incident on a superconductor from a metal, it is reflected as a hole in a process called Andreev reflection. If the metal N is sandwiched between two superconductors S in an SNS junction, multiple Andreev reflections (MARs) occur. We have found that, in SNS junctions with high transparency (τ → 1) based on the Dirac semimetal MoTe2, the MAR features are observed with exceptional resolution. By tuning the phase difference φ between the bracketing Al superconductors, we establish that the MARs coexist with a Josephson supercurrent Is=IA sinφ. As we vary the junction voltage V, the supercurrent amplitude IA varies in step with the MAR order n, revealing a direct relation between them. Two successive Andreev reflections serve to shuttle a Cooper pair across the junction. If the pair is shuttled coherently, it contributes to Is. The experiment measures the fraction of pairs shuttled coherently vs. V. Surprisingly, superconductivity in MoTe2 does not affect the MAR features. [ABSTRACT FROM AUTHOR]

Published

2022

13. Rather than resonance, flapping wing flyers may play on aerodynamics to improve performance.

Author

Ramananarivo, Sophie, Godoy-Diana, Ramiro, and Thiria, Benjamin

Subjects

*ANIMAL locomotion, *ANIMAL flight, *WINGS (Anatomy), *AERODYNAMICS, *ELASTICITY, *RESONANCE

Abstract

Saving energy and enhancing performance are secular preoccupations shared by both nature and human beings. In animal locomotion, flapping flyers or swimmers rely on the flexibility of their wings or body to passively increase their efficiency using an appropriate cycle of storing and releasing elastic energy. Despite the convergence of many observations pointing out this feature, the underlying mechanisms explaining how the elastic nature of the wings is related to propulsive efficiency remain unclear. Here we use an experiment with a self-propelled simplified insect model allowing to show how wing compliance governs the performance of flapping flyers. Reducing the description of the flapping wing to a forced oscillator model, we pinpoint different nonlinear effects that can account for the observed behavior-in particular a set of cubic nonlinearities coming from the clamped-free beam equation used to model the wing and a quadratic damping term representing the fluid drag associated to the fast flapping motion. In. contrast to what has been repeatedly suggested in the literature, we show that flapping flyers optimize their performance not by especially looking for resonance to achieve larger flapping amplitudes with less effort, but by tuning the temporal evolution of the wing shape (i.e., the phase dynamics in the oscillator model) to optimize the aerodynamics. [ABSTRACT FROM AUTHOR]

Published

2011

14. Systematic modeling-driven experiments identify distinct molecular clockworks underlying hierarchically organized pacemaker neurons.

Author

Eui Min Jeong, Miri Kwon, Eunjoo Cho, Sang Hyuk Lee, Hyun Kim, Eun Young Kim (김은영), and Jae Kyoung Kim

Subjects

NEURONS, TRANSCRIPTION factors, DROSOPHILA

Abstract

In metazoan organisms, circadian (∼24 h) rhythms are regulated by pacemaker neurons organized in a master–slave hierarchy. Although it is widely accepted that master pacemakers and slave oscillators generate rhythms via an identical negative feedback loop of transcription factor CLOCK (CLK) and repressor PERIOD (PER), their different roles imply heterogeneity in their molecular clockworks. Indeed, in Drosophila, defective binding between CLK and PER disrupts molecular rhythms in the master pacemakers, small ventral lateral neurons (sLNvs), but not in the slave oscillator, posterior dorsal neuron 1s (DN1ps). Here, we develop a systematic and expandable approach that unbiasedly searches the source of the heterogeneity in molecular clockworks from time-series data. In combination with in vivo experiments, we find that sLNvs exhibit higher synthesis and turnover of PER and lower CLK levels than DN1ps. Importantly, light shift analysis reveals that due to such a distinct molecular clockwork, sLNvs can obtain paradoxical characteristics as the master pacemaker, generating strong rhythms that are also flexibly adjustable to environmental changes. Our results identify the different characteristics of molecular clockworks of pacemaker neurons that underlie hierarchical multi-oscillator structure to ensure the rhythmic fitness of the organism. [ABSTRACT FROM AUTHOR]

Published

2022

15. Phase coupling and synchrony in the spatiotemporal dynamis of muskrat and mink populations....

Author

Haydon, D.T., Stenseth, N.C., Boyce, M.S., and Greenwood, P.E.

Subjects

*MUSKRAT, *MINKS

Abstract

Examines the phase coupling and synchrony in the spatiotemporal dynamics of muskrat and mink populations in Canada. Correlation between amplitudes and time-series; Identification of the cyclic minima; Causes of differences in regional phase dynamics.

Published

2001

16. A multiscale biophysical model gives quantized metachronal waves in a lattice of beating cilia.

Author

Chakrabarti, Brato, Fürthauer, Sebastian, and Shelley, Michael J.

Subjects

MULTISCALE modeling, CILIA & ciliary motion, MOLECULAR motor proteins, COLLECTIVE behavior, MILLIMETER waves

Abstract

Motile cilia are slender, hair-like cellular appendages that spontaneously oscillate under the action of internal molecular motors and are typically found in dense arrays. These active filaments coordinate their beating to generate metachronal waves that drive long-range fluid transport and locomotion. Until now, our understanding of their collective behavior largely comes from the study of minimal models that coarse grain the relevant biophysics and the hydrodynamics of slender structures. Here we build on a detailed biophysical model to elucidate the emergence of metachronal waves on millimeter scales fromnanometerscale motor activity inside individual cilia. Our study of a one-dimensional lattice of cilia in the presence of hydrodynamic and steric interactions reveals how metachronal waves are formed andmaintained. We find that, in homogeneous beds of cilia, these interactions lead to multiple attracting states, all of which are characterized by an integer charge that is conserved. This even allows us to design initial conditions that lead to predictable emergent states. Finally, and very importantly, we show that, in nonuniform ciliary tissues, boundaries and inhomogeneities provide a robust route to metachronal waves. [ABSTRACT FROM AUTHOR]

Published

2022

17. Observing the loss and revival of long-range phase coherence through disorder quenches.

Author

Nagler, Benjamin, Barbosa, Sian, Koch, Jennifer, Orso, Giuliano, and Widera, Artur

Subjects

QUANTUM theory, QUANTUM fluids, GROSS-Pitaevskii equations, QUANTUM gases, QUANTUM coherence

Abstract

Relaxation of quantum systems is a central problem in nonequilibrium physics. In contrast to classical systems, the underlying quantum dynamics results not only from atomic interactions but also from the long-range coherence of the many-body wave function. Experimentally, nonequilibrium states of quantum fluids are usually created using moving objects or laser potentials, directly perturbing and detecting the system's density. However, the fate of long-range phase coherence for hydrodynamic motion of disordered quantum systems is less explored, especially in three dimensions. Here, we unravel how the density and phase coherence of a Bose-Einstein condensate of 6Li2 molecules respond upon quenching on or off an optical speckle potential. We find that, as the disorder is switched on, long-range phase coherence breaks down one order of magnitude faster than the density of the quantum gas responds. After removing it, the system needs two orders of magnitude longer times to reestablish quantum coherence, compared to the density response. We compare our results with numerical simulations of the Gross-Pitaevskii equation on large three-dimensional grids, finding an overall good agreement. Our results shed light on the importance of longrange coherence and possibly long-lived phase excitations for the relaxation of nonequilibrium quantum many-body systems. [ABSTRACT FROM AUTHOR]

Published

2022

18. Polarization and tipping points.

Author

Macy, Michael W., Manqing Ma, Tabin, Daniel R., Jianxi Gao, and Szymanski, Boleslaw K.

Subjects

PHASE diagrams, POLITICAL elites, ATTITUDE change (Psychology), PHASE transitions, POLARIZATION (Social sciences)

Abstract

Research has documented increasing partisan division and extremist positions that are more pronounced among political elites than among voters. Attention has now begun to focus on how polarization might be attenuated. We use a general model of opinion change to see if the self-reinforcing dynamics of influence and homophily may be characterized by tipping points that make reversibility problematic. The model applies to a legislative body or other small, densely connected organization, but does not assume country-specific institutional arrangements that would obscure the identification of fundamental regularities in the phase transitions. Agents in the model have initially random locations in a multidimensional issue space consisting of membership in one of two equal-sized parties and positions on 10 issues. Agents then update their issue positions by moving closer to nearby neighbors and farther from those with whom they disagree, depending on the agents’ tolerance of disagreement and strength of party identification compared to their ideological commitment to the issues. We conducted computational experiments in which we manipulated agents’ tolerance for disagreement and strength of party identification. Importantly, we also introduced exogenous shocks corresponding to events that create a shared interest against a common threat (e.g., a global pandemic). Phase diagrams of political polarization reveal difficult-to-predict transitions that can be irreversible due to asymmetric hysteresis trajectories. We conclude that future empirical research needs to pay much closer attention to the identification of tipping points and the effectiveness of possible counter measures. [ABSTRACT FROM AUTHOR]

Published

2021

19. Cone photoreceptor dysfunction in retinitis pigmentosa revealed by optoretinography.

Author

Lassoued, Ayoub, Furu Zhang, Kazuhiro Kurokawa, Yan Liu, Bernucci, Marcel T., Crowell, James A., and Miller, Donald T.

Subjects

RETINITIS pigmentosa, CONES, OPTICAL coherence tomography, SPATIAL resolution, PHOTORECEPTORS

Abstract

Retinitis pigmentosa (RP) is the most common group of inherited retinal degenerative diseases, whose most debilitating phase is cone photoreceptor death. Perimetric and electroretinographic methods are the gold standards for diagnosing and monitoring RP and assessing cone function. However, these methods lack the spatial resolution and sensitivity to assess disease progression at the level of individual photoreceptor cells, where the disease originates and whose degradation causes vision loss. High-resolution retinal imaging methods permit visualization of human cone cells in vivo but have only recently achieved sufficient sensitivity to observe their function as manifested in the cone optoretinogram. By imaging with phase-sensitive adaptive optics optical coherence tomography, we identify a biomarker in the cone optoretinogram that characterizes individual cone dysfunction by stimulating cone cells with flashes of light and measuring nanometer-scale changes in their outer segments. We find that cone optoretinographic responses decrease with increasing RP severity and that even in areas where cone density appears normal, cones can respond differently than those in controls. Unexpectedly, in the most severely diseased patches examined, we find isolated cones that respond normally. Short-wavelength-sensitive cones are found to be more vulnerable to RP than medium- and long-wavelength-sensitive cones. We find that decreases in cone response and cone outersegment length arise earlier in RP than changes in cone density but that decreases in response and length are not necessarily correlated within single cones. [ABSTRACT FROM AUTHOR]

Published

2021

20. Increasing and decreasing interregional brain coupling increases and decreases oscillatory activity in the human brain.

Author

Sel, Alejandra, Verhagen, Lennart, Angerer, Katharina, David, Raluca, Klein-Flügge, Miriam C., and Rushworth, Matthew F. S.

Subjects

BETA rhythm, TRANSCRANIAL magnetic stimulation, THETA rhythm, PREMOTOR cortex, ALPHA rhythm

Abstract

The origins of oscillatory activity in the brain are currently debated, but common to many hypotheses is the notion that they reflect interactions between brain areas. Here, we examine this possibility by manipulating the strength of coupling between two human brain regions, ventral premotor cortex (PMv) and primary motor cortex (M1), and examine the impact on oscillatory activity in the motor system measurable in the electroencephalogram. We either increased or decreased the strength of coupling while holding the impact on each component area in the pathway constant. This was achieved by stimulating PMv and M1 with paired pulses of transcranial magnetic stimulation using two different patterns, only one of which increases the influence exerted by PMv over M1. While the stimulation protocols differed in their temporal patterning, they were comprised of identical numbers of pulses to M1 and PMv. We measured the impact on activity in alpha, beta, and theta bands during a motor task in which participants either made a preprepared action (Go) or withheld it (No-Go). Augmenting cortical connectivity between PMv andM1, by evoking synchronous pre- and postsynaptic activity in the PMv-M1 pathway, enhanced oscillatory beta and theta rhythms in Go and No-Go trials, respectively. Little change was observed in the alpha rhythm. By contrast, diminishing the influence of PMv over M1 decreased oscillatory beta and theta rhythms in Go and No-Go trials, respectively. This suggests that corticocortical communication frequencies in the PMv-M1 pathway can be manipulated following Hebbian spike-timing-dependent plasticity. [ABSTRACT FROM AUTHOR]

Published

2021

21. Recurrent dynamics in the cerebral cortex: Integration of sensory evidence with stored knowledge.

Author

Singer, Wolf

Subjects

CEREBRAL cortex, SENSORIMOTOR integration, DEEP learning, FEATURE extraction, EVIDENCE, PREDICTIVE tests, PATIENT discharge instructions

Abstract

Current concepts of sensory processing in the cerebral cortex emphasize serial extraction and recombination of features in hierarchically structured feed-forward networks in order to capture the relations among the components of perceptual objects. These concepts are implemented in convolutional deep learning networks and have been validated by the astounding similarities between the functional properties of artificial systems and their natural counterparts. However, cortical architectures also display an abundance of recurrent coupling within and between the layers of the processing hierarchy. This massive recurrence gives rise to highly complex dynamics whose putative function is poorly understood. Here a concept is proposed that assigns specific functions to the dynamics of cortical networks and combines, in a unifying approach, the respective advantages of recurrent and feed-forward processing. It is proposed that the priors about regularities of the world are stored in the weight distributions of feed-forward and recurrent connections and that the high-dimensional, dynamic space provided by recurrent interactions is exploited for computations. These comprise the ultrafast matching of sensory evidence with the priors covertly represented in the correlation structure of spontaneous activity and the context-dependent grouping of feature constellations characterizing natural objects. The concept posits that information is encoded not only in the discharge frequency of neurons but also in the precise timing relations among the discharges. Results of experiments designed to test the predictions derived from this concept support the hypothesis that cerebral cortex exploits the high-dimensional recurrent dynamics for computations serving predictive coding. [ABSTRACT FROM AUTHOR]

Published

2021

22. Active topolectrical circuits.

Author

Kotwal, Tejas, Moseley, Fischer, Stegmaier, Alexander, Imhof, Stefan, Brand, Hauke, Kießling, Tobias, Thomale, Ronny, Ronellenfitsch, Henrik, and Dunkel, Jörn

Subjects

ELECTRIC circuits, ELECTRONIC systems, AUTONOMOUS vehicles, CELLULAR signal transduction, OSCILLATIONS

Abstract

The transfer of topological concepts from the quantum world to classical mechanical and electronic systems has opened fundamentally different approaches to protected information transmission and wave guidance. A particularly promising emergent technology is based on recently discovered topolectrical circuits that achieve robust electric signal transduction by mimicking edge currents in quantum Hall systems. In parallel, modern active matter research has shown how autonomous units driven by internal energy reservoirs can spontaneously self-organize into collective coherent dynamics. Here, we unify key ideas from these two previously disparate fields to develop design principles for active topolectrical circuits (ATCs) that can selfexcite topologically protected global signal patterns. Realizing autonomous active units through nonlinear Chua diode circuits, we theoretically predict and experimentally confirm the emergence of self-organized protected edge oscillations in one- and two-dimensional ATCs. The close agreement between theory, simulations, and experiments implies that nonlinear ATCs provide a robust and versatile platform for developing high-dimensional autonomous electrical circuits with topologically protected functionalities. [ABSTRACT FROM AUTHOR]

Published

2021

23. Physics successfully implements Lagrange multiplier optimization.

Author

Vadlamani, Sri Krishna, Tianyao Patrick Xiao, and Yablonovitch, Eli

Subjects

LAGRANGE multiplier, QUANTUM annealing, MATHEMATICAL optimization, VARIATIONAL principles, SIMULATED annealing

Abstract

Optimization is a major part of human effort. While being mathematical, optimization is also built into physics. For example, physics has the Principle of Least Action; the Principle of Minimum Power Dissipation, also called Minimum Entropy Generation; and the Variational Principle. Physics also has Physical Annealing, which, of course, preceded computational Simulated Annealing. Physics has the Adiabatic Principle, which, in its quantum form, is called Quantum Annealing. Thus, physical machines can solve the mathematical problem of optimization, including constraints. Binary constraints can be built into the physical optimization. In that case, the machines are digital in the same sense that a flip-flop is digital. A wide variety of machines have had recent success at optimizing the Ising magnetic energy. We demonstrate in this paper that almost all those machines perform optimization according to the Principle of Minimum Power Dissipation as put forth by Onsager. Further, we show that this optimization is in fact equivalent to Lagrange multiplier optimization for constrained problems. We find that the physical gain coefficients that drive those systems actually play the role of the corresponding Lagrange multipliers. [ABSTRACT FROM AUTHOR]

Published

2020

24. Anoxic photogeochemical oxidation of manganese carbonate yields manganese oxide.

Author

Winnie Liu, Jihua Hao, Elzinga, Evert J., Piotrowiak, Piotr, Nanda, Vikas, Yee, Nathan, and Falkowski, Paul G.

Subjects

MANGANESE oxides, MANGANESE, SURFACE of the earth, OZONE layer, OXIDATION states

Abstract

The oxidation states of manganese minerals in the geological record have been interpreted as proxies for the evolution of molecular oxygen in the Archean eon. Here we report that an Archean manganese mineral, rhodochrosite (MnCO3), can be photochemically oxidized by light under anoxic, abiotic conditions. Rhodochrosite has a calculated bandgap of about 5.4 eV, corresponding to light energy centering around 230 nm. Light at that wavelength would have been present on Earth's surface in the Archean, prior to the formation of stratospheric ozone. We show experimentally that the photooxidation of rhodochrosite in suspension with light centered at 230 nm produced H2 gas and manganite (?-MnOOH) with an apparent quantum yield of 1.37 × 10-3 moles hydrogen per moles incident photons. Our results suggest that manganese oxides could have formed abiotically on the surface in shallow waters and on continents during the Archean eon in the absence of molecular oxygen. [ABSTRACT FROM AUTHOR]

Published

2020

25. Cavity molecular dynamics simulations of liquid water under vibrational ultrastrong coupling.

Author

Tao E. Li, Subotnik, Joseph E., and Nitzan, Abraham

Subjects

MOLECULAR dynamics, INFRARED spectra, WATER, DIFFUSION

Abstract

We simulate vibrational strong coupling (VSC) and vibrational ultrastrong coupling (V-USC) for liquid water with classical molecular dynamics simulations. When the cavity modes are resonantly coupled to the O-H stretch mode of liquid water, the infrared spectrum shows asymmetric Rabi splitting. The lower polariton (LP) may be suppressed or enhanced relative to the upper polariton (UP) depending on the frequency of the cavity mode. Moreover, although the static properties and the translational diffusion of water are not changed under VSC or V-USC, we do find the modification of the orientational autocorrelation function of H2O molecules especially under V-USC, which could play a role in ground-state chemistry. [ABSTRACT FROM AUTHOR]

Published

2020

26. Entrainment of mammalian motile cilia in the brain with hydrodynamic forces.

Author

Pellicciotta, Nicola, Hamilton, Evelyn, Kotar, Jurij, Faucourt, Marion, Delgehyr, Nathalie, Spassky, Nathalie, and Cicuta, Pietro

Subjects

CILIA & ciliary motion, CEREBRAL ventricles, ENERGY consumption, CHLAMYDOMONAS, ANIMALS

Abstract

Motile cilia are widespread across the animal and plant kingdoms, displaying complex collective dynamics central to their physiology. Their coordination mechanism is not generally understood, with previous work mainly focusing on algae and protists. We study here the entrainment of cilia beat in multiciliated cells from brain ventricles. The response to controlled oscillatory external flows shows that flows at a similar frequency to the actively beating cilia can entrain cilia oscillations. We find that the hydrodynamic forces required for this entrainment strongly depend on the number of cilia per cell. Cells with few cilia (up to five) can be entrained at flows comparable to cilia-driven flows, in contrast with what was recently observed in Chlamydomonas. Experimental trends are quantitatively described by a model that accounts for hydrodynamic screening of packed cilia and the chemomechanical energy efficiency of the flagellar beat. Simulations of a minimal model of cilia interacting hydrodynamically show the same trends observed in cilia. [ABSTRACT FROM AUTHOR]

Published

2020

27. Optoretinography is coming of age.

Author

Roorda, Austin

Subjects

COMING of age, RETINAL ganglion cells

Published

2021

28. The generation and propagation of the human alpha rhythm.

Author

Halgren, Milan, Ulbert, István, Bastuji, Hélène, Fabó, Dániel, Erőss, Lorand, Rey, Marc, Devinsky, Orrin, Doyle, Werner K., Mak-McCully, Rachel, Halgren, Eric, Wittner, Lucia, Chauvel, Patrick, Heit, Gary, Eskandar, Emad, Mandell, Arnold, and Cash, Sydney S.

Subjects

ALPHA rhythm, SOMATOSENSORY cortex, THALAMOCORTICAL system, VISUAL cortex, REPRODUCTION

Abstract

The alpha rhythm is the longest-studied brain oscillation and has been theorized to play a key role in cognition. Still, its physiology is poorly understood. In this study, we used microelectrodes and macroelectrodes in surgical epilepsy patients to measure the intracortical and thalamic generators of the alpha rhythm during quiet wakefulness. We first found that alpha in both visual and somatosensory cortex propagates from higher-order to lower-order areas. In posterior cortex, alpha propagates from higher-order anterosuperior areas toward the occipital pole, whereas alpha in somatosensory cortex propagates from associative regions toward primary cortex. Several analyses suggest that this cortical alpha leads pulvinar alpha, complicating prevailing theories of a thalamic pacemaker. Finally, alpha is dominated by currents and firing in supragranular cortical layers. Together, these results suggest that the alpha rhythm likely reflects short-range supragranular feedback, which propagates from higher- to lower-order cortex and cortex to thalamus. These physiological insights suggest how alpha could mediate feedback throughout the thalamocortical system. [ABSTRACT FROM AUTHOR]

Published

2019

29. Native mass spectrometry reveals the conformational diversity of the UVR8 photoreceptor.

Author

Camacho, Inês S., Theisen, Alina, Johannissen, Linus O., Díaz-Ramos, L. Aranzazú, Christie, John M., Jenkins, Gareth I., Bellina, Bruno, Barran, Perdita, and Jones, Alex R.

Subjects

MASS spectrometry, PLANT photoreceptors, PLANT photomorphogenesis, HOMODIMERS, MONOMERS

Abstract

UVR8 is a plant photoreceptor protein that regulates photomorphogenic and protective responses to UV light. The inactive, homodimeric state absorbs UV-B light, resulting in dissociation into monomers, which are considered to be the active state and comprise a β-propeller core domain and intrinsically disordered N- and C-terminal tails. The C terminus is required for functional binding to signaling partner COP1. To date, however, structural studies have only been conducted with the core domain where the terminal tails have been truncated. Here, we report structural investigations of full-length UVR8 using native ion mobility mass spectrometry adapted for photoactivation. We show that, while truncated UVR8 photoconverts from a single conformation of dimers to a single monomer conformation, the full-length protein exists in numerous conformational families. The full-length dimer adopts both a compact state and an extended state where the C terminus is primed for activation. In the monomer the extended C terminus destabilizes the core domain to produce highly extended yet stable conformations, which we propose are the fully active states that bind COP1. Our results reveal the conformational diversity of full-length UVR8. We also demonstrate the potential power of native mass spectrometry to probe functionally important structural dynamics of photoreceptor proteins throughout nature. [ABSTRACT FROM AUTHOR]

Published

2019

30. Cortical circuit activity underlying sleep slow oscillations and spindles.

Author

Niethard, Niels, Hong-Viet V. Ngo, Born, Jan, and Ehrlich, Ingrid

Subjects

NEOCORTEX, MICE, SLOW wave sleep, ELECTROENCEPHALOGRAPHY, INTERNEURONS, PARVALBUMINS, HIPPOCAMPUS (Brain)

Abstract

Slow oscillations and sleep spindles are hallmarks of the EEG during slow-wave sleep (SWS). Both oscillatory events, especially when co-occurring in the constellation of spindles nesting in the slow oscillation upstate, are considered to support memory formation and underlying synaptic plasticity. The regulatory mechanisms of this function at the circuit level are poorly understood. Here, using two-photon imaging in mice, we relate EEG-recorded slow oscillations and spindles to calcium signals recorded from the soma of cortical putative pyramidal-like (Pyr) cells and neighboring parvalbumin-positive interneurons (PV-Ins) or somatostatin-positive interneurons (SOM-Ins). Pyr calcium activity was increased more than threefold when spindles co-occurred with slow oscillation upstates compared with slow oscillations or spindles occurring in isolation. Independent of whether or not a spindle was nested in the slow oscillation upstate, the slow oscillation downstate was preceded by enhanced calcium signal in SOM-Ins that vanished during the upstate, whereas spindles were associated with strongly increased PV-In calcium activity. Additional wide-field calcium imaging of Pyr cells confirmed the enhanced calcium activity and its widespread topography associated with spindles nested in slow oscillation upstates. In conclusion, when spindles are nested in slow oscillation upstates, maximum Pyr activity appears to concur with strong perisomatic inhibition of Pyr cells via PV-Ins and low dendritic inhibition via SOM-Ins (i.e., conditions that might optimize synaptic plasticity within local cortical circuits). [ABSTRACT FROM AUTHOR]

Published

2018

31. Rpd3 regulates single-copy origins independently of the rDNA array by opposing Fkh1-mediated origin stimulation

Author

He, Yiwei, Petrie, Meghan V., Zhang, Haiyang, Peace, Jared M., and Aparicio, Oscar M.

Published

2022

32. Artificial intelligence exploration of unstable protocells leads to predictable properties and discovery of collective behavior.

Author

Points, Laurie J., Taylor, James Ward, Grizou, Jonathan, Donkersa, Kevin, and Cronin, Leroy

Subjects

ARTIFICIAL intelligence, COMPUTER software, MACHINE theory, ROBOTICS, ANIMATRONICS

Abstract

Protocell models are used to investigate how cells might have first assembled on Earth. Some, like oil-in-water droplets, can be seemingly simple models, while able to exhibit complex and unpredictable behaviors. How such simple oil-in-water systems can come together to yield complex and life-like behaviors remains a key question. Herein, we illustrate how the combination of automated experimentation and image processing, physicochemical analysis, and machine learning allows significant advances to be made in understanding the driving forces behind oil-in-water droplet behaviors. Utilizing >7,000 experiments collected using an autonomous robotic platform, we illustrate how smart automation cannot only help with exploration, optimization, and discovery of new behaviors, but can also be core to developing fundamental understanding of such systems. Using this process, we were able to relate droplet formulation to behavior via predicted physical properties, and to identify and predict more occurrences of a rare collective droplet behavior, droplet swarming. Proton NMR spectroscopic and qualitative pH methods enabled us to better understand oil dissolution, chemical change, phase transitions, and droplet and aqueous phase flows, illustrating the utility of the combination of smart-automation and traditional analytical chemistry techniques. We further extended our study for the simultaneous exploration of both the oil and aqueous phases using a robotic platform. Overall, this work shows that the combination of chemistry, robotics, and artificial intelligence enables discovery, prediction, and mechanistic understanding in ways that no one approach could achieve alone. [ABSTRACT FROM AUTHOR]

Published

2018

33. Tracking the insulator-to-metal phase transition in VO2 with few-femtosecond extreme UV transient absorption spectroscopy.

Author

Jager, Marieke F., Ott, Christian, Kraus, Peter M., Kaplan, Christopher J., Pouse, Winston, Marvel, Robert E., Haglund, Richard F., Neumark, Daniel M., and Leone, Stephen R.

Subjects

VANADIUM dioxide, METAL-insulator transitions, PHASE transitions, FEMTOSECOND lasers, ULTRAVIOLET spectroscopy

Abstract

Coulomb correlations can manifest in exotic properties in solids, but how these properties can be accessed and ultimately manipulated in real time is not well understood. The insulator-to-metal phase transition in vanadium dioxide (VO2) is a canonical example of such correlations. Here, few-femtosecond extreme UV transient absorption spectroscopy (FXTAS) at the vanadium M2,3 edge is used to track the insulator-to-metal phase transition in VO2. This technique allows observation of the bulk material in real time, follows the photoexcitation process in both the insulating and metallic phases, probes the subsequent relaxation in the metallic phase, and measures the phase-transition dynamics in the insulating phase. An understanding of the VO2 absorption spectrum in the extreme UV is developed using atomic cluster model calculations, revealing V3+/d² character of the vanadium center. We find that the insulator-to-metal phase transition occurs on a timescale of 26 ± 6 fs and leaves the system in a long-lived excited state of the metallic phase, driven by a change in orbital occupation. Potential interpretations based on electronic screening effects and lattice dynamics are discussed. A Mott-Hubbard-type mechanism is favored, as the observed timescales and d² nature of the vanadium metal centers are inconsistent with a Peierls driving force. The findings provide a combined experimental and theoretical roadmap for using time-resolved extreme UV spectroscopy to investigate nonequilibrium dynamics in strongly correlated materials. [ABSTRACT FROM AUTHOR]

Published

2017

34. Modeling the response of a tumor-suppressive network to mitogenic and oncogenic signals.

Author

Xinyu Tian, Bo Huang, Xiao-Peng Zhang, Mingyang Lu, Feng Liu, Onuchic, José N., and Wei Wang

Subjects

TUMOR genetics, ONCOGENIC viruses, CELL proliferation, TUMOR antigens, APOPTOSIS, PHYSIOLOGY

Abstract

Intrinsic tumor-suppressive mechanisms protect normal cells against aberrant proliferation. Although cellular signaling pathways engaged in tumor repression have been largely identified, how they are orchestrated to fulfill their function still remains elusive. Here, we built a tumor-suppressive network model composed of three modules responsible for the regulation of cell proliferation, activation of p53, and induction of apoptosis. Numerical simulations show a rich repertoire of network dynamics when normal cells are subject to serum stimulation and adenovirus E1A overexpression. We showed that oncogenic signaling induces ARF and that ARF further promotes p53 activation to inhibit proliferation. Mitogenic signaling activates E2F activators and promotes Akt activation. p53 and E2F1 cooperate to induce apoptosis, whereas Akt phosphorylates p21 to repress caspase activation. These prosurvival and proapoptotic signals compete to dictate the cell fate of proliferation, cell-cycle arrest, or apoptosis. The cellular outcome is also impacted by the kinetic mode (ultrasensitivity or bistability) of p53. When cells are exposed to serum deprivation and recovery under fixed E1A, the shortest starvation time required for apoptosis induction depends on the terminal serum concentration, which was interpreted in terms of the dynamics of caspase-3 activation and cytochrome c release. We discovered that caspase-3 can be maintained active at high serum concentrations and that E1A overexpression sensitizes serum-starved cells to apoptosis. This work elucidates the roles of tumor repressors and prosurvival factors in tumor repression based on a dynamic network analysis and provides a framework for quantitatively exploring tumor-suppressive mechanisms. [ABSTRACT FROM AUTHOR]

Published

2017

35. Geography of forest disturbance.

Author

Asner, Gregory P.

Subjects

FORESTS & forestry, ECOLOGICAL disturbances, GEOGRAPHY, BIOTIC communities

Abstract

The author discusses a report by J. Q. Chambers and colleagues concerning the steady-state succession and disturbance mosaic across the forest landscape in Central Amazon. The author says that the work provides a fresh perspective on the strategies in addressing challenge to quantify and understand forest disturbance regimes. He adds that the drivers of subsequent biotic responses and disturbance show a geographic variation.

Published

2013

36. CRYPTOCHROME mediates behavioral executive choice in response to UV light.

Author

Baik, Lisa S., Fogle, Keri J., Roberts, Logan, Galschiodt, Alexis M., Chevez, Joshua A., Recinos, Yocelyn, Nguy, Vinh, and Holmes, Todd C.

Subjects

CRYPTOCHROMES, ELECTROPHYSIOLOGY, PHYSIOLOGICAL effects of blue light, CIRCADIAN rhythms, NEURONS

Abstract

CRYPTOCHROME (CRY) mediates behavioral and electrophysiological responses to blue light coded by circadian and arousal neurons. However, spectroscopic and biochemical assays of heterologously expressed CRY suggest that CRY may mediate functional responses to UV-A (ultraviolet A) light as well. To determine the relative contributions of distinct phototransduction systems, we tested mutants lacking CRY and mutants with disrupted opsin-based phototransduction for behavioral and electrophysiological responses to UV light. CRY and opsin-based external photoreceptor systems cooperate for UV light-evoked acute responses. CRY mediates behavioral avoidance responses related to executive choice, consistent with its expression in central brain neurons. [ABSTRACT FROM AUTHOR]

Published

2017

37. Spatiotemporal order and emergent edge currents in active spinner materials.

Author

van Zuiden, Benjamin C., Paulose, Jayson, Vitelli, Vincenzo, Irvine, William T. M., and Bartolo, Denis

Subjects

SPATIOTEMPORAL processes, LIQUID crystals, COMPUTER simulation, ANTIFERROMAGNETIC materials, DIMERS

Abstract

Collections of interacting, self-propelled particles have been extensively studied as minimal models of many living and synthetic systems from bird flocks to active colloids. However, the influence of active rotations in the absence of self-propulsion (i.e., spinning without walking) remains less explored. Here, we numerically and theoretically investigate the behavior of ensembles of self-spinning dimers. We find that geometric frustration of dimer rotation by interactions yields spatiotemporal order and active melting with no equilibrium counterparts. At low density, the spinning dimers self-assemble into a triangular lattice with their orientations phase-locked into spatially periodic phases. The phase-locked patterns form dynamical analogs of the ground states of various spin models, transitioning from the three-state Potts antiferromagnet at low densities to the striped herringbone phase of planar quadrupoles at higher densities. As the density is raised further, the competition between active rotations and interactions leads to melting of the active spinner crystal. Emergent edge currents, whose direction is set by the chirality of the active spinning, arise as a nonequilibrium signature of the transition to the active spinner liquid and vanish when the system eventually undergoes kinetic arrest at very high densities. Our findings may be realized in systems ranging from liquid crystal and colloidal experiments to tabletop realizations using macroscopic chiral grains. [ABSTRACT FROM AUTHOR]

Published

2016

38. High-frequency oscillations in human and monkey neocortex during the wake-sleep cycle.

Author

Le Van Quyen, Michel, Muller II, Lyle E., Telenczuk, Bartosz, Halgren, Eric, Cash, Sydney, Hatsopoulos, Nicholas G., Dehghani, Nima, and Destexhe, Alain

Subjects

OSCILLATIONS, NEOCORTEX, SLEEP-wake cycle, MICROELECTRODES, THEORY of wave motion

Abstract

Beta (β)- and gamma (?)-oscillations are present in different cortical areas and are thought to be inhibition-driven, but it is not known if these properties also apply to ?-oscillations in humans. Here, we analyze such oscillations in high-density microelectrode array recordings in human and monkey during the wake-sleep cycle. In these recordings, units were classified as excitatory and inhibitory cells. We find that ?-oscillations in human and β-oscillations in monkey are characterized by a strong implication of inhibitory neurons, both in terms of their firing rate and their phasic firing with the oscillation cycle. The β- and ?-waves systematically propagate across the array, with similar velocities, during both wake and sleep. However, only in slow-wave sleep (SWS) β- and ?-oscillations are associated with highly coherent and functional interactions across several millimeters of the neocortex. This interaction is specifically pronounced between inhibitory cells. These results suggest that inhibitory cells are dominantly involved in the genesis of β- and ?-oscillations, as well as in the organization of their large-scale coherence in the awake and sleeping brain. The highest oscillation coherence found during SWS suggests that fast oscillations implement a highly coherent reactivation of wake patterns that may support memory consolidation during SWS. [ABSTRACT FROM AUTHOR]

Published

2016

39. Spatiotemporal dynamics of auditory attention synchronize with speech.

Author

Wöstmann, Malte, Herrmann, Björn, Maess, Burkhard, and Obleser, Jonas

Subjects

ATTENTION research, SPEECH research, MAGNETOENCEPHALOGRAPHY, COMPREHENSION, SENSES

Abstract

Attention plays a fundamental role in selectively processing stimuli in our environment despite distraction. Spatial attention induces increasing and decreasing power of neural alpha oscillations (8-12 Hz) in brain regions ipsilateral and contralateral to the locus of attention, respectively. This study tested whether the hemispheric lateralization of alpha power codes not just the spatial location but also the temporal structure of the stimulus. Participants attended to spoken digits presented to one ear and ignored tightly synchronized distracting digits presented to the other ear. In the magnetoencephalogram, spatial attention induced lateralization of alpha power in parietal, but notably also in auditory cortical regions. This alpha power lateralization was not maintained steadily but fluctuated in synchrony with the speech rate and lagged the time course of low-frequency (1-5 Hz) sensory synchronization. Higher amplitude of alpha power modulation at the speech rate was predictive of a listener's enhanced performance of stream-specific speech comprehension. Our findings demonstrate that alpha power lateralization is modulated in tune with the sensory input and acts as a spatiotemporal filter controlling the read-out of sensory content. [ABSTRACT FROM AUTHOR]

Published

2016

40. Network synchronization in hippocampal neurons.

Author

Penn, Yaron, Segal, Menahem, and Moses, Elisha

Subjects

HIPPOCAMPUS physiology, NEURAL physiology, OSCILLATING chemical reactions, NERVE cell culture, NEUROGENETICS

Abstract

Oscillatory activity is widespread in dynamic neuronal networks. The main paradigm for the origin of periodicity consists of specialized pacemaking elements that synchronize and drive the rest of the network; however, other models exist. Here, we studied the spontaneous emergence of synchronized periodic bursting in a network of cultured dissociated neurons from rat hippocampus and cortex. Surprisingly, about 60% of all active neurons were self-sustained oscillators when disconnected, each with its own natural frequency. The individual neuron's tendency to oscillate and the corresponding oscillation frequency are controlled by its excitability. The single neuron intrinsic oscillations were blocked by riluzole, and are thus dependent on persistent sodium leak currents. Upon a gradual retrieval of connectivity, the synchrony evolves: Loose synchrony appears already at weak connectivity, with the oscillators converging to one common oscillation frequency, yet shifted in phase across the population. Further strengthening of the connectivity causes a reduction in the mean phase shifts until zero-lag is achieved, manifested by synchronous periodic network bursts. Interestingly, the frequency of network bursting matches the average of the intrinsic frequencies. Overall, the network behaves like other universal systems, where order emerges spontaneously by entrainment of independent rhythmic units. Although simplified with respect to circuitry in the brain, our results attribute a basic functional role for intrinsic single neuron excitability mechanisms in driving the network's activity and dynamics, contributing to our understanding of developing neural circuits. [ABSTRACT FROM AUTHOR]

Published

2016

41. Formation and evolution of molecular products in α-pinene secondary organic aerosol.

Author

Xuan Zhang, McVay, Renee C., Huang, Dan D., Dalleska, Nathan F., Aumont, Bernard, Flagan, Richard C., and Seinfeld, John H.

Subjects

HUMIDITY, HYDROXYL group, MOLECULAR physics, MOISTURE, ISOTHERMAL processes

Abstract

Much of our understanding of atmospheric secondary organic aerosol (SOA) formation from volatile organic compounds derives from laboratory chamber measurements, including mass yield and elemental composition. These measurements alone are insufficient to identify the chemical mechanisms of SOA production. We present here a comprehensive dataset on the molecular identity, abundance, and kinetics of α-pinene SOA, a canonical system that has received much attention owing to its importance as an organic aerosol source in the pristine atmosphere. Identified organic species account for ~58-72% of the α-pinene SOA mass, and are characterized as semivolatile/low-volatility monomers and extremely low volatility dimers, which exhibit comparable oxidation states yet different functionalities. Features of the α-pinene SOA formation process are revealed for the first time, to our knowledge, from the dynamics of individual particle-phase components. Although monomeric products dominate the overall aerosol mass, rapid production of dimers plays a key role in initiating particle growth. Continuous production of monomers is observed after the parent α-pinene is consumed, which cannot be explained solely by gasphase photochemical production. Additionally, distinct responses of monomers and dimers to α-pinene oxidation by ozone vs. hydroxyl radicals, temperature, and relative humidity are observed. Gas-phase radical combination reactions together with condensed phase rearrangement of labile molecules potentially explain the newly characterized SOA features, thereby opening up further avenues for understanding formation and evolution mechanisms of α-pinene SOA. [ABSTRACT FROM AUTHOR]

Published

2015

42. Unconstrained muscle-tendon workloops indicate resonance tuning as a mechanism for elastic limb behavior during terrestrial locomotion.

Author

Robertson, Benjamin D. and Sawicki, Gregory S.

Subjects

RESONANCE frequency analysis, TENDONS, ELASTICITY, ANIMAL locomotion, GAIT in animals

Abstract

In terrestrial locomotion, there is a missing link between observed spring-like limb mechanics and the physiological systems driving their emergence. Previous modeling and experimental studies of bouncing gait (e.g., walking, running, hopping) identified muscle-tendon interactions that cycle large amounts of energy in series tendon as a source of elastic limb behavior. The neural, biomechanical, and environmental origins of these tuned mechanics, however, have remained elusive. To examine the dynamic interplay between these factors, we developed an experimental platform comprised of a feedback-controlled servo-motor coupled to a biological muscle-tendon. Our novel motor controller mimicked in vivo inertial/gravitational loading experienced by muscles during terrestrial locomotion, and rhythmic patterns of muscle activation were applied via stimulation of intact nerve. This approach was based on classical workloop studies, but avoided predetermined patterns of muscle strain and activation-constraints not imposed during real-world locomotion. Our unconstrained approach to position control allowed observation of emergent muscle-tendon mechanics resulting from dynamic interaction of neural control, active muscle, and system material/ inertial properties. This study demonstrated that, despite the complex nonlinear nature of musculotendon systems, cyclic muscle contractions at the passive natural frequency of the underlying biomechanical system yielded maximal forces and fractions of mechanical work recovered from previously stored elastic energy in series-compliant tissues. By matching movement frequency to the natural frequency of the passive biomechanical system (i.e., resonance tuning), muscle-tendon interactions resulting in spring-like behavior emerged naturally, without closed-loop neural control. This conceptual framework may explain the basis for elastic limb behavior during terrestrial locomotion. [ABSTRACT FROM AUTHOR]

Published

2015

43. Cross-immunity between strains explains the dynamical pattern of paramyxoviruses.

Author

Bhattacharyya, Samit, Gesteland, Per H., Korgenski, Kent, Bjørnstad, Ottar N., and Adler, Frederick R.

Subjects

PARAMYXOVIRUSES, RESPIRATORY infections, PUBLIC health, DISEASE prevalence, CROSS reactions (Immunology)

Abstract

Viral respiratory tract diseases pose serious public health problems. Our ability to predict and thus, be able to prepare for outbreaks is strained by the complex factors driving the prevalence and severity of these diseases. The abundance of diseases and transmission dynamics of strains are not only affected by external factors, such as weather, but also driven by interactions among viruses mediated by human behavior and immunity. To untangle the complex out-of-phase annual and biennial pattern of three common paramyxoviruses. Respiratory Syncytial Virus (RSV), Human Parainfluenza Virus (HPIV), and Human Metapneumovirus (hMPV), we adopt a theoretical approach that integrates ecological and immunological mechanisms of disease interactions. By estimating parameters from multiyear time series of laboratory-confirmed cases from the intermountain west region of the United States and using statistical inference, we show that models of immune-mediated interactions better explain the data than those based on ecological competition by convalescence. The strength of cross-protective immunity among viruses is correlated with their genetic distance in the phylogenetic tree of the paramyxovirus family. [ABSTRACT FROM AUTHOR]

Published

2015

44. Synchronizing theta oscillations with direct-current stimulation strengthens adaptive control in the human brain.

Author

Reinhart, Robert M. G., Zhu, Julia, Sohee Park, and Woodman, Geoffrey F.

Subjects

BRAIN stimulation, FRONTAL lobe, SCHIZOPHRENIA, ELECTROPHYSIOLOGY, NEUROPHYSIOLOGY

Abstract

Executive control and flexible adjustment of behavior following errors are essential to adaptive functioning. Loss of adaptive control may be a biomarker of a wide range of neuropsychiatric disorders, particularly in the schizophrenia spectrum. Here, we provide support for the view that oscillatory activity in the frontal cortex underlies adaptive adjustments in cognitive processing following errors. Compared with healthy subjects, patients with schizophrenia exhibited low frequency oscillations with abnormal temporal structure and an absence of synchrony over medialfrontal and lateral-prefrontal cortex following errors. To demonstrate that these abnormal oscillations were the origin of the impaired adaptive control in patients with schizophrenia, we applied noninvasive dc electrical stimulation over the medial-frontal cortex. This noninvasive stimulation descrambled the phase of the low-frequency neural oscillations that synchronize activity across cortical regions. Following stimulation, the behavioral index of adaptive control was improved such that patients were indistinguishable from healthy control subjects. These results provide unique causal evidence for theories of executive control and cortical dysconnectivity in schizophrenia. [ABSTRACT FROM AUTHOR]

Published

2015

45. GABA-mediated repulsive coupling between circadian clock neurons in the SCN encodes seasonal time.

Author

Jihwan Myung, Sungho Hong, DeWoskin, Daniel, De Schutter, Erik, Forger, Daniel B., and Toru Takumi

Subjects

COUPLING constants, NEURONS, CIRCADIAN rhythms, CELL nuclei, GABA

Abstract

The mammalian suprachiasmatic nucleus (SCN) forms not only the master circadian clock but also a seasonal clock. This neural network of ~10,000 circadian oscillators encodes season-dependent day-length changes through a largely unknown mechanism. We show that region-intrinsic changes in the SCN fine-tune the degree of network synchrony and reorganize the phase relationship among circadian oscillators to represent day length.Wemeasureoscillationsofthe clock gene Bmal1, at single-cell and regional levels in cultured SCN explanted from animals raised under short or long days. Coupling estimation using the Kuramoto framework reveals that the network has couplings that can be both phase-attractive (synchronizing) and -repulsive (desynchronizing). The phase gap between the dorsal and ventral regions increases and the overall period of the SCN shortens with longer day length. We find that one of the underlying physiological mechanisms is the modulation of the intracellular chloride concentration, which can adjust the strength and polarity of the ionotropic GABAA-mediated synaptic input.We show that increasing day-length changes the pattern of chloride transporter expression, yielding more excitatory GABA synaptic input, and that blocking GABAA signaling or the chloride transporter disrupts the unique phase and period organization induced by the day length. We test the consequences of this tunable GABA coupling in the context of excitation--inhibition balance through detailed realistic modeling. These results indicate that the network encoding of seasonal time is controlled by modulation of intracellular chloride, which determines the phase relationship among and period difference between the dorsal and ventral SCN. [ABSTRACT FROM AUTHOR]

Published

2015

46. Entrained neural oscillations in multiple frequency bands comodulate behavior.

Author

Henry, Molly J., Herrmann, Björn, and Obleser, Jonas

Subjects

OSCILLATING chemical reactions, COMODULATION masking release, NEURAL receptors, NEURAL stimulation, NEURAL transmission, NEUROCOMMUNICATION

Abstract

Our sensory environment is teeming with complex rhythmic structure, to which neural oscillations can become synchronized. Neural synchronization to environmental rhythms (entrainment) is hypothesized to shape human perception, as rhythmic structure acts to temporally organize cortical excitability. In the current human electroencephalography study, we investigated how behavior is influenced by neural oscillatory dynamics when the rhythmic fluctuations in the sensory environment take on a naturalistic degree of complexity. Listeners detected near-threshold gaps in auditory stimuli that were simultaneously modulated in frequency (frequency modulation, 3.1 Hz) and amplitude (amplitude modulation, 5.075 Hz); modulation rates and types were chosen to mimic the complex rhythmic structure of natural speech. Neural oscillations were entrained by both the frequency modulation and amplitude modulation in the stimulation. Critically, listeners' target-detection accuracy depended on the specific phase-phase relationship between entrained neural oscillations in both the 3.1-Hz and 5.075-Hz frequency bands, with the best performance occurring when the respective troughs in both neural oscillations coincided. Neural-phase effects were specific to the frequency bands entrained by the rhythmic stimulation. Moreover, the degree of behavioral comodulation by neural phase in both frequency bands exceeded the degree of behavioral modulation by either frequency band alone. Our results elucidate how fluctuating excitability, within and across multiple entrained frequency bands, shapes the effective neural processing of environmental stimuli. More generally, the frequency-specific nature of behavioral comodulation effects suggests that environmental rhythms act to reduce the complexity of high-dimensional neural states. [ABSTRACT FROM AUTHOR]

Published

2014

47. Time-resolved resting-state brain networks.

Author

Zalesky, Andrew, Fornito, Alex, Cocchi, Luca, Gollo, Leonardo L., and Breakspear, Michael

Subjects

FUNCTIONAL magnetic resonance imaging, BRAIN research, BIOCHEMISTRY, CROSS section fluctuations (Nuclear physics), HUMAN anatomy

Abstract

Neuronal dynamics display a complex spatiotemporal structure involving the precise, context-dependent coordination of activation patterns across a large number of spatially distributed regions. Functional magnetic resonance imaging (fMRI) has played a central role in demonstrating the nontrivial spatial and topological structure of these interactions, but thus far has been limited in its capacity to study their temporal evolution. Here, using high-resolution resting-state fMRI data obtained from the Human Connectome Project, we mapped time-resolved functional connectivity across the entire brain at a subsecond resolution with the aim of understanding how nonstationary fluctuations in pairwise interactions between regions relate to large-scale topological properties of the human brain. We report evidence for a consistent set of functional connections that show pronounced fluctuations in their strength over time. The most dynamic connections are intermodular, linking elements from topologically separable subsystems, and localize to known hubs of default mode and frontoparietal systems. We found that spatially distributed regions spontaneously increased, for brief intervals, the efficiency with which they can transfer information, producing temporary, globally efficient network states. Our findings suggest that brain dynamics give rise to variations in complex network properties over time, possibly achieving a balance between efficient information-processing and metabolic expenditure. [ABSTRACT FROM AUTHOR]

Published

2014

48. Phase locking and multiple oscillating attractors for the coupled mammalian clock and cell cycle.

Author

Feillet, Céline, Krusche, Peter, Tamanini, Filippo, Janssens, Roel C., Downey, Mike J., Martin, Patrick, Teboul, Michèle, Saito, Shoko, Lévi, Francis A., Bretschneider, Till, van der Horst, Gijsbertus T. J., Delaunay, Franck, and Rand, David A.

Subjects

CELL cycle, CELL division, CIRCADIAN rhythms, CELL proliferation, LABORATORY mice

Abstract

Daily synchronous rhythms of cell division at the tissue or organism level are observed in many species and suggest that the circadian clock and cell cycle oscillators are coupled. For mammals, despite known mechanistic interactions, the effect of such coupling on clock and cell cycle progression, and hence its biological relevance, is not understood. In particular, we do not know how the temporal organization of cell division at the single-cell level produces this daily rhythm at the tissue level. Here we use multispectral imaging of single live cells, computational methods, and mathematical modeling to address this question in proliferating mouse fibroblasts. We show that in unsynchronized cells the cell cycle and circadian clock robustly phase lock each other in a 1:1 fashion so that in an expanding cell population the two oscillators oscillate in a synchronized way with a common frequency. Dexamethasone-induced synchronization reveals additional clock states. As well as the low-period phase-locked state there are distinct coexisting states with a significantly higher period clock. Cells transition to these states after dexamethasone synchronization. The temporal coordination of cell division by phase locking to the clock at a single-cell level has significant implications because disordered circadian function is increasingly being linked to the pathogenesis of many diseases, including cancer. [ABSTRACT FROM AUTHOR]

Published

2014

49. Theory of amorphous ices.

Author

Limmer, David T. and Chandler, David

Subjects

AMORPHOUS substances, ICE, ERGODIC transformations, COMPUTER simulation, OSTWALD ripening

Abstract

We derive a phase diagram for amorphous solids and liquid supercooled water and explain why the amorphous solids of water exist in several different forms. Application of large-deviation theory allows us to prepare such phases in computer simulations. Along with nonequilibrium transitions between the ergodic liquid and two distinct amorphous solids, we establish coexistence between these two amorphous solids. The phase diagram we predict includes a nonequilibrium triple point where two amorphous phases and the liquid coexist. Whereas the amorphous solids are long-lived and slowly aging glasses, their melting can lead quickly to the formation of crystalline ice. Further, melting of the higher density amorphous solid at low pressures takes place in steps, transitioning to the lower-density glass before accessing a nonequilibrium liquid from which ice coarsens. [ABSTRACT FROM AUTHOR]

Published

2014

50. Role of granule-cell transmission in memory trace of cerebellum-dependent optokinetic motor learning.

Author

Norio Wada, Kazuo Funabiki, and Shigetada Nakanishi

Subjects

CYTOPLASMIC granules, CELL transmission model (Traffic engineering), CEREBELLUM, MOTOR learning, VESTIBULAR nuclei

Abstract

Adaptation of the optokinetic response (OKR) is an eye movement enhanced by repeated motion of a surrounding visual field and represents a prototype of cerebellum-dependent motor learning. Purkinje cells and vestibular nuclei (VN) receive optokinetic and retinal slip signals via the mossy fiber-granule cell pathway and climbing-fiber projections, respectively. To explore the neural circuits and mechanisms responsible for OKR adaptation, we adopted the reversible neurotransmission-blocking (RNB) technique, in which granule-cell transmission to Purkinje cells was selectively and reversibly blocked by doxycycline-dependent expression of transmission-blocking tetanus toxin in granule cells. Blockade of granule-cell inputs abolished both short-term and long-term OKR adaptation induced by repeated OKR training, but normal levels of both responses were immediately evoked in the pretrained RNB mice by OKR retraining once granule-cell transmission had recovered. Importantly, eye movement elicited by electrical stimulation of the cerebellar focculus was elevated by long-term but not by short-term OKR training in adaptive OKR-negative RNB mice. Furthermore, when the flocculus of adaptive OKR-negative RNB mice was electrically excited in-phase with OKR stimulation, these mice exhibited long-term adaptive OKR. These results indicate that convergent information to the VN was critical for acquisition and storage of long-term OKR adaptation with conjunctive action of Purkinje cells for OKR expression. Interestingly, in contrast to conditioned eyeblink memory, the expression of once acquired adaptive long-term OKR was not abrogated by blockade of granule-cell transmission, suggesting that distinct forms of neural plasticity would operate in different forms of cerebellum-dependent motor learning. [ABSTRACT FROM AUTHOR]

Published

2014