Impact of hyperglycemia on the expression of GLUT1 during oral carcinogenesis in rats.

BACKGROUND: On the background of the epidemiological link between diabetes and oral cancer, the present study aimed to analyze the potential involvement of selected glucose transporters (GLUT1/GLUT3/GLUT4), if any, in such putative association. METHODS AND RESULTS: Oral carcinogenesis was induced by 4-nitroquinoline N-oxide in 10 non-diabetic and 10 diabetic rats; 8 non-diabetic and 7 diabetic rats served as controls. Expressions of selected GLUTs at mRNA and protein levels were analyzed in oral tissue (normal/lesion) by quantitative real-time PCR and immunohistochemistry respectively. Premalignant lesions (hyperplasia/dysplasia/carcinoma-in-situ) appeared on tongues of carcinogen-treated animals. Significant increase of GLUT1mRNA level was seen from normal to lesion tongues, along increasing lesion grades (from hyperplasia/mild dysplasia to moderate/severe dysplasia) and in lesions induced under hyperglycemic condition than that induced under normoglycemic one; a similar trend was found in transcript variant-1 of GLUT1, but not in variant-2. GLUT3 and GLUT4 mRNA levels were comparable among lesions irrespective of grades and glycemic status. Concordant to mRNA level, overall expression of GLUT1 protein was higher in tongue lesions in presence of hyperglycemia than in absence of such condition; non-lesion portions of tongues exposed to carcinogen showed a similar trend. Moreover in carcinogen-treated groups, non-lesion and lesion portions of tongues under hyperglycemic condition showed predominantly membranous expression for GLUT1 which was again significantly higher than equivalent portions of tongue under normoglycemic condition. CONCLUSION: Hyperglycemia seemed to favor GLUT1 over-expression and membrane localization of the protein during oral carcinogenesis. GLUT1 transcript variant-1 appeared to be more important than variant-2 in disease pathogenesis.

Akt Phosphorylation Orchestrates T11TS Mediated Cell Cycle Arrest in Glioma Cells.

The novel anti-neoplastic glycopeptide T11TS retards glioma both in in-vitro clinical samples and in-vivo models. This study investigates the correlation between altering the glioma microenvironment with glioma arrest and death. Flow cytometry, immunoblotting, ELISA, and co-immunoprecipitation were employed to investigate glioma cell arrest and death. Results include a decline in phosphorylation of Akt and attenuation of p21 phosphorylation (Thr145,Ser146) and disassociation of p-Akt-Mdm2 and p-Akt-BAD facilitating death by Akt>BAD. T11TS influence phosphorylation patterns in two focal axes Akt>p21 and Akt>Mdm2>p53. The current article provides crucial insight in deciphering the mechanism of T11TS induced glioma cell arrest and death.

T11TS inhibits glioma angiogenesis by modulation of MMPs, TIMPs, with related integrin αv and TGF-ß1 expressions.

During glioma development, angiogenesis plays a crucial role in growth and vascularization of primary brain tumors. T11 target structure (T11TS), a bioactive molecule, has been documented as an anti-neoplastic agent in glioma-induced rats and also in human glioma in vitro. This novel molecule induces apoptosis of tumor cells by way of immune potentiation and impairs the glioma cell cycle, but its role in glioma angiogenesis has not been worked out in detail. Matrix metalloproteinases (MMPs) are enzymes promoting tumor angiogenesis by enzymatically remodeling the extracellular matrix and altering surface protein expression such as integrin αv and the matrix-bound proteins like TGF-ß1. The present study was formulated to assess the efficacy of T11TS in the modulations of MMP-2 and -9 and their endogenous inhibitors (TIMP-1 and TIMP-2) as well as modulations of integrin αv and TGF-ß1 in glioma-induced rats and also on the phenotypic markers of endothelial cells (CD31 and CD34). The parameters used were zymography, western blot, and flow cytometric analyses. It was observed that T11TS administration significantly downregulates the expression of matrix metalloproteinase-2 and -9 along with its ligand integrin αv and upregulates TIMP-1 and TIMP-2. In situ immunofluorescence and FACS results revealed that T11TS administration decreased the expression of the phenotypic markers (CD31/PECAM1, CD34), inhibiting the cell grip and also downregulating TGF-ß1 expression (ELISA) from microglia cells in the glioma microenvironment. These results suggest that T11TS suppresses the expression of positive angiogenic growth factors and potentiates the expression of negative regulators in glioma-associated endothelial cells (ECs), resulting in an anti-angiogenic effect on glioma-induced angiogenesis.

The novel immunotherapeutic molecule T11TS modulates glioma-induced changes of key components of the immunological synapse in favor of T cell activation and glioma abrogation.

T-cell-mediated immune responses are typically low in conditions of malignant glioma which has been known to cause marked immunesuppression and dysregulate major T-cell signaling molecules. Thus, T-cell-based immunotherapies are currently in vogue in the treatment of malignant glioma. The novel glycopeptide, T11TS/S-LFA-3/S-CD58 has previously been shown by our group to be highly efficacious in glioma abrogation in in vivo and in vitro conditions. This glycopeptide ligands to the costimulatory CD2 molecule on T-cells, causing profound immune stimulation leading to glioma abrogation, suggesting probable involvement of T11TS in modulation of the T-cell signaling pathway. The present study offers a multi-targeted approach towards repair of some of the key components of the immunological synapse at the T-cell-APC interface and is therefore the first of its kind to offer a holistic model of restoration of immunological synapse components so as to trigger T-cells towards activation against glioma. The study thus indicates that the totally dysregulated molecular events at the immunological synapse in glioma are restored back to normal levels with the administration of T11TS, which finally culminates in glioma abrogation. The present study thus delineates an important T-cell signaling approach whereby T11TS acts as an anti-neoplastic agent, thus helping to chart out newer avenues in the fight against gliomas.

Significant modulation of macrophages associated cytokines TNF-α, VEGF and apoptotoic protein Bax, Bcl2 abrogates tumor cells.

T11 target structure (T11TS), a membrane glycoprotein has been documented with anti neoplastic activity in glioma bearing animal model in our lab. In this study, we have evaluated the phagocytic potential, expression of VEGF, TNF-α in T11TS treated and untreated macrophages in all four grades of glioma. The data indicates the significant enhancement of phagocytosis in T11TS treated macrophages of grades I and II glioma. There was significant up regulation in TNF-α and significant down regulation in VEGF expression in T11TS treated macrophages in grade I and II glioma. We also attempted to know any possible apoptotic role of T11TS in tumor cells by comparing Bax and Bcl2 in treated and untreated tumor cells of all four grades. We found significant up regulation in Bax expression and down regulation in Bcl2 expression of grades I and II glioma. The outcome may help in pushing this molecule into pharmaceutical domain.

T11TS impedes glioma angiogenesis by inhibiting VEGF signaling and pro-survival PI3K/Akt/eNOS pathway with concomitant upregulation of PTEN in brain endothelial cells.

The crucial role of angiogenesis in malignant glioma progression makes it a potential target of therapeutic intervention in glioma. Previous studies from our lab showed that sheep erythrocyte membrane glycopeptide T11-target structure (T11TS) has potent anti-neoplastic and immune stimulatory effects in rodent glioma model. In the present study we investigated the anti-angiogenic potential of T11TS and deciphered the underlying molecular mechanism of its anti-angiogenic action in malignant glioma. Vascular endothelial growth factor (VEGF) signaling is crucial for initiating tumor angiogenic responses. The present preclinical study was designed to evaluate the effect of T11TS therapy on VEGF and VEGFR-2 expression in glioma associated brain endothelial cells and to determine the effects of in vivo T11TS administration on expression of PTEN and downstream pro-survival PI3K/Akt/eNOS pathway proteins in glioma associated brain endothelial cells. T11TS therapy in rodent glioma model significantly downregulated expression of VEGF along with its receptor VEGFR-2 and inhibited the expression of pro-survival PI3K/Akt/eNOS proteins in glioma associated brain endothelial cells. Furthermore, T11TS therapy in glioma induced rats significantly upregulated brain endothelial cell PTEN expression, inhibited eNOS phosphorylation and production of nitric oxide in glioma associated brain endothelial cells. Taken together our findings suggest that T11TS can be introduced as an effective angiogenesis inhibitor in human glioma as T11TS targets multiple levels of angiogenic signaling cascade impeding glioma neovascularisation.

Immunomodulatory role of TIITS in respect to cytotoxic lymphocytes in four grades of human glioma.

T11 target structure (T11TS), a membrane glycoprotein has been documented with antineoplastic activity in animal model in our lab. Previously, in animal study we have documented T11TS induced cytotoxic abrogation of tumor cells. Encouraged by these established findings by our group and as prerequisite for clinical trial, this study has been designed to assess the cytotoxic potential of the patient's lymphocytes in in vitro study of autologous human glioma as modulated by T11TS. Meningioma samples were chosen as disease control group. The data produced indicates T11TS induced up regulation of cytotoxicity of T lymphocytes in grade I and II glioma. Significant enhancement of cytotoxic protein, perforin and granzyme suggest cytotoxic death of T11TS induced target tumor. Also, T11TS downregulates the TGF-ß secretion in grade I and II tumor cells. These preliminary findings may help in pushing this molecule into pharmaceutical domain.

Comparative evaluation of T11 target structure and its deglycosylated derivative nullifies the importance of glycan moieties in immunotherapeutic efficacy.

Sheep red blood cell (SRBC), a non-specific biological response modifier that has long been used as a classical antigen, has been shown to exert an immunomodulatory and anti-tumor activities in experimental animals. The active component of SRBC, which is responsible for such effects, was found to be a cell surface acidic glycoprotein molecule, known as T11 target structure (T11TS). In the present study, T11TS was isolated and purified to homogeneity using a five-step protocol involving isolation of sheep erythrocyte membrane from packed cell volume, 20% ammonium sulfate cut of the crude membrane proteins mixture, immunoaffinity purification using mouse anti-sheep CD58 mAb (L180/1) tagged matrix, preparative gel electrophoresis, and gel electroelution process. Finally, the purity and identity of the proteins were confirmed by the matrix-assisted laser desorption/ionization (MALDI) mass spectrometric analysis. The in silico glycosylation site analysis showed that the extracellular domain contained three N-glycosylation sites (N-12, N-62, and N-111) and one O-glycosylation site (T-107). However, the experimental analysis negated the presence of O-linked glycan moieties on T11TS. To investigate the role of glycan moieties in the current immunotherapeutic regime, T11TS and its deglycosylated form (dT11TS) were administered intraperitoneally (i.p.) in N-ethyl-N-nitrosourea-induced immune-compromised mice at 0.4 mg/kg body weight. It was observed that both the forms of T11TS could activate the compromised immune status of mice by augmenting immune receptor expression (CD2, CD25, CD8, and CD11b), T-helper 1 shift of cytokine network, enhanced cytotoxicity, and phagocytosis activity. Therefore, the results nullify the active involvement of the N-linked glycan moieties in immunotherapeutic efficacy of T11TS.

Therapeutic intervention of glioma with the novel antineoplastic agent T11TS: the story so far.

The disease relevance of novel therapeutic agent T11TS, established first by the authors' group, was shown to ameliorate experimental glioma through multimodal mechanistic activities. T11TS reverses immunosuppression in glioma, causing profound effects on immune potentiation via peripheral, intracranial and hematopoietic cells. T-cell signaling in glioma is reversed by T11TS, modulating cytokine levels and favoring apoptotic killing of glioma cells. T11TS arrests the glioma cell cycle at the G1 phase via activation of p21. VEGF downregulation hypophosphorylates the Akt pathway. T11TS hinders endothelial cell progression and metastasis by arresting matrix degradation, inhibiting the Ras-Raf and Akt-PTEN pathways and initiating inflammatory changes, causing apoptosis. T11TS is effective against in vitro human glioma. Toxicity studies demonstrate that T11TS is nontoxic. The authors' study promise translational research with T11TS.

Glioma is a fatal brain tumor, and conventional treatments with surgery, radiotherapy, and chemotherapy often cause cancer recurrence. Therefore, newer strategies of treatment are being developed. In the authors' laboratory, a novel molecular approach with the biomolecule T11TS has been successfully applied in the eradication of glioma in an experimental rat model and on human samples. T11TS ameliorates glioma by various means, including immune augmentation and cytokine modulation; causes glioma cell death (apoptotic); halts the glioma cell cycle; and retards glioma blood vessel growth (antiangiogenic). T11TS is nontoxic. The author's study points to novel glioma therapy.

Induction of G1 arrest in glioma cells by T11TS is associated with upregulation of Cip1/Kip1 and concurrent downregulation of cyclin D (1 and 3).

In our laboratory, a novel therapeutic probe, T11TS, a membrane glycoprotein, was isolated which had antineoplastic activity against experimental glioma. Development of a novel therapeutic strategy with T11TS has unearthed a newer dimension of its mechanism of action: modulation of the cell cycle. In this study, we have presented evidence to support the finding that T11TS induces G1 cell cycle arrest of rat glioma cells. Results of flow cytometric studies showed that the treatment produced a marked increase in the proportion of cells in the G1 phase. Flow cytometry, immunoblotting, immunoprecipitation, and kinase assays were performed for investigating the involvement of G1 cell cycle regulators. T11TS induces downregulation of the cyclin-D (1 and 3) expression with the concurrent upregulation of p21 and p27 and their concomitant association with cyclin-dependent kinase 4, proliferating cell nuclear antigen and cyclin E respectively leading to a decrease in cyclin-dependent kinase 4 kinase activity. A transient rise in retinoblastoma protein level and coordinated binding of retinoblastoma protein with E2F coincided with the accumulation of cells in G1 phase. Thus, our observations have uncovered an antiproliferative pathway for T11TS, causing retardation of glioma cell cycle.

T11 target structure exerts effector function by activating immune cells in CNS against glioma where cytokine modulation provide favorable microenvironment.

Glycoprotein T 11 target structure (T11TS), derived from sheep erythrocyte membrane, directly interacts with T cells to activate them to enter in the brain. When untreated, glioma exerts an immune-suppressive environment in its vicinity by secreting prostaglandin E2 (PGE2), IL-10, tumor growth factor beta, gangliosides etc. to dampen the immune attack. But exogenous administration of T11TS reverses the situation to pro-inflammatory immune active state by expressing enhanced IL-12 and tumor necrosis factor alpha (TNF-alpha) production and suppression of IL-4 and IL-10 levels. The T11TS activated lymphocytic accumulation along the capillary endothelium in brain and their penetration in the matrix was evident from histological sections. IL-6 with TNF-alpha facilitates leukocyte migration to glioma site to exert cytotoxic effector function. Brain infiltrated lymphocytes offer cytotoxic proximity to neoplastic glial cells, which lead them to apoptosis. In the Th1 dominated microenvironment microglial cells was found with enhanced phagocytic functions. Initially infiltrated lymphocytes with microglia showed increased production of TNF-alpha, interferon gamma (IFN-gamma) to facilitate their effector actions. Repeated dosing of T11TS shows glioma abrogation in rat model, but also a resurgence of anti-inflammatory cytokine environment found with increased IL-4, IL-10 and decreased IL-12, IL-6, TNF-alpha. This is a unique homeostatic regulation of total immune system after T11TS mediated carnage of glioma. The resultant balance of cytokines between interacting glioma cells, T cells and microglia in T11TS induced condition determines the success of its immunotherapeutic effect in glioma.

Therapeutic profile of T11TS vs. T11TS+MiADMSA: a hunt for a more effective therapeutic regimen for arsenic exposure.

Arsenic exposure is a serious health hazard worldwide. We have previously established that it may result in immune suppression by upregulating Th2 cytokines while downregulating Th1 cytokines and causing lymphocytic death. Treatment modalities for arsenic poisoning have mainly been restricted to the use of chelating agents in the past. Only recently have combination therapies using a chelating agent in conjunction with other compounds such as anti-oxidants, micronutrients and various plant products, been introduced. In the present study, we used T11TS, a novel immune potentiating glycopeptide alone and in combination with the sulfhydryl-containing chelator, mono-iso-amyl-dimarcaptosuccinic acid (MiADMSA) as a therapeutic regimen to combat arsenic toxicity in a mouse model. Results indicated that Th1 cytokines such as TNF-α, IFNγ, IL12 and the Th2 cytokines such as IL4, IL6, IL10 which were respectively downregulated and upregulated following arsenic induction were more efficiently restored to their near normal levels by T11TS alone in comparison with the combined regimen. Similar results were obtained with the apoptotic proteins studied, FasL, BAX, BCL2 and the caspases 3, 8 and 9, where again T11TS proved more potent than in combination with MiADMSA in preventing lymphocyte death. The results thus indicate that T11TS alone is more efficient in immune re-establishment after arsenic exposureas compared to combination therapy with T11TS+MiADMSA.

Immunological profile of arsenic toxicity: a hint towards arsenic-induced carcinogenesis.

Arsenic (a Group I carcinogen in humans) contamination and poisoning of human populations in different parts of Southeast and Eastern Asia, including West Bengal and Bangladesh, has become a major environmental concern. Arsenic intoxication affects diverse human organs including the lungs, liver, skin, bladder and kidney. This metalloid acts as a promoter of carcinogenesis, exerting toxic effects on the immune system. The present study was aimed at investigating arsenic-induced carcinogenesis and effects on the immune system in an animal model. Tumors were induced using ethylnitrosourea (ENU) and arsenic was used as a promoter. To investigate specific effects on the immune system, cytokine (TNF-α, IFNγ, IL4, IL6, IL10, IL12) production of lymphocytes was evaluated by FACS. The damaging consequences of treatment were assessed by evaluating the specific programmed cell death cascade in lymphocytes, assessed by FACS readings. The results revealed that under arsenic influence, and more so with arsenic+ENU, marked neoplastic changes were noted, which were corroborated with histological changes, cytokine modulation and apoptosis hinted at marked neoplastic changes.