Cocaine-induced Plasticity in the Cerebellum of Sensitised Mice

Overview

Journal Psychopharmacology (Berl)

Specialty Pharmacology

Date 2015 Oct 21

PMID 26482898

Citations 17

Authors

Dolores Vazquez-Sanroman

Maria Carbo-Gas

Ketty Leto

Miguel Cerezo-Garcia

Isis Gil-Miravet

Carla Sanchis-Segura

Daniela Carulli

Ferdinando Rossi

Marta Miquel

Affiliations

Soon will be listed here.

Abstract

Rationale: Prior research has accumulated a substantial amount of evidence on the ability of cocaine to produce short- and long-lasting molecular and structural plasticity in the corticostriatal-limbic circuitry. However, traditionally, the cerebellum has not been included in the addiction circuitry, even though growing evidence supports its involvement in the behavioural changes observed after repeated drug experiences.

Objectives: In the present study, we explored the ability of seven cocaine administrations to alter plasticity in the cerebellar vermis.

Methods: After six cocaine injections, one injection every 48 h, mice remained undisturbed for 1 month in their home cages. Following this withdrawal period, they received a new cocaine injection of a lower dose. Locomotion, behavioural stereotypes and several molecular and structural cerebellar parameters were evaluated.

Results: Cerebellar proBDNF and mature BDNF levels were both enhanced by cocaine. The high BDNF expression was associated with dendritic sprouting and increased terminal size in Purkinje neurons. Additionally, we found a reduction in extracellular matrix components that might facilitate the subsequent remodelling of Purkinje-nuclear neuron synapses.

Conclusions: Although speculative, it is possible that these cocaine-dependent cerebellar changes were incubated during withdrawal and manifested by the last drug injection. Importantly, the present findings indicate that cocaine is able to promote plasticity modifications in the cerebellum of sensitised animals similar to those in the basal ganglia.

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