We studied tumorigenic and phenotypic characteristics of pre- and postimmortal human B-lymphoblastoid cell lines (LCLs) transformed by Epstein-Barr virus (EBV): preimmortal LCLs showed low telomerase activity and a normal diploid karyotype while postimmortal LCLs showed much higher telomerase activity and maintained a clonal aneuploidic state. Among five postimmortal LCLs tested, LCLs N0005 and N6803 formed colonies in agar medium and showed marked aneuploidy, and N6803 was transplantable into nude mice indicating that it had a complete malignant phenotype, but all preimmortal LCLs and the remaining three postimmortal LCLs lacked these characteristics. The products of tumor suppresser genes, p16(INK4A) and pRb, were downregulated in these two LCLs, and the p53 gene was mutated in N0005 LCL. We believe these results showed for the first time that some postimmortal EBV-transformed LCLs can become tumorigenic, contrary to previous reports, and that these LCLs provide an in vitro model of tumorigenesis induced by EBV.
Although immunological methods are widely used to diagnose various infectious diseases, they have rarely been employed to detect genetic diseases. In this study, we have established an immunoblot analysis system for the diagnosis of Werner syndrome (WS), a recessive genetic disorder causing premature aging and an enhanced risk of rare cancers. The method uses an immunoblot technique with specific monoclonal antibodies to WS gene product, and B-lymphoblastoid cell lines (LCLs) transformed by Epstein-Barr virus; these cell lines express an increased level of normal WS gene product DNA helicase. The method clearly distinguishes normal from patient LCLs containing any of the mutation types found so far in Japan, primarily because of the drastically reduced levels of mutated gene products, and secondarily because of the truncated product sizes. A comparison of this immunological diagnosis with the symptom-based clinical diagnosis has narrowed down the criteria of symptoms essential for WS diagnosis. This procedure is compatible with, and has some advantage over, the genetic method, because WS patients can be diagnosed without determining the mutated gene sequences. The method exemplified in WS may also be applied to detect some other genetic diseases.
Werner syndrome (WS) is caused by mutations in the gene encoding RecQ type DNA helicase (WRN). We report a 53-year-old Japanese male with WS who initially presented with skin ulcers on the feet and the left elbow. The patient had a high-pitched voice, hoarseness, a characteristic bird-like facial appearance with a beak-shaped nose, canities and juvenile cataracts. Immunoblot analysis using a monoclonal antibody directed against the WS gene product DNA helicase revealed that the patient's leucocytes lacked this particular molecule, confirming the diagnosis of WS. This new immunoblot system therefore enables the diagnosis of WS to be made without the need to undertake more complex mutational analysis.
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