Knots: Attractive Places with High Path Tortuosity in Mouse Open Field Exploration

Dvorkin, Anna; Szechtman, Henry; Golani, Ilan

doi:10.1371/journal.pcbi.1000638

Cited by 21 publications

(11 citation statements)

References 21 publications

(32 reference statements)

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“…tag swapping occurs), such an analysis is difficult to perform. Also note that spatial allocation could not only be affected by the presence of homebases but also by specific locations that are characterized by increased path tortuosity (or so-called ‘knots’, as described in mice [51]). For the heterogeneous groups (Fig.…”

Section: Discussionmentioning

confidence: 99%

Assessing Social Engagement in Heterogeneous Groups of Zebrafish: A New Paradigm for Autism-Like Behavioral Responses

Maaswinkel¹,

Zhu²,

Weng³

2013

PLoS ONE

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Because of its highly developed social character, zebrafish is a promising model system for the study of the genetic and neurochemical basis of altered social engagement such as is common in autism and schizophrenia. The traditional shoaling paradigm investigates social cohesion in homogeneous groups of zebrafish. However, the social dynamics of mixed groups is gaining interest from a therapeutic point of view and thus warrants animal modeling. Furthermore, mutant zebrafish are not always available in large numbers. Therefore, we developed a new paradigm that allows exploring shoaling in heterogeneous groups. The effects of MK-801, a non-competitive antagonist of the glutamate N-methyl-D-aspartate (NMDA) receptor, on social cohesion were studied to evaluate the paradigm. The drug has previously been shown to mimic aspects of autism and schizophrenia. Our results show that a single MK-801-treated zebrafish reduced social cohesion of the entire shoal drastically. Preliminary observations suggest that the social dynamics of the shoal as a whole was altered.

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Section: Discussionmentioning

confidence: 99%

Assessing Social Engagement in Heterogeneous Groups of Zebrafish: A New Paradigm for Autism-Like Behavioral Responses

Maaswinkel¹,

Zhu²,

Weng³

2013

PLoS ONE

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“…In the Eshkol Wachman Movement Notation these variables amount to speed and direction of shift of weight, and direction of front77. Changes in the direction of progression are calculated per unit of progression and as a function of time in order to have a geometric curvature7879 expressed in kinematic terms8081. Switching between clockwise and counterclockwise body rotation was assessed via the zero-crossings of the instantaneous time derivative of the body angle, removing artifacts during arrests by pruning out rotations smaller than 12 degrees.…”

Section: Methodsmentioning

confidence: 99%

Generative rules of Drosophila locomotor behavior as a candidate homology across phyla

Gomez‐Marin

Oron

Gakamsky

et al. 2016

Sci Rep

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The discovery of shared behavioral processes across phyla is a significant step in the establishment of a comparative study of behavior. We use immobility as an origin and reference for the measurement of fly locomotor behavior; speed, walking direction and trunk orientation as the degrees of freedom shaping this behavior; and cocaine as the parameter inducing progressive transitions in and out of immobility. We characterize and quantify the generative rules that shape Drosophila locomotor behavior, bringing about a gradual buildup of kinematic degrees of freedom during the transition from immobility to normal behavior, and the opposite narrowing down into immobility. Transitions into immobility unfold via sequential enhancement and then elimination of translation, curvature and finally rotation. Transitions out of immobility unfold by progressive addition of these degrees of freedom in the opposite order. The same generative rules have been found in vertebrate locomotor behavior in several contexts (pharmacological manipulations, ontogeny, social interactions) involving transitions in-and-out of immobility. Recent claims for deep homology between arthropod central complex and vertebrate basal ganglia provide an opportunity to examine whether the rules we report also share common descent. Our approach prompts the discovery of behavioral homologies, contributing to the elusive problem of behavioral evolution.

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“…Fig.S1 in supplementary material). Interestingly, Dvorkin et al, studying the exploration by mice of a featureless enclosure, found that a significant proportion of individuals established a unique location (referred to as a 'knot') near the point of release, which they returned to repeatedly over multiple days (Dvorkin et al, 2010). A knot was distinguished not by the mouse spending more time at that location (as is the case for so-called 'home bases') but rather by rapid turning that may provide an 'overview of the entire environment, allowing recalibration of the mouse's locale map and compass directions' (Dvorkin et al, 2010).…”

Section: Optimization Of the Ldmc Responsementioning

confidence: 99%

“…If the patterns of response are superimposed onto the animal's visual surroundings, they may be reflected not only in the directional properties but also in the spatial firing fields of cells that receive magnetic input, perhaps defined by the projected image of the pattern from a specific location (e.g. Dvorkin et al, 2010).…”

Section: Optimization Of the Ldmc Responsementioning

confidence: 99%

A behavioral perspective on the biophysics of the light-dependent magnetic compass: a link between directional and spatial perception?

Phillips

Muheim

Jorge

2010

Journal of Experimental Biology

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Summary In terrestrial organisms, sensitivity to the Earth's magnetic field is mediated by at least two different magnetoreception mechanisms, one involving biogenic ferromagnetic crystals (magnetite/maghemite) and the second involving a photo-induced biochemical reaction that forms long-lasting, spin-coordinated, radical pair intermediates. In some vertebrate groups (amphibians and birds), both mechanisms are present; a light-dependent mechanism provides a directional sense or ‘compass’, and a non-light-dependent mechanism underlies a geographical-position sense or ‘map’. Evidence that both magnetite- and radical pair-based mechanisms are present in the same organisms raises a number of interesting questions. Why has natural selection produced magnetic sensors utilizing two distinct biophysical mechanisms? And, in particular, why has natural selection produced a compass mechanism based on a light-dependent radical pair mechanism (RPM) when a magnetite-based receptor is well suited to perform this function? Answers to these questions depend, to a large degree, on how the properties of the RPM, viewed from a neuroethological rather than a biophysical perspective, differ from those of a magnetite-based magnetic compass. The RPM is expected to produce a light-dependent, 3-D pattern of response that is axially symmetrical and, in some groups of animals, may be perceived as a pattern of light intensity and/or color superimposed on the visual surroundings. We suggest that the light-dependent magnetic compass may serve not only as a source of directional information but also provide a spherical coordinate system that helps to interface metrics of distance, direction and spatial position.

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Knots: Attractive Places with High Path Tortuosity in Mouse Open Field Exploration

Cited by 21 publications

References 21 publications

Assessing Social Engagement in Heterogeneous Groups of Zebrafish: A New Paradigm for Autism-Like Behavioral Responses

Assessing Social Engagement in Heterogeneous Groups of Zebrafish: A New Paradigm for Autism-Like Behavioral Responses

Generative rules of Drosophila locomotor behavior as a candidate homology across phyla

A behavioral perspective on the biophysics of the light-dependent magnetic compass: a link between directional and spatial perception?

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