Summary
In pigmented rabbits anesthetized with N2O (70%) and halothane (2–4%), Purkinje cells were extracellularly recorded in the nodulus. Large field (60°×60°) optokinetic stimulation (OKS) with constant velocity was delivered to either the ipsi- or contralateral eye, and the direction and velocity selectivities of complex spike responses were examined. To ipsilateral OKS (n = 181), the preferred direction was forward (F, n = 72), upward (U, n = 38) or downward (D, n = 10), while the remaining cells (n = 61) showed no response (N). To contralateral OKS (n = 117), the preferred direction was backward (B, n = 22), upward (U, n = 7) or downward (D, n = 22), while the rest (n = 66) showed N. Cells tested with both eyes (n = 95) fell into 8 categories based on the preferred direction to ipsi- and contralateral OKS: (1) ipsi-F and contra-B (F/B type, n = 20), (2) ipsi-F but contra-N (F/N type, n = 12), (3) ipsi-U and contra-D (U/D type, n = 15), (4) ipsi-U but contra-N (U/N type, n = 13), (5) ipsi-N but contra-D (N/D type, n = 1), (6) ipsi-D but contra-N (D/N type, n = 5), (7) ipsi-N but contra-U (N/U type, n = 6), and (8) N to both eyes (N/N type, n = 23). The optimum velocity was in the range 0.1–2.0°/s for all cells responsive to OKS. In the ventral lamella, four medio-laterally aligned zones were demonstrated. In the most medial zone (0–0.5 mm from the midline), the majority of cells showed ipsi-N or contra-N responses. In the second zone (0.5–1.5 mm), most cells preferred ipsi-F or contra-B directions. In the third zone (1.5–2.5 mm), most cells preferred ipsi-U or contra-D directions. In the most lateral zone (2.5–3.5 mm), most cells preferred ipsi-F or contra-B directions. In the dorsal lamella, a longitudinal zone characterized with cells preferring ipsi-U or contra-D directions was found about 1.5–2.5 mm from the midline. This zone seemed to be the continuation of the third zone in the ventral lamella. Cells preferring ipsi-D or contra-U directions were scattered in the medial half of both the dorsal and ventral lamellae. Most cells responsive to electrical stimulation of the contralateral optic tract (OT) preferred the ipsi-F direction and were localized in the second and the most lateral zones of the ventral lamella. As for cells activated by a climbing fiber with a branching axon to the flocculus, no characteristic feature was found in terms of the preferred direction to OKS, except that none of the cells preferring ipsi-D or contra-U directions were activated by such branching climbing fibers. The results indicate that the nodulus consists of at least four functionally distinct zones in terms of direction selectivity of visual climbing fiber afferents.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alley K, Baker R, Simpson JI (1975) Afferents to the vestibulo-cerebellum and the origin of the visual climbing fibers in the rabbit. Brain Res 98:582–589
Angaut P, Brodal A (1967) The projection of the “vestibulo-cerebellum” onto the vestibular nuclei in the cat. Arch Ital Biol 105:441–479
Armstrong DM, Harvey RJ, Schild RF (1984) Cerebello-cerebellar responses mediated via climbing fibres. Exp Brain Res 18:19–39
Balaban CD (1984) Olivo-vestibular and cerebello-vestibular connections in albino rabbits. Neuroscience 12:129–149
Balaban CD, Henry RT (1988) Zonal organization of olivo-nodulus projections in albino rabbits. Neurosci Res 5:409–423
Barmack NH, Mugnaini E, Nelson BJ (1989) Vestibularly-evoked activity of single neurons in the beta nucleus of the inferior olive. Exp Brain Res Ser 17:313–322
Brodal A (1940) Experimentelle Untersuchungen über die olivocerebellare Lokalisation. Z Ges Neural Psychiat 169:1–153
Brodal A (1974) Anatomy of the vestibular nuclei and their connections. In: Kornhuber HH (eds) Handbook of sensory physiology : vestibular system, Part 1. Springer, Berlin Heidelberg New York, pp 239–352
Brodal A, Høivik B (1964) Sites and mode of termination of primary vestibulo-cerebellar fibers in the cat: an experimental study with silver impregnation methods. Arch Ital Biol 102:1–21
Dufossè M, Ito M, Miyashita Y (1977) Functional localization in the rabbit's cerebellar flocculus determined in relationship with eye movements. Neurosci Lett 5:273–277
Fukuda J, Highstein SM, Ito M (1972) Cerebellar inhibitory control of the vestibulo-ocular reflex investigated in rabbit IIIrd nucleus. Exp Brain Res 14:511–526
Ghelarducci B, Ito M, Yagi N (1975) Impulse discharges from flocculus Purkinje cells of alert rabbits during visual stimulation combined with horizontal head rotation. Brain Res 87:66–72
Graf W, Simpson JI, Leonard CS (1988) Spatial organization of visual messages of the rabbit's cerebellar flocculus. II. Complex and simple spike responses of Purkinje cells. J Neurophysiol 60:2091–2121
Highstein SM (1973) Synaptic linkage in the vestibulo-ocular and cerebello-vestibular pathways to the VIth nucleus in the rabbit. Exp Brain Res 17:301–314
Holstege G, Collewijn H (1982) The efferent connections of the nucleus of the optic tract and the superior colliculus in the rabbit. J Comp Neurol 209:139–175
Igarashi M, Isago H, O-Uchi T, Kubo T (1983) Uvulonodular lesion and eye-head coordination in squirrel monkeys. Adv Oto-Rhino-Laryng 31:18–27
Ito M (1982) Cerebellar control of the vestibulo-ocular reflex -around the flocculus hypothesis. Ann Rev Neurosci 5:275–296
Ito M (1984) The cerebellum and neural control. Raven Press, New York, pp 354–388
Ito M, Jastreboff PJ, Miyashita Y (1982a) Specific effects of unilateral lesions in the flocculus upon eye movements in albino rabbits. Exp Brain Res 45:233–242
Ito M, Nisimaru N, Yamamoto M (1977) Specific patterns of neuronal connections involved in the control of the rabbit's vestibulo ocular reflexes by the cerebellar flocculus. J Physiol (Lond) 265:833–854
Ito M, Orlov I, Yamamoto M (1982b) Topographical representation of vestibulo ocular reflexes in rabbit cerebellar flocculus. Neuroscience 7:1657–1664
Itoh K (1977) Efferent projections of the pretectum in the cat. Exp Brain Res 30:89–105
Kanda K-I, Sato Y, Ikarashi K, Kawasaki T (1989) Zonal organization of climbing fiber projections to the uvula in the cat. J Comp Neurol 279:138–148
Kano M, Kano M-S, Maekawa K (1989) Mossy fiber responses of Purkinje cells in the cerebellar nodulus to optokinetic stimulation-comparison with those in the flocculus. Neurosci Res Suppl 9:S100
Kano M, Kusunoki M, Kano M-S, Maekawa K (1988) Direction selectivity of complex spikes of nodulus Purkinje cells to optokinetic stimulation in pigmented rabbit. J Physiol Soc Jpn 50:465
Katayama S, Nisimaru N (1988) Parasagittal zonal pattern of olivonodular projections in rabbit cerebellum. Neurosci Res 5:424–438
Kawaguchi Y (1985) Two groups of secondary vestibular neurons mediating horizontal canal signals, probably to the ipsilateral medial rectus muscle, under inhibitory influences from the cerebellar flocculus in rabbits. Neurosci Res 2:434–446
Kimura M, Maekawa K (1981) Activity of flocculus Purkinje cells during passive eye movements. J Neurophysiol 46:1004–1017
Kusunoki M, Kano M, Kano M-S, Maekawa K (1990) Nature of optokinetic response and zonal organization of climbing fiber afferents in the vestibulo cerebellum of the pigmented rabbit. I. The flocculus. Exp Brain Res 80:225–237
Leonard CS, Simpson JI, Graf W (1988) Spatial organization of visual messages of the rabbit's cerebellar flocculus. I. Typology of inferior olive neurons of the dorsal cap of Kooy. J Neurophysiol 60:2073–2090
Maekawa K, Simpson JI (1973) Climbing fiber responses evoked in vestibulo cerebellum of rabbit from visual system. J Neurophysiol 36:649–666
Maekawa K, Takeda T (1975) Mossy fiber responses evoked in the cerebellar flocculus of rabbits by stimulation of the optic pathway. Brain Res 98:590–595
Maekawa K, Takeda T (1976) Electrophysiological identification of the climbing and mossy fiber pathways from the rabbit's retina to the contralateral cerebellar flocculus. Brain Res 109:169–174
Maekawa K, Takeda T (1979) Origin of descending afferents to the rostral part of dorsal cap of inferior olive which transfer contralateral optic activities to the flocculus. Brain Res 172:393–405
Maekawa K, Takeda T, Kano M, Kusunoki M (1989) Collateralized climbing fiber projection to the flocculus and the nodulus of the rabbit. Exp Brain Res Ser 17:30–45
Money KE (1970) Motion sickness. Physiol Rev 50:1–39
Nagao S (1983) Effects of vestibulo cerebellar lesions upon dynamic characteristics and adaptation of vestibulo-ocular and optokinetic responses in pigmented rabbits. Exp Brain Res 53:36–46
Nagao S (1988) Behavior of floccular Purkinje cells correlated with adaptation of horizontal optokinetic eye movement response in pigmented rabbits. Exp Brain Res 73:489–497
Nagao S, Ito M, Karachot L (1985) Eye field in the cerebellar flocculus of pigmented rabbits determined with local electrical stimulation. Neurosci Res 3:39–51
Nisimaru N, Watanabe Y (1985) Depressant area in the lateral nodulus-uvula of the cerebellum for renal sympathetic nerve activity and systemic blood pressure in the rabbit. Neurosci Res 3:177–181
Precht W (1979) Neural operations in the vestibular system. Springer, Berlin Heidelberg New York, pp 143–153
Precht W, Simpson JI, Llinás R (1976a) Responses of Purkinje cells in rabbit nodulus and uvula to natural vestibular and visual stimuli. Pflüger Arch 367:1–6
Precht W, Volkind R, Maeda M, Giretti ML (1976b) The effects of stimulating the cerebellar nodulus in the cat on the responses of vestibular neurons. Neuroscience 1:301–312
Robinson DA (1976) Adaptive gain control of vestibulo-ocular reflex by the cerebellum. J Neurophysiol 39:954–969
Robinson FR, Fraser MO, Hollerman JR, Tomko DL (1988) Yaw direction neurons in the cat inferior olive. J Neurophysiol 60:1739–1752
Sato Y, Barmack NH (1985) Zonal organization of olivo-cerebellar projections to the uvula in rabbits. Brain Res 359:281–289
Simpson JI, Alley KE (1974) Visual climbing fiber input to rabbit vestibulo-cerebellum: a source of direction-specific information. Brain Res 82:302–308
Soodak RT, Simpson JI (1988) The accessory optic system of rabbit. I. Basic visual response properties. J Neurophysiol 60:2037–2054
Takeda T, Maekawa K (1984) Collateralized projection of visual climbing fibers to the flocculus and nodulus of the rabbit. Neurosci Res 2:125–132
Takeda T, Maekawa K (1989a) Olivary branching projection to the flocculus, nodulus and uvula in the rabbit. I. An electrophysiological study. Exp Brain Res 74:47–62
Takeda T, Maekawa K (1989b) Olivary branching projection to the flocculus, nodulus and uvula in the rabbit. II. Retrograde double labeling study with fluorescent dyes. Exp Brain Res 76:323–332
Uchida K, Mizuno N, Sugimoto T, Itoh K (1982) Autoradiographic demonstration of retinal projections to the brain stem structures in the rabbit using transneuronal tracing technique with special reference to the retinal projections to the inferior olive. Exp Neurol 78:369–379
Waespe W, Cohen B, Raphan T (1985) Dynamic modulation of the vestibulo-ocular reflex by the nodulus and uvula. Science 228:199–202
Wilson VJ, Maeda M, Franck JI, Shimazu H (1976) Mossy fiber neck and second-order labyrinthine projections to cat flocculus. J Neurophysiol 39:301–310
Yamamoto M (1979) Topographical representation in rabbit cerebellar flocculus for various afferent inputs from the brainstem investigated by means of retrograde axonal transport of horseradish peroxidase. Neurosci Lett 12:29–34
Yamamoto M, Shimoyama I (1977) Differential localization of rabbit's flocculus Purkinje cells projecting to the medial and superior vestibular nuclei, investigated by means of the horseradish peroxidase retrograde axonal transport. Neurosci Lett 5:279–283
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Kano, M., Kano, M.S., Kusunoki, M. et al. Nature of optokinetic response and zonal organization of climbing fiber afferents in the vestibulocerebellum of the pigmented rabbit. Exp Brain Res 80, 238–251 (1990). https://doi.org/10.1007/BF00228152
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00228152