A typical flow cytometric marker of apoptosis is the appearance of a hypodiploid peak. This phenomenon is related to the chromatin fragmentation and loss that occurs during the late stages of the process. We describe herein the changes occurring at the chromatin level in purified nuclei preparations obtained from human peripheral blood mononuclear cells in a time-course study, including the simultaneous evaluation of nuclear proteins and DNA stainability, light-scattering properties, and spectrophotometric determination of the protein content. An augmentation of fluoroscein isothiocyanate (FITC) stainability was noticed as early as 1 h after irradiation. As this phenomenon is not correlated to changes in actual protein content, one can conclude that modifications of basic protein accessibility occur from the early phases of the apoptotic process. Also DNA stainability augmented with time, generating the transient appearance of a hyperdiploid peak that preceded the appearance of the hypodiploid peak typical of the late stages of the process, and that shared with the latter the same light-scattering properties. Chromatin status was further explored by staining apoptotic nuclei using DNA probes with peculiar molecular weight. Propidium iodide (PI) and ethidium bromide (EB), but not the much bulkier 7-aminoactinomycin D (7-AAD), identified the nuclei with a transient increase in DNA stainability confirming that an increased dye accessibility to binding sites was responsible for the phenomenon. Remarkably, all dyes identified the same proportion of hypodiploid nuclei when an apoptotic nucleus shed its fragmented chromatin. Control experiments included differential interference contrast and fluorescence microscopy that showed the purity of nuclei preparations and the typical morphological apoptotic features. Finally, the simultaneous evaluation of DNA by PI and nuclear proteins by FITC in a time course study allowed a thorough assessment of changes occurring at the chromatin level in the diverse stages of apoptosis. It is suggested that proteolysis precedes endonucleolysis and probably renders it easier the final endonucleolytic step leading to DNA fragmentation and loss.