Faculty Bibliography

1. The role of gamma-aminobutyric acid (GABA) on the pattern generation properties of neuronal ensembles in the olivocerebellar system was studied utilizing multiple electrode recordings of complex spikes (CSs) from rat crus 2a Purkinje cells (PCs). Initially multiple electrode experiments were combined with microinjections of picrotoxin into the inferior olive (IO). To corroborate the picrotoxin findings, the cerebellar nuclei, a major source of the GABAergic terminals in the IO, were chemically lesioned with the use of microinjections of kainic acid and N-methyl-D-aspartate. Both procedures generated comparable results. 2. After intraolivary picrotoxin injection there was an increase in the average firing rate, synchrony, and rhythmicity of spontaneous CS activity. In addition, the neuronal oscillation frequency tended to shift to lower frequencies. 3. The spatial distribution of synchronous CS activity in control conditions displayed a predominantly rostrocaudal orientation. Injection of picrotoxin to the IO disrupted this rostrocaudal organization and led to synchronous CS activity among PCs throughout crus 2a. Similar effects were observed relating to the distribution of CSs evoked via the 'climbing fiber reflex,' in which antidromic activation of the climbing fibers is followed by a return excitation that is mediated by the gap junctions between olivary neurons. 4. Chemical lesions of the cerebellar nuclei resulted in increased CS average firing rates. The effect of the lesions on CS synchronicity was similar to that following the picrotoxin injections, but greater in magnitude. In contrast to the olivary picrotoxin injections, the cerebellar nuclear lesions did not lead to an enhanced CS rhythmicity. 5. Bilateral recordings from left and right crus 2a demonstrated significant interhemispheric synchronization of CS activity, consistent with a previous report. Both unilateral olivary injections of picrotoxin and unilateral cerebellar nuclear lesions resulted in increased synchronization of CS activity between the left and right crus 2a. 6. We conclude that the cerebellar nucleoolivary projection to the olivary glomeruli modulates the effective electrotonic coupling between olivary neurons, and thereby carves out ensembles of neurons whose activity is synchronized. Thus these two nuclei may form the basis for a flexible and sophisticated motor coordination system able to help generate the many distinct movements that organisms are capable of performing

Simultaneous recordings of the left and right crus IIA of the cerebellar cortex in the rat have demonstrated that Purkinje cells of both sides can be activated synchronously by their climbing fibers. Because climbing fibers arise exclusively from the contralateral inferior olive (IO), this physiological finding seems to contradict the anatomy. To define the structural basis responsible for the bilateral synchrony, we examined the possibilities that bilateral common afferent inputs to the IO and interolivary connections form the underlying mechanisms. The bilaterality of the major afferents of the olivary regions that project to crus IIA was studied using Phaseolus vulgaris leucoagglutinin as an anterograde tracer. We found that the excitatory and inhibitory projections from the spinal trigeminal nucleus and dorsolateral hump of the interposed cerebellar nucleus to the transition area between the principal olive and dorsal accessory olive were bilateral. A second possible mechanism for bilateral synchrony, which is the possibility that axons of olivary neurons provide collaterals to the contralateral side, was investigated using biotinylated dextran amine as an anterograde tracer. Labeled axons were traced and reconstructed from the principal olive and dorsal and medial accessory olive up to the entrance of the contralateral restiform body. None of these axons gave rise to collaterals. The possibility that neurons in the left and right IO are electronically coupled via dendrodendritic connections was investigated by examining the midline region of the IO. The neuropil of the left and right IO is continuous in the dorsomedial cell column. Examination of Golgi impregnations of this subdivision demonstrated that (1) many dendrites cross from one side to the other, (2) neurons close to the midline give rise to dendrites that extend into both olives, and (3) dendrites of neurons in the dorsomedial cell column frequently traverse into adjacent olivary subdivisions such as the medial accessory olive and the transition area between the principal olive and dorsal accessory olive. Sections immunostained for dendritic lamellar bodies or GABAergic terminals showed the same pattern: the neuropils of the dorsomedial cell columns on both sides form a continuum with each other as well as with the neuropil of other adjacent olivary subdivisions. Ultrastructural examination of the dorsomedial cell column demonstrated that the midline area includes many complex glomeruli that contain dendritic spines linked by gap junctions. To verify whether the complex spike synchrony observed between left and right crus IIA could indeed be mediated in part through coupled neurons in the dorsomedial cell column, we recorded simultaneously from crus IIA areas and from left and right vermal lobule IX, which receives climbing fibers from the dorsomedial cell column. In these experiments we demonstrated that the climbing fibers of all four areas, i.e., the left and right crus IIA as well as the left and right lobule IX, can fire synchronously. The present results indicate that synchronous climbing fiber activation of the left and right crus IIA in the rat can be explained by (1) bilateral inputs to the transition areas between the principal olive and dorsal accessory olive and (2) dendrodendritic electrotonic coupling between neurons of the left and right dorsomedial cell column and between neurons of the dorsomedial cell column and adjacent olivary subdivisions

Simultaneous recording of complex spikes from multiple Purkinje cells (up to 44) in the rat cerebellum was used to examine the effects of 5-hydroxytryptamine (serotonin, 5-HT) on olivocerebellar function. Microinjection into the inferior olive was found to increase the average firing rate of inferior olivary neurons while slowing their oscillation frequency and increasing the coherence of their oscillations. Indeed, while the normal rostrocaudal band of synchronous activity remained unchanged, the degree of synchrony between Purkinje cell complex spikes within this band was enhanced following the 5-HT injections. Multiple-electrode recordings obtained from crus Ila and vermal lobule Vlb yielded qualitatively similar results; however, the effects on vermal activity were more pronounced. The effects of the 5-HT microinjection decayed with a time course of 75 min. The half-maximum effective concentration of 5-HT was between 10 and 100 microM. Injections of various 5-HT agonists and antagonists demonstrated that a 5-HT type-2A (5-HT2A) receptor is the main mediator for the 5-HT effect, which was very similar to the effect produced by injections of harmaline. However, 5-HT and harmaline appear to have independent mechanisms since the action of harmaline was not blocked by the 5-HT2A antagonist LY53857. A possible role for 5-HT, as a physiological enhancer of the timing of motor function of the olivocerebellar system, is discussed

What is the role of the cerebellum in motor coordination? Such coordination depends upon the integrity of the inferior olive, a major cerebellar afferent, as its lesion produces ataxic and dysmetric movement abnormalities. Using multiple-microelectrode recordings, we report here that there are domains of Purkinje cell activity that are generated by olivary input during skilled tongue movements in rats. Such activity domains are highly rhythmic and time-locked to movement. Patterns of synchronous olivocerebellar activity are geometrically complex and can change during a sequence of movements. The results support the view that the inferior olive organizes movement in time, by entraining motor-neuronal firing through rhythmic activation of the cerebellum, and in space, by synchronously activating cell ensembles that allow the use of individual muscles. Dynamic repatterning of olivocerebellar synchrony may allow different combinations of muscles to be used for movements intended to have varying spatial structures

Presynaptic injection of inositol 1,3,4,5-tetraphosphate, inositol 1,3,4,5,6-pentakisphosphate, or inositol 1,2,3,4,5,6-hexakisphosphate--which we denote here the inositol high-polyphosphate series (IHPS)--is shown to block synaptic transmission when injected into the preterminal of the squid giant synapse. This effect is not produced by injection of inositol 1,4,5-trisphosphate. The synaptic block is characterized by a time course in the order of 15-45 min, depending on the injection site in the preterminal fiber; the fastest block occurs when the injection is made at the terminal release site. Presynaptic voltage clamp during transmitter release demonstrates that IHPS block did not modify the presynaptic inward, calcium current. Analysis of synaptic noise at the postsynaptic axon shows that both the evoked and spontaneous transmitter release are blocked by the IHPS. Tetanic stimulation of the presynaptic fiber at frequencies of 100 Hz indicates that block is accompanied by gradual reduction of the postsynaptic response, demonstrating that the block interferes with vesicular fusion rather than with vesicular docking. These results, in combination with the recently demonstrated observation that the IHPS bind the C2B domain in synaptotagmin [Fukada, M., Aruga, J., Niinobe, M., Aimoto, S. & Mikoshiba, K. (1994) J. Biol. Chem. 269, 29206-29211], suggest that IHPS elements are involved in vesicle fusion and exocytosis. In addition, a scheme is proposed in which synaptotagmin triggers transmitter release directly by promoting the fusion of synaptic vesicles with the presynaptic plasmalemma, in agreement with the very rapid nature of transmitter release in chemical synapses

Localized elevation of intracellular free calcium [Ca2+]i concentration serves as the trigger for a wide variety of physiological processes, e.g., neurotransmitter release at most chemical synapses (1-3). The details of the mechanisms that regulate these processes are still unresolved (3-6), but they must involve precise temporal sequences of molecular events initiated by a transient localized elevation of Ca2+ concentration (i.e., a Ca2+ microdomain [3,7-15]). A microdomain is defined as an autonomous compartment of minimal spatio-temporal volume within which a signaled process can occur (8, 10, 12). A quantum emission domain (QED) is a quantal signal element (3, 16, 17). The concept of a QED was first applied to Ca2+ signaling at the synaptic preterminal (3, 4) and for large-diameter mitotic cells (16, 17). The concept of Ca2+ microdomains was tested by labeling preterminals of squid giant synapses with low-sensitivity aequorin (a photoprotein that emits a photon upon binding Ca2+ [18, 19]). That work confirmed earlier modeling efforts (10, 16) and showed that, upon depolarization, the [Ca2+]i profile reaches 200-300 microM within the microdomains, and that these [Ca2+]i profiles are composed of groups of short-lived 0.5 microns diameter QEDs. In those records, obtained with 2:1 interlacing devices operating at the RS-170 standard, QEDs appeared as striped dots or chevrons rather than as solid dots, indicating that a QED lasted less than 16.6 ms (one video field), and thus establishing the need for higher sampling rates to better characterize the QED.(ABSTRACT TRUNCATED AT 250 WORDS)

Transmitter release is considered to be a secretory event triggered by localized calcium influx which, by binding to a low-affinity Ca2+ site at the presynaptic active zone, initiates vesicular exocytosis (1-7). In previous experiments with aequorin-loaded presynaptic terminals we visualized, upon tetanic presynaptic stimulation, small points of light produced by calcium concentration microdomains of about 300 microM (5). These microdomains had a diameter of about 0.5 microns (5) and covered 5-10% of the total presynaptic membrane with an average density of 8.4 microns2 per 100 microns2, corresponding closely to the size and distribution of the active zones in that junction (6, 7). To understand in more detail the nature of these concentration microdomains, we obtained rapid video images (400/s) after injecting the photoprotein n-aequorin-J into the presynaptic terminals of squid giant synapses. Using that experimental approach, we determined that microdomains evoked by presynaptic spike activation had a duration of about 800 microseconds. Spontaneous quantum emission domains (QEDs) observed at about the same locations as the microdomains were smaller in amplitude, shorter in duration, and less frequent. These results illustrate the time course of the calcium concentration profiles responsible for transmitter release. Their extremely short duration compares closely with that of calcium current flow during a presynaptic action potential and indicates that, as theorized in the past (6-8), intracellular calcium concentration at the active zone remains high only for the duration of transmembrane calcium flow

1. The issue of isochronicity of olivocerebellar fibre conduction time as a basis for synchronizing complex spike activity in cerebellar Purkinje cells has been addressed by latency measurement, multiple-electrode recording and Phaseolus vulgaris leucoagglutinin (PHA-L) tracing of climbing fibres in the adult rat. 2. The conduction time of the olivocerebellar fibres was measured by recording Purkinje cell complex spike (CS) responses from various areas of the cerebellum. The CSs were evoked by stimulating the olivocerebellar fibres near the inferior olive. In spite of a difference in length, as determined directly by light microscopy, the conduction times of different climbing fibres were quite uniform, 3.98 +/- 0.36 ms (mean +/- S.D., n = 660). 3. Multiple-electrode recording of spontaneous Purkinje cell CS activity was employed to study the spatial extent of CS synchronicity in the cerebellar cortex. Recordings of CS were obtained from Purkinje cells located on the surface and along the walls of lobule crus 2a. The rostrocaudal band-like distribution of simultaneous (within 1 ms) CS activity in Purkinje cells extended down the sides of the cerebellar folia to the deepest areas recorded (1.6-2.6 mm deep). As shown in previous experiments, the distribution of simultaneous CS activity did not extend significantly (500 microns) in the mediolateral axis of the cerebellar cortex. 4. In two animals a detailed determination of the length of the olivocerebellar fibre bundles was performed by staining the fibres with PHA-L injected into the contralateral inferior olive. This measurement included fibre bundles terminating in twenty-six different areas, ranging from the tops of the various folia to the bottoms of the fissures in both the hemisphere and the vermis. There was a 47.5% difference between the length of the longest measured fibre bundle (15.8 mm, terminating in lobule 6b, zone A) and the length of the shortest measured fibre bundle (8.3 mm, terminating in the cortex at the base of the primary fissure, zone D), after correction for tissue shrinkage. To attain an isochronous conduction time the conduction velocities for these two fibre bundles were calculated to be 4.22 m/s and 2.37 m/s, respectively. 5. By interpolating between measured points a simple formula was derived to estimate the average length of olivocerebellar fibres terminating in any given area of the cerebellar cortex, excluding the paraflocculus, the flocculus and the most lateral regions of the hemisphere. 6. We investigated the most likely mechanisms by which conduction velocity variations with length could result in global isochronicity.(ABSTRACT TRUNCATED AT 400 WORDS)