27 research outputs found

    Imaging escape and avoidance behavior in zebrafish larvae

    No full text
    Abstract This review provides an overview of the assays that are used for measuring escape and avoidance behavior in zebrafish, with a specific focus on zebrafish larvae during the first week of development. Zebrafish larvae display a startle response when exposed to tactile, acoustic, or visual stimuli and will avoid dark areas, moving objects, conspecifics, and open spaces. Emotional states such as fear and anxiety might be induced when larvae are exposed to stimuli that they would normally escape from or avoid. Although these emotional states probably differ between species and change during development, much can be learned about human fear and anxiety using zebrafish as a model system. The molecular mechanisms of fear and anxiety are highly conserved in vertebrates and are present during early zebrafish development. Larvae during the first week of development display elevated cortisol levels in response to stress and are sensitive to the same anxiolytics that are used for the management of anxiety in humans. Zebrafish larvae are well suited for high-throughput analyses of behavior, and automated systems have been developed for imaging and analyzing the behavior of zebrafish larvae in multiwell plates. These high-throughput analyses will not only provide a wealth of information on the genes and environmental factors that influence escape and avoidance behaviors and the emotional states that might accompany them but will also facilitate the discovery of novel pharmaceuticals that could be used in the management of anxiety disorders in humans.</jats:p

    Patterns of free calcium in zebrafish embryos

    No full text
    Direct knowledge of Ca2+ patterns in vertebrate development is largely restricted to early stages, in which they control fertilization, ooplasmic segregation and cleavage. To explore new roles of Ca2+ in vertebrate development, we injected the Ca2+ indicator aequorin into zebrafish eggs and imaged Ca2+ throughout the first day of development. During early cleavages, a high Ca2+ zone is seen in the cleavage furrows. The high Ca2+ zone during first cleavage spreads as a slow wave (0.5 mu m/second) and is preceded by three Ca2+ pulses within the animal pole region of the egg. When Ca2+ concentrations are clamped at the resting level by BAPTA buffer injection into the zygote, all signs of development are blocked. In later development, Ca2+ patterns are associated with cell movements during gastrulation, with neural induction, with brain regionalization, with formation of the somites and neural keel, with otic placode formation, with muscle movements and with formation of the heart. Particularly remarkable is a sharp boundary between high Ca2+ in the presumptive forebrain and midbrain versus low Ca2+ in the presumptive hindbrain starting at 10 hours of development. When Ca2+ changes are damped by injection of low concentrations of BAPTA, fish form with greatly reduced eyes and hearts. The present study provides a first overview of Ca2+ patterns during prolonged periods of vertebrate development and points to new roles of Ca2+ in cellular differentiation and pattern formation

    Patterns of free calcium in zebrafish embryos

    No full text
    Direct knowledge of Ca2+ patterns in vertebrate development is largely restricted to early stages, in which they control fertilization, ooplasmic segregation and cleavage. To explore new roles of Ca2+ in vertebrate development, we injected the Ca2+ indicator aequorin into zebrafish eggs and imaged Ca2+ throughout the first day of development. During early cleavages, a high Ca2+ zone is seen in the cleavage furrows. The high Ca2+ zone during first cleavage spreads as a slow wave (0.5 mu m/second) and is preceded by three Ca2+ pulses within the animal pole region of the egg. When Ca2+ concentrations are clamped at the resting level by BAPTA buffer injection into the zygote, all signs of development are blocked. In later development, Ca2+ patterns are associated with cell movements during gastrulation, with neural induction, with brain regionalization, with formation of the somites and neural keel, with otic placode formation, with muscle movements and with formation of the heart. Particularly remarkable is a sharp boundary between high Ca2+ in the presumptive forebrain and midbrain versus low Ca2+ in the presumptive hindbrain starting at 10 hours of development. When Ca2+ changes are damped by injection of low concentrations of BAPTA, fish form with greatly reduced eyes and hearts. The present study provides a first overview of Ca2+ patterns during prolonged periods of vertebrate development and points to new roles of Ca2+ in cellular differentiation and pattern formation

    Patterns of free calcium in zebrafish embryos

    No full text
    Direct knowledge of Ca2+ patterns in vertebrate development is largely restricted to early stages, in which they control fertilization, ooplasmic segregation and cleavage. To explore new roles of Ca2+ in vertebrate development, we injected the Ca2+ indicator aequorin into zebrafish eggs and imaged Ca2+ throughout the first day of development. During early cleavages, a high Ca2+ zone is seen in the cleavage furrows. The high Ca2+ zone during first cleavage spreads as a slow wave (0.5 mu m/second) and is preceded by three Ca2+ pulses within the animal pole region of the egg. When Ca2+ concentrations are clamped at the resting level by BAPTA buffer injection into the zygote, all signs of development are blocked. In later development, Ca2+ patterns are associated with cell movements during gastrulation, with neural induction, with brain regionalization, with formation of the somites and neural keel, with otic placode formation, with muscle movements and with formation of the heart. Particularly remarkable is a sharp boundary between high Ca2+ in the presumptive forebrain and midbrain versus low Ca2+ in the presumptive hindbrain starting at 10 hours of development. When Ca2+ changes are damped by injection of low concentrations of BAPTA, fish form with greatly reduced eyes and hearts. The present study provides a first overview of Ca2+ patterns during prolonged periods of vertebrate development and points to new roles of Ca2+ in cellular differentiation and pattern formation

    Patterns of free calcium in zebrafish embryos

    No full text
    Direct knowledge of Ca2+ patterns in vertebrate development is largely restricted to early stages, in which they control fertilization, ooplasmic segregation and cleavage. To explore new roles of Ca2+ in vertebrate development, we injected the Ca2+ indicator aequorin into zebrafish eggs and imaged Ca2+ throughout the first day of development. During early cleavages, a high Ca2+ zone is seen in the cleavage furrows. The high Ca2+ zone during first cleavage spreads as a slow wave (0.5 mu m/second) and is preceded by three Ca2+ pulses within the animal pole region of the egg. When Ca2+ concentrations are clamped at the resting level by BAPTA buffer injection into the zygote, all signs of development are blocked. In later development, Ca2+ patterns are associated with cell movements during gastrulation, with neural induction, with brain regionalization, with formation of the somites and neural keel, with otic placode formation, with muscle movements and with formation of the heart. Particularly remarkable is a sharp boundary between high Ca2+ in the presumptive forebrain and midbrain versus low Ca2+ in the presumptive hindbrain starting at 10 hours of development. When Ca2+ changes are damped by injection of low concentrations of BAPTA, fish form with greatly reduced eyes and hearts. The present study provides a first overview of Ca2+ patterns during prolonged periods of vertebrate development and points to new roles of Ca2+ in cellular differentiation and pattern formation
    corecore