PROJECT II: SUMMARY/ABSTRACT Approximately two thirds of patients with Parkinson?s disease (PD) experience falls; a primary cause of hospitalization and nursing home admission. These debilitating features of PD are resistant to dopamine replacement therapy, emphasizing the urgent need for basic research and therapeutic development focused on non-dopaminergic systems degenerating in PD. We previously established a rodent model of PD falls and developed novel behavioral paradigms that reflect critical elements of PD falls. Our work identified disruptions of the Attentional-Motor Interface (AMI) network as a major pathophysiologic substrate of impaired gait and balance in PD. The novel Michigan Complex Motor Control Task (MCMCT) assesses falls resulting from impaired AMI function in rats. We also demonstrated that rats with dual losses of cortical cholinergic and striatal dopamine (DL rats), reflecting PET-based findings in PD fallers, exhibit high rates of falls on the MCMCT. As in PD fallers, impairments in attention of DL rats predict fall rates. Treatment with an ?4?2* nicotinic acetylcholine receptor agonist, combination treatments of AChase inhibitors and a 5-HT6 receptor antagonist (idalopirdine) reduce fall rates, indicating translational value of our system. We now propose rigorous mechanistic studies identifying critical synaptic dysfunction within key AMI nodes. We will assess the role of basal forebrain cholinergic signaling in falls (Aim 1), of cholinergically-driven cortico-striatal information transfer (Aim 2), and of the role of striatal cholinergic interneurons (Aim 3). This work will directly complement the research of Projects I and III. The proposed research is supported by extensive preliminary evidence demonstrating: 1) the impact of optogenetic manipulations of basal forebrain cholinergic signaling on complex movement control; 2) that cues guiding complex movements are ?imported? into the striatum via cortico-striatal glutamatergic activity; 3) that DREADD- based inhibition or stimulation of striatal cholinergic interneuronal activity cause and prevent falls, respectively; 4) that these interneurons broadly code cues utilized to execute movements. The proposed research will identify mechanisms of nodal and synaptic AMI dysfunctions, identify novel intervention targets, extend a valuable preclinical model for therapy development, and substantiate falls as a useful behavioral endpoint for studying key nodes of the AMI.