Juvenile Shank3 KO Mice Adopt Distinct Hunting Strategies during Prey Capture Learning.

Mice are opportunistic omnivores that readily learn to hunt and eat insects such as crickets. The details of how mice learn these behaviors and how these behaviors may differ in strains with altered neuroplasticity are unclear. We quantified the behavior of juvenile wild-type (WT) and Shank3 knock-out (KO) mice as they learned to hunt crickets during the critical period for ocular dominance plasticity. This stage involves heightened cortical plasticity including homeostatic synaptic scaling, which requires Shank3, a glutamatergic synaptic protein that, when mutated, produces Phelan-McDermid syndrome and is often comorbid with autism spectrum disorder (ASD). Both strains showed interest in examining live and dead crickets and learned to hunt. Shank3 knock-out mice took longer to become proficient, and, after 5 d, did not achieve the efficiency of wild-type mice in either time-to-capture or distance-to-capture. Shank3 knock-out mice also exhibited different characteristics when pursuing crickets that could not be explained by a simple motor deficit. Although both genotypes moved at the same average speed when approaching a cricket, Shank3 KO mice paused more often, did not begin final accelerations toward crickets as early, and did not close the distance gap to the cricket as quickly as wild-type mice. These differences in Shank3 KO mice are reminiscent of some behavioral characteristics of individuals with ASD as they perform complex tasks, such as slower action initiation and completion. This paradigm will be useful for exploring the neural circuit mechanisms that underlie these learning and performance differences in monogenic ASD rodent models.

Exploring DNA in biochemistry lab courses: DNA barcoding and phylogenetic analysis.

DNA structure has been leveraged in a variety of facets that allow scientists to perform a range of assays, including ones for identification of species, establishing evolutionary relationships between taxa, or even identifying individuals. Here, we present a DNA barcoding method as practical, hands-on approach that connects several experimental techniques in one sequence to teach the principles behind DNA isolation, purification, PCR, sequencing, and phylogeny analysis. Our set of exercises is designed for a teaching university laboratory setting. The three laboratory class assignments utilize DNA from a mushroom (can be purchased at a supermarket) and provide a pipeline to guide students through the process of identifying an unknown sample, like in many research laboratories. The third assignment can be used as a stand-alone exercise on phylogeny analysis and can be taught remotely. Students explore the theory behind the standard molecular techniques and apply it in a hands-on setting that involves experimental design, sample preparation, and use of hallmark molecular instruments.