Must-Read Circuit Neuroscience of 2020: Vol. I
We're two months into 2020 and our beloved circuit neuroscience community has already served up so many treats that we're wondering if it's still the holidays! We're excited to share with you our collection of top reads of 2020 thus far. You'll find that each of them informs on fundamental biological functions and provided novel insights into neural circuitry. Happy reading!
1. All hands on deck for motor learning!
Cortical synaptic AMPA receptor plasticity during motor learning by Richard H. Roth, Robert H. Cudmore, Han L. Tan, Ingie Hong, Yong Zhang, Richard L. Huganir. Neuron.
Sure, there are parts of the brain super specialized to perform certain functions. But this study shows that for a certain motor learning function at least, multiple brain areas including non-motor function regions are involved. Using in vivo two-photon microscopy during a forelimb reaching task (for food), Roth et al. examined mouse cortical AMPA receptor (AMPARs) activity. They found increased activity in not just the motor cortex, but in the visual cortex too, suggesting that multiple sensory cues are involved in successful motor learning.
2. Extinguishing fear is the reward.
Amygdala Reward Neurons Form and Store Fear Extinction Memory by Xiangyu Zhang, Joshua Kim, Susumu Tonegawa. Neuron.
During fear extinction training, mice can overcome fear memory-induced behavior by what is thought to be suppression of the fear memory with the formation of new memories. Zhang et al. present an elegant demonstration of how this happens, using the nVistaᵀᴹ miniscope. Briefly, a specific subset of posterior basolateral amygdala (pBLA) neurons expressing Ppp1r1b drive positive reward memories that override the negative valence associated with the original fear memories via Rspo2-expressing neuronal activity. The authors hope that identification of the specific neuronal subpopulation responsible for fear extinction can help treat fear disorders like PTSD and anxiety.
3. Hypothetical thinking, explained.
4. Does this newly identified neural activity make humans... humans?