Influence of Nanomolar Deltamethrin on the Hallmarks of Primary Cultured Cortical Neuronal Network and the Role of Ryanodine Receptors.

Abstract

Background:The pyrethroid deltamethrin (DM) is broadly used for insect control. Although DM hyperexcites neuronal networks by delaying inactivation of axonal voltage-dependent channels, this mechanism is unlikely to mediate neurotoxicity at lower exposure levels during critical perinatal periods in mammals.Objectives:We aimed to identify mechanisms by which acute and subchronic DM altered axonal and dendritic growth, patterns of synchronous oscillations (SCOs), and electrical spike activity (ESA) functions critical to neuronal network formation.Methods:Measurements of SCOs using imaging, ESA using microelectrode array (MEA) technology, and dendritic complexity using Sholl analysis were performed in primary murine cortical neurons from wild-type (WT) and/or ryanodine receptor 1 () mice between 5 and 14 d in vitro (DIV). binding analysis and a single-channel voltage clamp were utilized to measure engagement of RyRs as a direct target of DM.Results:Neuronal networks responded to DM () as early as 5 DIV, reducing SCO amplitude and depressing ESA and burst frequencies by 60–70%. DM () enhanced axonal growth in a nonmonotonic manner. enhanced dendritic complexity. DM stabilized channel open states of RyR1, RyR2, and cortical preparations expressing all three isoforms. DM () altered gating kinetics of RyR1 channels, increasing mean open time, decreasing mean closed time, and thereby enhancing overall open probability. SCO patterns from cortical networks expressing were more responsive to DM than WT. neurons showed inherently longer axonal lengths than WT neurons and maintained less length-promoting responses to nanomolar DM.Conclusions:Our findings suggested that RyRs were sensitive molecular targets of DM with functional consequences likely relevant for mediating abnormal neuronal network connectivity in vitro. https://doi.org/10.1289/EHP4583