Compressed sensing based approach identifies modular neural circuitry driving learned pathogen avoidance.

An animal's survival hinges on its ability to integrate past information to modify future behavior. The nematode adapts its behavior based on prior experiences with pathogen exposure, transitioning from attraction to avoidance of the pathogen. A systematic screen for the neural circuits that integrate the information of previous pathogen exposure to modify behavior has not been feasible because of the lack of tools for neuron type specific perturbations.

Chemosensory detection of polyamine metabolites guides to nutritive microbes.

Much is known about molecular mechanisms by which animals detect pathogenic microbes, but how animals sense beneficial microbes remains poorly understood. The roundworm is a microbivore that must distinguish nutritive microbes from pathogens. We characterized a neural circuit used by to rapidly discriminate between nutritive bacteria and pathogens.

SAMPL is a high-throughput solution to study unconstrained vertical behavior in small animals.

Balance and movement are impaired in many neurological disorders. Recent advances in behavioral monitoring provide unprecedented access to posture and locomotor kinematics but without the throughput and scalability necessary to screen candidate genes/potential therapeutics. Here, we present a scalable apparatus to measure posture and locomotion (SAMPL).

High-fidelity encoding of mechanostimuli by tactile food-sensing neurons requires an ensemble of ion channels.

The nematode C. elegans uses mechanosensitive neurons to detect bacteria, which are food for worms. These neurons release dopamine to suppress foraging and promote dwelling.

Scalable Apparatus to Measure Posture and Locomotion (SAMPL): a high-throughput solution to study unconstrained vertical behavior in small animals.

Balance and movement are impaired in a wide variety of neurological disorders. Recent advances in behavioral monitoring provide unprecedented access to posture and locomotor kinematics, but without the throughput and scalability necessary to screen candidate genes / potential therapeutics. We present a powerful solution: a Scalable Apparatus to Measure Posture and Locomotion (SAMPL).