V3 Interneurons Are Active and Recruit Spinal Motor Neurons during In Vivo Fictive Swimming in Larval Zebrafish.

Survival for vertebrate animals is dependent on the ability to successfully find food, locate a mate, and avoid predation. Each of these behaviors requires motor control, which is set by a combination of kinematic properties. For example, the frequency and amplitude of motor output combine in a multiplicative manner to determine features of locomotion such as distance traveled, speed, force (thrust), and vigor. Although there is a good understanding of how different populations of excitatory spinal interneurons establish locomotor frequency, there is a less thorough mechanistic understanding for how locomotor amplitude is established. Recent evidence indicates that locomotor amplitude is regulated in part by a subset of functionally and morphologically distinct V2a excitatory spinal interneurons (Type II, nonbursting) in larval and adult zebrafish. Here, we provide direct evidence that most V3 interneurons (V3-INs), which are a developmentally and genetically defined population of ventromedial glutamatergic spinal neurons, are active during fictive swimming. We also show that elimination of the spinal V3-IN population reduces the proportion of active motor neurons (MNs) during fictive swimming but does not alter the range of locomotor frequencies produced. These data are consistent with V3-INs providing excitatory drive to spinal MNs during swimming in larval zebrafish and may contribute to the production of locomotor amplitude independently of locomotor frequency.

Epigenomically Bistable Regions across Neuron-Specific Genes Govern Neuron Eligibility to a Coding Ensemble in the Hippocampus.

Sensory inputs activate sparse neuronal ensembles in the dentate gyrus of the hippocampus, but how eligibility of individual neurons to recruitment is determined remains elusive. We identify thousands of largely bistable (CpG methylated or unmethylated) regions within neuronal gene bodies, established during mouse dentate gyrus development. Reducing DNA methylation and the proportion of the methylated epialleles at bistable regions compromises novel context-induced neuronal activation. Conversely, increasing methylation and the frequency of the methylated epialleles at bistable regions enhances intrinsic excitability. Single-nucleus profiling reveals enrichment of specific epialleles related to a subset of primarily exonic, bistable regions in activated neurons. Genes displaying both differential methylation and expression in activated neurons define a network of proteins regulating neuronal excitability and structural plasticity. We propose a model in which bistable regions create neuron heterogeneity and constellations of exonic methylation, which may contribute to cell-specific gene expression, excitability, and eligibility to a coding ensemble.

Evaluating the predictive value of doublecortin as a marker for adult neurogenesis in canaries (Serinus canaria).

Doublecortin (DCX) is an important microtubule-associated protein involved in the migration of young neurons into the cortical layers of the brain during early human development. The continued expression of DCX in brain areas with protracted neuron recruitment has promoted this endogenous protein as a popular indirect tool to monitor adult neurogenesis in a variety of species. However, little is known about its possible involvement in other cellular processes and a thorough validation of DCX as a quantitative measure for neurogenesis is generally lacking. Here we investigated the relationship between DCX expression and neuron recruitment in the brains of adult canaries (Serinus canaria), a species well-known for its adult neurogenesis. We examined the age and functional state of DCX-labeled cells by using mitotic and neuron-specific markers, retrograde tracings, and immediate early gene colocalizations. Although DCX expression was high in brain areas implicated in adult neurogenesis, DCX-expressing neurons were also abundant in regions that do not recruit new neurons. Moreover, DCX expression was observed in adult, active neurons, differentiated projection neurons, and birth-dated neurons of up to 1 year of age. Season and testosterone treatment affected DCX expression in two song control nuclei, HVC and Area X, but did not correlate with known patterns of neuron recruitment. Together, these results demonstrate that DCX expression is not exclusive to young migrating neurons, and does not predict neuron recruitment equally throughout the canary brain. Therefore, DCX labeling needs careful validation for each brain region separately in each species analyzed when used to quantify adult neurogenesis.