Abstract Body: Balance of cholinergic and catecholaminergic activation is necessary to maintain heart health. Interrogating the acute interaction of these autonomic pathways can be done using optogenetics via selective expression of channelrhodopsin (ChR2) within intrinsic cardiac neurons. We tested the hypothesis that cholinergic activation via exogenous acetylcholine (ACh) would suppress the beta-adrenergic heart rate (HR) acceleration induced by tyrosine hydroxylase (TH) neuron stimulation, with the prominence of AV block increasing with increased ACh concentration. ECGs were recorded during perfused heart studies using wild-type (WT) mice and transgenic mice that selectively expressed ChR2 in TH neurons that secrete norepinephrine (NE). HR responses were measured for WT while increasing [NE] and for TH by illuminating the right atrium (465nm, microLED) at a range duty cycles and frequencies. Duty cycles (at 5Hz) increasing from 5-50% caused proportional increases in HR however HR was unstable at duty cycles >30%. At 20% duty cycle, HR increased by 39.43±6.79% (n=6). HR increased sigmoidally at frequencies from 2.5-15Hz (with 30ms pulse width) but HR was unstable at 15Hz. At 10Hz, heart rate increased by 64.24±13.47% (n=4). When comparing HR increases for TH (n=5) and WT+NE (n=4), optogenetic activation resulted in similar maximum HRs but drastically different rise times (7.6±1.25 vs 46.43±5.01 beats/sec, respectively). HR suppression at increasing doses of ACh was measured while perfusing WT hearts with NE and photostimulating TH hearts. The addition of ACh caused beta-adrenergic HR increases to diminish, eventually reaching below baseline HR. In WT+NE animals this occurred at 400nM ACh and in TH animals this did not occur until 1800nM ACh. As ACh increased in TH animals, onset of AV block occurred sooner and more prominently. In conclusion, optogenetic activation of TH neurons caused rapid HR acceleration that was suppressed by ACh at concentrations much higher than that required to suppress acceleration during NE perfusion. AV block also occurred more rapidly during TH neuron activation as [ACh] increased, demonstrating a time-dependent effect in the interaction of cholinergic and catecholaminergic activation.