Abstract
Schizophrenia shows high heritability and several of the genes associated with this disorder are involved in calcium (Ca2+) signalling and synaptic function. One of these is the Rab-3 interacting molecule-1 (RIM1), which has recently been associated with schizophrenia by Genome Wide Association Studies (GWAS). However, its contribution to the pathophysiology of this disorder remains unexplored. In this work, we use Drosophila mutants of the orthologue of RIM1, Rim, to model some aspects of the classical and non-classical symptoms of schizophrenia. Rim mutants showed several behavioural features relevant to schizophrenia including social distancing and altered olfactory processing. These defects were accompanied by reduced evoked Ca2+ influx and structural changes in the presynaptic terminals sent by the primary olfactory neurons to higher processing centres. In contrast, expression of Rim-RNAi in the mushroom bodies (MBs), the main memory centre in flies, spared learning and memory suggesting a differential role of Rim in different synapses. Circadian deficits have been reported in schizophrenia. We observed circadian locomotor activity deficits in Rim mutants, revealing a role of Rim in the pacemaker ventral lateral clock neurons (LNvs). These changes were accompanied by impaired day/night remodelling of dorsal terminal synapses from a subpopulation of LNvs and impaired day/night release of the circadian neuropeptide pigment dispersing factor (PDF) from these terminals. Lastly, treatment with the commonly used antipsychotic haloperidol rescued Rim locomotor deficits to wildtype. This work characterises the role of Rim in synaptic functions underlying behaviours disrupted in schizophrenia.
Original language | English |
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Article number | 292 |
Pages (from-to) | 17 |
Journal | Translational Psychiatry |
Volume | 11 |
Issue number | 1 |
Early online date | 17 May 2021 |
DOIs | |
Publication status | Published - 17 May 2021 |
Bibliographical note
Funding Information:The authors would like to thank Dr. Anne Simon (The University of Western Ontario, Canada) for help setting up the social space paradigm. We thank Drs. Scott Waddell, Ralf Stanewsky, Herman Wijnen and the Bloomington Drosophila Stock Center for sharing flies. We thank Drs. Valentina Zavala and Edgar Buhl for providing comments on the manuscript and acknowledge the Wolfson Bioimaging facilities at University of Bristol. This work was supported by PUC-VRI Puente Grants No. P-1805 to J.M.C. S.H. was supported by CONICYT-PCHA/Doctorado Nacional/2016-21161611 (Chile) and J.J.L.H. by a Leverhulme Trust grant (RPG-2016-318).
Publisher Copyright:
© 2021, The Author(s).