Abstract
The nervous system is organized to detect, internally represent and process sensory information to generate appropriate behaviors. Despite the crucial importance of odors that elicit instinctive behaviors, such as pheromones and kairomones, their neural representation remains little characterized in the mammalian brain. Here we used expression of the immediate early gene product c-Fos as a marker of neuronal activity to find that a wide range of pheromones and kairomones produces activation in the medial nucleus of the amygdala, a brain area anatomically connected with the olfactory sensory organs. We see that activity in this nucleus depends on vomeronasal organ input, and that distinct vomeronasal stimuli activate a dispersed ensemble of cells, without any apparent spatial segregation. This activity pattern does not reflect the chemical category of the stimuli, their valence or the induced behaviors. These findings will help build a complete understanding of how odor information is processed in the brain to generate instinctive behaviors.
Highlights
In mammals, sensory information is detected by specialized sensory cells at the periphery and is sent to the brain, where it must be systematically represented by coherent patterns of neural activity (Luo and Flanagan, 2007)
Chemosignals Detected by the VNO Activate the Medial Nucleus of the Amygdala In order to investigate in detail the patterns of activity in the MeA, we separately exposed C57BL/6 mice to the various intraand interspecies olfactory stimuli listed in Table S1
Representation of Olfactory Information in the Brain In this study, we investigated the activity in the mouse medial amygdala induced by odors that elicit instinctive behaviors important for the survival of the individual and the species
Summary
Sensory information is detected by specialized sensory cells at the periphery and is sent to the brain, where it must be systematically represented by coherent patterns of neural activity (Luo and Flanagan, 2007). Pheromones (released by an individual and detected by the same species) and kairomones (released by an individual and detected by another species) are chemosignals that mediate a range of instinctive behavioral responses, including aggression (Chamero et al, 2007), mating, gender discrimination (Stowers et al, 2002; Kimchi et al, 2007), and fear (Papes et al, 2010) Since these cues crucially regulate the interactions between individuals, the study of their neural representation is central to understanding how the brain controls animal behavior, indirectly impacting life cycle, natural history, and evolution
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
