Heat treatment of human erythrocytes led to increased passive cation permeability, followed by haemolysis. K+ leakage was linear up to a loss of about 80% in the temperature range 46-54 degrees C. Kinetic analysis of the results revealed an activation energy of 246 kJ/mol, implicating a transition in the membrane as critical step. Pretreatment of erythrocytes with 4,4'-di-isothiocyano-2,2'-stilbenedisulphonate, chymotrypsin or chlorpromazine caused a potentiation of subsequent heat-induced K+ leakage. Photodynamic treatment of erythrocytes with Photofrin II, eosin isothiocyanate or a porphyrin-Cu2+ complex as sensitizer also induced an increase in passive cation permeability, ultimately resulting in colloid osmotic haemolysis. The combination of photodynamic treatment immediately followed by hyperthermia had a synergistic effect on K+ leakage. Analysis of the results by the Arrhenius equation revealed that both the activation energy and the frequency factor of heat-induced K+ leakage were decreased significantly by preceding photodynamic treatment, suggesting that hyperthermia and photodynamic treatment have a common target for the induction of K+ leakage. Several lines of reasoning indicate that this common target is band 3. A model is thus proposed for the observed potentiation of hyperthermically induced K+ leakage by photodynamic treatment, in which photo-oxidation of band 3 results in increased sensitivity to subsequent thermal denaturation. These phenomena may be of more general significance, as photodynamic treatment and hyperthermia interacted synergistically with respect to K+ leakage with L929 fibroblasts also.