Your search keyword '"escape"' showing total 18 results

1. Sparse genetically defined neurons refine the canonical role of periaqueductal gray columnar organization

Author

Mimi Q La-Vu, Ekayana Sethi, Sandra Maesta-Pereira, Peter J Schuette, Brooke C Tobias, Fernando MCV Reis, Weisheng Wang, Anita Torossian, Amy Bishop, Saskia J Leonard, Lilly Lin, Catherine M Cahill, and Avishek Adhikari

Subjects

periaqueductal gray, predator, escape, fear, optogenetics, cholecystokinin, Medicine, Science, Biology (General), QH301-705.5

Abstract

During threat exposure, survival depends on defensive reactions. Prior works linked large glutamatergic populations in the midbrain periaqueductal gray (PAG) to defensive freezing and flight, and established that the overarching functional organization axis of the PAG is along anatomically-defined columns. Accordingly, broad activation of the dorsolateral column induces flight, while activation of the lateral or ventrolateral (l and vl) columns induces freezing. However, the PAG contains diverse cell types that vary in neurochemistry. How these cell types contribute to defense remains unknown, indicating that targeting sparse, genetically-defined populations may reveal how the PAG generates diverse behaviors. Though prior works showed that broad excitation of the lPAG or vlPAG causes freezing, we found in mice that activation of lateral and ventrolateral PAG (l/vlPAG) cholecystokinin-expressing (CCK) cells selectively caused flight to safer regions within an environment. Furthermore, inhibition of l/vlPAG-CCK cells reduced predator avoidance without altering other defensive behaviors like freezing. Lastly, l/vlPAG-CCK activity decreased when approaching threat and increased during movement to safer locations. These results suggest CCK cells drive threat avoidance states, which are epochs during which mice increase distance from threat and perform evasive escape. Conversely, l/vlPAG pan-neuronal activation promoted freezing, and these cells were activated near threat. Thus, CCK l/vlPAG cells have opposing function and neural activation motifs compared to the broader local ensemble defined solely by columnar boundaries. In addition to the anatomical columnar architecture of the PAG, the molecular identity of PAG cells may confer an additional axis of functional organization, revealing unexplored functional heterogeneity.

Published

2022

2. Reciprocally inhibitory circuits operating with distinct mechanisms are differently robust to perturbation and modulation

Author

Ekaterina Morozova, Peter Newstein, and Eve Marder

Subjects

half-center oscillator, mutual inhibition, dynamic clamp, release, escape, temperature, Medicine, Science, Biology (General), QH301-705.5

Abstract

Reciprocal inhibition is a building block in many sensory and motor circuits. We studied the features that underly robustness in reciprocally inhibitory two neuron circuits. We used the dynamic clamp to create reciprocally inhibitory circuits from pharmacologically isolated neurons of the crab stomatogastric ganglion by injecting artificial graded synaptic (ISyn) and hyperpolarization-activated inward (IH) currents. There is a continuum of mechanisms in circuits that generate antiphase oscillations, with ‘release’ and ‘escape’ mechanisms at the extremes, and mixed mode oscillations between these extremes. In release, the active neuron primarily controls the off/on transitions. In escape, the inhibited neuron controls the transitions. We characterized the robustness of escape and release circuits to alterations in circuit parameters, temperature, and neuromodulation. We found that escape circuits rely on tight correlations between synaptic and H conductances to generate bursting but are resilient to temperature increase. Release circuits are robust to variations in synaptic and H conductances but fragile to temperature increase. The modulatory current (IMI) restores oscillations in release circuits but has little effect in escape circuits. Perturbations can alter the balance of escape and release mechanisms and can create mixed mode oscillations. We conclude that the same perturbation can have dramatically different effects depending on the circuits’ mechanism of operation that may not be observable from basal circuit activity.

Published

2022

3. Dorsal premammillary projection to periaqueductal gray controls escape vigor from innate and conditioned threats

Author

Weisheng Wang, Peter J Schuette, Mimi Q La-Vu, Anita Torossian, Brooke C Tobias, Marta Ceko, Philip A Kragel, Fernando MCV Reis, Shiyu Ji, Megha Sehgal, Sandra Maesta-Pereira, Meghmik Chakerian, Alcino J Silva, Newton S Canteras, Tor Wager, Jonathan C Kao, and Avishek Adhikari

Subjects

periaqueductal gray, dorsal premammillary nucleus, predator, panic, fear, escape, Medicine, Science, Biology (General), QH301-705.5

Abstract

Escape from threats has paramount importance for survival. However, it is unknown if a single circuit controls escape vigor from innate and conditioned threats. Cholecystokinin (cck)-expressing cells in the hypothalamic dorsal premammillary nucleus (PMd) are necessary for initiating escape from innate threats via a projection to the dorsolateral periaqueductal gray (dlPAG). We now show that in mice PMd-cck cells are activated during escape, but not other defensive behaviors. PMd-cck ensemble activity can also predict future escape. Furthermore, PMd inhibition decreases escape speed from both innate and conditioned threats. Inhibition of the PMd-cck projection to the dlPAG also decreased escape speed. Intriguingly, PMd-cck and dlPAG activity in mice showed higher mutual information during exposure to innate and conditioned threats. In parallel, human functional magnetic resonance imaging data show that a posterior hypothalamic-to-dlPAG pathway increased activity during exposure to aversive images, indicating that a similar pathway may possibly have a related role in humans. Our data identify the PMd-dlPAG circuit as a central node, controlling escape vigor elicited by both innate and conditioned threats.

Published

2021

4. A cross-modality enhancement of defensive flight via parvalbumin neurons in zona incerta

Author

Xiyue Wang, Xiaolin Chou, Bo Peng, Li Shen, Junxiang J Huang, Li I Zhang, and Huizhong W Tao

Subjects

zona incerta, defensive behavior, parvalbumin, escape, somatosensory, auditory, Medicine, Science, Biology (General), QH301-705.5

Abstract

The ability to adjust defensive behavior is critical for animal survival in dynamic environments. However, neural circuits underlying the modulation of innate defensive behavior remain not well-understood. In particular, environmental threats are commonly associated with cues of multiple sensory modalities. It remains to be investigated how these modalities interact to shape defensive behavior. In this study, we report that auditory-induced defensive flight behavior can be facilitated by somatosensory input in mice. This cross-modality modulation of defensive behavior is mediated by the projection from the primary somatosensory cortex (SSp) to the ventral sector of zona incerta (ZIv). Parvalbumin (PV)-positive neurons in ZIv, receiving direct input from SSp, mediate the enhancement of the flight behavior via their projections to the medial posterior complex of thalamus (POm). Thus, defensive flight can be enhanced in a somatosensory context-dependent manner via recruiting PV neurons in ZIv, which may be important for increasing survival of prey animals.

Published

2019

5. Chronology-based architecture of descending circuits that underlie the development of locomotor repertoire after birth

Author

Avinash Pujala and Minoru Koyama

Subjects

hindbrain, V2a, descending pathways, locomotion, escape, spontaneous swim, Medicine, Science, Biology (General), QH301-705.5

Abstract

The emergence of new and increasingly sophisticated behaviors after birth is accompanied by dramatic increase of newly established synaptic connections in the nervous system. Little is known, however, of how nascent connections are organized to support such new behaviors alongside existing ones. To understand this, in the larval zebrafish we examined the development of spinal pathways from hindbrain V2a neurons and the role of these pathways in the development of locomotion. We found that new projections are continually layered laterally to existing neuropil, and give rise to distinct pathways that function in parallel to existing pathways. Across these chronologically layered pathways, the connectivity patterns and biophysical properties vary systematically to support a behavioral repertoire with a wide range of kinematics and dynamics. Such layering of new parallel circuits equipped with systematically changing properties may be central to the postnatal diversification and increasing sophistication of an animal’s behavioral repertoire.

Published

2019

6. A circuit motif in the zebrafish hindbrain for a two alternative behavioral choice to turn left or right

Author

Minoru Koyama, Francesca Minale, Jennifer Shum, Nozomi Nishimura, Chris B Schaffer, and Joseph R Fetcho

Subjects

motor control, escape, inhibitory interneurons, Medicine, Science, Biology (General), QH301-705.5

Abstract

Animals collect sensory information from the world and make adaptive choices about how to respond to it. Here, we reveal a network motif in the brain for one of the most fundamental behavioral choices made by bilaterally symmetric animals: whether to respond to a sensory stimulus by moving to the left or to the right. We define network connectivity in the hindbrain important for the lateralized escape behavior of zebrafish and then test the role of neurons by using laser ablations and behavioral studies. Key inhibitory neurons in the circuit lie in a column of morphologically similar cells that is one of a series of such columns that form a developmental and functional ground plan for building hindbrain networks. Repetition within the columns of the network motif we defined may therefore lie at the foundation of other lateralized behavioral choices.

Published

2016

7. A choice motif

Author

Sabine L Renninger and Michael B Orger

Subjects

motor control, escape, inhibitory interneurons, Medicine, Science, Biology (General), QH301-705.5

Abstract

A simple neural circuit motif in the zebrafish brain enables robust and reliable behavioral choices.

Published

2016

8. Sparse genetically defined neurons refine the canonical role of periaqueductal gray columnar organization.

Author

La-Vu MQ, Sethi E, Maesta-Pereira S, Schuette PJ, Tobias BC, Reis FMCV, Wang W, Torossian A, Bishop A, Leonard SJ, Lin L, Cahill CM, and Adhikari A

Subjects

Animals, Cholecystokinin, Mice, Neurons physiology, Fear physiology, Periaqueductal Gray physiology

Abstract

During threat exposure, survival depends on defensive reactions. Prior works linked large glutamatergic populations in the midbrain periaqueductal gray (PAG) to defensive freezing and flight, and established that the overarching functional organization axis of the PAG is along anatomically-defined columns. Accordingly, broad activation of the dorsolateral column induces flight, while activation of the lateral or ventrolateral (l and vl) columns induces freezing. However, the PAG contains diverse cell types that vary in neurochemistry. How these cell types contribute to defense remains unknown, indicating that targeting sparse, genetically-defined populations may reveal how the PAG generates diverse behaviors. Though prior works showed that broad excitation of the lPAG or vlPAG causes freezing, we found in mice that activation of lateral and ventrolateral PAG (l/vlPAG) cholecystokinin-expressing (CCK) cells selectively caused flight to safer regions within an environment. Furthermore, inhibition of l/vlPAG-CCK cells reduced predator avoidance without altering other defensive behaviors like freezing. Lastly, l/vlPAG-CCK activity decreased when approaching threat and increased during movement to safer locations. These results suggest CCK cells drive threat avoidance states, which are epochs during which mice increase distance from threat and perform evasive escape. Conversely, l/vlPAG pan-neuronal activation promoted freezing, and these cells were activated near threat. Thus, CCK l/vlPAG cells have opposing function and neural activation motifs compared to the broader local ensemble defined solely by columnar boundaries. In addition to the anatomical columnar architecture of the PAG, the molecular identity of PAG cells may confer an additional axis of functional organization, revealing unexplored functional heterogeneity., Competing Interests: ML, ES, SM, PS, BT, FR, WW, AT, AB, SL, LL, CC, AA No competing interests declared, (© 2022, La-Vu et al.)

Published

2022

9. A cross-modality enhancement of defensive flight via parvalbumin neurons in zona incerta

Author

Xiao-lin Chou, Bo Peng, Li Shen, Huizhong W. Tao, Xiyue Wang, Junxiang J Huang, and Li I. Zhang

Subjects

0301 basic medicine, Mouse, zona incerta, QH301-705.5, Cross modality, Science, Thalamus, Somatosensory system, General Biochemistry, Genetics and Molecular Biology, somatosensory, Mice, 03 medical and health sciences, 0302 clinical medicine, Stimulus modality, Escape Reaction, Evoked Potentials, Somatosensory, parvalbumin, medicine, Biological neural network, Animals, defensive behavior, auditory, Biology (General), Neurons, General Immunology and Microbiology, biology, General Neuroscience, Somatosensory Cortex, General Medicine, Parvalbumins, 030104 developmental biology, medicine.anatomical_structure, Acoustic Stimulation, biology.protein, Medicine, Zona incerta, escape, Nerve Net, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin, Research Article

Abstract

The ability to adjust defensive behavior is critical for animal survival in dynamic environments. However, neural circuits underlying the modulation of innate defensive behavior remain not well-understood. In particular, environmental threats are commonly associated with cues of multiple sensory modalities. It remains to be investigated how these modalities interact to shape defensive behavior. In this study, we report that auditory-induced defensive flight behavior can be facilitated by somatosensory input in mice. This cross-modality modulation of defensive behavior is mediated by the projection from the primary somatosensory cortex (SSp) to the ventral sector of zona incerta (ZIv). Parvalbumin (PV)-positive neurons in ZIv, receiving direct input from SSp, mediate the enhancement of the flight behavior via their projections to the medial posterior complex of thalamus (POm). Thus, defensive flight can be enhanced in a somatosensory context-dependent manner via recruiting PV neurons in ZIv, which may be important for increasing survival of prey animals.

Published

2019

10. Building behaviors, one layer at a time

Author

Claire Wyart and Vatsala Thirumalai

Subjects

0301 basic medicine, animal structures, QH301-705.5, Science, Hindbrain, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Interneurons, medicine, descending pathways, Animals, Layer (object-oriented design), Biology (General), Zebrafish, development, General Immunology and Microbiology, General Neuroscience, musculoskeletal, neural, and ocular physiology, fungi, General Medicine, Spinal cord, biology.organism_classification, Rhombencephalon, locomotion, 030104 developmental biology, medicine.anatomical_structure, nervous system, Spinal Cord, embryonic structures, behavioral modules, Medicine, V2a, escape, Neuroscience, spontaneous swim, 030217 neurology & neurosurgery, hindbrain, V2a interneurons, Research Article, Developmental Biology

Abstract

The emergence of new and increasingly sophisticated behaviors after birth is accompanied by dramatic increase of newly established synaptic connections in the nervous system. Little is known, however, of how nascent connections are organized to support such new behaviors alongside existing ones. To understand this, in the larval zebrafish we examined the development of spinal pathways from hindbrain V2a neurons and the role of these pathways in the development of locomotion. We found that new projections are continually layered laterally to existing neuropil, and give rise to distinct pathways that function in parallel to existing pathways. Across these chronologically layered pathways, the connectivity patterns and biophysical properties vary systematically to support a behavioral repertoire with a wide range of kinematics and dynamics. Such layering of new parallel circuits equipped with systematically changing properties may be central to the postnatal diversification and increasing sophistication of an animal’s behavioral repertoire., eLife digest Newborn babies have limited abilities. Indeed, most of our actions shortly after birth are the result of reflexes that serve our most basic need: to stay alive. As we get older, however, our behaviour gradually becomes more sophisticated. During this time, the billions of cells in our brain form new connections to build intricate ‘circuits’ of neurons that allow for more complicated thoughts and actions. It is clear that the brain circuits that support new behaviours must develop in a way that does not interfere with the existing circuits that are vital for survival. However, the challenge has been to find a way to peer into a brain as it develops to see how these new circuits form. In recent years, zebrafish have revolutionised research into neuronal circuits in animals. Developing over the course of a few days, these small transparent fish provide a window into the brain during the earliest stages of development. Indeed, the circuits of neurons that descend from the brain and connect to the spinal cord have already been mapped in these animals. Now, Pujala and Koyama have begun to follow the careful development of these ‘descending’ neurons, and relate it to the appearance of new behaviours in young zebrafish. Time-lapse imaging with a fluorescent protein that is active only in specific descending neurons revealed that new circuits are laid down over existing ones, like the growth rings in a tree. Next, at different timepoints in zebrafish development, Pujala and Koyama traced these neurons backwards from the spine to the brain to identify which connections formed first. This showed that the spinal connections develop one after the other, in the same order that the neurons mature. Next, Pujala and Koyama asked how the activity of neurons that mature early or late in development relates to specific behaviours in young zebrafish. Early-born circuits connect to neurons that produce powerful, reflex-driven, whole-body movements such as an escape response. The later circuits connect to different neurons through slower, less direct pathways; the late-born neurons also generate the refined movements that are acquired later in a zebrafish’s development and help the fish to explore its environment. These findings show that descending circuits in zebrafish run parallel to each other, but with distinct connections and properties that allow them to control different kinds of movements. While this study was conducted using an animal model, a better understanding of how such circuits develop and the movements they control may one day aid the treatment of patients with neurodegenerative diseases or injuries where connections have been lost.

Published

2019

11. Reciprocally inhibitory circuits operating with distinct mechanisms are differently robust to perturbation and modulation.

Author

Morozova E, Newstein P, and Marder E

Subjects

Animals, Ganglia, Ganglia, Invertebrate physiology, Brachyura physiology, Neurons physiology

Abstract

Reciprocal inhibition is a building block in many sensory and motor circuits. We studied the features that underly robustness in reciprocally inhibitory two neuron circuits. We used the dynamic clamp to create reciprocally inhibitory circuits from pharmacologically isolated neurons of the crab stomatogastric ganglion by injecting artificial graded synaptic (I Syn ) and hyperpolarization-activated inward (I H ) currents. There is a continuum of mechanisms in circuits that generate antiphase oscillations, with 'release' and 'escape' mechanisms at the extremes, and mixed mode oscillations between these extremes. In release, the active neuron primarily controls the off/on transitions. In escape, the inhibited neuron controls the transitions. We characterized the robustness of escape and release circuits to alterations in circuit parameters, temperature, and neuromodulation. We found that escape circuits rely on tight correlations between synaptic and H conductances to generate bursting but are resilient to temperature increase. Release circuits are robust to variations in synaptic and H conductances but fragile to temperature increase. The modulatory current (I MI ) restores oscillations in release circuits but has little effect in escape circuits. Perturbations can alter the balance of escape and release mechanisms and can create mixed mode oscillations. We conclude that the same perturbation can have dramatically different effects depending on the circuits' mechanism of operation that may not be observable from basal circuit activity., Competing Interests: EM, PN, EM No competing interests declared, (© 2022, Morozova et al.)

Published

2022

12. Dorsal premammillary projection to periaqueductal gray controls escape vigor from innate and conditioned threats.

Author

Wang W, Schuette PJ, La-Vu MQ, Torossian A, Tobias BC, Ceko M, Kragel PA, Reis FM, Ji S, Sehgal M, Maesta-Pereira S, Chakerian M, Silva AJ, Canteras NS, Wager T, Kao JC, and Adhikari A

Subjects

Adult, Animals, Brain Mapping, Cholecystokinin genetics, Cholecystokinin metabolism, Female, Humans, Hypothalamus, Posterior diagnostic imaging, Hypothalamus, Posterior metabolism, Magnetic Resonance Imaging, Male, Mice, Inbred C57BL, Mice, Transgenic, Neural Pathways physiology, Optogenetics, Periaqueductal Gray diagnostic imaging, Periaqueductal Gray metabolism, Photic Stimulation, Rats, Long-Evans, Time Factors, Video Recording, Visual Perception, Young Adult, Mice, Rats, Behavior, Animal, Conditioning, Psychological, Escape Reaction, Fear, Hypothalamus, Posterior physiology, Periaqueductal Gray physiology

Abstract

Escape from threats has paramount importance for survival. However, it is unknown if a single circuit controls escape vigor from innate and conditioned threats. Cholecystokinin (cck)-expressing cells in the hypothalamic dorsal premammillary nucleus (PMd) are necessary for initiating escape from innate threats via a projection to the dorsolateral periaqueductal gray (dlPAG). We now show that in mice PMd-cck cells are activated during escape, but not other defensive behaviors. PMd-cck ensemble activity can also predict future escape. Furthermore, PMd inhibition decreases escape speed from both innate and conditioned threats. Inhibition of the PMd-cck projection to the dlPAG also decreased escape speed. Intriguingly, PMd-cck and dlPAG activity in mice showed higher mutual information during exposure to innate and conditioned threats. In parallel, human functional magnetic resonance imaging data show that a posterior hypothalamic-to-dlPAG pathway increased activity during exposure to aversive images, indicating that a similar pathway may possibly have a related role in humans. Our data identify the PMd-dlPAG circuit as a central node, controlling escape vigor elicited by both innate and conditioned threats., Competing Interests: WW, PS, ML, AT, BT, MC, PK, FR, SJ, MS, SM, MC, AS, NC, TW, JK, AA none, (© 2021, Wang et al.)

Published

2021

13. A choice motif

Author

Michael B. Orger and Sabine L. Renninger

Subjects

0301 basic medicine, animal structures, Patch-Clamp Techniques, QH301-705.5, Science, Action Potentials, Computational biology, Biology, Choice Behavior, General Biochemistry, Genetics and Molecular Biology, Animals, Genetically Modified, 03 medical and health sciences, Neural Pathways, Animals, Biology (General), Zebrafish, Neurons, General Immunology and Microbiology, Behavior, Animal, General Neuroscience, fungi, inhibitory interneurons, General Medicine, Anatomy, biology.organism_classification, Rhombencephalon, 030104 developmental biology, ComputingMethodologies_PATTERNRECOGNITION, embryonic structures, Medicine, escape, Perception, Motif (music), Laser Therapy, Insight, Locomotion, Neuroscience, Motor Control

Abstract

Animals collect sensory information from the world and make adaptive choices about how to respond to it. Here, we reveal a network motif in the brain for one of the most fundamental behavioral choices made by bilaterally symmetric animals: whether to respond to a sensory stimulus by moving to the left or to the right. We define network connectivity in the hindbrain important for the lateralized escape behavior of zebrafish and then test the role of neurons by using laser ablations and behavioral studies. Key inhibitory neurons in the circuit lie in a column of morphologically similar cells that is one of a series of such columns that form a developmental and functional ground plan for building hindbrain networks. Repetition within the columns of the network motif we defined may therefore lie at the foundation of other lateralized behavioral choices.

Published

2016

14. A circuit motif in the zebrafish hindbrain for a two alternative behavioral choice to turn left or right

Author

Joseph R. Fetcho, Francesca Minale, Chris B. Schaffer, Jennifer Shum, Nozomi Nishimura, and Minoru Koyama

Subjects

0301 basic medicine, Left and right, QH301-705.5, media_common.quotation_subject, Science, Hindbrain, Escape response, Biology, Choice Behavior, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Interneurons, Perception, motor control, Animals, Biology (General), Zebrafish, media_common, General Immunology and Microbiology, General Neuroscience, Motor control, inhibitory interneurons, General Medicine, 16. Peace & justice, biology.organism_classification, Silence, 030104 developmental biology, Medicine, escape, Motif (music), Cognitive psychology, Neuroscience, Research Article

Abstract

Animals collect sensory information from the world and make adaptive choices about how to respond to it. Here, we reveal a network motif in the brain for one of the most fundamental behavioral choices made by bilaterally symmetric animals: whether to respond to a sensory stimulus by moving to the left or to the right. We define network connectivity in the hindbrain important for the lateralized escape behavior of zebrafish and then test the role of neurons by using laser ablations and behavioral studies. Key inhibitory neurons in the circuit lie in a column of morphologically similar cells that is one of a series of such columns that form a developmental and functional ground plan for building hindbrain networks. Repetition within the columns of the network motif we defined may therefore lie at the foundation of other lateralized behavioral choices. DOI: http://dx.doi.org/10.7554/eLife.16808.001, eLife digest Humans and other vertebrate animals constantly make choices about whether to respond to the left or to the right. Do they look left or right; turn left or right; reach left or right? In humans, the distinction between left and right is so fundamental that it has entered our collective thinking. Many societies define their political positions, for example, in terms of leaning to the left or to the right. However, we know little about the wiring of the brain that accomplishes the task of making physical left-right choices. Koyama et al. therefore set out to identify the neural circuit responsible for the decision to turn either left or right. Zebrafish larvae were chosen as subjects because they execute rapid left or right turns to escape predators. Given that one wrong turn can result in the death of the zebrafish, a correct choice matters more than in most of the other decisions that animals make. Experiments revealed that a process of competition between neurons on the left and right sides of the brain underlies this decision-making. Neurons on the right collect evidence that an attack is coming from the right, and drive turns to the left, away from the threat. These neurons also attempt to silence competing neurons on the left that act to produce turns to the right. By weighing up the evidence from left and right sides, the circuit as a whole comes to a decision about the best direction in which to turn. The region of the brain that controls the left versus right escape response in zebrafish is present in all vertebrates. Moreover, it appears to have a similar structure across species, consisting of repeating columns of neurons. This raises the possibility that other left-right choices in fish and other animals occur in a similar way – a principle that can be tested in future work. DOI: http://dx.doi.org/10.7554/eLife.16808.002

Published

2016

15. A cross-modality enhancement of defensive flight via parvalbumin neurons in zona incerta.

Author

Wang X, Chou X, Peng B, Shen L, Huang JJ, Zhang LI, and Tao HW

Subjects

Acoustic Stimulation, Animals, Evoked Potentials, Somatosensory, Mice, Somatosensory Cortex physiology, Escape Reaction, Nerve Net physiology, Neurons chemistry, Neurons physiology, Parvalbumins analysis, Zona Incerta physiology

Abstract

The ability to adjust defensive behavior is critical for animal survival in dynamic environments. However, neural circuits underlying the modulation of innate defensive behavior remain not well-understood. In particular, environmental threats are commonly associated with cues of multiple sensory modalities. It remains to be investigated how these modalities interact to shape defensive behavior. In this study, we report that auditory-induced defensive flight behavior can be facilitated by somatosensory input in mice. This cross-modality modulation of defensive behavior is mediated by the projection from the primary somatosensory cortex (SSp) to the ventral sector of zona incerta (ZIv). Parvalbumin (PV)-positive neurons in ZIv, receiving direct input from SSp, mediate the enhancement of the flight behavior via their projections to the medial posterior complex of thalamus (POm). Thus, defensive flight can be enhanced in a somatosensory context-dependent manner via recruiting PV neurons in ZIv, which may be important for increasing survival of prey animals., Competing Interests: XW, XC, BP, LS, JH, LZ, HT No competing interests declared, (© 2019, Wang et al.)

Published

2019

16. Chronology-based architecture of descending circuits that underlie the development of locomotor repertoire after birth.

Author

Pujala A and Koyama M

Subjects

Animals, Rhombencephalon growth & development, Rhombencephalon physiology, Spine growth & development, Spine physiology, Time Factors, Efferent Pathways growth & development, Efferent Pathways physiology, Locomotion, Nerve Net growth & development, Nerve Net physiology, Zebrafish growth & development

Abstract

The emergence of new and increasingly sophisticated behaviors after birth is accompanied by dramatic increase of newly established synaptic connections in the nervous system. Little is known, however, of how nascent connections are organized to support such new behaviors alongside existing ones. To understand this, in the larval zebrafish we examined the development of spinal pathways from hindbrain V2a neurons and the role of these pathways in the development of locomotion. We found that new projections are continually layered laterally to existing neuropil, and give rise to distinct pathways that function in parallel to existing pathways. Across these chronologically layered pathways, the connectivity patterns and biophysical properties vary systematically to support a behavioral repertoire with a wide range of kinematics and dynamics. Such layering of new parallel circuits equipped with systematically changing properties may be central to the postnatal diversification and increasing sophistication of an animal's behavioral repertoire., Competing Interests: AP, MK No competing interests declared, (© 2019, Pujala and Koyama.)

Published

2019

17. A choice motif.

Author

Renninger SL and Orger MB

Subjects

Animals, Choice Behavior, Interneurons, Zebrafish

Abstract

A simple neural circuit motif in the zebrafish brain enables robust and reliable behavioral choices.

Published

2016

18. A circuit motif in the zebrafish hindbrain for a two alternative behavioral choice to turn left or right.

Author

Koyama M, Minale F, Shum J, Nishimura N, Schaffer CB, and Fetcho JR

Subjects

Action Potentials, Animals, Animals, Genetically Modified, Laser Therapy, Neurons physiology, Patch-Clamp Techniques, Perception, Zebrafish, Behavior, Animal, Choice Behavior, Locomotion, Neural Pathways anatomy & histology, Neural Pathways physiology, Rhombencephalon anatomy & histology, Rhombencephalon physiology

Abstract

Animals collect sensory information from the world and make adaptive choices about how to respond to it. Here, we reveal a network motif in the brain for one of the most fundamental behavioral choices made by bilaterally symmetric animals: whether to respond to a sensory stimulus by moving to the left or to the right. We define network connectivity in the hindbrain important for the lateralized escape behavior of zebrafish and then test the role of neurons by using laser ablations and behavioral studies. Key inhibitory neurons in the circuit lie in a column of morphologically similar cells that is one of a series of such columns that form a developmental and functional ground plan for building hindbrain networks. Repetition within the columns of the network motif we defined may therefore lie at the foundation of other lateralized behavioral choices.

Published

2016