Role of soluble Fas ligand in autoimmune diseases.

AIM: To investigate the role of soluble Fas ligand in autoimmune diseases. METHODS: RT-PCR was performed to amplify sFasL cDNA from the total RNA extracted from activated human peripheral blood lymphocytes. DNA fragments were cloned into PCR vector. After sequenced, sFasL gene fragments were inserted into pQE-31 vector and expressed in E. Coli M15 respectively. Proteins were purified through affinity chromatography column with ligand of 6XHis tag and identified by SDS-PAGE and Western blot. Mice were immunized with sFasL protein and specific anti-serum was harvested 6 wk after immunization. Monoclonal anti-human FasL antibody was made from the immunized mice. Serum level of sFasL in different patients was detected using anti-FasL antibodies from the immunized mice. RESULTS: The protein expressed was 24 ku by SDS-PAGE electrophrosis. The protein was specially bound to anti-human FasL antibody by Western blot analysis. The sFasL protein could induce Jurket cell apoptosis in vitro. The concentration of serum sFasL in patients with autoimmune diseases was higher than that in normal individuals. sFasL could reduce arthritis in collagen induced arthritis (CIA) mice model by subcutaneous injection. CONCLUSION: sFasL may be involved in either induction of apoptosis or autoimmune diseases. Furthermore, sFasL may have potential application in treatment of autoimmune diseases.

[Purification and identification of human recombinant IFN-beta expressed in yeast Pichia pastoris].

To find an effective and quick way of purifying and identifying recombinant human IFN-beta (rhIFN-beta) expressed in yeast Pichia pastoris, Blue Sepharose 6 fast flow (Blue S6FF) and immunological affinity chromatography (IAC) were compared in this report. rhIFN-beta was produced in 15 liter bioreactor and purified using the two methods mentioned above. The protein concentrations of rhIFN-beta and residual mouse IgG in purified rhIFN-beta were determined with ELISA. The molecular weight and specificity were demonstrated by PAGE and Western blot. The density of the specific precipitation bands was determined by gel scanning. The relative bioactivities were determined by cyto pathogenic effect inhibition (CPEI). The results showed that 2.65 and 3.03 mg of rhIFN-beta were obtained, respectively, by purifying with Blue S6FF or IAC from 2 liter of fermentation supernatant. The molecular weight was 22 kD. The concentrations of the special precipitation of rhIFN-beta were 95.1% and 96.2% respectively. The relative bioactivity of rhIFN-beta purified by Blue S6FF and IAC were 1.63x10(7) IU/mg and 1.43x10(7) IU/mg, respectively. The residual mouse IgG in purified rhIFN-beta by IAC was less than 50 microg/L. The results indicated that rhIFN-beta could be purified effectively and quickly from fermentation supernatant of yeast Pichia pastoris by IAC. The rhIFN-beta products purified by Blue S6FF and IAC had almost the same purity and bioactivity. The data accumulated from the experiment are useful to the preparation of rhIFN-beta on a larger scale.

Active Chinese mistletoe lectin-55 enhances colon cancer surveillance through regulating innate and adaptive immune responses.

AIM: To investigate the potential role of active Chinese mistletoe lectin-55 (ACML-55) in tumor immune surveillance. METHODS: In this study, an experimental model was established by hypodermic inoculating the colon cancer cell line CT26 (5 x 10(5) cells) into BALB/c mice. The experimental treatment was orally administered with ACML-55 or PBS, followed by the inoculation of colon cancer cell line CT26. Intracellular cytokine staining was used to detect IFN-gamma production by tumor antigen specific CD8+ T cells. FACS analysis was employed to profile composition and activation of CD4+, CD8+, gammadelta T and NK cells. RESULTS: Our results showed, compared to PBS treated mice, ACML-55 treatment significantly delayed colon cancer development in colon cancer-bearing Balb/c mice in vivo. Treatment with ACML-55 enhanced both Ag specific activation and proliferation of CD4+ and CD8+ T cells, and increased the number of tumor Ag specific CD8+ T cells. It was more important to increase the frequency of tumor Ag specific IFN-gamma producing-CD8+ T cells. Interestingly, ACML-55 treatment also showed increased cell number of NK, and gammadeltaT cells, indicating the role of ACML-55 in activation of innate lymphocytes. CONCLUSION: Our results demonstrate that ACML-55 therapy can enhance function in immune surveillance in colon cancer-bearing mice through regulating both innate and adaptive immune responses.

[The expression and application of human Fas ligand in E.coli].

AIM: To express recombinant human FasL molecule in E.coli. METHODS: RT-PCR was applied to amplify FasL cDNA from the total RNA extracted from activated human peripheral blood lymphocytes. The DNA fragment was cloned into PCR2.1 vector. After sequencing, the FasL gene was inserted into pQE-31 vector and expressed in E.coli M15. The FasL protein was purified through Ni-ATA affinity chromatography column and identified by SDS-PAGE and Western blot. The mice were immunized with the FasL protein and the specific anti-serum was harvested 6 weeks after immunization. The serum level of FasL from with different kinds of diseases patients were detected using the anti-FasL antibodies from the immunized mice. RESULTS: The expressed protein could be recognized by anti-human FasL antibody in Western-blot analysis with M(r)40 000. This protein could induce Jurket cells apoptosis. anti-FasL serum prepared from mouse could detect the serum FasL as sensitive as commercial ELISA kits. CONCLUSION: The human FasL protein is obtained. It lays the foundation for the further detecting the concentration of FasL and sFasL of patients.

[Study of HLA molecules and its associated genes expression in human ovarian cancer cells].

AIM: To explore the correlation between the expressions of HLA gene and its related gene, and expression of class II transactivator (CIITA) gene induced by IFN-gamma in human ovarian cells. METHODS: The expression of HLA molecule in the tumor cells was detected by Western blot, immunohistochemical staining and flow cytometry. The expressions of transporters associated with antigen processing (TAP), low molecular weight peptides (LMP), and CIITA genes were analyzed by RT-PCR. RESULTS: Abnormal expression rate of HLA class I molecule reached 45% in the 11 ovarian cancer cells. The expressed abnormalities of HLA class I molecule had relation to those of 4 genes (TAP1, TAP2, LMP2 and LMP7). Expression of HLA class II molecule was identical with that of CIITA gene in the ovarian cancer cells or other tumor cells. After IFN-gamma treatment, expressions of HLA class I and II molecule were increased in the cells of CIITA-expressing constitutively or inducibly, while no enhancement of HLA molecule expression manifested itself in the tumor cells of that CIITA was not yet expressed after IFN-gamma induction. CONCLUSION: Deletion of TAP and LMP gene expression in the ovarian cancer cells is an important factor causing abnormal expression of HLA class I molecule, suggesting that the CIITA gene has involved in the modulation of HLA classes I and II molecule expressions in the tumor cells.