Plasticity in the cerebellum: What molecular mechanisms are behind physiological learning
Alcarva C. 2023. Plasticity in the cerebellum: What molecular mechanisms are behind physiological learning. Institute of Science and Technology Austria.
Download
Thesis_CatarinaAlcarva_final pdfA.pdf
9.88 MB
[Published Version]
Thesis
| PhD
| Published
| English
Author
Supervisor
Department
Series Title
ISTA Thesis
Abstract
Understanding the mechanisms of learning and memory formation has always been one of
the main goals in neuroscience. Already Pavlov (1927) in his early days has used his classic
conditioning experiments to study the neural mechanisms governing behavioral adaptation.
What was not known back then was that the part of the brain that is largely responsible for
this type of associative learning is the cerebellum.
Since then, plenty of theories on cerebellar learning have emerged. Despite their differences,
one thing they all have in common is that learning relies on synaptic and intrinsic plasticity.
The goal of my PhD project was to unravel the molecular mechanisms underlying synaptic
plasticity in two synapses that have been shown to be implicated in motor learning, in an
effort to understand how learning and memory formation are processed in the cerebellum.
One of the earliest and most well-known cerebellar theories postulates that motor learning
largely depends on long-term depression at the parallel fiber-Purkinje cell (PC-PC) synapse.
However, the discovery of other types of plasticity in the cerebellar circuitry, like long-term
potentiation (LTP) at the PC-PC synapse, potentiation of molecular layer interneurons (MLIs),
and plasticity transfer from the cortex to the cerebellar/ vestibular nuclei has increased the
popularity of the idea that multiple sites of plasticity might be involved in learning.
Still a lot remains unknown about the molecular mechanisms responsible for these types of
plasticity and whether they occur during physiological learning.
In the first part of this thesis we have analyzed the variation and nanodistribution of voltagegated calcium channels (VGCCs) and α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid
type glutamate receptors (AMPARs) on the parallel fiber-Purkinje cell synapse after vestibuloocular reflex phase reversal adaptation, a behavior that has been suggested to rely on PF-PC
LTP. We have found that on the last day of adaptation there is no learning trace in form of
VGCCs nor AMPARs variation at the PF-PC synapse, but instead a decrease in the number of
PF-PC synapses. These data seem to support the view that learning is only stored in the
cerebellar cortex in an initial learning phase, being transferred later to the vestibular nuclei.
Next, we have studied the role of MLIs in motor learning using a relatively simple and well characterized behavioral paradigm – horizontal optokinetic reflex (HOKR) adaptation. We
have found behavior-induced MLI potentiation in form of release probability increase that
could be explained by the increase of VGCCs at the presynaptic side. Our results strengthen
the idea of distributed cerebellar plasticity contributing to learning and provide a novel
mechanism for release probability increase.
Publishing Year
Date Published
2023-04-06
Publisher
Institute of Science and Technology Austria
Acknowledged SSUs
Page
115
ISSN
IST-REx-ID
Cite this
Alcarva C. Plasticity in the cerebellum: What molecular mechanisms are behind physiological learning. 2023. doi:10.15479/at:ista:12809
Alcarva, C. (2023). Plasticity in the cerebellum: What molecular mechanisms are behind physiological learning. Institute of Science and Technology Austria. https://doi.org/10.15479/at:ista:12809
Alcarva, Catarina. “Plasticity in the Cerebellum: What Molecular Mechanisms Are behind Physiological Learning.” Institute of Science and Technology Austria, 2023. https://doi.org/10.15479/at:ista:12809.
C. Alcarva, “Plasticity in the cerebellum: What molecular mechanisms are behind physiological learning,” Institute of Science and Technology Austria, 2023.
Alcarva C. 2023. Plasticity in the cerebellum: What molecular mechanisms are behind physiological learning. Institute of Science and Technology Austria.
Alcarva, Catarina. Plasticity in the Cerebellum: What Molecular Mechanisms Are behind Physiological Learning. Institute of Science and Technology Austria, 2023, doi:10.15479/at:ista:12809.
Main File(s)
File Name
Thesis_CatarinaAlcarva_final pdfA.pdf
9.88 MB
Access Level
Closed Access
Date Uploaded
2023-04-07
Embargo End Date
2024-04-07
MD5 Checksum
35b5997d2b0acb461f9d33d073da0df5
Source File
File Name
Access Level
Closed Access
Date Uploaded
2023-04-07
MD5 Checksum
81198f63c294890f6d58e8b29782efdc
Source File
File Name
Thesis_CatarinaAlcarva_final.docx
84.73 MB
Access Level
Closed Access
Date Uploaded
2023-04-07
MD5 Checksum
0317bf7f457bb585f99d453ffa69eb53