Your search keyword '"Laurence D, Picton"' showing total 7 results

1. Principles Governing Locomotion in Vertebrates: Lessons From Zebrafish

Author

Eva M. Berg, E. Rebecka Björnfors, Irene Pallucchi, Laurence D. Picton, and Abdeljabbar El Manira

Subjects

spinal cord, excitatory interneurons, neural networks, plasticity, motor behavior and motor control, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Locomotor behaviors are critical for survival and enable animals to navigate their environment, find food and evade predators. The circuits in the brain and spinal cord that initiate and maintain such different modes of locomotion in vertebrates have been studied in numerous species for over a century. In recent decades, the zebrafish has emerged as one of the main model systems for the study of locomotion, owing to its experimental amenability, and work in zebrafish has revealed numerous new insights into locomotor circuit function. Here, we review the literature that has led to our current understanding of the neural circuits controlling swimming and escape in zebrafish. We highlight recent studies that have enriched our comprehension of key topics, such as the interactions between premotor excitatory interneurons (INs) and motoneurons (MNs), supraspinal and spinal circuits that coordinate escape maneuvers, and developmental changes in overall circuit composition. We also discuss roles for neuromodulators and sensory inputs in modifying the relative strengths of constituent circuit components to provide flexibility in zebrafish behavior, allowing the animal to accommodate changes in the environment. We aim to provide a coherent framework for understanding the circuitry in the brain and spinal cord of zebrafish that allows the animal to flexibly transition between different speeds, and modes, of locomotion.

Published

2018

2. Developmental switch in the function of inhibitory commissural V0d interneurons in zebrafish

Author

Laurence D. Picton, E. Rebecka Björnfors, Pierre Fontanel, Irene Pallucchi, Maria Bertuzzi, and Abdeljabbar El Manira

Subjects

Motor Neurons, Spinal Cord, Interneurons, Larva, Animals, General Agricultural and Biological Sciences, General Biochemistry, Genetics and Molecular Biology, Locomotion, Zebrafish

Abstract

During development, all animals undergo major adaptations to accommodate behavioral flexibility and diversity. How these adaptations are reflected in the changes in the motor circuits controlling our behaviors remains poorly understood. Here, we show, using a combination of techniques applied at larval and adult zebrafish stages, that the pattern-generating V0d inhibitory interneurons within the locomotor circuit undergo a developmental switch in their role. In larvae, we show that V0d interneurons have a primary function in high-speed motor behavior yet are redundant for explorative swimming. By contrast, adult V0d interneurons have diversified into speed-dependent subclasses, with an overrepresentation of those active at the slowest speeds. The ablation of V0d interneurons in adults disrupts slow explorative swimming, which is associated with a loss of mid-cycle inhibition onto target motoneurons. Thus, we reveal a developmental switch in V0d interneuron function from a role in high-speed motor behavior to a function in timing and thus coordinating slow explorative locomotion. Our study suggests that early motor circuit composition is not predictive of the adult system but instead undergoes major functional transformations during development.

Published

2022

3. Multiple Rhythm-Generating Circuits Act in Tandem with Pacemaker Properties to Control the Start and Speed of Locomotion

Author

Jessica Ausborn, Konstantinos Ampatzis, Abdeljabbar El Manira, Jianren Song, Laurence D. Picton, Irene Pallucchi, Maria Bertuzzi, and Pierre Fontanel

Subjects

0301 basic medicine, Electronic speed control, Interneuron, Computer science, 03 medical and health sciences, 0302 clinical medicine, Rhythm, Biological Clocks, Neural Pathways, Biological neural network, medicine, Animals, Zebrafish, Electronic circuit, Motor Neurons, Tandem, Recurrent excitation, General Neuroscience, Central pattern generator, 030104 developmental biology, medicine.anatomical_structure, Spinal Cord, Central Pattern Generators, Neuroscience, 030217 neurology & neurosurgery, Locomotion

Abstract

In vertebrates, specific command centers in the brain can selectively drive slow-explorative or fast-speed locomotion. However, it remains unclear how the locomotor central pattern generator (CPG) processes descending drive into coordinated locomotion. Here, we reveal, in adult zebrafish, a logic of the V2a interneuron rhythm-generating circuits involving recurrent and hierarchical connectivity that acts in tandem with pacemaker properties to provide an ignition and gear-shift mechanism to start locomotion and change speed. A comprehensive mapping of synaptic connections reveals three recurrent circuit modules engaged sequentially to increase locomotor speed. The connectivity between V2a interneurons of different modules displayed a clear asymmetry in favor of connections from faster to slower modules. The interplay between V2a interneuron pacemaker properties and their organized connectivity provides a mechanism for locomotor initiation and speed control. Thus, our results provide mechanistic insights into how the spinal CPG transforms descending drive into locomotion and align its speed with the initial intention.

Published

2019

4. A spinal organ of proprioception for integrated motor action feedback

Author

Elin Dahlberg, Maria Bertuzzi, Laurence D. Picton, Pierre Fontanel, E. Rebecka Björnfors, Francesco Iacoviello, Paul R. Shearing, Abdeljabbar El Manira, and Irene Pallucchi

Subjects

Male, 0301 basic medicine, Sensory Receptor Cells, Movement, Central nervous system, Motor program, Sensory system, Biology, Inhibitory postsynaptic potential, Mechanotransduction, Cellular, Ion Channels, 03 medical and health sciences, 0302 clinical medicine, Feedback, Sensory, Interneurons, medicine, Animals, Zebrafish, Motor Neurons, Proprioception, General Neuroscience, Motor control, Zebrafish Proteins, Commissure, Spinal cord, 030104 developmental biology, medicine.anatomical_structure, Spinal Cord, Central Pattern Generators, RNA, Female, Nerve Net, Tomography, X-Ray Computed, Neuroscience, Locomotion, 030217 neurology & neurosurgery

Abstract

Proprioception is essential for behavior and provides a sense of our body movements in physical space. Proprioceptor organs are thought to be only in the periphery. Whether the central nervous system can intrinsically sense its own movement remains unclear. Here we identify a segmental organ of proprioception in the adult zebrafish spinal cord, which is embedded by intraspinal mechanosensory neurons expressing Piezo2 channels. These cells are late-born, inhibitory, commissural neurons with unique molecular and physiological profiles reflecting a dual sensory and motor function. The central proprioceptive organ locally detects lateral body movements during locomotion and provides direct inhibitory feedback onto rhythm-generating interneurons responsible for the central motor program. This dynamically aligns central pattern generation with movement outcome for efficient locomotion. Our results demonstrate that a central proprioceptive organ monitors self-movement using hybrid neurons that merge sensory and motor entities into a unified network.

Published

2021

5. Principles Governing Locomotion in Vertebrates: Lessons From Zebrafish

Author

E. Rebecka Björnfors, Abdeljabbar El Manira, Irene Pallucchi, Laurence D. Picton, and Eva M. Berg

Subjects

0301 basic medicine, Cognitive Neuroscience, Neuroscience (miscellaneous), Sensory system, lcsh:RC321-571, 03 medical and health sciences, Spinal circuits, Cellular and Molecular Neuroscience, 0302 clinical medicine, motor behavior and motor control, excitatory interneurons, Interneurons, Biological neural network, Animals, Humans, Zebrafish, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Swimming, Flexibility (engineering), biology, fungi, spinal cord, biology.organism_classification, neural networks, Sensory Systems, 030104 developmental biology, plasticity, Models, Animal, Nerve Net, Neuroscience, 030217 neurology & neurosurgery, Locomotion

Abstract

Locomotor behaviors are critical for survival and enable animals to navigate their environment, find food and evade predators. The circuits in the brain and spinal cord that initiate and maintain such different modes of locomotion in vertebrates have been studied in numerous species for over a century. In recent decades, the zebrafish has emerged as one of the main model systems for the study of locomotion, owing to its experimental amenability, and work in zebrafish has revealed numerous new insights into locomotor circuit function. Here, we review the literature that has led to our current understanding of the neural circuits controlling swimming and escape in zebrafish. We highlight recent studies that have enriched our comprehension of key topics, such as the interactions between premotor excitatory interneurons (INs) and motoneurons (MNs), supraspinal and spinal circuits that coordinate escape maneuvers, and developmental changes in overall circuit composition. We also discuss roles for neuromodulators and sensory inputs in modifying the relative strengths of constituent circuit components to provide flexibility in zebrafish behavior, allowing the animal to accommodate changes in the environment. We aim to provide a coherent framework for understanding the circuitry in the brain and spinal cord of zebrafish that allows the animal to flexibly transition between different speeds, and modes, of locomotion.

Published

2018

6. Sodium pump regulation of locomotor control circuits

Author

Keith T. Sillar, Hong-Yan Zhang, Laurence D. Picton, Carnegie Trust, University of St Andrews. School of Psychology and Neuroscience, and University of St Andrews. Institute of Behavioural and Neural Sciences

Subjects

0301 basic medicine, BF Psychology, Physiology, Xenopus, QH301 Biology, Sodium, BF, chemistry.chemical_element, Review, Sodium pumps, Membrane Potentials, Ion, Mice, QH301, 03 medical and health sciences, 0302 clinical medicine, Species Specificity, Animals, Central pattern generator, Motor memory, Electronic circuit, Neurons, Spinal cord, Chemistry, General Neuroscience, Biological Evolution, Memory, Short-Term, 030104 developmental biology, Spinal Cord, Membrane protein, Central Pattern Generators, T-DAS, RC0321, Biophysics, Sodium pump, Sodium-Potassium-Exchanging ATPase, Energy source, RC0321 Neuroscience. Biological psychiatry. Neuropsychiatry, Neuroscience, Locomotion, 030217 neurology & neurosurgery

Abstract

The authors are grateful for the financial support of the BBSRC (grant numbers: BB/M024946/1 and BB/JO1446X/1), the Carnegie Trust and the University of St Andrews. Sodium pumps are ubiquitously expressed membrane proteins that extrude three Na+ ions in exchange for two K+ ions using ATP as an energy source. Recent studies have illuminated additional, dynamic roles for sodium pumps in regulating the excitability of neuronal networks in an activity-dependent fashion. Here we review their role in a novel form of short-term memory within rhythmic locomotor networks. The data we review derives mainly from recent studies on Xenopus tadpoles and neonatal mice. The role and underlying mechanisms of pump action broadly match previously published data from an invertebrate, the Drosophila larva. We therefore propose a highly conserved mechanism by which sodium pump activity increases following a bout of locomotion. This results in an ultraslow afterhyperpolarisation (usAHP) of the membrane potential that lasts around 1 minute, but which only occurs in around half the network neurons. This usAHP in turn alters network excitability so that network output is reduced in a locomotor interval-dependent manner. The pumps therefore confer on spinal locomotor networks a temporary memory trace of recent network performance. Postprint

Published

2017

7. Mechanisms underlying the endogenous dopaminergic inhibition of spinal locomotor circuit function in Xenopus tadpoles

Author

Laurence D. Picton and Keith T. Sillar

Subjects

Motor Neurons, Potassium Channels, Spinal Cord, Receptors, Dopamine D2, Dopamine, Dopaminergic Neurons, Larva, Xenopus, Animals, Neural Inhibition, human activities, Article, Swimming

Abstract

Dopamine plays important roles in the development and modulation of motor control circuits. Here we show that dopamine exerts potent effects on the central pattern generator circuit controlling locomotory swimming in post-embryonic Xenopus tadpoles. Dopamine (0.5–100 μM) reduced fictive swim bout occurrence and caused both spontaneous and evoked episodes to become shorter, slower and weaker. The D2-like receptor agonist quinpirole mimicked this repertoire of inhibitory effects on swimming, whilst the D4 receptor antagonist, L745,870, had the opposite effects. The dopamine reuptake inhibitor bupropion potently inhibited fictive swimming, demonstrating that dopamine constitutes an endogenous modulatory system. Both dopamine and quinpirole also inhibited swimming in spinalised preparations, suggesting spinally located dopamine receptors. Dopamine and quinpirole hyperpolarised identified rhythmically active spinal neurons, increased rheobase and reduced spike probability both during swimming and in response to current injection. The hyperpolarisation was TTX-resistant and was accompanied by decreased input resistance, suggesting that dopamine opens a K+ channel. The K+ channel blocker barium chloride (but not TEA, glybenclamide or tertiapin-Q) significantly occluded the hyperpolarisation. Overall, we show that endogenously released dopamine acts upon spinally located D2-like receptors, leading to a rapid inhibitory modulation of swimming via the opening of a K+ channel.

Published

2016