Elevated levels of carbon dioxide increase lung ventilation in Helix aspersa. The hypercapnic response originates from a discrete respiratory chemosensory region in the dorsal subesophageal ganglia that contains CO₂-sensitive neurons. We tested the hypothesis that pH-dependent inhibition of potassium channels in neurons in this region mediated the chemosensory response to CO₂. Cells isolated from the dorsal subesophageal ganglia retained CO₂ chemosensitivity and exhibited membrane depolarization and/or an increase in input resistance during an acid challenge. Isolated somata expressed two voltage dependent K⁺ channels, an A-type and a delayed rectifier type channel (I_KA and I_KDR). Both conductances were inhibited during hypercapnia. The pattern of voltage dependence indicated that I_KA was affected by extracellular or intracellular pH, but the activity of I_KDR was modulated by extracellular pH only. Application of inhibitors of either channel mimicked many of the effects of acidification in isolated cells and neurons in situ. We also detected evidence of a pH-sensitive calcium-activated potassium channel (I_KCa) in neurons in situ. The results support the hypothesis that I_KA initiates the chemosensory response, and I_KDR and I_KCa prolong the period of activation of CO₂ sensitive neurons. Thus, multiple K⁺ channels are inhibited by acidosis, and we did not find a single chemosensory channel. The chemosensitive channels that we did find were not unique in any way that we could detect. The protein machinery of CO₂ chemosensitivity is probably widespread among neurons, and the selection process whereby a neuron acts or does not act as a respiratory CO₂ chemosensor probably depends on the resting membrane potential and synaptic connectivity.