The challenge of the BRAIN Initiative and the European Human Brain Project is to determine how the billions of neurons and trillions of synapses in the human brain organize themselves into neural circuits that enable brain function. Yet the anatomical organization of neural circuits is not sufficient to understand information processing, since it is well known that neuromodulators that act outside of synapses can reconfigure patterns of neural activation by recruiting or rejecting the involvement of specific circuit components. Dynamically changing the spatial pattern of neural activation may be particularly important in the cerebellar cortex, where the precise spatial-temporal patterns of Purkinje cell (PC) activation are critical for the complex sensory-integration function of motor control. The pattern of Purkinje cell activation is controlled by olivocerebellar climbing fibers (CFs) that form powerful one-to-one glutamatergic synapses with single PCs. CFs generate a complex spike in postsynaptic PCs as well as a pause in PC simple spiking. However, CFs can also control the excitability of neighboring PCs through the activation of inhibitory interneurons. Surprisingly, CF-interneuron signaling occurs via spillover transmission in the absence of anatomically defined synaptic structures. The goal of this proposal is to determine how glutamate spillover from CFs influences cerebellar circuit function at the level of single cells, small microcircuits and cerebellar compartments. We hypothesize that CF spillover organizes the temporal-spatial pattern of neural activity at each level to expand the influence of CFs beyond the targeted PC. We will use a variety of electrophysiological, imaging and transgenic approaches to test predictions about the role of CF glutamate spillover in the spatial organization of cerebellar circuit activity. Successful completion of the proposed Aims has the potential to dramatically shift the current view of the role of CFs in cerebellar function. The conceptual novelty of this proposal stems from the demonstration that fast extrasynaptic glutamate signaling does not require morphologically-defined synapses and provides a mechanism to mediate patterned of neural activation that is regulated by spatial proximity rather than synaptic connectivity. The significance of the proposed experiments is supported by several in vivo observations suggesting that this unconventional mode of transmission from CFs contributes to the temporal- spatial pattern of PC activity in a manner that is critical for cerebellar function. Cerebellar dysfunction can lead to many human diseases involving motor control, including a family of nearly 40 conditions known as the spinocerebellar ataxias.The cerebellum is also involved in executive functions, spatial learning and memory, and emotion as well as more recently being associated with schizophrenia and autism. A more complete understanding of cerebellar circuit information processing will thus benefit a wide range of basic and clinical fields.

Public Health Relevance

Normal function of the cerebellum relies on appropriate spatial-temporal patterns of neural activity of Purkinje cells, the sole output neurons. The goal of this project is to determine how glutamate spillover from climbing fibers contributes to the spatial-temporal dynamics of Purkinje cell excitability. Completion of this project will provide insight into the mechanisms that control patterned neural activity in the cerebellar circuit as well as how synaptic signaling outside of anatomically defined circuits can contribute to normal brain function.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS065920-07
Application #
8845260
Study Section
Sensorimotor Integration Study Section (SMI)
Program Officer
Talley, Edmund M
Project Start
2009-06-01
Project End
2019-05-31
Budget Start
2015-06-01
Budget End
2016-05-31
Support Year
7
Fiscal Year
2015
Total Cost
$321,563
Indirect Cost
$102,813
Name
University of Alabama Birmingham
Department
Neurosciences
Type
Schools of Medicine
DUNS #
063690705
City
Birmingham
State
AL
Country
United States
Zip Code
35294
Gonzalez, Jose Carlos; Epps, S Alisha; Markwardt, Sean J et al. (2018) Constitutive and Synaptic Activation of GIRK Channels Differentiates Mature and Newborn Dentate Granule Cells. J Neurosci 38:6513-6526
Froula, Jessica M; Henderson, Benjamin W; Gonzalez, Jose Carlos et al. (2018) ?-Synuclein fibril-induced paradoxical structural and functional defects in hippocampal neurons. Acta Neuropathol Commun 6:35
Nietz, Angela K; Vaden, Jada H; Coddington, Luke T et al. (2017) Non-synaptic signaling from cerebellar climbing fibers modulates Golgi cell activity. Elife 6:
Adlaf, Elena W; Vaden, Ryan J; Niver, Anastasia J et al. (2017) Adult-born neurons modify excitatory synaptic transmission to existing neurons. Elife 6:
Erlenhardt, Nadine; Yu, Hong; Abiraman, Kavitha et al. (2016) Porcupine Controls Hippocampal AMPAR Levels, Composition, and Synaptic Transmission. Cell Rep 14:782-794
Dieni, Cristina V; Panichi, Roberto; Aimone, James B et al. (2016) Low excitatory innervation balances high intrinsic excitability of immature dentate neurons. Nat Commun 7:11313
Rudolph, Stephanie; Tsai, Ming-Chi; von Gersdorff, Henrique et al. (2015) The ubiquitous nature of multivesicular release. Trends Neurosci 38:428-38
Coddington, Luke T; Nietz, Angela K; Wadiche, Jacques I (2014) The contribution of extrasynaptic signaling to cerebellar information processing. Cerebellum 13:513-20
Chancey, Jessica H; Poulsen, David J; Wadiche, Jacques I et al. (2014) Hilar mossy cells provide the first glutamatergic synapses to adult-born dentate granule cells. J Neurosci 34:2349-54
Overstreet-Wadiche, Linda; Wadiche, Jacques I (2014) Good housekeeping. Neuron 81:715-7

Showing the most recent 10 out of 15 publications