The enterochromaffin-like (ECL) cells, which are the predominant endocrine cell type in the acid-producing part of the vertebrate stomach, are characterized by numerous, electron-lucent vesicles and few electron-dense granules in the cytoplasm. The biological and physiological significance of the ECL cells remains poorly understood. They produce and store histamine and pancreastatin and are thought to produce an as yet unidentified peptide hormone. The most important clue to their function is their willingness to respond to changes in circulating gastrin. The present review presents current knowledge of the biology and physiology of the rat stomach ECL cells. Examination of serially sectioned ECL cells has revealed that the cytoplasmic vesicles almost invariably contain an electron-dense core, suggesting that perhaps the distinction between granules and vesicles is artificial. We propose a life cycle of the secretory organelles in the ECL cells with a progressive development from granules to vesicles. The results showed that the gastrin-evoked release of histamine and pancreastatin was accompanied by loss of vesicles, and that synthesis of histamine and pancreastatin was accelerated by sustained infusion of gastrin, a treatment that was associated with renewal of vesicles. The events described are instrumental in bringing about a change in the "steady state" or "equilibrium" of the ECL cells, from a non-stimulated, resting state to a gastrin-stimulated, active state. This change is attained within six to eight hr. The next "steady state" change is that from "normal-sized" but active ECL cells to "hypertrophic" ECL cells. The increase in cell size is complete after about one week. The gastrin-evoked increase in the ECL cell self-replication rate is maximal after about 10 days, after which time there is a gradual return back to pre-stimulation values. The ECL cell density increases fairly slowly and does not reach maximum (four-fold increase) until after 20 weeks hypergastrinemia. The activity of the histamine-forming enzyme, histidine decarboxylase, is elevated by gastrin and remains elevated for as long as the gastrin stimulus is maintained (the longest time studied was 20 weeks). The physiological significance of the ECL cells is probably related to their capacity to produce and store histamine and an as yet unidentified peptide hormone. The ECL cells are thought to be the source of histamine necessary for the gastrin-evoked acid response. In addition, preliminary evidence suggests that the ECL cells and the anticipated ECL cell hormone play a role in bone formation.