Abstract
Output from the interpositus nucleus can inhibit the inferior olive, probably via the GABA-ergic nucleo-olivary pathway. It has been suggested that the function of this inhibition might be to regulate synaptic plasticity resulting from parallel fibre/climbing fibre interaction in cerebellar Purkinje cells, by providing negative feedback information to the olive. Thus, when a learned response, generated by the interpositus nucleus, reaches a sufficient amplitude, the olive would be inhibited and further learning blocked. This suggestion was tested in a classical conditioning paradigm. Decerebrate ferrets were trained using electrical skin stimulation of the forelimb as the conditioned stimulus (CS) and periorbital stimulation as the unconditioned stimulus (US). Climbing fibre responses evoked in Purkinje cells by the US were recorded as surface field potentials in the part of the c3 zone controlling eyeblink. It was found that the CS did not inhibit the olive at the beginning of training, but when conditioned responses were large, the olive was inhibited by the CS in some animals. After a number of unpaired CS presentations, which caused extinction of the conditioned response, the inhibition disappeared. The size of individual conditioned responses correlated negatively with the size of the climbing fibre responses evoked by the US. Climbing fibre responses evoked by direct stimulation of the olive were also inhibited. It was concluded that cerebellar output during performance of a conditioned response inhibits the inferior olive. The results thus support the hypothesis of a cerebellar locus of conditioning and are consistent with the proposed role of cerebello-olivary inhibition.
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References
Albus JS (1971) A theory of cerebellar function. Math Biosci 10:25–61
Andersson G (1984) Mutual inhibition between olivary cell groups projecting to different cerebellar microzones in the cat. Exp Brain Res 54:293–303
Andersson G, Hesslow G (1987a) Inferior olive excitability after high frequency climbing fibre activation in the cat. Exp Brain Res 67:523–532
Andersson G, Hesslow G (1987b) Activity of Purkinje cells and interpositus neurones during and after high frequency climbing fibre activation in the cat. Exp Brain Res 67:533–542
Andersson G, Garwicz M, Hesslow G (1988) Evidence for a GABA-mediated inhibition of the inferior olive in the cat. Exp Brain Res 72:450–456
Davis KD, Dostrovsky JO (1986) Modulatory influences of red nucleus stimulation on the somatosensory responses of cat trigeminal subnucleus oralis neurons. Exp Neurol 91:80–101
Gormezano I, Moore JW (1976) Classical conditioning. In: Marx MH (ed) Learning: processes. Macmillan, New York, pp 119–203
Hesslow G (1986) Inhibition of inferior olivary transmission by mesencephalic stimulation in the cat. Neurosci Lett 63:76–80
Hesslow G (1992) Cerebellar inhibition of the inferior olive during conditioned eyeblink responses in decerebrate ferrets. Eur J Neurosci Suppl 5:1063
Hesslow G (1994a) Correspondence between climbing fibre input and motor output in eyeblink related areas in cat cerebellar cortex. J Physiol (Lond) 476:229–244
Hesslow G (1994b) Inhibition of classically conditioned eyeblink responses by stimulation of the cerebellar cortex in the cat. J Physiol (Lond) 476:245–251
Hesslow G (1995) Cerebellum and classical conditioning of eyeblink in decerebrate cats and ferrets. In: Ferrell WR, Proske RU (eds) Neural control of movement. Plenum Press, New York, pp 117–1221
Hesslow G, Ivarsson M (1994) Suppression of cerebellar Purkinje cells during conditioned responses in ferrets. Neuroreport 5:649–652
Hesslow G, Hardiman M, Yeo CH (1990) Cerebellar lesions abolish eyeblink conditioning in the decerebrate rabbit. Eur J Neurosci Suppl 3:301
Ito M (1984) The cerebellum and neuronal control. Raven Press, New York
Ivarsson M, Hesslow G (1993) Bilateral control of the orbicularis oculi muscle from one cerebellar hemisphere in the ferret. Neuroreport 4:1127–1130
Kamin L (1969) Predictability, surprise, attention, and conditioning. In: Campbell BA, Church RM (eds) Punishment and aversive behavior. Appleton-Century-Crofts, New York, pp 279–296
Kelly TM, Zuo C-C, Bloedel JR (1990) Classical conditioning of the eyeblink reflex in the decerebrate-decerebellate rabbit. Behav Brain Res 38:7–18
Krupa DJ, Thompson JK, Thompson RF (1993) Localization of a memory trace in the mammalian brain. Science 260:989–991
Mackintosh NJ (1974) The psychology of animal learning. Academic Press, London
Marr D (1969) A theory of cerebellar cortex. J Physiol (Lond) 202:437–470
Mauk MD, Thompson RF (1987) Retention of classically conditioned eyelid responses following acute decerebration. Brain Res 403:89–95
McCormick DA, Thompson RF (1984) Cerebellum: essential involvement in the classically conditioned eyelid response. Science 223:296–299
Nelson B, Mugnaini E (1989) Origins of GABA-ergic inputs to the inferior olive. In: Strata P (ed) The olivo-cerebellar system in motor control. (Experimental Brain Research, series 17) Springer, Berlin Heidelberg New York, pp 86–107
Nordholm AF, Lavond DG, Thompson RF (1991) Are eyeblink responses to tone in the decerebrate, decerebellate rabbit conditioned responses? Behav Brain Res 44:27–34
Norman RJ, Villablanca JR, Brown KA, Schwafel JA, Buchwald JS (1974) Classical eyeblink conditioning in the bilaterally hemispherectomized cat. Exp Neurol 44:363–380
Sears LL, Steinmetz JE (1991) Dorsal accessory olive activity diminishes during acquisition of the rabbit classically conditioned eyelid response. Brain Res 545:114–122
Solomon RL, Turner LH (1962) Discriminative classical conditioning in dogs paralysed by curare can later control discriminative avoidance responses in the normal state. Psychol Rev 69:202–219
Welsh JP, Harvey JA (1989) Cerebellar lesions and the nictitating membrane reflex: performance deficits of the conditioned and unconditioned response. J Neurosci 9:299–311
Welsh JP, Harvey JA (1991) Pavlovian conditioning in the rabbit during inactivation of the interpositus nucleus. J Physiol (Lond) 444:459–480
Yeo CH (1991) Cerebellum and classical conditioning of motor responses. In: Wolpaw JR, Schmidt JT, Vaughan TM (eds) Activity driven CNS changes in learning and development. Ann NY Acad Sci 627:292–304
Yeo CH, Hardiman MJ (1992) Cerebellar cortex and eyeblink conditioning: a reexamination. Exp Brain Res 88:623–638
Yeo CH, Hardiman MJ, Glickstein M (1985a) Classical conditioning of the nictitating membrane response of the rabbit. I. Lesions of the cerebellar nuclei. Exp Brain Res 60:87–98
Yeo CH, Hardiman MJ, Glickstein M (1985b) Classical conditioning of the nictitating membrane response of the rabbit. II. Lesions of the cerebellar cortex. Exp Brain Res 60:99–113
Yeo CH, Hardiman MJ, Glickstein M (1986) Classical conditioning of the nictitating membrane response of the rabbit. IV. Lesions of the inferior olive. Exp Brain Res 63:81–92
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Hesslow, G., Ivarsson, M. Inhibition of the inferior olive during conditioned responses in the decerebrate ferret. Exp Brain Res 110, 36–46 (1996). https://doi.org/10.1007/BF00241372
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DOI: https://doi.org/10.1007/BF00241372