Much of the neural circuitry controlling respiratory pumping in Aplysia has been well characterized, but the function of this movement is incompletely understood. To gain insight into possible functions of respiratory pumping, responses were examined for a 40 min exposure to two stimuli that modulate the movement: 1) increase and 2) decrease in seawater concentration. Thresholds were present for both stimuli to affect respiratory pumping. Above threshold, there were graded increases in the number of pumps elicited. There were decrements in respiratory pump frequency as a function of time exposed to the stimulus. Increased respiratory pumping did not contribute to volume regulation in response to exposure to altered seawaters, but was associated with increased defensive responses, such as escape locomotion (swimming) and inking. In addition, head shock, a well-established noxious stimulus, elicited temporal patterns of respiratory pumping similar to those elicited by altered seawaters. The data indicate that in our experimental conditions, respiratory pumping is elicited as part of an integrated defensive response to noxious seawaters.