Bloom syndrome (BS) is a rare human genetic disease in which patients exhibit growth retardation, immunodeficiency, infertility, photosensitivity, and predisposition to cancer. The gene defective in BS has recently been cloned (named BLM) and was found to belong to an evolutionarily conserved helicase family, called RecQ. The recombinant BLMp protein has been shown to possess a helicase activity in vitro, suggesting that BS could be caused by a defect in a DNA metabolic reaction, such as replication or repair. Interestingly, BLM gene belongs to the helicase family, like the genes mutated in Werner Syndrome and Rothmund-Thomson syndrome (RTS). All three diseases have some common features, such as genetic instability and predisposition to cancer. But each disease has its own distinctive symptoms. For example, WS patients prematurely display many age-related features, including osteoporosis, atherosclerosis, diabetes and cataracts, which are not observed in BS or RTS. Also, WS individuals do not show immunodeficiency or photosensivity like BS patients. To understand the molecular mechanism of these human diseases, we propose to isolate the protein complexes containing each gene product. To investigate the mechanism of BS, we isolated from human HeLa extracts three complexes containing the helicase defective in BS, BLM. Interestingly, one of the complexes, termed BRAFT, also contains five of the Fanconi anemia (FA) complementation group proteins (FA). FA resembles BS in genomic instability and cancer predisposition, but most of its gene products have no known biochemical activity and the molecular pathogenesis of the disease is poorly understood. BRAFT displays a DNA-unwinding activity, which requires the presence of BLM because complexes isolated from BLM-deficient cells lack such an activity. The complex also contains topoisomerase IIIa and replication protein A, proteins that are known to interact with BLM and could facilitate unwinding of DNA. We show that BLM complexes isolated from a FA cell line have a lower molecular mass. Our study provides the first biochemical characterization of a multiprotein FA complex and suggests a connection between the BLM and FA pathways of genomic maintenance. The findings that FA proteins are part of a DNA-unwinding complex imply that FA proteins may participate in DNA repair. This work has recently been published in Mol. Cell. Biol. We are currently investigating the function of other subunits of the BRAFT. Preliminary suggest that one of them, BLAP75, is an integral part of the BRAFT complex.
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