Abstract:
Attachment powerfully shapes our development and remains a primary driver of health and well-being in
adulthood; disruption of attachments is highly traumatic. While affiliation, defined as general positive social
interactions, is shared widely among mammals, attachment, or selective affiliation as a result of a bond, is far
rarer and of primary relevance to humans. While affiliation has been studied in a number of contexts, how the
neural circuitry that underlies affiliation ultimately contributes to adult attachment remains largely unknown. In
this proposal, we will take a comparative framework to understand how the basic circuitry and neuronal patterns
that underlie non-selective affiliation are ultimately engaged and underlie selective attachment in adulthood.
Specifically, we will examine how the neurobiology of affiliative behavior in mice has been elaborated to support
the more complex attachments formed by monogamous prairie voles and gregarious fruit bats, representing a
spectrum of social relationships. We will focus on the hippocampal CA2 region as it has been shown to play a
specialized role in social behavior and receives direct inputs from oxytocin and vasopressin producing cells in
the paraventricular hypothalamus. Specifically, we will test the overarching hypothesis that CA2 population
activity patterns follow similar trajectories across species before and during mating, and subsequently diverge to
causally drive affiliative investigation in mice (Golshani/Hong) and different forms of attachment in prairie voles
(Donaldson) and bats (Yartsev). To test this hypothesis we will refine and use new generation open-source
wireless miniaturized microscopes (Aharoni) that will allow prolonged recordings of large neuronal populations
in freely behaving animals. Kennedy will bring computational expertise and allow a unified data analysis
framework cross species. In Aim 1 we will perform in-vivo calcium imaging in mice, prairie voles and bats to test
the hypothesis that mating experiences modulate CA2 neural dynamics and that CA2 activity patterns encode
spatial and identity information. We hypothesize that species that form attachments to mating partners, activity
patterns will differentiate preferred vs. non-preferred partners. In Aim 2 we will use chemogenetic inhibition of
CA2 in all species to determine whether CA2 causally drives affiliative and attachment behaviors. In Aim 3 we
will test the hypothesis that inhibition of vasopressin inputs to CA2 will reduce the dimensionality of CA2
population activity patterns after mating, diminish memory of the mate in all species, and in voles and bats,
reduce the decodability of the identity of the previous mating partner. In a technology development aim, we will
develop and test a “true wireless” digital data transmitting microscope with power over distance charging
capability that will allow prolonged imaging over many hours without human intervention.