Abstract— The effect of Photofrin encapsulated in a liposome delivery vehicle for photodynamic therapy (PDT) of the 9L gliosarcoma and normal rat brain was tested. We hypothesized that the liposome vehicle enhances therapeutic efficacy, possibly by increasing tumor tissue concentration of Photofrin. Male Fisher rats bearing a 9L gliosarcoma were treated 16 days after intracerebral tumor implantation with either Photofrin in dextrose (n = 5) or Photofrin in liposome (n = 6). Nontumor‐bearing animals were treated with Photofrin delivered either in dextrose (n = 4) or liposome (n = 4) vehicle. Tissue concentrations of Photofrin delivered either in dextrose (n = 4) or liposome (n = 4) vehicle were measured in tumor, brain adjacent to tumor and in normal brain tissue. Photofrin was administered (intraperitoneally) at a dose of 12.5 mg/kg and PDT (17 J/cm 2 of 632 nm light at 100 mW/cm 2 ) was performed 24 h after Photofrin administration. Brains were removed 24 h after PDT and stained with hematoxylin and eosin for analysis of cellular damage. The PDT using Photofrin in the liposome vehicle caused significantly more damage to the tumor ( P < 0.001) than did PDT with Photofrin in dextrose. The PDT of tumor with Photofrin delivered in liposomes caused a 22% volume of cellular necrosis, while PDT of tumor with Photofrin delivered in dextrose caused only scattered cellular damage. Photofrin concentration in tumors was significantly higher ( P = 0.021) using liposome (33.8 ± 18.9 μg/g) compared to dextrose delivery (5.5 ± 1.5 μg/g). Normal brain was affected similarly in both groups, with only scattered cellular necrosis. Our data suggest that the liposome vehicle enhances the therapeutic efficacy of PDT treatment of 9L tumors.
Doublecortin (DCX) is one of the three genes found from Affymetrix gene chip analysis related to glioma patient survival. Two other genes (e.g., osteonectin and semaphorin 3B) are well characterized as antioncogenic and tumor suppressor genes. However, there is no report about the involvement of DCX in cancer. Here, we show that gene transfer technology into DCX-deficient glioblastoma cell lines, such as A172, U87, U251N, RG2, and 9L, with DCX cDNA significantly suppressed growth of these glioma cells. U87 cells with ectopic expression of DCX exhibit a marked suppression of the transformed phenotype as growth arrested in the G(2) phase of the cell cycle progression, small colony formation in soft agar, and no tumor formation in nude rats. This transformed phenotype can be restored by knocking down DCX expression with DCX small interfering RNA. DCX was highly phosphorylated in glioma cells. Phosphorylation in the glioma cells was greater than in noncancer cells such as mouse NIH 3T3 and human embryonic kidney 293T cells. Coimmunoprecipitation of the phosphorylated DCX and spinophilin/neurabin II from DCX-synthesizing glioma cells indicated their interaction. This interaction would lead to a block of anchorage-independent growth as neurabin II is a synergistic inhibitor of anchorage-independent growth with p14ARF (ARF). Interaction between phosphorylated DCX and neurabin II may induce the association of the protein phosphatase 1 catalytic subunit (PP1) with neurabin II and inactivate PP1 and block mitosis during G(2) and M phases of the cell cycle progression. Thus, DCX seems to be a tumor suppressor of glioma.
Clinical studies have indicated that photodynamic therapy (PDT) significantly prolonged the median survival of patients with gliomas. Experimental studies demonstrate that increasing optical energy and photosensitizer dose leads to increased volume of tumor necrosis. However, increasing the light dose delivered to the tumor may increase the risks of inducing permanent neurological deficits. In the current study, we sought to test the behavioral deficits induced in normal rats by brain PDT and the neurorestorative effects of atorvastatin on PDT-induced behavioral deficits. Considering its potential as a combination treatment of brain tumors, we investigated both in vitro and in vivo whether atorvastatin treatment promotes brain tumor growth. Non-tumored Fischer rats received PDT (n=18). Nine of the PDT-treated animals were treated with atorvastatin. Control animals underwent the same surgical procedure, but did not receive Photofrin and laser light. PDT-treated animals had significant behavioral deficits on days 2, 5, 7, 9 and 14 after PDT, compared with surgery controls. PDT-treated animals receiving atorvastatin displayed significantly ameliorated behavioral deficits on days 7, 9 and 14 after PDT, compared to PDT-treated rats. In vitro tumor cell viability and growth were evaluated. Atorvastatin did not affect the growth of glioma cells. Fischer rats with intracranial 7-day-old 9L glioma tumor cell implantation were randomly subjected to no treatment, PDT alone, atorvastatin alone, or combined treatment with atorvastatin and PDT (6 rats/group). Our data indicate that atorvastatin did not promote tumor growth in either PDT treated and non-treated rats. However, atorvastatin significantly reduced the cell damage caused by PDT. To further test the mechanisms underlying the atorvastatin-mediated reduction of functional deficits, we investigated the effects of atorvastatin on angiogenesis and synaptogenesis. Our data demonstrate that atorvastatin significantly induced angiogenesis and synaptogenesis in the PDT-damaged brain tissue. Our data indicate that PDT induces functional deficits. Atorvastatin treatment promotes functional restoration after PDT, but does not promote glioma growth in vitro and in vivo. Atorvastatin reduces astrocyte and endothelial cell damage caused by PDT and induces angiogenesis and synaptogenesis after PDT. Thus consideration and further testing of the combination of atorvastatin and PDT for the treatment of glioma is warranted.
Objective:To investigate the relationship between clinicopathologic features and immunophenotypes in non-Hodgkin's lymphoma (NHL), and to the different expression of immunophenotypes in NH、RH、and chronic lymphadenitis.Methods:Puncture lymphatic from 206 cases and diagenose lymph through microscope, then immunophenotypes in 206 patients were detected quantitatively with FCM.Results:①95 cases were chronic lymphadenitis, 40 cases were RH, 71 cases were NHL.②The B-NHL were 53 cases(74.64%);T-NHL were 12 case (16.90%) in 71 cases of NHL.The straining rates of poly clonal CD3、CD4、CD34 were 21.13%、8.45%、42.25%.③There were significant difference in immunophenotypes among NHL、RH and chronic lymphadenitis( P 0.05).Conclusion:The results showed that analysis of the immunophenotype of NHL is helpful to ensure the character of T cell or B cell.It is helpful to differentiate the NHL too.
Armadillo repeat-containing protein 8 (ARMC8) plays an important role in regulating cell migration, proliferation, tissue maintenance, signal transduction, and tumorigenesis. However, the expression pattern and role of ARMC8 in osteosarcoma are still unclear. In this study, our aims were to examine the effects of ARMC8 on osteosarcoma and to explore its underlying mechanism. Our results demonstrated that ARMC8 was overexpressed in osteosarcoma cell lines. Knockdown of ARMC8 significantly inhibited osteosarcoma cell proliferation in vitro and markedly inhibited xenograft tumor growth in vivo. ARMC8 silencing also suppressed the epithelial‐mesenchymal transition (EMT) phenotype, as well as inhibited the migration and invasion of osteosarcoma cells. Furthermore, knockdown of ARMC8 obviously inhibited the expression of β-catenin, c-Myc, and cyclin D1 in MG-63 cells. In conclusion, this report demonstrates that ARMC8 silencing inhibits proliferation and invasion of osteosarcoma cells. Therefore, ARMC8 may play an important role in the development and progression of human osteosarcoma and may represent a novel therapeutic target in the treatment of osteosarcoma.
Vascular endothelial growth factor (VEGF) is abundantly produced by glioma cells especially glioblastoma, the most malignant form of astrocytoma. VEGF, a well known angiogenic factor, acts in a paracrine fashion on endothelial cells to develop tumor vasculature. However, recent studies have found that several tumor cells express VEGF receptors, and an autocrine action of VEGF on tumor cells has been suggested. To test this hypothesis, three human glioma cell lines (U251n, U87 and A172) were checked for VEGF and VEGFR expression. These cells express 0.1-0.6 ng/ml VEGF165 in cell culture medium within 24 hours. Western blot analysis showed that these cells express all of the VEGF receptors, VEGFR-1/Flt-1, VEGFR-2/KDR, Neuropilin-1 (NRP-1) and Neuropilin-2(NRP-2), even though tyrosine kinase receptor VEGFR-2/KDR exhibited baseline levels of expression. VEGF expression was significantly down regulated by phosphorothioate oligodeoxynucleotide (PS-ODN) and VEGF RNAi transfection. However, VEGF RNAi transfection as well as VEGF and VEGFR2 neutralization antibody treatment did not decrease cell proliferation detected by MTT and CyQuant NF proliferation assay except that PS-ODN transfection caused a non-specific decrease on cell proliferation. VEGF RNAi transfection did not alter cell invasion, as demonstrated in a matrigel invasion assay. Matrix metalloproteinase-2 (MMP-2) and MMP-9, facilitating cell invasion and over expressed in glioma cells, were not altered by VEGF RNAi transfection, as shown by zymographic assays. Our data indicate that the decrease of endogenous VEGF expression may not affect glioma cell proliferation and invasion.
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