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The Journal of Neuroscience, November 7, 2007, 27(45):12267-12276; doi:10.1523/JNEUROSCI.3694-07.2007

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Behavioral/Systems/Cognitive
Reconfiguration of a Vertebrate Motor Network: Specific Neuron Recruitment and Context-Dependent Synaptic Plasticity

Wen-Chang Li,¹ Bart Sautois,² Alan Roberts,¹ and Stephen R. Soffe¹

¹School of Biological Sciences, University of Bristol, Bristol BS8 1UG, United Kingdom, and ²Department of Applied Mathematics and Computer Science, Ghent University, B-9000 Ghent, Belgium

Correspondence should be addressed to Dr. Stephen R. Soffe, School of Biological Sciences, University of Bristol, Woodland Road, Bristol BS8 1UG, UK. Email: s.r.soffe{at}bristol.ac.uk

Motor networks typically generate several related output patterns or gaits where individual neurons may be shared or recruited between patterns. We investigate how a vertebrate locomotor network is reconfigured to produce a second rhythmic motor pattern, defining the detailed pattern of neuronal recruitment and consequent changes in the mechanism for rhythm generation. Hatchling Xenopus tadpoles swim if touched, but when held make slower, stronger, struggling movements. In immobilized tadpoles, a brief current pulse to the skin initiates swimming, whereas 40 Hz pulses produce struggling. The classes of neurons active during struggling are defined using whole-cell patch recordings from hindbrain and spinal cord neurons during 40 Hz stimulation of the skin. Some motoneurons and inhibitory interneurons are active in both swimming and struggling, but more neurons are recruited within these classes during struggling. In addition, and in contrast to a previous study, we describe two new classes of excitatory interneuron specifically recruited during struggling and define their properties and synaptic connections. We then explore mechanisms that generate struggling by building a network model incorporating these new neurons. As well as the recruitment of new neuron classes, we show that reconfiguration of the locomotor network to the struggling central pattern generator (CPG) reveals a context-dependent synaptic depression of reciprocal inhibition: the result of increased inhibitory neuron firing frequency during struggling. This provides one possible mechanism for burst termination not seen in the swimming CPG. The direct demonstration of depression in reciprocal inhibition confirms a key element of Brown's (1911) hypothesis for locomotor rhythmogenesis.

Key words: Xenopus; synaptic depression; interneurons; modeling; switching; inhibition

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Received July 9, 2007; revised Sept. 11, 2007; accepted Sept. 11, 2007.

Correspondence should be addressed to Dr. Stephen R. Soffe, School of Biological Sciences, University of Bristol, Woodland Road, Bristol BS8 1UG, UK. Email: s.r.soffe{at}bristol.ac.uk

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