Neuroblastoma demonstrates various clinical behaviors, ranging from spontaneous regression to rapid progression regardless of the therapy used. To study the possibility that progression occurs in neuroblastoma through the accumulation of genetic aberrations, we analyzed the clonal constitution of the primary tumor and metastatic tumor samples from a stage-4 patient. Using cytofluorometry and FISH analyses, intratumor clonal heterogeneity was revealed. In the initial primary tumor sample, the nuclear DNA content indicated the coexistence of diploid and aneuploid clones, and the copy number of chromosome 1 varied from two to six. The chromosome 1 aneusomy population was composed of MYCN-amplified and 1p-deleted clones, whereas, in the chromosome 1 disomy population, coexistence of MYCN-amplified and non-amplified clones as well as 1p-deleted and 1p-intact clones was revealed. In the primary tumor after chemotherapy, the DNA-diploid component had become predominant, although the coexistence of MYCN-amplified and non-amplified clones could still be demonstrated in poorly- and well-differentiated tumor regions, respectively. This contrasted with the findings in the metastatic tumors, in which either diploid or aneuploid clone with MYCN amplification and 1p deletion dominated completely in each metastatic site. The findings suggest that the aneuploid clones had evolved from a diploid clone with MYCN amplification and a 1p deletion which, in turn, may have evolved from a diploid clone with neither MYCN nor 1p abnormality. This illustrates how various stages of multiple-step tumorigenesis may provide clues to a better understanding of the clinical heterogeneity of neuroblastoma.