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Query: UMLS:C0153640 (
Cerebellum
)
1,777
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Inferior olivary neurons receive extensive glutamatergic and GABAergic innervation. Yet, because of the membrane properties of olivary neurons these neurotransmitters can produce only small changes in the firing rates of these cells. Moreover, olivary neurons can generate spontaneous spike activity in the absence of excitatory glutamatergic input. These facts suggest that glutamate and GABA have additional roles within the olivocerebellar system beyond simply modulating single cell firing probability. Indeed, one of the characteristics of the olivocerebellar system is its ability to generate synchronous complex spike activity across populations of Purkinje cells. The pattern of synchronous activity changes rapidly, and is thought to reflect the momentary distribution of effective electrotonic coupling between olivary neurons as shaped by afferent input to the inferior olive. However, it also possible that synchronous olivocerebellar activity is the result of synchrony inherent in the afferent activity itself. The issue of the origin of complex spike synchrony, and the role of glutamatergic olivary afferents in modulating its distribution were recently studied using multiple electrode recordings from Purkinje cells. The results of these studies, reviewed here, demonstrate that synchronous complex spike activity occurs in the absence of glutamatergic (and GABAergic) input to the inferior olive, and therefore indicate that synchronization of complex spike activity primarily results from the electrotonic coupling of olivary neurons, rather than from synchronization present within their afferents. Instead of triggering synchronous discharges directly, the results suggest that the function of tonic excitatory activity is to modulate the effective coupling of spike activity between olivary neurons.
Blocking
glutamate within the inferior olive causes an enhancement of the normal banding pattern of complex spike synchrony, with higher synchrony among parasagittally aligned Purkinje cells and less synchrony between non-aligned cells. This is in contrast to the more uniform synchrony distribution that follows block of GABAergic olivary afferents. Thus, GABA and glutamate play critical, and complementary, roles in determining the patterns of synchronous complex spike activity that are likely central to the functioning of the olivocerebellar system.
Cerebellum
2003
PMID:Excitatory afferent modulation of complex spike synchrony. 1450 65
Flavoprotein autofluorescence imaging, an intrinsic mitochondrial signal, has proven useful for monitoring neuronal activity. In the cerebellar cortex, parallel fiber stimulation evokes a beam-like response consisting of an initial, short-duration increase in fluorescence (on-beam light phase) followed by a longer duration decrease (on-beam dark phase). Also evoked are parasagittal bands of decreased fluorescence due to molecular layer inhibition. Previous work suggests that the on-beam light phase is due to oxidative metabolism in neurons. The present study further investigated the metabolic and cellular origins of the flavoprotein signal in vivo, testing the hypotheses that the dark phase is mediated by glia activation and the inhibitory bands reflect decreased flavoprotein oxidation and increased glycolysis in neurons.
Blocking
postsynaptic ionotropic and metabotropic glutamate receptors abolished the on-beam light phase and the parasagittal bands without altering the on-beam dark phase. Adding glutamate transporter blockers reduced the dark phase. Replacing glucose with lactate (or pyruvate) or adding lactate to the bathing media abolished the on-beam dark phase and reduced the inhibitory bands without affecting the light phase.
Blocking
monocarboxylate transporters eliminated the on-beam dark phase and increased the light phase. These results confirm that the on-beam light phase is due primarily to increased oxidative metabolism in neurons. They also show that the on-beam dark phase involves activation of glycolysis in glia resulting in the generation of lactate that is transferred to neurons. Oxidative savings in neurons contributes to the decrease in fluorescence characterizing the inhibitory bands. These findings provide strong in vivo support for the astrocyte-neuron lactate shuttle hypothesis.
Cerebellum
2011 Sep
PMID:Cellular and metabolic origins of flavoprotein autofluorescence in the cerebellar cortex in vivo. 2150 91
