Extracellular, cell-permeable survivin inhibits apoptosis while promoting proliferative and metastatic potential.

The tumour microenvironment is believed to be involved in development, growth, metastasis, and therapy resistance of many cancers. Here we show survivin, a member of the inhibitor of apoptosis protein (IAP) family, implicated in apoptosis inhibition and the regulation of mitosis in cancer cells, exists in a novel extracellular pool in tumour cells. Furthermore, we have constructed stable cell lines that provide the extracellular pool with either wild-type survivin (Surv-WT) or the previously described dominant-negative mutant survivin (Surv-T34A), which has proven pro-apoptotic effects in cancer cells but not in normal proliferating cells. Cancer cells grown in conditioned medium (CM) taken from Surv-WT cells absorbed survivin and experienced enhanced protection against genotoxic stresses. These cells also exhibited an increased replicative and metastatic potential, suggesting that survivin in the tumour microenvironment may be directly associated with malignant progression, further supporting survivin's function in tumourigenesis. Alternatively, cancer cells grown in CM taken from the Surv-T34A cells began to apoptose through a caspase-2- and caspase-9-dependent pathway that was further enhanced by the addition of other chemo- and radiotherapeutic modalities. Together our findings suggest a novel microenvironmental function for survivin in the control of cancer aggressiveness and spread, and should result in the genesis of additional cancer treatment modalities.

Synthesis of an HIV-1 Tat transduction domain-rotavirus enterotoxin fusion protein in transgenic potato.

A DNA fragment encoding a 12-amino acid (aa) HIV-1 Tat transduction peptide fused to a 90-aa murine rotavirus NSP4 enterotoxin protein (Tat-NSP4(90)) was transferred to Solanum tuberosum by Agrobacterium tumefaciens-mediated transformation. The fusion gene was detected in the genomic DNA of transformed plant leaf tissues by PCR DNA amplification. The Tat-NSP4(90 )fusion protein was identified in transformed tuber extracts by immunoblot analysis using anti-NSP4(90) and anti-Tat as the primary antibodies. Enzyme-linked immunosorbent assay results showed that the Tat-NSP4(90) fusion protein made up to 0.0015% of the total soluble tuber protein. The synthesis of Tat-NSP4(90) fusion protein in transformed potato tuber tissues demonstrates the feasibility of plant cell delivery of the HIV-1 Tat transduction domain as a carrier for non-specific targeting of fused antigens to the mucosal immune system.

Assembly of cholera toxin B subunit full-length rotavirus NSP4 fusion protein oligomers in transgenic potato.

A CTB-NSP4(175) fusion gene encoding the entire 175-aa murine rotavirus NSP4 enterotoxin protein was transferred into Solanum tuberosum cells by Agrobacterium tumefaciens-mediated transformation. The CTB-NSP4(175) enterotoxin fusion gene was detected in the genomic DNA of transformed leaves by PCR DNA amplification. Synthesis and assembly of the full-length CTB-NSP4(175) fusion protein into oligomeric structures of pentamer size was detected in transformed tuber extracts by immunoblot analysis. The binding of CTB-NSP4(175 )fusion protein pentamers to intestinal epithelial cell membrane receptors was quantified by G(M1)-ganglioside enzyme-linked immunosorbent assay (G(M1)-ELISA). The ELISA results showed that CTB-NSP4(175) fusion protein was 0.006-0.026% of the total soluble tuber protein. The synthesis of CTB-NSP4(175) monomers and their assembly into biologically active oligomers in transformed potato tubers demonstrates the feasibility of using edible plants for the synthesis of enterocyte-targeted full-length rotavirus enterotoxin antigens that retain all of their pathogenic epitopes for initiation of a maximum mucosal immune response.