Your search keyword '"Shemesh, Y."' showing total 7 results

1. Wireless Optogenetic Stimulation of Oxytocin Neurons in a Semi-natural Setup Dynamically Elevates Both Pro-social and Agonistic Behaviors.

Author

Anpilov S, Shemesh Y, Eren N, Harony-Nicolas H, Benjamin A, Dine J, Oliveira VEM, Forkosh O, Karamihalev S, Hüttl RE, Feldman N, Berger R, Dagan A, Chen G, Neumann ID, Wagner S, Yizhar O, and Chen A

Subjects

Animals, Mice, Neurons metabolism, Agonistic Behavior physiology, Behavior, Animal physiology, Neurons physiology, Optogenetics methods, Oxytocin metabolism, Social Behavior, Wireless Technology

Abstract

Complex behavioral phenotyping techniques are becoming more prevalent in the field of behavioral neuroscience, and thus methods for manipulating neuronal activity must be adapted to fit into such paradigms. Here, we present a head-mounted, magnetically activated device for wireless optogenetic manipulation that is compact, simple to construct, and suitable for use in group-living mice in an enriched semi-natural arena over several days. Using this device, we demonstrate that repeated activation of oxytocin neurons in male mice can have different effects on pro-social and agonistic behaviors, depending on the social context. Our findings support the social salience hypothesis of oxytocin and emphasize the importance of the environment in the study of social neuromodulators. Our wireless optogenetic device can be easily adapted for use in a variety of behavioral paradigms, which are normally hindered by tethered light delivery or a limited environment., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2020

2. Identity domains capture individual differences from across the behavioral repertoire.

Author

Forkosh O, Karamihalev S, Roeh S, Alon U, Anpilov S, Touma C, Nussbaumer M, Flachskamm C, Kaplick PM, Shemesh Y, and Chen A

Subjects

Animals, Behavior, Animal, Hierarchy, Social, Male, Mice, Individuality, Models, Theoretical, Personality, Social Behavior

Abstract

Personality traits can offer considerable insight into the biological basis of individual differences. However, existing approaches toward understanding personality across species rely on subjective criteria and limited sets of behavioral readouts, which result in noisy and often inconsistent outcomes. Here we introduce a mathematical framework for describing individual differences along dimensions with maximum consistency and discriminative power. We validate this framework in mice, using data from a system for high-throughput longitudinal monitoring of group-housed male mice that yields a variety of readouts from across the behavioral repertoire of individual animals. We demonstrate a set of stable traits that capture variability in behavior and gene expression in the brain, allowing for better-informed mechanistic investigations into the biology of individual differences.

Published

2019

3. Ucn3 and CRF-R2 in the medial amygdala regulate complex social dynamics.

Author

Shemesh Y, Forkosh O, Mahn M, Anpilov S, Sztainberg Y, Manashirov S, Shlapobersky T, Elliott E, Tabouy L, Ezra G, Adler ES, Ben-Efraim YJ, Gil S, Kuperman Y, Haramati S, Dine J, Eder M, Deussing JM, Schneidman E, Yizhar O, and Chen A

Subjects

Animals, Behavior, Animal physiology, Corticotropin-Releasing Hormone metabolism, Inhibition, Psychological, Mice, Mice, Knockout, Neurons metabolism, Receptors, Corticotropin-Releasing Hormone genetics, Urocortins genetics, Amygdala metabolism, Receptors, Corticotropin-Releasing Hormone metabolism, Social Behavior, Urocortins metabolism

Abstract

Social encounters are associated with varying degrees of emotional arousal and stress. The mechanisms underlying adequate socioemotional balance are unknown. The medial amygdala (MeA) is a brain region associated with social behavior in mice. Corticotropin-releasing factor receptor type-2 (CRF-R2) and its specific ligand urocortin-3 (Ucn3), known components of the behavioral stress response system, are highly expressed in the MeA. Here we show that mice deficient in CRF-R2 or Ucn3 exhibit abnormally low preference for novel conspecifics. MeA-specific knockdown of Crfr2 (Crhr2) in adulthood recapitulated this phenotype. In contrast, pharmacological activation of MeA CRF-R2 or optogenetic activation of MeA Ucn3 neurons increased preference for novel mice. Furthermore, chemogenetic inhibition of MeA Ucn3 neurons elicited pro-social behavior in freely behaving groups of mice without affecting their hierarchal structure. These findings collectively suggest that the MeA Ucn3-CRF-R2 system modulates the ability of mice to cope with social challenges.

Published

2016

4. Potent social synchronization can override photic entrainment of circadian rhythms.

Author

Fuchikawa T, Eban-Rothschild A, Nagari M, Shemesh Y, and Bloch G

Subjects

Animals, Photoperiod, Bees physiology, Circadian Rhythm, Social Behavior

Abstract

Circadian rhythms in behaviour and physiology are important for animal health and survival. Studies with individually isolated animals in the laboratory have consistently emphasized the dominant role of light for the entrainment of circadian rhythms to relevant environmental cycles. Although in nature interactions with conspecifics are functionally significant, social signals are typically not considered important time-givers for the animal circadian clock. Our results challenge this view. By studying honeybees in an ecologically relevant context and using a massive data set, we demonstrate that social entrainment can be potent, may act without direct contact with other individuals and does not rely on gating the exposure to light. We show for the first time that social time cues stably entrain the clock, even in animals experiencing conflicting photic and social environmental cycles. These findings add to the growing appreciation for the importance of studying circadian rhythms in ecologically relevant contexts.

Published

2016

5. High-order social interactions in groups of mice.

Author

Shemesh Y, Sztainberg Y, Forkosh O, Shlapobersky T, Chen A, and Schneidman E

Subjects

Animals, Mice, Ultraviolet Rays, Social Behavior

Abstract

Social behavior in mammals is often studied in pairs under artificial conditions, yet groups may rely on more complicated social structures. Here, we use a novel system for tracking multiple animals in a rich environment to characterize the nature of group behavior and interactions, and show strongly correlated group behavior in mice. We have found that the minimal models that rely only on individual traits and pairwise correlations between animals are not enough to capture group behavior, but that models that include third-order interactions give a very accurate description of the group. These models allow us to infer social interaction maps for individual groups. Using this approach, we show that environmental complexity during adolescence affects the collective group behavior of adult mice, in particular altering the role of high-order structure. Our results provide new experimental and mathematical frameworks for studying group behavior and social interactions. DOI:http://dx.doi.org/10.7554/eLife.00759.001.

Published

2013

6. Microarray analysis of natural socially regulated plasticity in circadian rhythms of honey bees.

Author

Rodriguez-Zas SL, Southey BR, Shemesh Y, Rubin EB, Cohen M, Robinson GE, and Bloch G

Subjects

Animals, Bees genetics, Circadian Rhythm physiology, Cytochrome P-450 Enzyme System genetics, Genome-Wide Association Study, Motor Activity physiology, Oligonucleotide Array Sequence Analysis, Periodicity, RNA, Messenger analysis, Rod Opsins genetics, Bees physiology, Brain metabolism, Circadian Clocks genetics, Circadian Rhythm genetics, Motor Activity genetics, Nerve Tissue Proteins genetics, Social Behavior

Abstract

Honey bee workers care for ("nurse") the brood around the clock without circadian rhythmicity, but then they forage outside with strong circadian rhythms and a consolidated nightly rest. This chronobiological plasticity is associated with variation in the expression of the canonical "clock genes" that regulate the circadian clock: nurse bees show no brain rhythms of expression, while foragers do. These results suggest that the circadian system is organized differently in nurses and foragers. Nurses switch to activity with circadian rhythms shortly after being removed from the hive, suggesting that at least some clock cells in their brain continue to measure time while in the hive. We performed a microarray genome-wide survey to determine general patterns of brain gene expression in nurses and foragers sampled around the clock. We found 160 and 541 transcripts that exhibited significant sinusoidal oscillations in nurses and foragers, respectively, with peaks of expression distributed throughout the day in both task groups. Consistent with earlier studies, transcripts of genes involved in circadian rhythms, including Clockwork Orange that has not been studied before in bees, oscillated in foragers but not in nurses. The oscillating transcripts also were enriched for genes involved in the visual system, "development" and "response to stimuli" (foragers), "muscle contraction" and "microfilament motor gene expression" (nurses), and "generation of precursor metabolites" and "energy" (both). Transcripts of genes encoding P450 enzymes oscillated in both nurses and foragers but with a different phase. This study identified new putative clock-controlled genes in the honey bee and suggests that some brain functions show circadian rhythmicity even in nurse bees that are active around the clock.

Published

2012

7. Molecular dynamics and social regulation of context-dependent plasticity in the circadian clockwork of the honey bee.

Author

Shemesh Y, Eban-Rothschild A, Cohen M, and Bloch G

Subjects

Animals, Bees genetics, Biological Clocks genetics, Brain cytology, Brain physiology, CLOCK Proteins genetics, Female, Gene Expression Regulation genetics, Hierarchy, Social, Male, Maternal Behavior physiology, Models, Neurological, Nerve Net cytology, Nerve Net physiology, Neuronal Plasticity genetics, Species Specificity, Bees physiology, CLOCK Proteins physiology, Circadian Rhythm genetics, Neuronal Plasticity physiology, Social Behavior

Abstract

The social environment influences the circadian clock of diverse animals, but little is known about the functional significance, the specifics of the social signals, or the dynamics of socially mediated changes in the clock. Honey bees switch between activities with and without circadian rhythms according to their social task. Forager bees have strong circadian rhythms, whereas "nurse" bees typically care for the brood around-the-clock with no circadian rhythms in behavior or clock gene expression. Here we show that nurse-age bees that were restricted to a broodless comb inside or outside the hive showed robust behavioral and molecular circadian rhythms. By contrast, young nurses tended brood with no circadian rhythms in behavior or clock gene expression, even under a light-dark illumination regime or when placed with brood--but no queen--in a small cage outside the hive. This behavior is context-dependent because nurses showed circadian rhythms in locomotor activity shortly after removal from the hive, and in clock gene expression after ∼16 h. These findings suggest that direct interaction with the brood modulates the circadian system of honey bees. The dynamics of rhythm development best fit models positing that at least some pacemakers continue to oscillate and be entrained by the environment in nurses that are active around the clock. These cells set the phase to the clock network when the nurse is removed from the hive. These findings suggest that despite its robustness, the circadian system exhibits profound plasticity, enabling adjustment to rapid changes in the social environment.

Published

2010