miR-124-dependent tagging of synapses by synaptopodin enables input-specific homeostatic plasticity.

Homeostatic synaptic plasticity is a process by which neurons adjust their synaptic strength to compensate for perturbations in neuronal activity. Whether the highly diverse synapses on a neuron respond uniformly to the same perturbation remains unclear. Moreover, the molecular determinants that underlie synapse-specific homeostatic synaptic plasticity are unknown.

Microdosing psychedelics: More questions than answers? An overview and suggestions for future research.

Background: In the past few years, the issue of 'microdosing' psychedelics has been openly discussed in the public arena where claims have been made about their positive effect on mood state and cognitive processes such as concentration. However, there are very few scientific studies that have specifically addressed this issue, and there is no agreed scientific consensus on what microdosing is.

Aim: This critique paper is designed to address questions that need to be answered by future scientific studies and to offer guidelines for these studies.

Small RNA-Seq reveals novel miRNAs shaping the transcriptomic identity of rat brain structures.

In the central nervous system (CNS), miRNAs are involved in key functions, such as neurogenesis and synaptic plasticity. Moreover, they are essential to define specific transcriptomes in tissues and cells. However, few studies were performed to determine the miRNome of the different structures of the rat CNS, although a major model in neuroscience.

Oxaliplatin treatment impairs extension of sensory neuron neurites in vitro through miR-204 overexpression.

Oxaliplatin is a platinum-based drug used in the treatment of gastric cancers. Oxaliplatin treatment induces sensory neuropathy characterized by cold hypersensibility in the acute phase and sensory impairment when the neuropathy becomes chronic. In order to determine the effect of oxaliplatin on sensory neurons, we used an in vitro model in which oxaliplatin treatment reduced arborization of dorsal root ganglia neurons in a dose-dependent manner.

miR-92a regulates expression of synaptic GluA1-containing AMPA receptors during homeostatic scaling.

We investigated whether microRNAs could regulate AMPA receptor expression during activity blockade. miR-92a strongly repressed the translation of GluA1 receptors by binding the 3' untranslated region of rat GluA1 (also known as Gria1) mRNA and was downregulated in rat hippocampal neurons after treatment with tetrodotoxin and AP5. Deleting the seed region in GluA1 or overexpressing miR-92a blocked homeostatic scaling, indicating that miR-92a regulates the translation and synaptic incorporation of new GluA1-containing AMPA receptors.