A Combined Proteomics and Metabolomics Profiling of Gastric Cardia Cancer Reveals Characteristic Dysregulations in Glucose Metabolism*

Gastric cardia cancer (GCC), which occurs at the gastric-esophageal boundary, is one of the most malignant tumors. Despite its high mortality and morbidity, the molecular mechanism of initiation and progression of this disease is largely unknown. In this study, using proteomics and metabolomics approaches, we found that the level of several enzymes and their related metabolic intermediates involved in glucose metabolism were deregulated in GCC. Among these enzymes, two subunits controlling pyruvic acid efflux, lactate dehydrogenase A (LDHA) and pyruvate dehydrogenase B (PDHB), were further analyzed in vitro. Either down-regulation of LDH subunit LDHA or overexpression of PDH subunit PDHB could force pyruvic acid into the Krebs cycle rather than the glycolysis process in AGS gastric cancer cells, which inhibited cell growth and cell migration. Our results reflect an important glucose metabolic signature, especially the dysregulation of pyruvic acid efflux in the development of GCC. Forced transition from glycolysis to the Krebs cycle had an inhibitory effect on GCC progression, providing potential therapeutic targets for this disease.

Despite the steadily falling incidence of gastric non-cardia cancer in the past two decades (1), the rate of GCC has risen rapidly, establishing gastric cancer as the second major cause of cancer-related deaths throughout the world (2). GCC has become a significant cause of mortality and morbidity both in the west (3)(4)(5) and in Asia (6,7), especially in China (8). Although this cancer has become an important health problem worldwide, the its pathogenesis has not been well characterized (1). Most patients are diagnosed at an advanced stage, contributing to the high mortality rate of the disease.
Systematic proteomics analysis has proved to be a powerful approach in a variety of human cancer research, including lung (9), esophagus (10), gastric (11), liver (12), breast (13), and brain cancer (14). Metabolomics, another new bio-omics technology recently introduced into cancer research (15), is the global analysis of the small metabolites produced by normal or pathologic cellular processes. Some metabolic intermediates have been identified as new cancer biomarkers (16).
Using proteomics and metabolomics methods in this study, we found that a series of proteins and metabolic intermediates, mainly involved in glucose metabolism, were altered during the development of GCC. The high activity of anaerobic glycolysis and the impairment of aerobic respiration occurring in these cells recapitulated the Warburg effect (17). Further studies using a gastric cancer cell line demonstrated that the predominant anaerobic glycolysis was essential for tumor cells to sustain rapid proliferation, whereas forced transition from anaerobic glycolysis to aerobic respiration inhibited the growth of tumor cells. In conclusion, our study revealed the major metabolic alterations essential for the development of GCC and discovered a biomarker signature of GCC. Such a finding has the potential to improve early diagnosis and prognosis and helps to identify new therapeutic targets.

MATERIALS AND METHODS
Patients-All GCC tissues and corresponding non-cancerous gastric cardia tissues were obtained from patients treated at the First Affiliated Hospital of Zhengzhou University (Henan, China) with written consent from the patients. Our study was approved by the Ethics Committee Board of Zhengzhou University. TNM classification, according to the criteria of the American Joint Committee on Cancer and the International Union against Cancer, was used by pathologists to stage the tumors (18). The corresponding non-cancerous tissues were resected 5 cm away from the cancer tissues from the same patient. All the samples were quickly frozen by liquid nitrogen and then kept at Ϫ80°C. The basic histopathologic variables are summarized in Table I.
Proteomics Analysis-Five pairs of matched samples, randomly selected and mixed according to their differentiation level or lymph node metastasis status, were crushed and dissolved in lysis buffer (7 M urea, 2 M thiourea, 4% CHAPS, 0.5% IPG buffer, 3-10 NL, 0.5% Triton) containing protease inhibitor mixture. The process of twodimensional gel separation and protein identification was carried out as described previously (10). The peptides were generated by trypsin. Keratin and trypsin peptide peaks were excluded from analysis. Both ESI-TOF and MS/MS spectra were processed by Analysis QS 1.1 Build 9865 (Applied Biosystems) and were searched using Mascot 1.6b13 (Matrix Science). All spectra were searched against the mass spectrometry protein sequence database (MSDB) from the National Center for Biotechnology Information (release date, September 8, 2006; including 3,239,079 sequences). The following parameters were used for the searches: one missed and/or nonspecific cleavage permitted; mass tolerance for precursor ions, Ϯ0.2 Da; mass tolerance for fragment ions, Ϯ0.5 Da; MS/MS filtering: reject spectra if less than 10 peaks or precursor Ͻ50 or precursor Ͼ10,000. Probabilitybased Mowse score was used as the tool to determine whether the hit was a random event.
Metabolite Profiling-50 mg of tissue samples were pulverized after being frozen in liquid nitrogen with the addition of 250 l of mixed solvent (chloroform:methanol:water, 1:2:1, v/v/v). The lysate was ultrasonicated for 1 min and centrifuged at 12,000 rpm for 10 min. A total of 150 l of aqueous supernatant was transferred to a GC vial containing two internal standards, L-2-chlorophenylalanine (10 l, 0.3 mg/ml) and heptadecanoic acid (10 l, 1.0 mg/ml). The deposit was rehomogenized with a T10 basic homogenizer (IKA, Staufen, Germany) for 30 s at 0°C after adding 250 l of methanol. After a second centrifugation, another 150-l aliquot of supernatant was added to the mixture in the GC vial and vacuum-dried. Following the derivatization process, GC-TOF MS spectral acquisition and data analysis were performed according to the procedure described previously (19) with some modifications. Details of the method are provided in the supplemental material.
RNA Isolation and Real Time PCR-Total RNA was extracted from GCC specimens and their matched normal counterparts using TRIzol according to the standard protocol. 2 g of RNA were processed directly to cDNA using a reverse transcription kit (Promega, Madison, WI) according to the manufacturer's instructions. Amplification reactions were performed in a 15-l volume with 0.2 l of SYBR Green. All of the reactions were performed in triplicate using an iCycler iQ System (Bio-Rad). To confirm the specificity of amplification, PCR products from each primer pair were subjected to a melting curve analysis and subjected to electrophoresis using a 2% agarose gel. POLR2A was used as an internal control for normalization. The relative gene expression level of each pair of GCC samples was calculated as described previously (20). The primers used in the experiments are listed in Table II.
Cell Culture-Gastric cancer cell line AGS was obtained from the Cell Bank of Type Culture Collection of the Chinese Academy of Sciences (Shanghai Institute of Cell Biology, Chinese Academy of Sciences) and cultured in RPMI 1640 medium (Invitrogen) supplemented with 10% fetal bovine serum and 10 units/ml penicillin-G at 37°C in a humidified atmosphere containing 5% CO 2 .
Establishment of AGS/Pyruvate Dehydrogenase B (PDHB) Stable Cell Line-The pcDNA3.1-PDHB and pcDNA3.1 plasmids were transfected into AGS cells using FuGENE reagent. The transfected cells were selected in the presence of G418 (800 g/ml), and after 2 weeks of selection, single clones were isolated for further analysis.
RNA Interference of LDHA-Target sequences of small interfering RNA (siRNA) for LDHA as well as a randomly aligned sequence used as negative control are listed in supplemental Table S1. FG12 lentiviral vector was used to produce double-stranded siRNA to inhibit LDHA expression in AGS cells; the information and usage of this vector system have been described previously (21).
High Performance Liquid Chromatography Analysis of Lactic Acid-Supernatants and cell lysis, respectively, were collected after the cells were grown for 2 days. Three volumes of methanol were added to remove protein from the samples above. After centrifugation and filtration through 0.22-m PVDF membrane, a 20-l aliquot of supernatant was injected into an Agilent 1100 instrument. Separation was achieved on an Agilent Zorbax Extend C 18 column (4.6 ϫ 250 mm, 5 m) with phosphate buffer (100 mM NaH 2 PO 4 in 0.01 M H 3 PO 4 , pH 2.5) containing 5% acetonitrile as the mobile phase at a constant MTT and Soft Agar Assay-For cell growth analysis, equal numbers of cells were seeded in 48-well plates. Cell numbers were measured by MTT assay according to the manufacturer's protocol (Roche Applied Science) every 2 days. For the clonogenic assay, cells were plated into 24-well, flat bottom plates using a two-layer soft agar system with 2000 cells/well in a volume of 400 l/well as described previously (22). After 7 days of incubation, the colonies were counted and measured.
Statistical Analysis-SPSS 13.0 for Windows was used for statistical analysis, and data are expressed as mean Ϯ S.E. Statistically significant differences were determined by Student's t test, one-way analysis of variance, and bivariate correlation analysis where appropriate and defined as p Ͻ 0.05 (*) and p Ͻ 0.01 (**).

RESULTS
Proteomics Analysis of GCC-To identify proteins involved in either initiation or progression of GCC, protein expression profiles were compared between pooled cancer and corresponding normal tissues, which were mixed according to the status of either tumor differentiation or lymph node metastasis. After two-dimensional gel separation and subsequent profile analysis, we identified a series of proteins with changes in their expression level (Fig. 1, A-D). ENO1 and LDHB were two representative spots on the gels indicating different intensity between cancer tissues and their corresponding normal counterparts ( Fig. 1E and supplemental Fig. S1). Our results identified 44 protein spots produced by 38 genes whose expression showed an association with the degree of tumor differentiation. Furthermore, 29 protein products of 25 genes were differentially expressed during the process of tumor metastasis (Table III and supplemental Table S2). The expression of 17 proteins from 15 genes was closely related to the status of both tumor dedifferentiation and tumor metastasis, indicating that these proteins play important roles in tumor progression and providing new candidates for early disease detection and prediction. These differentially expressed proteins participate in a variety of cellular functions, which could be classified into seven categories: cytoskeletal organization, cell proliferation, apoptosis, signal transduction, protein chaperone, metabolic enzymes, and proteins with other functions.
Metabolite Profiling of GCC-Alterations of metabolic enzymes were the prominently detected major changes in the proteomics analysis. These changes spanned from lipids to amino acids, especially glucose metabolism, suggesting that the tumor cells had acquired totally different metabolite profiles compared with their normal cellular counterparts. The metabolite profiles of 40 paired GCC samples underwent further analysis to identify the metabolic intermediates showing changes consistent with the related enzymes.
Typical GC-TOF MS methods were used to analyze the samples from both GCC and normal tissues ( Fig. 2A), and in total, 223 variables were introduced to the subsequent analysis. The OPLS-DA model provided optimal modeling and predictive abilities with one predictive component and two orthogonal components (R 2 Y cum Ͼ 0.875, Q 2 cum Ͼ 0.7), achieving a distinct separation between the metabolite profiles of the two groups ( Fig. 2B and supplemental Fig. S2). Significant differences were confirmed in a total of 44 metabolites involved in the metabolism of glucose, lipid, amino acids, nucleic acids, and vitamins. As shown in supplemental Table S3, 30 metabolites were up-regulated in cancer tissues, whereas 14 were down-regulated compared with their matched normal tissues.
Unique Glucose Metabolism in GCC-As revealed by proteomics analysis, 11 glucose metabolic enzymes identified from 13 spots showed different expression levels between cancer and normal tissues (Table III). These important enzymes in glycolysis, including fructose-1,6-diphosphate al-

Special Glucose Metabolic Pathway in Gastric Cardia Cancer
dolase A (ALDOA), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and ENO1, exhibited an elevated expression level in the cancer cells. In contrast, five enzymes involved in the Krebs cycle and oxidative phosphorylation were remarkably down-regulated in cancer tissues, including PDHB, ACO2, fumarate hydratase (FH), malate dehydrogenase (MDH), and ubiquinol-cytochrome-c reductase core protein I (UQCRC1). Another enzyme in the Krebs cycle, isocitrate dehydrogenase (IDH1), also showed a slightly decreased expression level in the cancer cells. Additionally, the enzyme LDHB was down-regulated in GCC. This enzyme normally performs a major function in aerobic pathways transforming lactate to pyruvic acid (23). Further metabolomics study discovered that six intermediates in the glucose metabolism were changed during tumorigenesis (Table IV). As expected, fructose (fructose 6phosphate and fructose 1,6-diphosphate), glyceraldehyde (glyceraldehyde 3-phosphate), and pyruvic acid produced during glycolysis were elevated in the tumor samples, and the end product of anaerobic pathway, lactic acid, was also increased. Fumaric acid produced by the Krebs cycle was decreased, which was consistent with down-regulation of fumarate hydratase. However, another product in the Krebs cycle, isocitric acid, was greatly enhanced in the tumor samples. The higher isocitric acid level was presumably due to the difference in metabolic rate from citrate to ␣-ketoglutarate involving citrate synthase. The conversion of isocitric acid to ketoglutarate and then to succinyl-CoA is relatively slow because it is the critical step to build up NADH, causing the accumulation of isocitric acid. In general, the integrated results from proteomics and metabolite profiling clearly revealed that, unlike normal cells, glycolysis followed by anaerobic respiration was utilized as the major pathway to metabolize glucose in GCC cells, whereas the Krebs cycle and oxidative phosphorylation were impaired.
Validation of Glucose Metabolic Characteristics in Additional GCC Patients: RNA and Protein Levels of Key Pathways-To extend our initial observations of changes in the glucose metabolism of GCC, RNA and protein levels of the corresponding genes were examined by real time PCR and Western blot of additional GCC patients. Because the isoenzymes of PKM2 (M1 and M2; labeled as PKM2a and PKM2b in the following) and the subunits of LDH (LDHA and LDHB) may play different roles in cancer, the mRNA levels of both PKM2 isoenzymes and LDHA were measured. When compared with matched normal gastric cardia samples, six of the seven glycolytic enzymes (combined with LDHA and LDHB for ease of analysis) were significantly overexpressed with the exception of LDHB, which was obviously down-regulated (Fig. 3A). However, most enzymes in the Krebs cycle (combined with UQCRC1 for the same reason) were greatly downregulated in GCC with the exception of IDH1 and FH, which were only slightly decreased (Fig. 3B). Moreover, a significant correlation was found between the change in levels of relative mRNA expression and the expression ratio of the same protein identified in the two-dimensional gel (Fig. 3C), adding to our knowledge that these enzyme levels were truly altered in GCC. Nevertheless, no significant relationship was detected between the mRNA expression of these target genes and the  Table S4), which may indicate that such metabolic conversions might happen in the early stage of tumorigenesis.
On the other hand, the protein expression levels of ENO1, LDHA, LDHB, and ACO2 were analyzed by Western blot (Fig.  3D). ACO2 showed decreased expression in seven of eight cancer samples, whereas the level of ENO1 was increased in six of eight cancer samples compared with their normal counterparts. Due to the high homology of LDHA and LDHB, the antibodies could not distinguish the two bands clearly on the gel. Thus, we differentiated the two bands using specific siRNA to knock down either LDHA or LDHB, which facilitated the identification of each band successfully. As shown in supplemental Fig. S3, the upper band was LDHB, whereas the lower band was LDHA. Seven of eight cancer samples showed LDHA overexpression, and six of eight tumor tissues had decreased expression of LDHB. Notably, none of the GCC samples had a normal glucose metabolic pathway; each had an abnormality in one or several steps in this process, which might facilitate the early detection of GCC.
Fate of Pyruvic Acid Regulated by LDH and PDH Is Intrinsically Intertwined with Survival of Cancer Cells-One metabolic characteristic of GCC discovered from our results was that more pyruvic acid was transformed into lactic acid, rather than acetyl-CoA, following the Krebs cycle. We speculated that the ratio of the two enzyme complexes, LDH and PDH, determined the fate of pyruvic acid, which changed the glucose metabolism pathway and influenced the cell transformation process. When LDHA was knocked down by siRNA (Fig.  4A), the activity of LDH to catalyze pyruvic acid (supplemental Fig. S4A) and produce lactic acid (Fig. 4B) dramatically decreased, which further confirmed the effect of siRNA in these function assays. Meanwhile, a zymogram of the LDH isoenzyme pattern showed that in LDHA knockdown cells the intensities of the five bands obviously shifted from LDH5 (A4) a Metabolites were identified by comparing the exact mass and retention time of our reference metabolites in our laboratory.
b -Fold change with a value Ͼ1 indicates a relatively higher concentration present in GCC patients, whereas a value Ͻ1means a relatively lower concentration as compared with the healthy controls. c -Fold change and p value were calculated from a non-parametric t test.
d Variable importance in the projection was obtained from OPLS-DA with a threshold of 1.0.  to LDH1 (B4) (supplemental Fig. S4B), which was found to be consistent with diminished enzymatic activity. The MTT assay revealed that these LDHA knockdown cells grew much slower than the control cells (Fig. 4C). Moreover, LDHA knockdown cells formed fewer colonies in soft agar (Fig. 4D) and also had a relatively impaired ability to migrate in a Boyden chamber (supplemental Fig. S5). We concluded that an overexpression of LDHA and high activity of LDH complex were necessary for tumor cells to sustain rapid proliferation and migration. In contrast, in vitro stable overexpression of PDHB (Fig. 4E) (a subunit of PDH complex that was down-regulated in GCC as mentioned above) diverted more pyruvic acids to the Krebs cycle and caused an impairment in the production of lactic acid (Fig. 4F), resulting in cell growth inhibition (Fig. 4G) and a decrease in the ability to form colonies in soft agar (Fig. 4H). Interestingly, overexpression of PDHB had almost no effect on cell migration (supplemental Fig. S5), which was slightly different from knockdown of LDHA, although both of them resulted in the increasing conversion from acetyl-CoA to pyruvic acids. In conclusion, transforming more pyruvic acids to lactic acids by GCC cells was necessary to sustain their rapid proliferation and was controlled by the levels of LDH and PDH. DISCUSSION In the last two decades, the incidence of GCC, or proximal gastric cancer, has increased almost all over the world (24 -26), including China (27). This cancer is often diagnosed late in its course and is often fatal. Little progress has been achieved in the prevention and treatment of this disease because of the lack of an effective and sensitive diagnostic biomarker as well as knowledge of its etiology (28). Therefore, systematic research of GCC is required to better understand its molecular pathogenesis.
In this study, we first discovered the comprehensive differences of proteins and metabolic intermediates between paired normal and GCC samples, especially those involved in glucose metabolism. Glucose is the major source for energy production and macromolecule biosynthesis to maintain continuous rapid proliferation of tumor cells (29). Many groups have demonstrated that a variety of solid tumors, including renal (30), colon, stomach (31), and breast (32), prefer anaerobic glycolysis to the Krebs cycle for energy production even under normoxia, or the Warburg effect (17). In our study, we also found a predominance of anaerobic glycolysis, rather than the Krebs cycle, in GCC at different levels, spanning from RNA to protein to the corresponding metabolic intermediates, thus validating that the Warburg effect also exists in GCC (Fig.  5A). Several enzymes involved in the glycolysis are considered ubiquitously overexpressed in a variety of cancers, such as ENO1, GAPDH, and PKM (33), which is consistent with our observation in GCC. A high level of glycolysis endows cancer cells with a growth advantage, which enhances unconstrained proliferation and invasion. As for the enzymes involved in the Krebs cycle, the situation is more complicated, depending on the cancer type. Succinate dehydrogenase (SDH) and FH are often dysregulated in renal cancer, both of which are associated with hypoxia-inducible factor (HIF) activation (34). Genes encoding enzymes, such as IDH1, have been found frequently mutated, demonstrating early genetic alterations in glioma (35). The activity of ACO2 is usually elevated in prostate cancer, promoting the transformation of normal citrate-producing epithelial cells to malignant citrate-oxidizing cells (36). However, ACO2 is often deleted in colorectal cancer (37). In our GCC samples, IDH1, ACO2, FH, and MDH were all downregulated, which indicated an impaired Krebs cycle. Highly active glycolysis and an impaired Krebs cycle guarantee enough metabolic intermediates by avoiding thorough oxidation of glucose, which is essential for the synthesis of macromolecules, such as lipid, protein, and nuclear acid, during cell division (38 -40). Moreover, the hypoxic environment in tumor tissues causes increased reactive oxygen species production (41,42), which leads to severe oxidative damage and cell apoptosis, so that tumor cells often adopt impaired oxidative phosphorylation to evade such reactive oxygen species-mediated cell death (43). Our work revealed that the Warburg effect is also prevalent in GCC, spanning from genes to metabolites, suggesting that such metabolic transition is important for the development of GCC, and the glycolysis signature provides potential biomarker identification for clinical diagnosis of this intractable cancer.
The balance between aerobic glycolysis and the Krebs cycle in cancer cells ensures the maximal and rapid production of both energy and metabolic intermediates for cell proliferation. Two enzyme complexes, LDH and PDH, control the metabolism of pyruvic acids, transforming them to either lactic acids or acetyl-CoA, then entering the Krebs cycle. The tetrameric LDH contains five isoenzymes formed by random association of two subunits, LDHA and LDHB, interconverting pyruvate and lactate with concomitant interconversion of NADH and NAD ϩ (44). The change of LDHB expression suggested by our two-dimensional gel analysis encouraged us to further examine the expression of LDHA in GCC. In contrast to the down-regulation of LDHB, LDHA was found to be overexpressed in GCC. Overexpression of LDHA has been previ-ously reported to favor the formation of cathodic LDH (isoenzymes 4 and 5) and generation of lactate, which is often observed in solid tumors and correlated with advanced tumor grade, poor prognosis, VEGF up-regulation, and hypoxia (45)(46)(47). In our study, we also observed the influence of deregulated LDHA on the efflux of pyruvic acid. A knockdown of LDHA by siRNA resulted in a shift of LDH isoenzymes from Stages 3/4/5 to 1/2 with a concomitant significant decrease in catalytic activity as well as lactic acid production. Furthermore, a knockdown of LDHA could obviously hamper both anchorage-dependent and -independent growth of tumor cells, which is consistent with the previous study reporting that LDHA was essential for the transformation process (48,49).
The other pyruvic acid efflux controller, PDH multienzyme complex, catalyzes the first reaction of an oxidative decarboxylation sequence and converts pyruvate to acetyl-CoA and CO 2 . It has been reported that in various cancer types, such as lung (50) as well as head and neck squamous cancer (51), pyruvate dehydrogenase kinase induced by overexpressed HIF-1 phosphorylates and inactivates the PDH complex, inhibits the conversion of pyruvate to acetyl-CoA, and thereby attenuates mitochondrial function and respiration (52). In our study, we found that one of the components in PDH multienzyme complex, PDHB, was down-regulated in GCC, leading to decreased enzymatic activity and an impaired Krebs cycle. Consistent with our observation, overexpression of PDHB reduced lactate acid production and decreased the proliferation of tumor cells in both an anchorage-dependent and -independent manner. Thus, our study clearly demonstrated that LDHA and PDHB can determine the fate of pyruvic acid, anaerobic glycolysis or aerobic respiration, via the regulation of LDH and PDH complex, respectively. These studies have improved our understanding of the Warburg effect and its influence on GCC development and progression, and the metabolic pathway can serve as a potential target for GCC therapy (Fig. 5B).
Although either knockdown of LDHA or overexpression of PDHB promoted the conversion from acetyl-CoA to pyruvic acids, leading to the retardation of tumor growth, only LDHA but not PDHB affected cell migration, indicating that the corresponding molecules, such as lactic acid, pyruvic acid, and acetyl-CoA, might not influence cell migration directly, whereas other concomitant changes such as the ratio of NAD ϩ /NADH might influence the cell migration. Of course, we cannot exclude that LDHA has its own special role in cancer cell migration except for its usual role in cell metabolism.
This study highlighted several other proteins that expand our understanding of the molecular pathology of GCC. For example, selenium-binding protein 1 (SELENBP1) was significantly down-regulated in these cancers, consistent with the findings in colorectal (53), ovarian (54), and lung (55) cancers. Some investigators have suggested that selenium may have an anticarcinogenic property toward GCC (56). In addition, elevated levels of many metabolic intermediates of the nucle-FIG. 5. Unique glucose metabolic characteristics in GCC may have potential as targets for cancer therapy. A, the fingerprint map of the glucose metabolic network in GCC highlighting those enzymes and metabolic intermediates that are dysregulated. B, normal cells preferred the Krebs cycle and oxidative phosphorylation (OXPHOS) compared with anaerobic respiration. This favored pathway is controlled by the high activity of PDH and relatively low activity of LDH (left). GCC cells not only favor glycolysis by up-regulating the enzymes involved but also strongly prefer anaerobic respiration with production of prominent lactic acids rather than the Krebs cycle and oxidative phosphorylation because of activating LDH and suppressing PDH (middle). This divergence between GCC and normal tissues will give us new therapeutic opportunities (right). GAP, glyceraldehyde 3-phosphate; Lac, lactic acid; Pyr, pyruvate. otide metabolism were noted that were also observed in previous reports (19,57), indicating active nucleic acid turnover in tumor tissues. Also of interest, fatty acids were all down-regulated in the tumor samples examined, which was consistent with the dramatically decreased expression of lipase, gastric (LIPF). Down-regulation of lipase in GCC resulted in impaired triglyceride and phospholipid hydrolysis, leading to the lack of dissociative fatty acids. This was further confirmed by the decrease of another two intermediates (glycerol phosphate and myoinositol). As expected, a number of amino acids and their polyamine derivatives were increased in cancer tissues to meet the requirement of protein synthesis. A low expression level of the enzyme aspartate aminotransferase (AspT) was noted in our proteomics analysis of the GCC cells. This enzyme normally helps aspartate to enter the Krebs cycle through transamination. Large amounts of aspartic acid and asparagine in cancer tissues might result from impairment of this enzyme, diverting more aspartic acids to participate in the synthesis of purines as well as proteins rather than entering the impaired Krebs cycle.
In summary, with the help of proteomics and metabolomics analysis, we discovered that a series of proteins and related metabolites in glucose metabolism showed an altered expression level in GCC tissues. These findings will not only benefit early diagnosis of this cancer at the molecular level but also improve our understanding of the initiation and development of GCC. A highly activated anaerobic glycolysis and an impaired aerobic respiration are important for maintaining the rapid proliferation of this cancer, which is achieved by highly active LDH concomitant with relatively inactivated PDH to divert more pyruvic acids into the anaerobic glycolysis pathway. Our fin dings suggest that an antagonist to LDH as well as an agonist of PDH may be a novel therapy for GCC.