p53 enhances the Delta-24 conditionally replicative adenovirus anti-glioma effect.

Previous studies have demonstrated that the conditionally replicative adenovirus Ad5Delta24 is a powerful cytolytic agent against glioma selectively affecting cells with a defective p16/Rb/E2F pathway. The p53 protein is also known to be an apoptotic factor for glioma cells. In this study, we examined the simultaneous delivery of the combination of exogenous p53 and Ad5Delta24 adenovirus in glioma cells. Infecting cells with low doses of adenovirus p53 and Ad5Delta24 resulted in an additive effect on cell death. The cell death induced by both agents was independent of the p53 status of cells. Flow cytometry revealed that the potent anti-tumor effect induced by the mixture of Ad5CMV-p53 and Ad5Delta24 adenoviruses was due to a combination of apoptosis and cell lysis. Our results indicate that Ad5CMV-p53 enhances the oncolytic effect of the Ad5Delta24 adenovirus, and the combination of adenovirus Ad5Delta24 and Ad5CMV-p53 may thus be a potential therapeutic tool for gliomas.

Novel approaches toward early diagnosis of islet allograft rejection.

BACKGROUND: The inability to diagnose early rejection of an islet allograft has previously proved to be a major impediment to progress in clinical islet transplantation. The need to detect early rejection will become even more relevant as new tolerance-inducing protocols are evaluated in the clinic. We explored three novel approaches toward development of early diagnostic markers of islet rejection after islet allotransplantation. METHODS: (a) Canine islet allograft transplant recipients were immunosuppressed for 1 month, then therapy was withdrawn. Serum glutamic acid decarboxylase antigen (GAD65), an endogenous islet protein, was monitored daily with a CO2 release assay. (b) Rodent islets were genetically engineered to express a unique foreign protein (beta-galactosidase) by using adenoviral vectors, and after allograft transplantation, the viral-specific protein was measured in serum using optical luminescence. (c) Rodents receiving islet allografts were immunosuppressed temporarily, and daily glucose tolerance tests were followed until graft failure occurred. RESULTS: (a) Although serum monitoring of GAD65 antigen demonstrated elevated levels preceding loss of graft function in preliminary studies, the effect was not reproducible in all animals. (b) Genetically engineered rodent islets demonstrated normal insulin kinetics in vitro (insulin stimulation index 2.57+/-0.2 vs. 2.95+/-0.3 for control islets, P=ns), and purified viral protein products had a stable half-life of 8 hr in vivo. After islet allotransplantation, there were two peak elevations in serum viral proteins, confirming that an intra-islet "sentinel signal" could be detected serologically during acute rejection. There was no lead-time ahead of hyperglycemia, however. (c) Daily sequential intravenous glucose tolerance (IVGT) tests demonstrated evidence of allograft dysfunction (decline in KG) with a 2-day lead time to hyperglycemia (2.58+/-0.3 vs. 1.63+/-0.2%/min, respectively, P<0.001), with an accuracy of 89%, sensitivity of 78%, and specificity of 95%. CONCLUSIONS: Of the three diagnostic tests, metabolic assessment with an abbreviated IVGT was the most effective method of demonstrating early islet dysfunction due to rejection.

Co-expression of E2F-2 enhances the p53 anti-cancer effect in human glioma cells.

Gliomas are highly resistant to conventional treatment. Improved knowledge of the molecular defects of glioma cells offers new avenues for the development of gene therapy strategies. Transfer of the p53 gene has proven effective in suppressing proliferation in human glioma cell lines. However, several human glioma cell lines are resistant to p53-induced cell death. The E2F family of transcription factors are pivotal for the regulation of cell-cycle and cell-death related genes in gliomas. In the present study, we sought a more effective strategy for glioma treatment by examining the therapeutic potential of the simultaneous transfer of p53 and E2F-2 to gliomas. Trypan blue cell viability assays and flow cytometric cell-cycle analysis demonstrated that the transfer of both p53 and E2F-2 induced cell death in D-54 MG, a p53-resistant glioma cell line. In addition, transfer of E2F-2 did not interfere with the apoptotic properties of exogenous wild-type p53 in U-251 MG cells. Finally, the expression of E2F-2 in D-54 MG cells suppressed the expression of the apoptotic molecule mdm-2 induced by exogenous p53 in these cells. These results show that co-expression of E2F-2 and p53 enhances the anti-cancer effect of p53 in gliomas.

No specific reactivity to E. coli glutamic acid decarboxylase from sera of newly-diagnosed insulin dependent diabetic patients.

The 65 kD isoform of Glutamic Acid Decarboxylase (GAD), is one of the major autoantigens in human type 1 diabetes mellitus. This enzyme shares amino acid identity, in select regions already determined as antigenic with its counterpart from E. coli. We tested the reactivity of diabetic and normal sera and an E. coli GAD-specific monoclonal antibody (2D9) to E. coli GAD by solid phase and competition ELISA, as well as immunoblotting to check for cross-reactivity of autoantibodies to the two antigens. Specific antibodies for E. coli GAD are present in diabetics and normal subjects without any differences in frequency and titer. The reactivity of such antibodies in ELISA could be blocked in a dose-dependent manner by the addition of excess antigen in the liquid phase. Furthermore, the monoclonal antibody against E. coli GAD does not recognise human recombinant GAD65 in an ELISA. We conclude that there is no basis for cross-reactivity between the two antigens, and antibody reactivity to GAD65 in man cannot arise from cross-reactivity to the E. coli enzyme.