Share this post on:

Tly worse for patients withHexokinase and Choline Kinase in Liver CancerHK2-positive tumors relative to patients with HK2-negative tumors (Log-Rank test p = 0.003). C) Among stage I and II HCC patients, OS was significantly worse for patients with CKA-positive tumors relative to patients with CKA-negative tumors (Log-rank p = 0.03). D) Among stage I and II HCC patients, OS was also significantly worse for patients with HK2-positive tumors relative to patients with HK2-negative tumors (Log-rank p = 0.02). E) Among patients with HK2-negative tumors, OS did not differ significantly on the basis of CKA expression (Log-Rank test p = 0.53). F) Among patients with HK2-positive tumors, OS was significantly worse in patients whose tumors were also CKA-positive (Log-Rank test p = 0.04). G) Among patients with CKA-negative tumors, OS did not differ significantly on the basis of HK2 expression (Log-Rank test p = 0.35). H) Among patients with CKA-positive tumors, OS was significantly worse in patients whose tumors were also HK2-positive (Log-Rank test p = 0.01). doi:10.1371/journal.pone.0046591.gimaging studies involving viral-induced woodchuck hepatomas suggest glycolytic activity to vary among liver tumors in association with the levels of HK2 activity [12]. In other cancers, expression of HK2 has been strongly associated with increased tumor biologic aggressiveness [27?9]. An association between HK2 expression, cancer stage, and survival found in the current study might therefore suggest that abnormal get JSI-124 glycolysis is a feature of biologically aggressive tumors in HCC. The tendency for malignant tumors to exhibit increased glycolytic activity under conditions suitable for oxidative phosphorylation, a phenomenon known as the Warburg effect, has been hypothesized to confer tumor cells with a survival advantage [2]. Specifically, glycolysis produces lactate, which may not only increase tumor antioxidative capacity but also 15755315 reduce extracellular pH that in turn can expedite extracellular matrix remodeling, dampen host defenses, and facilitate tumor invasion and metastasis. In conditions of low oxygen tension, hypoxia-indicuble factor-1 alpha (HIF-1) has also been shown to upregulate HK2 expression and stimulate the proliferation of hepatoma cells [30]. Co-expression of HIF-1 and HK2 has also been found to disproportionately localize in the central portions of hepatomas as well as to areas surrounding tumoral necrosis [31,32]. Altogether, these results implicate glycolysis in the adaptation of liver tumors to a hostile stromal Fexinidazole environment. The role of glycolysis in sustaining tumor progression may therefore underly the association between tumor HK2 expression and patient mortality observed in the current study. Currently, FDG PET is the only method available for noninvasively measuring tissue glycolysis in-vivo. Tumor FDG uptake on PET has been correlated with risk of tumor recurrence in patients undergoing hepatic resection for HCC [14,33,34]. Tumor FDG uptake has also been shown to predict recurrence-free survival in patients undergoing liver transplantation for HCC [35]. Furthermore, HCC tumor differentiation has been shown to correlate with tumor FDG uptake [34]. The association of tumor HK2 expression with HCC grade, stage, and overall survival in the current study helps to explain the results of these clinical FDG PET studies, given that the cellular retention of FDG is mediated by HK2. Tumor CK expression was also significantly associated with less.Tly worse for patients withHexokinase and Choline Kinase in Liver CancerHK2-positive tumors relative to patients with HK2-negative tumors (Log-Rank test p = 0.003). C) Among stage I and II HCC patients, OS was significantly worse for patients with CKA-positive tumors relative to patients with CKA-negative tumors (Log-rank p = 0.03). D) Among stage I and II HCC patients, OS was also significantly worse for patients with HK2-positive tumors relative to patients with HK2-negative tumors (Log-rank p = 0.02). E) Among patients with HK2-negative tumors, OS did not differ significantly on the basis of CKA expression (Log-Rank test p = 0.53). F) Among patients with HK2-positive tumors, OS was significantly worse in patients whose tumors were also CKA-positive (Log-Rank test p = 0.04). G) Among patients with CKA-negative tumors, OS did not differ significantly on the basis of HK2 expression (Log-Rank test p = 0.35). H) Among patients with CKA-positive tumors, OS was significantly worse in patients whose tumors were also HK2-positive (Log-Rank test p = 0.01). doi:10.1371/journal.pone.0046591.gimaging studies involving viral-induced woodchuck hepatomas suggest glycolytic activity to vary among liver tumors in association with the levels of HK2 activity [12]. In other cancers, expression of HK2 has been strongly associated with increased tumor biologic aggressiveness [27?9]. An association between HK2 expression, cancer stage, and survival found in the current study might therefore suggest that abnormal glycolysis is a feature of biologically aggressive tumors in HCC. The tendency for malignant tumors to exhibit increased glycolytic activity under conditions suitable for oxidative phosphorylation, a phenomenon known as the Warburg effect, has been hypothesized to confer tumor cells with a survival advantage [2]. Specifically, glycolysis produces lactate, which may not only increase tumor antioxidative capacity but also 15755315 reduce extracellular pH that in turn can expedite extracellular matrix remodeling, dampen host defenses, and facilitate tumor invasion and metastasis. In conditions of low oxygen tension, hypoxia-indicuble factor-1 alpha (HIF-1) has also been shown to upregulate HK2 expression and stimulate the proliferation of hepatoma cells [30]. Co-expression of HIF-1 and HK2 has also been found to disproportionately localize in the central portions of hepatomas as well as to areas surrounding tumoral necrosis [31,32]. Altogether, these results implicate glycolysis in the adaptation of liver tumors to a hostile stromal environment. The role of glycolysis in sustaining tumor progression may therefore underly the association between tumor HK2 expression and patient mortality observed in the current study. Currently, FDG PET is the only method available for noninvasively measuring tissue glycolysis in-vivo. Tumor FDG uptake on PET has been correlated with risk of tumor recurrence in patients undergoing hepatic resection for HCC [14,33,34]. Tumor FDG uptake has also been shown to predict recurrence-free survival in patients undergoing liver transplantation for HCC [35]. Furthermore, HCC tumor differentiation has been shown to correlate with tumor FDG uptake [34]. The association of tumor HK2 expression with HCC grade, stage, and overall survival in the current study helps to explain the results of these clinical FDG PET studies, given that the cellular retention of FDG is mediated by HK2. Tumor CK expression was also significantly associated with less.

Share this post on: