BACKGROUND: Calcium homeostasis is disturbed in many ways in the course of chronic kidney disease (CKD). The concentration of free cytoplasmic calcium in erythrocytes is increased. Maintenance of a high concentration gradient (between the cystoplasmic and extracellular space) is possible only due to a finely tuned cooperation between many regulating systems in the cytoplasmic membranes and cell organelles. The aim of our study was to evaluate the activity of Ca(2+)-Mg(2+)-dependent ATPase (PMCA), calmodulin and calpain-calpastatin (CANP-CAST) system in erythrocytes of CKD children treated conservatively in the stages II-IV. METHODS: A total of 36 patients with CKD were enrolled in the study. Group A contained patients with CKD stage II; group B with CKD stage III; and group C with CKD stage IV. The control group D consisted of 30 healthy subjects. In the serum, we determined the following: intact parathormon, total calcium, creatinine; in the red blood cells: free cytosolic calcium concentration (Ca(i)(2+)), activity of Ca(2+)-Mg(2+)-transporting ATPase (PMCA), basal PMCA (bPMCA), calmodulin (CALM), CANP, CAST. RESULTS: In all groups, Ca(i)(2+) concentrations were significantly higher, whereas PMCA and bPMCA activity were lower than in the controls. CANP concentrations in group A were elevated compared to the controls, whereas in groups B and C they were significantly lower. In group C, the mean CAST activity reached the highest values. CALM concentrations were decreased versus controls in all groups of patients. CONCLUSIONS: The intracellular Ca(i)(2+) homeostasis is disturbed in children with CKD and aggravates the deterioration of renal function as well. The reasons for the progressing increase of erythrocyte calcium concentration are multifactorial. Undoubtedly, the decreased PMCA activity, the calmodulin deficiency and the dysregulated CANP-CAST system are responsible for that phenomenon. The impact of many other biological modulators, creating a network defending the cell against the calcium accumulation, cannot be excluded.