[A clinical study of 104 patients with tongue cancer and the relationship between DNA ploidy and prognosis in 41 cases].

One-hundred and four patients with previously untreated tongue cancer seen in our department between 1986 and 1998 were enrolled in a clinical study. The DNA ploidy patterns observed in fresh frozen specimens obtained from 41 patients were analyzed, and prognostic factors were investigated. According to the TNM classification (UICC 1997), 43 patients had stage I tumors, 29 had stage II tumors, 17 had stage III tumors, and 15 had stage IV tumors. The 5-year cause-specific survival rates for each stage were 94.7%, 64.4%, 50.0% and 45.7%, respectively. The most frequent cause of death associated with the original disease was the recurrence of the disease in cervical lymph nodes (19/27, 70.4%). The occurrence of late cervical metastasis was high among patients with a T2N0 disease. Patients with stage II disease should undergo elective neck dissection or be carefully monitored using ultrasonography. Among the 41 cases in which the DNA ploidy pattern was analyzed, diploid patterns were found in 30 cases and aneuploid patterns were found in 11. The 5-year cause-specific survival rate and the 5-year locoregional control rate were significantly lower for the aneuploid cases (18.2%, 38.9%) than for the diploid cases (66.5%, 69.8%) (p = 0.0003, p = 0.0339). The incidence of distant metastasis was significantly higher among the aneuploid cases (6/11, 54.5%) than among the diploid cases (3/30, 10.0%) (p = 0.0058). The ploidy pattern, as determined by flow cytometric DNA analysis, may reflect the malignancy grade of tongue cancers.

Overexpression of the Wilms' tumor gene WT1 in head and neck squamous cell carcinoma.

The expression levels of the Wilms' tumor gene WT1 were examined in 56 cases of head and neck squamous cell carcinoma (HNSCC) using quantitative real-time reverse transcriptase-polymerase chain reaction (RT-PCR). They included 4 cases of floor of mouth, 9 of gingiva, 25 of tongue, 10 of oropharynx, 3 of hypopharynx, and 5 larynx squamous cell carcinoma (SCC). All (100%) of 4 cases of floor of mouth, 5 (56%) of 9 gingiva, 17 (68%) of 25 tongue, 8 (80%) of 10 oropharynx, all (100%) of 3 hypopharynx, and all (100%) of 5 larynx SCC overexpressed the WT1 gene in the range of 3.07 x 10(-4)-8.60 x 10(-1) levels (the WT1 expression level in K562 leukemic cells was defined as 1.0). Thus, 42 (75%) out of 56 cases of HNSCC overexpressed the WT1 gene. The high expression level of the WT1 gene significantly correlated with poor histological tumor differentiation and high tumor stage of HNSCC. Immunohistochemical analysis confirmed the expression of WT1 protein in 6 cases (one floor of mouth, 2 tongue, 2 oropharynx, and one larynx SCC) with overexpression of the WT1 gene. The direct sequencing analysis of the WT1 genomic DNA showed no mutations in any of 10 exons of the WT1 gene in 5 different HNSCC. These findings suggest an important role of the wild-type WT1 gene in the tumorigenesis of HNSCC.

Malignant transformation of thyroid follicular cells by galectin-3.

Galectin-3, a beta-galactoside binding lectin, is highly expressed in thyroid carcinomas of follicular cell origin, whereas neither benign thyroid adenomas nor normal thyroid tissues express galectin-3. We previously showed that antisense inhibition of galectin-3 expression markedly reduced the malignant phenotype of thyroid papillary carcinoma cells. In the present study we transfected galectin-3 cDNA into TAD-2 normal thyroid follicular cells. Stable transfectants expressing galectin-3 acquired the phenotype of serum-independent growth, clonogenicity in soft agar, as well as loss of contact inhibition. We also compared the gene expression profile of the galectin-3 transfectants to that of the vehicle control, which revealed that a series of genes were differentially expressed between the two. They include proliferating cell nuclear antigen, replication factor C, and retinoblastoma genes that participate in G1-S transition. These results indicate the transformation of thyroid follicular cells by galectin-3 and possible involvement of galectin-3 in cell cycle.

Inhibition of human cancer cell growth and metastasis in nude mice by oral intake of modified citrus pectin.

BACKGROUND: The role of dietary components in cancer progression and metastasis is an emerging field of clinical importance. Many stages of cancer progression involve carbohydrate-mediated recognition processes. We therefore studied the effects of high pH- and temperature-modified citrus pectin (MCP), a nondigestible, water-soluble polysaccharide fiber derived from citrus fruit that specifically inhibits the carbohydrate-binding protein galectin-3, on tumor growth and metastasis in vivo and on galectin-3-mediated functions in vitro. METHODS: In vivo tumor growth, angiogenesis, and metastasis were studied in athymic mice that had been fed with MCP in their drinking water and then injected orthotopically with human breast carcinoma cells (MDA-MB-435) into the mammary fat pad region or with human colon carcinoma cells (LSLiM6) into the cecum. Galectin-3-mediated functions during tumor angiogenesis in vitro were studied by assessing the effect of MCP on capillary tube formation by human umbilical vein endothelial cells (HUVECs) in Matrigel. The effects of MCP on galectin-3-induced HUVEC chemotaxis and on HUVEC binding to MDA-MB-435 cells in vitro were studied using Boyden chamber and labeling assays, respectively. The data were analyzed by two-sided Student's t test or Fisher's protected least-significant-difference test. RESULTS: Tumor growth, angiogenesis, and spontaneous metastasis in vivo were statistically significantly reduced in mice fed MCP. In vitro, MCP inhibited HUVEC morphogenesis (capillary tube formation) in a dose-dependent manner. In vitro, MCP inhibited the binding of galectin-3 to HUVECs: At concentrations of 0.1% and 0.25%, MCP inhibited the binding of galectin-3 (10 micro g/mL) to HUVECs by 72.1% (P =.038) and 95.8% (P =.025), respectively, and at a concentration of 0.25% it inhibited the binding of galectin-3 (1 micro g/mL) to HUVECs by 100% (P =.032). MCP blocked chemotaxis of HUVECs toward galectin-3 in a dose-dependent manner, reducing it by 68% at 0.005% (P<.001) and inhibiting it completely at 0.1% (P<.001). Finally, MCP also inhibited adhesion of MDA-MB-435 cells, which express galectin-3, to HUVECs in a dose-dependent manner. CONCLUSIONS: MCP, given orally, inhibits carbohydrate-mediated tumor growth, angiogenesis, and metastasis in vivo, presumably via its effects on galectin-3 function. These data stress the importance of dietary carbohydrate compounds as agents for the prevention and/or treatment of cancer.

Galectin-3 phosphorylation is required for its anti-apoptotic function and cell cycle arrest.

Galectin-3, a beta-galactoside-binding protein, is implicated in cell growth, adhesion, differentiation, and tumor progression by interactions with its ligands. Recent studies have revealed that galectin-3 suppresses apoptosis and anoikis that contribute to cell survival during metastatic cascades. Previously, it has been shown that human galectin-3 undergoes post-translational signaling modification of Ser(6) phosphorylation that acts as an "on/off" switch for its sugar-binding capability. We questioned whether galectin-3 phosphorylation is required for its anti-apoptotic function. Serine to alanine (S6A) and serine to glutamic acid (S6E) mutations were produced at the casein kinase I phosphorylation site in galectin-3. The cDNAs were transfected into a breast carcinoma cell line BT-549 that innately expresses no galectin-3. Metabolic labeling revealed that only wild type galectin-3 undergoes phosphorylation in vivo. Expression of Ser(6) mutants of galectin-3 failed to protect cells from cisplatin-induced cell death and poly(ADP-ribose) polymerase from degradation when compared with wild type galectin-3. The non-phosphorylated galectin-3 mutants failed to protect cells from anoikis with G(1) arrest when cells were cultured in suspension. In response to a loss of cell-substrate interactions, only cells expressing wild type galectin-3 down-regulated cyclin A expression and up-regulated cyclin D(1) and cyclin-dependent kinase inhibitors, i.e. p21(WAF1/CIP1) and p27(KIP1) expression levels. These results demonstrate that galectin-3 phosphorylation regulates its anti-apoptotic signaling activity.