Abstract

Cells from patients with Bloom's syndrome (BS), an autosomal recessive disorder associated with an increased risk of cancer, exhibit genomic instability. Increased numbers of sister-chromatid exchanges (SCE) and delayed DNA chain maturation are typically observed in BS cells. To elucidate the basis for the previously reported decreased DNA ligase I activity in BS cells, simultaneous immunoblot and activity assays for ligase-[32P]AMP adduct formation were performed on extracts from BS and normal lymphoblastoid cell lines. Immunoblot analysis using antibody to DNA ligase I indicate that the amount of the major reactive protein (98 kDa) in normal and BS cells is similar. However, a 50-90% decrease was observed in the ligase activity of the 98-kDa polypeptide in high-SCE BS cells (HG1514 and GM3403c). In contrast, the activity in low-SCE BS cells (HG1554) did not differ significantly from that in normal cells. The data, together with mixing experiments, indicate that the defect in BS ligase I is due at least in part to the loss of ATP binding and/or hydrolytic activity and not to differences in numbers of protein molecules or inhibitory substances. These results suggest that mutation of the DNA ligase I gene may account for the primary metabolic defect in BS.