Differentiation of three Lactobacillus rhamnosus strains (E/N, Oxy and Pen) by SDS-PAGE and two-dimensional electrophoresis of surface-associated proteins.

SDS-PAGE of extracted surface-associated proteins of Lactobacillus rhamnosus strains E/N, Oxy, and Pen, was performed. The obtained protein patterns allowed differentiation of the examined strains, which was not accomplished by the commonly used RAPD genotypic method. The differentiation by the SDS-PAGE method proved to be a useful tool for strain-specific identification, which was further confirmed by 2DE analysis. Therefore, it can be used as an alternative or complementary method for both conventional and genotypic identification procedures, especially when closely related lactobacilli isolates are identified.

Presence of MHC-I in rat glioma cells expressing antisense IGF-I-receptor RNA.

The supposed immunogenic character of glioma cells transfected with antisense IGF-I-Receptor (IGF-I-R) expression vector was tested for the presence of MHC-I currently present in cells of IGF-I antisense type. C6 rat glioma cell line was comparatively transfected in vitro with IGF I antisense (pMT-Anti-IGF I) or IGF I Receptor antisense (pMT-Anti-IGF I R) expression vectors. The wild and transfected cells were examined for the presence of IGF-I and MHC-I molecules. Using RT PCR technique, the transfected "antisens" cells showed total inhibition of IGF-I. The both transfected cultures of IGF-I and of IGF-I-R type were positively stained for MHC-I. Moreover "antisense IGF-I-R" cells as compared to "IGF-I antisense" cells showed slightly higher expression of MHC-I. The transfected cells showed also the feature of apoptosis in 60% of cells. The immunogenicity of IGF-I-R antisense glioma cells is related to MHC-I presence; therefore both approaches of antisense IGF-I and of antisense IGF-I-R could be use in paralel for cellular therapy of glioblastoma.

IGF-I triple helix gene therapy of rat and human gliomas.

PURPOSE: IGF-I anti-gene technology was applied in treatment of rat and human gliomas using IGF-I triple helix approach. MATERIAL AND METHODS: CNS-1 rat glioma cell and primary human glioblastoma cell lines established from surgically removed glioblastomas multiforme were transfected in vitro with IGF-I antisense (pMT-Anti-IGF-I) or IGF-I triple helix (pMT-AG-TH) expression vectors. The transfected cells were examined for immunogenicity (immunocytochemistry and flow cytometry analysis) and apoptosis phenomena (electron microscopy). 3 x 10(6) transfected cells were inoculated subcutaneously either into transgenic Lewis rats or in patients with glioblastoma. The peripheral blood lymphocytes (PBL) derived from "vaccinated" patients were immunophenotyped for the set of CD antigens (CD4, CD8 etc). RESULTS: Using immunocytochemistry and Northern blot techniques, the transfected "antisense" and "triple-helix" cells showed total inhibition of IGF. Transfected cultures were positively stained either for both MHC-I and B7 antigens--60% of cloned lines, or for MHC-I only--40% of cloned lines. Moreover "triple helix" cells as compared to "antisense" cells showed slightly higher expression of MHC-I or B7. Transfected cells also showed the feature of apoptosis in 60%-70% of cells. In in vivo experiments with rats bearing tumors, the injection of "triple helix" cells expressing both MHC-I and B7 interrupted tumor growth in 80% of cases. In contrast, transfected cells expressing only MHC-I stopped development in 30% of tumors. In five patients with surgically resected glioblastoma who were inoculated with "triple helix" cells, PBL showed an increased percentage of CD4 + CD25+ and CD8 + CD11b-cells, following two vaccinations. CONCLUSIONS: The anti-tumor effectiveness of IGF-I anti-gene technology may be related to both MHC-I and B7 expression in cells used for therapy. The IGF-I antigene therapy of human glioblastoma multiforme increases immune response of treated patients.

IGF-I triple helix strategy in hepatoma treatment.

BACKGROUND/AIMS: To investigate the effect of gene therapy for hepatocellular carcinoma based on inhibition of cellular IGF-I expression, the technique of IGF-I triple helix was investigated in mice developing programmed hepatoma. METHODOLOGY: mhAT1F1 mouse hepatoma cell line was transfected in vitro with IGF-I triple helix expression vector (pMT-AG-TH) or with IGF-I antisense expression vector (pMT-Anti-IGF-I). 10 x 10(6) transfected cells of either triple helix or antisense type were inoculated intraperitonealy into transgenic ATIIITB6 mice developing genetically programmed hepatoma (mice die between the age of 6 and 7 months). In parallel, human cell cultures established from surgically removed hepatomas were investigated. RESULTS: mhAT1F1 and human primary cell cultures, transfected with pMT-AG-TH or pMT-Anti-IGF-I vectors resulted in total inhibition of IGF-I demonstrated by immunocytochemical and Northern blot techniques. Transfected cells changed their phenotype and recovered major histocompatibility complex I expression showed by fluorescence-activated cell sorting analysis and Western blot. Moreover, two phenomena were observed in IGF-I "antisense" or "triple helix" transfected cells: 1) the apoptosis, demonstrated by TUNEL technique; 2) the presence of IL-6 simultaneously with disappearance of tumor necrosis factor-alpha and IL-10, investigated by reverse transcriptase-polymerase chain reaction technique. In in vivo experiments, injection of murine transfected cells into mice in terminal-phase prolonged their survival 3-4 months in 100% of cases, as well in "antisense" group (8/8) as in "triple helix" group (10/10). CONCLUSIONS: Injection of hepatoma cells transfected with IGF-I triple helix expression vector, and showing immunogenic and apoptotic characteristics, can constitute an effective cellular therapy against hepatocellular carcinoma.