PROJECT SUMMARY
The SCid, a sensorimotor hub in the midbrain, plays a fundamental role in stimulus-guided behavior as well as spatial
attention control. It encodes a topographic map of stimulus priority, i.e., of physical salience + behavioral relevance of
stimuli, as well as a map of relative stimulus priority, which, together, form the basis of SCid's role in behavior. However,
the contributions of intrinsic inhibitory cell types to the construction of the SCid's priority map and to behavior are not
known. Similarly, how SCid's map of relative stimulus priority, which requires long-range competitive inhibition, is
constructed, is unclear. Dissecting the logic of local and long-range competitive inhibition in the SCid, as well as their
roles in visually guided behavior necessitates the use of cutting edge technologies for the measurement and perturbation of
neural circuits in a cell-type specific manner. The central focus of our future planned R01 is to address these questions in
freely behaving mice engaged in visual discrimination tasks, as well in rigorous, primate-like visuospatial attention tasks
(that we have developed in the lab). In this R34, we propose to acquire and establish the use of two revolutionary
technologies that are indispensable to this endeavor. In Aim 1, using the nVoke system (Inscopix Inc.), we will measure
the responses of ensembles of excitatory SCid neurons to visual stimuli in awake, head-fixed mice, without and with
optogenetic inactivation of local inhibitory neurons. This unique technology for combined endoscopic calcium imaging
and optogenetic perturbation of neurons of different sub-types intermingled within the same brain area will elucidate the
role of intrinsic inhibition in the construction of SCid's map of stimulus salience. In Aim 2, using the Quartet system
(Neurescence Inc.), we will measure the responses of ensembles of excitatory SCid neurons to competing visual stimuli in
awake head-fixed mice, without and with optogenetic inactivation of a group of parvalbumin-positive GABAergic
neurons in the midbrain tegmentum called the periparabigeminal lateral tegmental nucleus (pLTN). This unique
technology that permits simultaneous endoscopic calcium imaging and optogenetic perturbation of neurons in distinct
brain areas will allow us to test the hypothesis, produced by our recent work in barn owls, that the mammalian pLTN
generates the long-range competitive inhibition that is essential for competitive representations in SCid, and for the
construction of SCid's map of relative stimulus salience. These two aims, coupled with the novel behavioral paradigms
that we have developed in the lab for studying spatial attention and visual discrimination in freely behaving mice, will
establish the scientific and methodological foundation necessary to pursue our longer-term goals in the planned R01: (a)
to dissect the role of local inhibitory circuits of different sub-types in the construction of SCid's map of stimulus priority,
as well as in visually-guided behaviors and spatial attention, and (b) to investigate the role of the GABAergic pLTN in the
construction of SCid's map of relative stimulus priority, as well as in distracter suppression, target selection and spatial
attention. Results have the potential to reveal fundamental mechanistic insights into intrinsic as well as extrinsic inhibitory
circuitry that shape SCid function and mediate its role in behavior.
