Cardiac ischemia (angina pectoris), the situation when heart receives insufficient blood supply, always causes clinical problems such as chest pain or even death. However, how cardiac sensory neurons respond to ischemia and cause pain sensation is still unknown. Acid-sensing ion channel 3 (ASIC3) is the possible candidate expressed on cardiac sensory afferents to sense protons and solicit some regulations. Here, we used radio-telemetry electrocardiography to examine Isoproterenol (Iso)-induced cardiac ischemia in mice lacking ASIC3. Iso-treated mice increased heart rate (tachycardia) and showed ST-depression in electrocardiogram indicating an episode of cardiac ischemia. These results were further proofed by positive labeling of Hypoxyprobe, which reacts with proteins in hypoxic tissues, and pathological consequences of cardiac fibrosis. ASIC3-/- mice performed longer duration of Iso-induced tachycardia and ST-depression as well as more severe cardiac fibrosis than ASIC3+/+ mice. Furthermore, ASIC3+/+ mice showed higher parasympathetic tones than ASIC3-/- mice just before ST-depression vanished based on heart rate variability analyses. To further resolve the underlying mechanism, we used atropine to block parasympathetic neuron activity in Iso-induced cardiac ischemia and found atropine altered the recovery phases of ST-depression and tachycardia only in ASIC3+/+ but not ASIC3-/- mice. In contrast, atropine didn’t affect Iso-induced cardiac fibrosis in ASIC3+/+ mice, whereas atropine reduced Iso-induced cardiac fibrosis in ASIC3-/- mice. Besides, we used resiniferatoxin (RTX) to rule out contribution of TRPV1 (another acid sensor) and found TRPV1 is not involved in this milder cardiac ischemia. However, unexpected neuropathic effects were generated. In conclusion, we developed an animal model for cardiac ischemia induced by Isoproterenol and demonstrated that ASIC3 is involved in detection and triggering ischemia-induced autonomic regulation. TRPV1 is not involved in this condition.