Research output: Contribution to journal › Article › peer-review
Cortical gamma rhythm is involved in transmission of information (communication) between brain areas that are believed to be involved in the pathogenesis of cognitive dysfunctions. Trace amines represent a group of endogenous biogenic amines that are known to be involved in modulation of function of classical monoamines, such as dopamine. To evaluate potential modulatory influence of a specific receptor for trace amines Trace Amine-Associated Receptor 5 (TAAR5) on the dopamine system, we used HPLC measurements of dopamine and its metabolites in the mouse striatum following administration of the putative TAAR5 agonist α-NETA. Administration of α-NETA caused significant modulation of dopaminergic system as evidenced by an altered dopamine turnover rate in the striatum. Then, to evaluate potential modulatory influence of TAAR5 on the rat brain gamma rhythm, we investigated the changes of electrocorticogram (ECoG) spectral power in the gamma-frequency range (40–50 Hz) following administration of the putative TAAR5 agonist α-NETA. In addition, we analyzed the changes of spatial synchronization of gamma oscillations of rat ECoG by multichannel recording. Significant complex changes were observed in the ECoG spectrum, including an increase in the spectral power in the ranges of delta (1 Hz), theta (7 Hz), and gamma rhythms (40–50 Hz) after the introduction of α-NETA. Furthermore, a decrease in the spatial synchronization of gamma oscillations of 40-50 Hz and its increase for theta oscillations of 7 Hz were detected after the introduction of α-NETA. In conclusion, putative TAAR5 agonist α-NETA can modulate striatal dopamine transmission and cause significant alterations of gamma rhythm of brain activity in a manner consistent with schizophrenia-related deficits described in humans and experimental animals. These observations suggest a role of TAAR5 in the modulation of cognitive functions affected in brain pathologies.
Original language | English |
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Journal | Cellular and Molecular Neurobiology |
DOIs | |
State | Published - 2019 |
ID: 49222913