Pre-motor neuronal networks, from connectivity to function
Lead Research Organisation:
University of Glasgow
Department Name: College of Medical, Veterinary, Life Sci
Abstract
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Technical Summary
The timing of motoneuron firing is regulated by the strength and density of synaptic inputs they receive from an intricate network of excitatory and inhibitory premotor interneurons, whose characteristics, spatial distribution and relative effect on motoneurons are largely unknown. The recent development of viral trans-synaptic tracers that can selectively label individual motor nuclei and retrogradely cross a single synaptic step gives us a unique opportunity to target last order interneurons for expression of fluorescent proteins to label them and of light activated opsins, to excite them selectively. We will obtain a connectivity map for motor nuclei corresponding to specific pairs of antagonist or synergist hindlimb muscles and determine whether muscles with different functions are controlled by spatially separated groups of premotor interneurons. Reconstruction of fixed and labelled tissue, together with immunocytochemistry will be used to identify the position of known classes of premotor cells, including neurons with proprioceptive inputs, Renshaw cells and commissural interneurons. Using multiple patch clamp recordings we will measure the strength of individual excitatory and inhibitory synapses and determine whether synaptic strength differs systematically among cells belonging to different classes or those contacting motor nuclei with different functions. We will also test whether premotor interneurons contacting synergist or antagonist motor pools have a stereotyped pattern of connectivity and whether this depends on their excitatory/inhibitory phenotype.
Our experiments will produce a large scale connectivity map of premotor circuits and will provide a quantitative measure of the strength and distribution of inputs to motoneurons. Knowledge of the circuitry of networks involved in motor control is a strict requirement for understanding and possibly repairing, the damage occurring due to disease or injury, and our proposal is a step in this direction.
Our experiments will produce a large scale connectivity map of premotor circuits and will provide a quantitative measure of the strength and distribution of inputs to motoneurons. Knowledge of the circuitry of networks involved in motor control is a strict requirement for understanding and possibly repairing, the damage occurring due to disease or injury, and our proposal is a step in this direction.
Planned Impact
Understanding the wiring diagrams in the central nervous system is basic research, but there are many reasons why the work we are proposing has the potential for being exploited for the general well-being of society. While some of the outcomes might take time to come to fruition, others might be achieved within the time scale of our proposed project.
Health sector
One pathway towards impact is represented by potential contributions to the health sector: in the UK alone there are more than 50,000 people suffering severe disabilities due to spinal cord injury and the social and economic cost is enormous. Any research that can improve our knowledge of motor function in a healthy organism has potential impact on their well being.
Traditionally, research strategies have focussed on fibre regeneration or on electrical stimulation in an attempt to bridge across the damaged connections. Both approaches require:
1) knowledge of the circuits
2) safe and locally efficient drug delivery methods
3) electrical control of the neural network.
These frontier themes are fully developed in our research program, since we will describe motor circuits in an intact organism and exploit a novel method of gene transfer using viral constructs. Recently, a similar method of gene delivery by means of viral constructs has been successfully used to control epilepsy in mice. Our techniques have a high potential of being translated into animal models, with the future prospect of an application to humans with spinal cord injuries. We are in an advantageous position to promote the translation, due to the overlap of interests of the PI with the neighbouring Sobell Department of Motor Neuroscience and Movement Disorders at UCL, one of the UK's leading institutions in motor research. The PI is already interacting with the Sobell Unit, through joint meetings and seminars. We will extend this interaction to include informal lab presentations and explore the applicability of our techniques to current animal models of spinal cord injury and disease. The co-PI (DJM) is currently involved in a collaborative study of the reorganisation of corticospinal tract terminations in a rat stroke model, with basic scientists and clinicians. In this study we are examining the potential for information from the corticospinal tract to be conveyed to motoneurons via novel 'detour' circuits. This project will ultimately involve the use of stem cells to promote new growth; a technique that is currently being pursued in clinical trials in Glasgow. Greater knowledge of premotor interneurons will enable us to understand their role in motor networks and ultimately identify suitable candidates for detour circuits. In particular, we need much more information about commissural interneurons which have the potential to convey information from the corticospinal tract to contralateral regions of the cord that have become denervated as a consequence of stroke.
Industry
During the past 4 years the PI has worked in close contact with suppliers of optical and electrophysiological instruments and has offered advice on the design of new tools and the optimization of existing ones. Especially fruitful has been the interaction with Scientifica, a leading UK provider of specialized tools for research and recent winner of the Queen's Award for Enterprise. The PI designed a custom accessory to avoid transmitting vibration during delicate recordings that is currently commercially available and widely used in the community. Furthermore, the PI contributed to the design, troubleshooting and testing of a novel amplifier (ELC-03), that is the only commercially available instrument designed to perform simultaneously recordings and stimulations of neurons. The PI has currently a pending application for a Case Studentship (jointly funded by UCL and Scientifica) to develop a new tool for selective optical stimulation. Its development is in progress and the first bench tests are expected within a year.
Health sector
One pathway towards impact is represented by potential contributions to the health sector: in the UK alone there are more than 50,000 people suffering severe disabilities due to spinal cord injury and the social and economic cost is enormous. Any research that can improve our knowledge of motor function in a healthy organism has potential impact on their well being.
Traditionally, research strategies have focussed on fibre regeneration or on electrical stimulation in an attempt to bridge across the damaged connections. Both approaches require:
1) knowledge of the circuits
2) safe and locally efficient drug delivery methods
3) electrical control of the neural network.
These frontier themes are fully developed in our research program, since we will describe motor circuits in an intact organism and exploit a novel method of gene transfer using viral constructs. Recently, a similar method of gene delivery by means of viral constructs has been successfully used to control epilepsy in mice. Our techniques have a high potential of being translated into animal models, with the future prospect of an application to humans with spinal cord injuries. We are in an advantageous position to promote the translation, due to the overlap of interests of the PI with the neighbouring Sobell Department of Motor Neuroscience and Movement Disorders at UCL, one of the UK's leading institutions in motor research. The PI is already interacting with the Sobell Unit, through joint meetings and seminars. We will extend this interaction to include informal lab presentations and explore the applicability of our techniques to current animal models of spinal cord injury and disease. The co-PI (DJM) is currently involved in a collaborative study of the reorganisation of corticospinal tract terminations in a rat stroke model, with basic scientists and clinicians. In this study we are examining the potential for information from the corticospinal tract to be conveyed to motoneurons via novel 'detour' circuits. This project will ultimately involve the use of stem cells to promote new growth; a technique that is currently being pursued in clinical trials in Glasgow. Greater knowledge of premotor interneurons will enable us to understand their role in motor networks and ultimately identify suitable candidates for detour circuits. In particular, we need much more information about commissural interneurons which have the potential to convey information from the corticospinal tract to contralateral regions of the cord that have become denervated as a consequence of stroke.
Industry
During the past 4 years the PI has worked in close contact with suppliers of optical and electrophysiological instruments and has offered advice on the design of new tools and the optimization of existing ones. Especially fruitful has been the interaction with Scientifica, a leading UK provider of specialized tools for research and recent winner of the Queen's Award for Enterprise. The PI designed a custom accessory to avoid transmitting vibration during delicate recordings that is currently commercially available and widely used in the community. Furthermore, the PI contributed to the design, troubleshooting and testing of a novel amplifier (ELC-03), that is the only commercially available instrument designed to perform simultaneously recordings and stimulations of neurons. The PI has currently a pending application for a Case Studentship (jointly funded by UCL and Scientifica) to develop a new tool for selective optical stimulation. Its development is in progress and the first bench tests are expected within a year.
Publications
Bhumbra GS
(2014)
The recurrent case for the Renshaw cell.
in The Journal of neuroscience : the official journal of the Society for Neuroscience
| Description | The purpose of this investigation is to discover how networks of small neurons (interneurons) in the spinal cord operate to control movement. Muscle activity is initiated by motoneurons which, in turn, are controlled by networks of interneurons. We demonstrated that a specific last-order interneuron, the Renshaw cell, had much more powerful actions on motoneuron activity than was previously thought. We used a viral tracing method which labels entire networks of interneurons that form monosynaptic connections with motoneurons. We have shown that premotor interneurons innervating motoneurons form characteristic rostro-caudal and medio-lateral distributions by creating 3 dimensional models of neuronal populations within the spinal cord. We originally hypothesised that common premotor interneurons would innervate synergist muscles whereas separate groups of interneurons would innervate antagonist muscles. In order to test this hypothesis we injected virus coupled to fluorescent markers (GFP and mCherry) into pairs of synergist or antagonist muscles. However less than 4% of synergist premotor interneurons were double-labelled and a similar percentage was found for antagonist last-order interneurons. These experiments show that most last-order premotor interneurons innervate specific motoneurons and hence that integration of synergist and or antagonist activity must occur at a stage in the premotor network prior to the last-order cells. Contrary to a previously published report, we did not see any segregation of flexor/extensor premotor interneurons. At present the reason for this difference is not clear but it was a consistent finding. We have new data on last-order cells that express the glycine transporter-2 which shows that there asimmetry in the distribution of excitatory/inhibitory premotor Ins in the ventral contralateral side; this applies to all tested muscles. There was also an indication that Glyt2+ Ins receive more proprioceptive inputs than the negative cells. The data have now been published as a pre-print. We pooled our data with those of two other laboratories for this publication and have invited comments. |
| Exploitation Route | These findings will be of interest to other investigators working in motor control and also generally in modelling neuronal networks. The models and digitized neuronal reconstructions have been made freely available. |
| Sectors | Digital/Communication/Information Technologies (including Software),Education,Healthcare,Culture, Heritage, Museums and Collections,Other |
| URL | http://doi.org/10.1101/2021.02.10.430608 |
| Title | Improved G-deleted rabies production |
| Description | We have established a technique for improving the production and quality of a strain of modified rabies virus, used fro trans-synaptic tracing of neuronal connections. This is a modification of previously published methods (developed in the lab of Prof. Callaway, at the salk Institute). We have set up the reagents and tools needed for the production and we are currently one of only three labs who can produce large quantities of highly concnetrated rabies virus. |
| Type Of Material | Biological samples |
| Year Produced | 2016 |
| Provided To Others? | Yes |
| Impact | The improvement in the quality of our rabies production has resulted in two main outcomes: 1) We are sharing our virus with two other labs at UCL (Dr. MacAskill and Prof. Brownstone) and the shared use of the same reagents has given rise to new collaborations among the groups 2) Improved quality of the viral tracer has resulted in more than halving the number of animals needed |
| Title | NeuroMorpho.org |
| Description | Reconstructions of Renshaw Cells and Motoneurons. http://Will be available in June 2016 |
| Type Of Material | Database/Collection of data |
| Year Produced | 2016 |
| Provided To Others? | Yes |
| Impact | None |
| Title | motoneuron-Renshaw cell |
| Description | Full anatomical reconstructions of pairs of synaptically coupled motoneurons and inhibitory interneurons |
| Type Of Material | Database/Collection of data |
| Year Produced | 2014 |
| Provided To Others? | Yes |
| Impact | Not yet applicable |
| Description | Divergence of DI3 interneurons |
| Organisation | University College London |
| Department | Institute of Neurology |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | We are providing training and performing experiments in collaboration with Prof Rob Brownstone at the Institte of neurology. The optimization of the technique for trans-synaptic tracing, that is the main focus of our award, has generated large interest in the nearby scientific environment. As a consequence, we have been contacted by Prof. Brownstone and asked to collaborate on a project whose aim is to determine the degree of divergence of a special class of spinal interneurones onto specified subsets of motneurons. The neurons we are studying, named DI3 interneurons, have a special role in the modulation of the grasp refles and, even more interestingly, have been shown to be a necessary player in recovery of locomor abilities following a complete spinal cord transection. We have provided to Prof. Brownstone infected tissue and he and his team are currently analyzing it to determine whether DI3 neurons exhibit a lrger than average degree of divergence onto differnt motor nuclei |
| Collaborator Contribution | While we are producing the viral tracer and performing most of the surgeries, Prof' Brownstone inititated the project and his group is performing the analysis of the smaple we provide. Regular group meetings are held, to discuss the current state of the project and its future directions. |
| Impact | The collaboration has only started in the late months of 2016, therfore no impact has been achieved yet. |
| Start Year | 2016 |
| Description | UCL-Glasgow |
| Organisation | University of Glasgow |
| Department | Institute of Neuroscience and Psychology |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Development of computational and electrophysiological methods to measure the strength and features of synaptic connection in the spinal cord |
| Collaborator Contribution | anatomical experiments to validate independently the findings derived form electrophysiological experiments in living tissue |
| Impact | Publication of scientific papers, applications for grant funding. We apply different techniques (electrophysiology and anatomy) to address the same research questions using a multidisciplinary approach |
| Start Year | 2008 |