Summary: A mother’s willingness to sacrifice their own lives to protect their children depends upon the action of oxytocin on neurons in the amygdala, a new study reports.
Source: Champalimaud Center for the Unknown.
From birds to mammals, from fish to reptiles, the immediate reaction to an impending threat to the animal itself is usually to flee or to stop moving in an attempt to go unnoticed. However, when parents feel threatened in the presence of their young, their reaction is completely different: they seek to protect them. What happens in the brains of the parents for them to to be willing to sacrifice their own life in the interest of their offspring’s safety?
A team lead by neuroscientists from the Champalimaud Centre for the Unknown, in Lisbon, Portugal, has discovered that this radical change in the parents’ behavior (from self-defense to defending their young) depends on the action of the so-called “love hormone”, oxytocin, on the neurons of the amygdala, a specific brain structure known for its crucial role in the processing of emotional reactions. Their results have been published in the journal eLife.
Oxytocin is responsible for the bonding between mothers and their young, and within couples. Its effects are not well understood; oxytocin probably has many functions, therefore making its difficult.
Experts do know, however, that its release into the amygdala is able to inhibit that basic self-defense reaction they call freezing, when the animal ceases to move.
Nonetheless, the potential usefulness of this inhibition had not been elucidated. The new study, which was done on female rats that had recently given birth, solves this mystery by bridging the gap between these two phenomena.
“We put both things together”, says Marta Moita, who led the study. “We developed a new experiment that allows us to study the mother’s defensive behavior either in the presence or the absence of her pups, while at the same time testing whether oxytocin’s action in the amygdala is required for the regulation of this behavior.”
Since oxytocin acts on many parts of the brain, affecting many behaviors, it is usually difficult to interpret the results when manipulating this hormone. But in the new experiments, says Marta Moita, “we manipulated a circuit where we know precisely how oxytocin leads to inhibition of freezing. So we are very sure of our interpretation of the behavioral results.”
The experiments consisted in conditioning the mother rats, in the absence of their pups, to associate a peppermint scent with the imminence of an innocuous electric shock. After training, these female rats perceived the odor as a threat and froze accordingly.