An understanding of how a brain transforms a mass of sensory signals into a behaviourally appropriate motor response will rest heavily upon understanding the integrative actions of Local Circuit Neurones that are the most numerous central neuronal elements in sophisticated nervous systems. This proposal has two objectives. First, to reveal the design principles of local circuits by analysing the organization of reflex pathways in which local interneurones participate and the types of integrative mechanisms they use. Second, to examine the mechanisms by which the local circuits of different legs are linked by projection interneurones so that a coordinated locomotory movement of all the legs can occur. These objectives can be met by analyzing restricted but repeatable reflexes in a nervous system where these neurones are readily accessible. In an insect, postural and locomotory adjustments of a limb are controlled by two types of individually identifiable local interneurones that have distinct physiological properties and integrative actions. Nonspiking local interneurones control the output of sets of motor neurones by the graded release of transmitter. Spiking local interneurones provide the initial step in processing the sensory inflow from the joints and from the surface of the legs. The local circuits of these interneurones controlling one leg are linked to the local circuits of adjacent legs by a population of identified projection interneurones. The direct contribution of an individual local or projection interneurone to a movement in an alert animal can be assessed. The methods will be physiological to determine by intracellular recording the connections between afferent neurones and local interneurones, between the two types of local interneurone themselves, and between local and projection interneurones. Morphological, by intracellular injection of dyes to reveal the structure of individual interneurones and the regions of neuropile to which they project. Immunocytochemical to label known groups of local interneurones and to identify their putative transmitters. Organizational principles underlying the local circuit control of limb movements should emerge from this broad combination of techniques applied to identified local and projection interneurones.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS016058-08
Application #
3396647
Study Section
Neurology B Subcommittee 1 (NEUB)
Project Start
1980-12-01
Project End
1990-08-31
Budget Start
1988-09-01
Budget End
1989-08-31
Support Year
8
Fiscal Year
1988
Total Cost
Indirect Cost
Name
University of Cambridge
Department
Type
DUNS #
226552610
City
Cambridge
State
Country
United Kingdom
Zip Code
CB2 1TN
Ott, S R; Jones, I W; Burrows, M et al. (2000) Sensory afferents and motor neurons as targets for nitric oxide in the locust. J Comp Neurol 422:521-32
Ott, S R; Burrows, M (1999) NADPH diaphorase histochemistry in the thoracic ganglia of locusts, crickets, and cockroaches: species differences and the impact of fixation. J Comp Neurol 410:387-97
Friedel, T (1999) The vibrational startle response of the desert locust Schistocerca gregaria. J Exp Biol 202:2151-9
Baudoux, S; Duch, C; Morris, O T (1998) Coupling of efferent neuromodulatory neurons to rhythmical leg motor activity in the locust. J Neurophysiol 79:361-70
Ott, S R; Burrows, M (1998) Nitric oxide synthase in the thoracic ganglia of the locust: distribution in the neuropiles and morphology of neurones. J Comp Neurol 395:217-30
Baudoux, S; Burrows, M (1998) Synaptic activation of efferent neuromodulatory neurones in the locust Schistocerca gregaria. J Exp Biol 201:3339-54
Newland, P L; Kondoh, Y (1997) Dynamics of neurons controlling movements of a locust hind leg II. Flexor tibiae motor neurons. J Neurophysiol 77:1731-46
Newland, P L; Kondoh, Y (1997) Dynamics of neurons controlling movements of a locust hind leg. III. Extensor tibiae motor neurons. J Neurophysiol 77:3297-310
Hedwig, B; Burrows, M (1996) Presynaptic inhibition of sensory neurons during kicking movements in the locust. J Neurophysiol 75:1221-32
Kondoh, Y; Okuma, J; Newland, P L (1995) Dynamics of neurons controlling movements of a locust hind leg: Wiener kernel analysis of the responses of proprioceptive afferents. J Neurophysiol 73:1829-42

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