Your search keyword '"Amanda M. Pocratsky"' showing total 13 results

1. Reversible silencing of lumbar spinal interneurons unmasks a task-specific network for securing hindlimb alternation

Author

Amanda M. Pocratsky, Darlene A. Burke, Johnny R. Morehouse, Jason E. Beare, Amberly S. Riegler, Pantelis Tsoulfas, Gregory J. R. States, Scott R. Whittemore, and David S. K. Magnuson

Subjects

Science

Abstract

Intra- and interlimb coordination during locomotion is governed by hierarchically organized lumbar spinal networks. Here, the authors show that reversible silencing of spinal L2–L5 interneurons specifically disrupts hindlimb alternation leading to a continuum of walking to hopping.

Published

2017

2. Spinal premotor interneurons controlling antagonistic muscles are spatially intermingled

Author

Remi Ronzano, Sophie Skarlatou, Bianca K Barriga, B Anne Bannatyne, Gardave Singh Bhumbra, Joshua D Foster, Jeffrey D Moore, Camille Lancelin, Amanda M Pocratsky, Mustafa Görkem Özyurt, Calvin Chad Smith, Andrew J Todd, David J Maxwell, Andrew J Murray, Samuel L Pfaff, Robert M Brownstone, Niccolò Zampieri, and Marco Beato

Subjects

spinal cord, premotor interneurons, rabies viral tracing, flexor muscles, extensor muscles, Medicine, Science, Biology (General), QH301-705.5

Abstract

Elaborate behaviours are produced by tightly controlled flexor-extensor motor neuron activation patterns. Motor neurons are regulated by a network of interneurons within the spinal cord, but the computational processes involved in motor control are not fully understood. The neuroanatomical arrangement of motor and premotor neurons into topographic patterns related to their controlled muscles is thought to facilitate how information is processed by spinal circuits. Rabies retrograde monosynaptic tracing has been used to label premotor interneurons innervating specific motor neuron pools, with previous studies reporting topographic mediolateral positional biases in flexor and extensor premotor interneurons. To more precisely define how premotor interneurons contacting specific motor pools are organized, we used multiple complementary viral-tracing approaches in mice to minimize systematic biases associated with each method. Contrary to expectations, we found that premotor interneurons contacting motor pools controlling flexion and extension of the ankle are highly intermingled rather than segregated into specific domains like motor neurons. Thus, premotor spinal neurons controlling different muscles process motor instructions in the absence of clear spatial patterns among the flexor-extensor circuit components.

Published

2022

3. Silencing long ascending propriospinal neurons after spinal cord injury improves hindlimb stepping in the adult rat

Author

Courtney T Shepard, Amanda M Pocratsky, Brandon L Brown, Morgan A Van Rijswijck, Rachel M Zalla, Darlene A Burke, Johnny R Morehouse, Amberley S Riegler, Scott R Whittemore, and David SK Magnuson

Subjects

spinal cord injury, propriospinal neurons, locomotion, viral vector, neuronal silencing, Medicine, Science, Biology (General), QH301-705.5

Abstract

Long ascending propriospinal neurons (LAPNs) are a subpopulation of spinal cord interneurons that directly connect the lumbar and cervical enlargements. Previously we showed, in uninjured animals, that conditionally silencing LAPNs disrupted left-right coordination of the hindlimbs and forelimbs in a context-dependent manner, demonstrating that LAPNs secure alternation of the fore- and hindlimb pairs during overground stepping. Given the ventrolateral location of LAPN axons in the spinal cord white matter, many likely remain intact following incomplete, contusive, thoracic spinal cord injury (SCI), suggesting a potential role in the recovery of stepping. Thus, we hypothesized that silencing LAPNs after SCI would disrupt recovered locomotion. Instead, we found that silencing spared LAPNs post-SCI improved locomotor function, including paw placement order and timing, and a decrease in the number of dorsal steps. Silencing also restored left-right hindlimb coordination and normalized spatiotemporal features of gait such as stance and swing time. However, hindlimb-forelimb coordination was not restored. These data indicate that the temporal information carried between the spinal enlargements by the spared LAPNs post-SCI is detrimental to recovered hindlimb locomotor function. These findings are an illustration of a post-SCI neuroanatomical-functional paradox and have implications for the development of neuronal- and axonal-protective therapeutic strategies and the clinical study/implementation of neuromodulation strategies.

Published

2021

4. Long ascending propriospinal neurons provide flexible, context-specific control of interlimb coordination

Author

Amanda M Pocratsky, Courtney T Shepard, Johnny R Morehouse, Darlene A Burke, Amberley S Riegler, Josiah T Hardin, Jason E Beare, Casey Hainline, Gregory JR States, Brandon L Brown, Scott R Whittemore, and David SK Magnuson

Subjects

spinal cord, long ascending propriospinal neurons, locomotor circuitry, central pattern generator, synaptic silencing, Medicine, Science, Biology (General), QH301-705.5

Abstract

Within the cervical and lumbar spinal enlargements, central pattern generator (CPG) circuitry produces the rhythmic output necessary for limb coordination during locomotion. Long propriospinal neurons that inter-connect these CPGs are thought to secure hindlimb-forelimb coordination, ensuring that diagonal limb pairs move synchronously while the ipsilateral limb pairs move out-of-phase during stepping. Here, we show that silencing long ascending propriospinal neurons (LAPNs) that inter-connect the lumbar and cervical CPGs disrupts left-right limb coupling of each limb pair in the adult rat during overground locomotion on a high-friction surface. These perturbations occurred independent of the locomotor rhythm, intralimb coordination, and speed-dependent (or any other) principal features of locomotion. Strikingly, the functional consequences of silencing LAPNs are highly context-dependent; the phenotype was not expressed during swimming, treadmill stepping, exploratory locomotion, or walking on an uncoated, slick surface. These data reveal surprising flexibility and context-dependence in the control of interlimb coordination during locomotion.

Published

2020

5. Pathophysiology of Dyt1-Tor1a dystonia in mice is mediated by spinal neural circuit dysfunction

Author

Amanda M. Pocratsky, Filipe Nascimento, M. Görkem Özyurt, Ian J. White, Roisin Sullivan, Benjamin J. O’Callaghan, Calvin C. Smith, Sunaina Surana, Marco Beato, and Robert M. Brownstone

Subjects

General Medicine, Article

Abstract

Dystonia, a neurological disorder defined by abnormal postures and disorganized movements, is considered to be a neural circuit disorder with dysfunction arising within and between multiple brain regions. Given that spinal neural circuits constitute the final pathway for motor control, we sought to determine their contribution to this movement disorder. Focusing on the most common inherited form of dystonia in humans, DYT1- TOR1A , we generated a conditional knockout of the torsin family 1 member A ( Tor1a ) gene in the mouse spinal cord and dorsal root ganglia (DRG). We found that these mice recapitulated the phenotype of the human condition, developing early-onset generalized torsional dystonia. Motor signs emerged early in the mouse hindlimbs before spreading caudo-rostrally to affect the pelvis, trunk, and forelimbs throughout postnatal maturation. Physiologically, these mice bore the hallmark features of dystonia, including spontaneous contractions at rest and excessive and disorganized contractions, including cocontractions of antagonist muscle groups, during voluntary movements. Spontaneous activity, disorganized motor output, and impaired monosynaptic reflexes, all signs of human dystonia, were recorded from isolated mouse spinal cords from these conditional knockout mice. All components of the monosynaptic reflex arc were affected, including motor neurons. Given that confining the Tor1a conditional knockout to DRG did not lead to early-onset dystonia, we conclude that the pathophysiological substrate of this mouse model of dystonia lies in spinal neural circuits. Together, these data provide new insights into our current understanding of dystonia pathophysiology.

Published

2023

6. Author response: Spinal premotor interneurons controlling antagonistic muscles are spatially intermingled

Author

Gardave Singh Bhumbra, B Anne Bannatyne, Bianca K Barriga, Sophie Skarlatou, Remi Ronzano, Joshua D Foster, Jeffrey D Moore, Camille Lancelin, Amanda M Pocratsky, Mustafa Görkem Özyurt, Calvin Chad Smith, Andrew J Todd, David J Maxwell, Andrew J Murray, Samuel L Pfaff, Robert M Brownstone, Niccolò Zampieri, and Marco Beato

Published

2022

7. Pathophysiology of Dyt1 dystonia is mediated by spinal cord dysfunction

Author

Amanda M. Pocratsky, Filipe Nascimento, M. Görkem Özyurt, Ian J. White, Roisin Sullivan, Benjamin J. O’Callaghan, Calvin C. Smith, Sunaina Surana, Marco Beato, and Robert M. Brownstone

Abstract

SummaryDystonia, a neurological disorder defined by abnormal postures and disorganised movements, is considered to be a neural circuit disorder with dysfunction arising within and between multiple brain regions. Given that spinal circuits constitute the final pathway for motor control, we sought to determine their contribution to the movement disorder. Focusing on the most common inherited dystonia, DYT1-TOR1A, we confined a conditional knockout ofTor1ato the spinal cord and dorsal root ganglia (DRG) and found that these mice recapitulated the phenotype of the human condition, developing early onset generalised torsional dystonia. Physiologically, these mice bore the hallmark features of dystonia: spontaneous contractions at rest, excessive sustained contractions during voluntary movements including co-contractions of motor antagonists, and altered sensory-motor reflexes. Furthermore, spinal locomotor circuits were impaired. Together, these data challenge current understanding of dystonia, and lead to broader insights into spinal cord function and movement disorder pathophysiology.

Published

2022

8. Silencing long ascending propriospinal neurons after spinal cord injury improves hindlimb stepping in the adult rat

Author

Morgan A. Van Rijswijck, Rachel M Zalla, Scott R. Whittemore, Darlene A. Burke, Johnny R. Morehouse, Brandon L Brown, David S.K. Magnuson, Courtney T Shepard, Amberley S Riegler, and Amanda M. Pocratsky

Subjects

animal structures, QH301-705.5, Science, Hindlimb, Biology, General Biochemistry, Genetics and Molecular Biology, Rats, Sprague-Dawley, Lumbar, Interneurons, propriospinal neurons, medicine, Gene silencing, Animals, Biology (General), Spinal cord injury, Temporal information, Gait, Spinal Cord Injuries, General Immunology and Microbiology, business.industry, General Neuroscience, Spinal cord white matter, viral vector, Extremities, General Medicine, Recovery of Function, neuronal silencing, medicine.disease, Spinal cord, Neuromodulation (medicine), spinal cord injury, locomotion, Disease Models, Animal, medicine.anatomical_structure, Rat, Medicine, Female, business, Neuroscience, Research Article

Abstract

Long ascending propriospinal neurons (LAPNs) are a subpopulation of spinal cord interneurons that directly connect the lumbar and cervical enlargements. In uninjured animals, conditionally silencing LAPNs resulted in disrupted left-right coordination of the hindlimbs and forelimbs in a context-dependent manner, demonstrating that LAPNs secure alternation of the fore- and hindlimb pairs during overground stepping in the adult rat. Given their ventrolateral location in the spinal cord white matter, many LAPN axons likely remain intact following thoracic spinal cord injury (SCI), suggesting a potential role in the recovery of stepping. Thus, we hypothesized that silencing LAPNs after SCI would result in diminished hindlimb locomotor function. We found instead that silencing of spared LAPNs post-SCI restored the left-right hindlimb coordination associated with alternating gaits that was lost as a result of SCI. Several other fundamental characteristics of hindlimb stepping were also improved and the number of abnormal steps were reduced. However, hindlimb-forelimb coordination was not restored. These data suggest that the temporal information carried between the enlargements by the LAPNs after SCI may be detrimental to hindlimb locomotor function. These observations have implications for our understanding of the relationship between injury severity and functional outcome, for the efforts to develop neuro- and axo-protective therapeutic strategies, and also for the clinical study/implementation of spinal stimulation and neuromodulation.

Published

2021

9. Author response: Silencing long ascending propriospinal neurons after spinal cord injury improves hindlimb stepping in the adult rat

Author

Courtney T Shepard, Amanda M Pocratsky, Brandon L Brown, Morgan A Van Rijswijck, Rachel M Zalla, Darlene A Burke, Johnny R Morehouse, Amberley S Riegler, Scott R Whittemore, and David SK Magnuson

Published

2021

10. Long ascending propriospinal neurons provide flexible, context-specific control of interlimb coordination

Author

Gregory J. R. States, Johnny R. Morehouse, David S.K. Magnuson, Casey Hainline, Amberley S Riegler, Darlene A. Burke, Scott R. Whittemore, Courtney T Shepard, Amanda M. Pocratsky, Jason E. Beare, Brandon L Brown, and Josiah T Hardin

Subjects

Flexibility (anatomy), QH301-705.5, Science, long ascending propriospinal neurons, Biology, Commissural Interneurons, General Biochemistry, Genetics and Molecular Biology, Rats, Sprague-Dawley, Rhythm, locomotor circuitry, Interneurons, medicine, Locomotor rhythm, Animals, Biology (General), Treadmill, General Immunology and Microbiology, General Neuroscience, spinal cord, Central pattern generator, Extremities, General Medicine, Proprioception, Spinal cord, Rats, synaptic silencing, central pattern generator, medicine.anatomical_structure, Context specific, Central Pattern Generators, Rat, Medicine, Female, Neuroscience, Research Article

Abstract

Within the cervical and lumbar spinal enlargements, central pattern generator (CPG) circuitry produces the rhythmic output necessary for limb coordination during locomotion. Long propriospinal neurons that inter-connect these CPGs are thought to secure hindlimb-forelimb coordination, ensuring that diagonal limb pairs move synchronously while the ipsilateral limb pairs move out-of-phase during stepping. Here, we show that silencing long ascending propriospinal neurons (LAPNs) that inter-connect the lumbar and cervical CPGs disrupts left-right limb coupling of each limb pair in the adult rat during overground locomotion on a high-friction surface. These perturbations occurred independent of the locomotor rhythm, intralimb coordination, and speed-dependent (or any other) principal features of locomotion. Strikingly, the functional consequences of silencing LAPNs are highly context-dependent; the phenotype was not expressed during swimming, treadmill stepping, exploratory locomotion, or walking on an uncoated, slick surface. These data reveal surprising flexibility and context-dependence in the control of interlimb coordination during locomotion.

Published

2020

11. Author response: Long ascending propriospinal neurons provide flexible, context-specific control of interlimb coordination

Author

Darlene A. Burke, Gregory J. R. States, Johnny R. Morehouse, David S.K. Magnuson, Jason E. Beare, Amanda M. Pocratsky, Scott R. Whittemore, Casey Hainline, Josiah T Hardin, Brandon L Brown, Courtney T Shepard, and Amberley S Riegler

Subjects

Computer science, Context specific, Control (linguistics), Neuroscience

Published

2020

12. Long Ascending Propriospinal Neurons Provide Task-Specific, Context-Driven Control of Interlimb Coordination

Author

Johnny R. Morehouse, Courtney T Shepard, David S.K. Magnuson, Scott R. Whittemore, Josiah T Hardin, Jason E. Beare, Amanda M. Pocratsky, Casey Hainline, Amberly S. Riegler, Gregory J. R. States, and Darlene A. Burke

Subjects

Rhythm, medicine.anatomical_structure, Locomotor rhythm, medicine, Central pattern generator, Context specificity, Context (language use), Biology, Spinal cord, Temporal information, Neuroscience, Task (project management)

Abstract

Within the cervical and lumbar spinal enlargements, central pattern generating (CPG) circuitry produces the rhythmic output necessary for limb coordination during locomotion. Long propriospinal neurons that inter-connect these CPGs are thought to secure hindlimb-forelimb coordination, ensuring that diagonal limb pairs move synchronously while the ipsilateral limb pairs move out-of-phase during stepping. Here, we show that silencing long ascending propriospinal neurons (LAPNs) that interconnect the lumbar and cervical CPGs disrupts left-right limb coupling at each girdle. These perturbations to interlimb coordination occurred independent of the locomotor rhythm, did not affect intralimb coordination, and did not disrupt the speed-dependent (or any other) principal features of locomotion. Strikingly, the functional consequences of silencing LAPNs are highly context-dependent; the phenotype was not expressed during swimming, treadmill stepping, exploratory locomotion, or walking on an uncoated, slick surface. Together, these data show that LAPNs provide temporal information important for interlimb coordination in a flexible, context-driven manner.

Published

2019

13. Reversible silencing of lumbar spinal interneurons unmasks a task-specific network for securing hindlimb alternation

Author

Darlene A. Burke, David S.K. Magnuson, Pantelis Tsoulfas, Scott R. Whittemore, Gregory J. R. States, Amberly S. Riegler, Amanda M. Pocratsky, Jason E. Beare, and Johnny R. Morehouse

Subjects

0301 basic medicine, Nerve net, Science, General Physics and Astronomy, Cell Count, Hindlimb, Electromyography, Walking, Biology, General Biochemistry, Genetics and Molecular Biology, Article, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, Rhythm, Spatio-Temporal Analysis, Interneurons, Forelimb, Neural Pathways, medicine, Biological neural network, Animals, Muscle, Skeletal, Spinal Cord Injuries, Motor Neurons, Multidisciplinary, medicine.diagnostic_test, General Chemistry, Spinal cord, Biomechanical Phenomena, Rats, Walking Speed, Lumbar Spinal Cord, 030104 developmental biology, medicine.anatomical_structure, Spinal Cord, Models, Animal, Synapses, Female, Nerve Net, Neuroscience, 030217 neurology & neurosurgery, Locomotion

Abstract

Neural circuitry in the lumbar spinal cord governs two principal features of locomotion, rhythm and pattern, which reflect intra- and interlimb movement. These features are functionally organized into a hierarchy that precisely controls stepping in a stereotypic, speed-dependent fashion. Here, we show that a specific component of the locomotor pattern can be independently manipulated. Silencing spinal L2 interneurons that project to L5 selectively disrupts hindlimb alternation allowing a continuum of walking to hopping to emerge from the otherwise intact network. This perturbation, which is independent of speed and occurs spontaneously with each step, does not disrupt multi-joint movements or forelimb alternation, nor does it translate to a non-weight-bearing locomotor activity. Both the underlying rhythm and the usual relationship between speed and spatiotemporal characteristics of stepping persist. These data illustrate that hindlimb alternation can be manipulated independently from other core features of stepping, revealing a striking freedom in an otherwise precisely controlled system., Intra- and interlimb coordination during locomotion is governed by hierarchically organized lumbar spinal networks. Here, the authors show that reversible silencing of spinal L2–L5 interneurons specifically disrupts hindlimb alternation leading to a continuum of walking to hopping.

Published

2017