From lamprey to monkeys, the organization of the descending control of locomotion is conserved across vertebrates. Reticulospinal neurons (RSNs) form a bottleneck for descending commands, receiving innervation from diencephalic and mesencephalic locomotor centers and providing locomotor drive to spinal motor circuits. Given their optical accessibility in early development, larval zebrafish offer a unique opportunity to study reticulospinal circuitry. In fish, RSNs are few, highly stereotyped, uniquely identifiable, large neurons spanning from the midbrain to the medulla. Classically labeled by tracer dye injections into the spinal cord, recent advances in genetic tools have facilitated the targeted expression of transgenes in diverse brainstem neurons of larval zebrafish. Here, we provide a comparative characterization of four existing and three newly established transgenic lines in larval zebrafish. We determine which identified neurons are consistently labeled and offer projection-specific genetic access...

Recording the spiking activity from subcellular compartments of neurons such as axons and dendrites during mouse behavior with 2-photon calcium imaging is increasingly common yet remains challenging due to low signal-to-noise, inaccurate region-of-interest (ROI) identification, movement artifacts, and difficulty in grouping ROIs from the same neuron. To address these issues, we present a computationally efficient preprocessing pipeline for subcellular signal detection, movement artifact identification, and ROI grouping. For subcellular signal detection, we capture the frequency profile of calcium transient dynamics by applying fast Fourier transform (FFT) on smoothed time-series calcium traces collected from axon ROIs. We then apply bandpass filtering methods (e.g., 0.05–0.12 Hz) to select ROIs that contain frequencies that match the power band of transients. To remove motion artifacts from z -plane movement, we apply principal component analysis on all calcium traces and use a bottom-up segmentation chang...

The medial prefrontal cortex (mPFC) is thought to play a central role in human social perception, cognition, and behavior. In adults, the mPFC is involved in representing and interpreting the mental states in self and others. Developmental research using neuroimaging techniques like functional near-infrared spectroscopy and functional magnetic resonance imaging has begun to extend these findings into infancy. Novel evidence reviewed in this opinion demonstrates that infant mPFC (1) plays a specialized, proactive, and evaluative role in social perception, (2) is involved in connecting with other minds while interacting and when watching other minds interact, and (3) predicts overt social behavior beyond infancy. These findings suggest that, from early in human ontogeny, the mPFC plays a multifaceted role in social perception, cognition, and behavior.

The most important skill a scientist needs, after the skills needed to execute a study, is the ability to report his or her scientific endeavors in writing. The editors-in-chief of four international neuroscience journals — Brain and Behavior, the European Journal of Neuroscience, the Journal of Neuroscience Research, and Neuroscience, the journal of the International Brain Research Organization — come together in this workshop to offer insight into what editors look for, what their roles are, and what you can to do to make your paper stand out. Watch the recording to learn more about the review process, including why peer review is important, what’s essential to include in your paper, and how to be ethical and ensure reproducibility in your experiments.

Learn how to make yourself a stronger job candidate, consider career paths you may not have thought of, connect with like-minded scientists, and find work-life balance. In this interview, Samantha Baglot, a PhD student at the University of Calgary, in Canada, shares how she’s pursuing her passion for improving education through neuroscience outreach and project management. What made you want to start doing outreach, and how did you get involved? When I started my master's degree about three years ago, I joined the Neuroscience Graduate Student Association at The University of British Columbia. I was interested in what their vice president of outreach was doing. At the time, she was organizing Vancouver's Brain Bee and Brain Awareness Week events, as well as collaborative events with artists and other communities on campus. I worked with her. Then an opportunity came up for a project where we look at the history of neuroscience through cartoons, and I took the lead on that. I do a lot of delegating, organizing, and recruiting volunteers.

Live imaging of neuronal populations often reveals a background signal that engulfs the signal from individual neurons. Typically, this background signal is dismissed as uninformative or as an epiphenomenon. We imaged in freely moving mice acetylcholine-releasing (cholinergic) interneurons in the striatum that play a critical role in basal ganglia function and dysfunction in movement disorders. Importantly, these interneurons give rise to a profusely dense neuropil of fine neuronal processes that fill the striatum. Under these circumstances, our analysis revealed the background signal arising from the neuropil represents a “mean-field” readout of the collective recurrent activity of cholinergic interneurons. Thus, the neuropil signal functions as a physiological readout of the network state. For over half a century, clinicians and scientists have known a disruption of the so-called balance between acetylcholine and dopamine released in the region of the brain called the striatum is a central pathological correlate of various movement disorders such as Parkinson’s disease and Huntington’s disease. This imbalance was deduced from biochemical and histological studies of the striatum. However, evidence for such an imbalance in the physiological activity of brain circuits has been lacking.

Developing strategic research and personal connections — a global network — can help you navigate career transitions and challenges and be successful in your career. In this workshop from Neuroscience 2018, a panel of researchers with experience living and working away from their home countries offered advice for building these culturally based support systems, centered around the four themes below. Read on for highlights and advice, and watch the recording to listen in on this interactive panel discussion.

In the mouse, no complete innate behavioral circuit has been defined, and mechanistic understanding of the neurons that drive behavior remains largely unknown. Lisa Stowers was one of the first postdocs to work with Howard Hughes Medical Institute investigator Catherine Dulac on decoding the mouse olfactory system. In this Meet-the-Expert, she delves into why, 20 years after they began, there’s work left to do, and why innate behavior is not so easy to study as advertised. By watching you’ll gain an understanding of the means and metrics of analysis, assumptions of circuit coding, and interpretations of the effects of viral and optogenetic manipulations, contributing to a greater overall understanding of the coding of innate behavior.

Arianna Maffei is an associate professor at Stony Brook University, where she has led an independent research program since 2008. In this interview, she answers some of postdocs’ most common questions at the start of their careers, on topics including finding mentors, applying and interviewing for jobs, and starting a lab.

Open communication can help scientists and institutions increase public support for animal research by improving public trust, understanding of the necessity of animal research, and perception of how animal studies are conducted. In this recording of the Animals in Research Panel from Neuroscience 2018, learn effective ways to communicate openly and start positive conversations about animal research. Panelists will share strategies all scientists can use to increase public support in their local communities.