GLUT1 as a therapeutic target in hepatocellular carcinoma

Mutant BRAF induces DNA strand breaks, activates DNA damage response pathway, and up-regulates glucose transporter-1 in nontransformed epithelial cells

Although the oncogenic functions of activating BRAF mutations have been clearly demonstrated in human cancer, their roles in nontransformed epithelial cells remain largely unclear. Investigating the cellular response to the expression of mutant BRAF in nontransformed epithelial cells is fundamental to the understanding of the roles of BRAF in cancer pathogenesis. In this study, we used two nontransformed cyst108 and RK3E epithelial cell lines as models in which to compare the phenotypes of cells expressing BRAF(WT) and BRAF(V600E). We found that transfection of the BRAF(V600E), but not the BRAF(WT), expression vector suppressed cellular proliferation and induced apoptosis in both cell types. BRAF(V600E) generated reactive oxygen species, induced DNA double-strand breaks, and caused subsequent DNA damage response as evidenced by an increased number of pCHK2 and γH2AX nuclear foci as well as the up-regulation of pCHK2, p53, and p21. Because BRAF and KRAS (alias Ki-ras) mutations have been correlated with GLUT1 up-regulation, which encodes glucose transporter-1, we demonstrated here that expression of BRAF(V600E), but not BRAF(WT), was sufficient to up-regulate GLUT1. Taken together, our findings provide new insights into mutant BRAF-induced oncogenic stress that is manifested by DNA damage and growth arrest by activating the pCHK2-p53-p21 pathway in nontransformed cells, while it also confers tumor-promoting phenotypes such as the up-regulation of GLUT1 that contributes to enhanced glucose metabolism that characterizes tumor cells.

Liverome: a curated database of liver cancer-related gene signatures with self-contained context information

Background

Hepatocellular carcinoma (HCC) is the fifth most common cancer worldwide. A number of molecular profiling studies have investigated the changes in gene and protein expression that are associated with various clinicopathological characteristics of HCC and generated a wealth of scattered information, usually in the form of gene signature tables. A database of the published HCC gene signatures would be useful to liver cancer researchers seeking to retrieve existing differential expression information on a candidate gene and to make comparisons between signatures for prioritization of common genes. A challenge in constructing such database is that a direct import of the signatures as appeared in articles would lead to a loss or ambiguity of their context information that is essential for a correct biological interpretation of a gene’s expression change. This challenge arises because designation of compared sample groups is most often abbreviated, ad hoc, or even missing from published signature tables. Without manual curation, the context information becomes lost, leading to uninformative database contents. Although several databases of gene signatures are available, none of them contains informative form of signatures nor shows comprehensive coverage on liver cancer. Thus we constructed Liverome, a curated database of liver cancer-related gene signatures with self-contained context information.

Description

Liverome’s data coverage is more than three times larger than any other signature database, consisting of 143 signatures taken from 98 HCC studies, mostly microarray and proteome, and involving 6,927 genes. The signatures were post-processed into an informative and uniform representation and annotated with an itemized summary so that all context information is unambiguously self-contained within the database. The signatures were further informatively named and meaningfully organized according to ten functional categories for guided browsing. Its web interface enables a straightforward retrieval of known differential expression information on a query gene and a comparison of signatures to prioritize common genes. The utility of Liverome-collected data is shown by case studies in which useful biological insights on HCC are produced.

Conclusion

Liverome database provides a comprehensive collection of well-curated HCC gene signatures and straightforward interfaces for gene search and signature comparison as well. Liverome is available at http://liverome.kobic.re.kr.

Involvement of mitophagy in oncogenic K-Ras-induced transformation: overcoming a cellular energy deficit from glucose deficiency

Although mitochondrial impairment has often been implicated in carcinogenesis, the mechanisms of its development in cancer remain unknown. We report here that autophagy triggered by oncogenic K-Ras mediates functional loss of mitochondria during cell transformation to overcome an energy deficit resulting from glucose deficiency. When Rat2 cells were infected with a retrovirus harboring constitutively active K-Ras (V12) , mitochondrial respiration significantly declined in parallel with the acquisition of transformation characteristics. Decreased respiration was not related to mitochondrial biogenesis but was inversely associated with the increased formation of acidic vesicles enclosing mitochondria, during which autophagy-related proteins such as Beclin 1, Atg5, LC3-II and vacuolar ATPases were induced. Interestingly, blocking autophagy with conventional inhibitors (bafilomycin A, 3-methyladenin) and siRNA-mediated knockdown of autophagy-related genes recovered respiratory protein expression and respiratory activity; JNK was involved in these phenomena as an upstream regulator. The cells transformed by K-Ras (V12) maintained cellular ATP level mainly through glycolytic ATP production without induction of GLUT1, the low Km glucose transporter. Finally, K-Ras (V12) -triggered LC3-II formation was modulated by extracellular glucose levels, and LC3-II formation increased only in hepatocellular carcinoma tissues exhibiting low glucose uptake and increased K-Ras expression. Taken together, our observations suggest that mitochondrial functional loss may be mediated by oncogenic K-Ras-induced mitophagy during early tumorigenesis even in the absence of hypoxia, and that this mitophagic process may be an important strategy to overcome the cellular energy deficit triggered by insufficient glucose.

Exercise training prevents endometrial hyperplasia and biomarkers for endometrial cancer in rat model of type 1 diabetes

Background

Endometrial cancer is one of the most common types of gynecologic cancers. The ability of exercise to reduce the risk of endometrial cancer in women with type 2 diabetes has been established, but no studies have examined this link in type 1 diabetes.A randomized, controlled animal study was designed using a standard rat model of type 1 diabetes. The goal of this study was to investigate the ability of exercise to prevent increased levels of endometrial cancer biomarkers, estrogen receptor (ERα) and p16, and endometrial hyperplasia associated with diabetes.

Methods

Forty female rats were randomized into four groups: sedentary control, exercise control, sedentary or exercised diabetic. Diabetes was induced by alloxan injection. A 4-week treadmill training program was initiated with the development of diabetes. Endometrial tissues were evaluated for hyperplasia and ERα and p16 levels and subcellular localization using microscopy.

Results

Severe diabetes lead to hyperplasia in the endometrial tissue in 70% of sedentary diabetic rats. Exercise-trained diabetic rats and the non-diabetic rats displayed no hyperplasia. The expression of ERα increased significantly (p < 0.02) while the expression level of p16 decreased significantly (p < 0.04) in the diabetic sedentary group compared to the non-diabetic groups. Exercise training led to a reversal in the percentage of p16 and ERα positive cells in diabetic rats.

Conclusions

Severe diabetes leads to hyperplasia of the endometrial tissue and increased ERα levels and decreased p16 levels in rats, which can be prevented with aerobic exercise.

Keywords

Diabetes; Estrogen receptor alpha; P16; Endometrial hyperplasia; Endometrial cancer; Exercise

Expression of hypoxia inducible factor-1α and its significance in laryngeal carcinoma

This study examined levels of hypoxia inducible factor-1α (HIF-1α) protein in 40 laryngeal squamous cell carcinoma specimens using immunohistochemistry. Correlations between HIF-1α immunoreactivity and patient age, tumour lymph node metastasis stage, histological grade (extent of differentiation), and alcohol and smoking history were evaluated. Of the tumour tissues obtained, 35 (87.5%) were located in the glottic area and five (12.5%) in the supraglottic area. All patients were male and aged between 35 and 71 years; 12 (30.0%) presented with lymph node metastases, 24 (60.0%) had cancer classified as T(1) or T(2), and 16 (40.0%) as high clinical stage (T(3) or T(4)). The pattern of HIF-1α protein localization in tumour tissues, when present, was mixed nuclear/cytoplasmic, with positive HIF-1α expression in 27 patients (67.5%). Differences in HIF-1α levels in samples from different tumour stages and in those with lymph node-positive versus lymph node-negative cancers were statistically significant.

Glucose transporter-1 as a new therapeutic target in laryngeal carcinoma

Treatment options for laryngeal carcinoma, one of the most common head and neck malignancies, consist of radiotherapy, surgery, chemotherapy or a combination thereof. The functional treatment of laryngeal carcinoma poses a considerable challenge because of its resistance to chemotherapy and radiotherapy, and its tendency for local recurrence. Finding ways to inhibit the energy supply of malignant tumours is becoming an increasingly attractive proposition. Glucose transporter-1 (Glut-1; encoded by the SLC2A1 gene in humans) is the main transporter of glucose in solid carcinomas and has become a focus of cancer research. Recently, it was shown that the increased expression of SLC2A1 in head and neck carcinomas is correlated with lymph node metastasis, poor survival and clinical stage, and revealed that the suppression of SLC2A1 expression by antisense oligodeoxynucleotides decreased glucose uptake and inhibited the proliferation of Hep-2 cells. Thus, the authors propose the suppression of SLC2A1 expression as a new therapeutic target for laryngeal carcinoma.

Analysis of a promoter polymorphism of the GLUT1 gene in patients with hepatocellular carcinoma

The glucose transporter isoform 1 (GLUT1) is a key rate-limiting factor in the transport and metabolism of glucose in cancer cells. Recently, we found that GLUT1 expression is increased in hepatocellular carcinoma (HCC) and promotes tumorigenicity of HCC cells. Hypoxia further increased GLUT1 expression in HCC cells, and this induction was dependent on the activation of the transcription factor hypoxia-inducible factor (HIF)-1alpha. The promoter region of the GLUT1 gene harbors a single nucleotide polymorphism (SNP; Rs710218; A to T at -2841) closely positioned to a putative HIF-1alpha binding site, and recently, this SNP was found to be more frequent in patients with renal cell carcinoma. In the present study, the A-2841T genotype distribution did not differ significantly between HCC patients (n = 95; AA: 60%; AT 36% and TT: 4%) and healthy controls (n = 127; AA: 50%; AT 41% and TT: 9%). However and noteworthy, non-carriers of the T allele had higher GLUT1 expression levels in cancerous hepatic tissue, and tended to reveal a more aggressive tumour growth. These data indicate that the SNP Rs710218 is not associated with a higher risk for HCC but rather for HCC progression, potentially via HIF-1alpha mediated increased GLUT1 expression.

Effects of suppressing glucose transporter-1 by an antisense oligodeoxynucleotide on the growth of human hepatocellular carcinoma cells

BACKGROUND

The glucose transporter-1 (Glut-1), a key rate-limiting factor in the transport and metabolism of glucose in cancer cells, is over-expressed in many human cancer cells and this over-expression is correlated with poor biological behavior. The increased levels of Glut-1 expression in hepatocellular carcinoma (HCC) cells functionally affect tumorigenicity. This study was undertaken to investigate effects of suppressing Glut-1 by an antisense oligodeoxynucleotide (AS-ODN) on the growth of human hepatocellular carcinoma (HepG-2) cells.

METHODS

We used AS-ODN targeting against the Glut-1 gene in a HepG-2 cell line. There were four experimental groups: empty pcDNA3.1 vector (mock transfection), pcDNA3.1-anti-Glut (+), pcDNA3.1-Glut (+), and non-transfected HepG-2 cells. The Glut-1 mRNA expression was detected by RT-PCR and the Glut-1 protein expression by Western blotting after cell culture, and the glucose uptake was detected after glucose stimulation in each group.

RESULTS

Compared with non-transfected HepG-2 or Glut-1 pcDNA3.1, a down-regulation of Glut-1 mRNA in HepG-2 cells transfected with anti-Glut-1 pcDNA3.1 was noted (P<0.05). Glut-1 protein in HepG-2 cells transfected with Glut-1 AS-ODN was decreased compared with non-transfected HepG-2, Glut-1 pcDNA3.1, or empty vectors. Glucose uptake by the HepG-2 cells transfected with AS-ODN was decreased at 1 hour after glucose stimulation.

CONCLUSIONS

The application of Glut-1 AS-ODN can down-regulate the expression of Glut-1 at mRNA and protein, and inhibit glucose uptake partially in HepG-2 cells. The Glut-1 gene maybe a potential therapeutic target for HCC.

Down-regulation of methylthioadenosine phosphorylase (MTAP) induces progression of hepatocellular carcinoma via accumulation of 5'-deoxy-5'-methylthioadenosine (MTA)

Recently, we have shown that down-regulation of methylthioadenosine phosphorylase (MTAP) in hepatocellular carcinoma (HCC) cells enhances the invasive potential and the resistance against cytokines. Here, we aimed at investigating the molecular mechanism underlying this tumor-promoting effect and expanded the analysis to a large series of human HCC tissues. Liquid chromatography tandem mass spectrometry revealed that reduced MTAP expression resulted in higher intra- and extracellular concentrations of 5'-deoxy-5'-methylthioadenosine (MTA) in cultivated HCC cells and, concordantly, higher levels of MTA in HCC tissue. MTA induced matrix metalloproteinase (MMP) and interleukin-8 transcription in HCC cells in vitro, accompanied by enhanced proliferation and activation of the transcription factor NFκB. In addition, MTA secreted by HCC cells induced expression of fibroblast growth factor-2 and MMP1 in stromal myofibroblasts. In human HCC tissues, MTAP mRNA correlated inversely with MTA levels, and immunohistochemical analysis of a tissue microarray of 140 human HCCs revealed that low MTAP protein expression correlated with advanced tumor stages. In conclusion, MTAP deficiency results in accumulation of MTA, which is associated with increased tumorigenicity. These data further indicate MTAP as a tumor suppressor in HCC, and MTA as a potential biomarker for HCC progression.

TSdb: a database of transporter substrates linking metabolic pathways and transporter systems on a genome scale via their shared substrates

TSdb ( http://tsdb.cbi.pku.edu.cn ) is the first manually curated central repository that stores formatted information on the substrates of transporters. In total, 37608 transporters with 15075 substrates from 884 organisms were curated from UniProt functional annotation. A unique feature of TSdb is that all the substrates are mapped to identifiers from the KEGG Ligand compound database. Thus, TSdb links current metabolic pathway schema with compound transporter systems via the shared compounds in the pathways. Furthermore, all the transporter substrates in TSdb are classified according to their biochemical properties, biological roles and subcellular localizations. In addition to the functional annotation of transporters, extensive compound annotation that includes inhibitor information from the KEGG Ligand and BRENDA databases has been integrated, making TSdb a useful source for the discovery of potential inhibitory mechanisms linking transporter substrates and metabolic enzymes. User-friendly web interfaces are designed for easy access, query and download of the data. Text and BLAST searches against all transporters in the database are provided. We will regularly update the substrate data with evidence from new publications.

GLUT1 expression in malignant tumors and its use as an immunodiagnostic marker

OBJECTIVE

To analyze glucose transporter 1 expression patterns in malignant tumors of various cell types and evaluate their diagnostic value by immunohistochemistry.

INTRODUCTION

Glucose is the major source of energy for cells, and glucose transporter 1 is the most common glucose transporter in humans. Glucose transporter 1 is aberrantly expressed in several tumor types. Studies have implicated glucose transporter 1 expression as a prognostic and diagnostic marker in tumors, primarily in conjunction with positron emission tomography scan data.

METHODS

Immunohistochemistry for glucose transporter 1 was performed in tissue microarray slides, comprising 1955 samples of malignant neoplasm from different cell types.

RESULTS

Sarcomas, lymphomas, melanomas and hepatoblastomas did not express glucose transporter 1. Forty-seven per cent of prostate adenocarcinomas were positive, as were 29% of thyroid, 10% of gastric and 5% of breast adenocarcinomas. Thirty-six per cent of squamous cell carcinomas of the head and neck were positive, as were 42% of uterine cervix squamous cell carcinomas. Glioblastomas and retinoblastomas showed membranous glucose transporter 1 staining in 18.6% and 9.4% of all cases, respectively. Squamous cell carcinomas displayed membranous expression, whereas adenocarcinomas showed cytoplasmic glucose transporter 1 expression.

CONCLUSION

Glucose transporter 1 showed variable expression in various tumor types. Its absence in sarcomas, melanomas, hepatoblastomas and lymphomas suggests that other glucose transporters mediate the glycolytic pathway in these tumors. The data suggest that glucose transporter 1 is a valuable immunohistochemical marker that can be used to identify patients for evaluation by positron emission tomography scan. The function of cytoplasmic glucose transporter 1 in adenocarcinomas must be further examined.