Revealed: Neurons that help create infant-mother bonds in young mice

Specific neurons in the brain’s zona incerta (ZI) play a crucial role in the early social interactions of an infant and its mother, building their bond and reducing stress, according to a new study in mice. Activation of the same neurons in adult mice increased anxiety- and fear-like responses, the study showed. In humans, as in other mammals, infants have an inborn tendency to form an attachment bond with their mothers or caregivers – a bond that plays a crucial role in the infant’s development. This bond helps newborns feel secure and serves as a safety net from which to explore their surroundings, learn, and develop crucial skills and behaviors. However, the neural mechanisms underlying these important social bonds during an infant’s development are not fully understood. Given an infant’s response to their mother requires the integration of diverse sensory inputs, the ZI – a brain region that serves as a node for both external and internal stimuli – may play an important role in this process. What’s more, previous research has shown that the ZI connects more densely to other brain regions early in life but retracts these connections after weaning.

In this study in preweaning mice, Yuexuan Li and colleagues investigated the role that neurons in the ZI play to integrate the early social experiences of the infant and facilitate a maternal bond. Using fiber photometry, Li et al. recorded the activity of ZI neurons in 16- to 18-day-old pups during interaction with their mother. They discovered that presence of the pup’s mother led to increased activity of somatostatin (SST)-expressing neurons in the ZI (ZI^SST), but not other types. Increased periods of social isolation between interactions with the mother did not change the activation response, suggesting that ZI^SST neurons track the presence of and direct interaction with the mother. Other forms of social interactions, including those with unfamiliar adults, peers, or siblings, also activated ZI^SST, but much more modestly. Moreover, ZI^SST neurons integrate sensory signals, such as olfactory and whisker inputs, to respond to social interactions. Removing both sensory inputs reduced activation, highlighting the importance of multisensory integration. According to the findings, a mother’s presence significantly influences infant behavior by reducing distress and stress hormone levels. Artificial activation of ZI^SST neurons mimics these calming effects during isolation. Li et al.’s results contrast with the effects of ZI^SST in adult mice, where activation of the same neurons increased anxiety- and fear-like responses, indicating that this neural circuit may adapt to support the distinct needs of individuals across development. “Our findings provide an entry point to study infant-specific responses during neurotypical and neurodivergent development,” write the authors.