Metabolic network-based stratification of hepatocellular carcinoma reveals three distinct tumor subtypes

Significance Hepatocellular carcinoma (HCC) is a heterogeneous and deadly form of liver cancer. Here, we stratified and characterized HCC tumors by applying graph and control theory concepts to the topology of genome-scale metabolic networks. We identified three HCC subtypes with distinct differences in metabolic and signaling pathways and clinical survival and validated our results by performing additional experiments. We further identified HCC subtype-specific genes pivotal in controlling the entire metabolism and discovered genes that can be targeted for development of efficient treatment strategies for specific HCC subtypes. Our systems-level analyses provided a systematic way for characterization of HCC subtypes and identification of drug targets for effective treatment of HCC patients. Hepatocellular carcinoma (HCC) is one of the most frequent forms of liver cancer, and effective treatment methods are limited due to tumor heterogeneity. There is a great need for comprehensive approaches to stratify HCC patients, gain biological insights into subtypes, and ultimately identify effective therapeutic targets. We stratified HCC patients and characterized each subtype using transcriptomics data, genome-scale metabolic networks and network topology/controllability analysis. This comprehensive systems-level analysis identified three distinct subtypes with substantial differences in metabolic and signaling pathways reflecting at genomic, transcriptomic, and proteomic levels. These subtypes showed large differences in clinical survival associated with altered kynurenine metabolism, WNT/β-catenin–associated lipid metabolism, and PI3K/AKT/mTOR signaling. Integrative analyses indicated that the three subtypes rely on alternative enzymes (e.g., ACSS1/ACSS2/ACSS3, PKM/PKLR, ALDOB/ALDOA, MTHFD1L/MTHFD2/MTHFD1) to catalyze the same reactions. Based on systems-level analysis, we identified 8 to 28 subtype-specific genes with pivotal roles in controlling the metabolic network and predicted that these genes may be targeted for development of treatment strategies for HCC subtypes by performing in silico analysis. To validate our predictions, we performed experiments using HepG2 cells under normoxic and hypoxic conditions and observed opposite expression patterns between genes expressed in high/moderate/low-survival tumor groups in response to hypoxia, reflecting activated hypoxic behavior in patients with poor survival. In conclusion, our analyses showed that the heterogeneous HCC tumors can be stratified using a metabolic network-driven approach, which may also be applied to other cancer types, and this stratification may have clinical implications to drive the development of precision medicine.

[1]  Andrew M. Gross,et al.  Network-based stratification of tumor mutations , 2013, Nature Methods.

[2]  Jung-Hwan Yoon,et al.  Identification of a cholangiocarcinoma-like gene expression trait in hepatocellular carcinoma. , 2010, Cancer research.

[3]  Qicheng Ma,et al.  Activation of a metabolic gene regulatory network downstream of mTOR complex 1. , 2010, Molecular cell.

[4]  J. Nielsen,et al.  Identification of anticancer drugs for hepatocellular carcinoma through personalized genome‐scale metabolic modeling , 2014, Molecular systems biology.

[5]  C. Mathers,et al.  Estimates of worldwide burden of cancer in 2008: GLOBOCAN 2008 , 2010, International journal of cancer.

[6]  J. Nielsen,et al.  Uncovering transcriptional regulation of metabolism by using metabolic network topology. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[7]  Yongshuai Jiang,et al.  The drug target genes show higher evolutionary conservation than non-target genes , 2015, Oncotarget.

[8]  Charles M. Perou,et al.  Asparagine bioavailability governs metastasis in a model of breast cancer , 2018, Nature.

[9]  Yu Wei,et al.  Hepatic stem-like phenotype and interplay of Wnt/beta-catenin and Myc signaling in aggressive childhood liver cancer. , 2008, Cancer cell.

[10]  B. Balkau,et al.  The kynurenine pathway is activated in human obesity and shifted toward kynurenine monooxygenase activation , 2015, Obesity.

[11]  Steven J. M. Jones,et al.  Comprehensive and Integrative Genomic Characterization of Hepatocellular Carcinoma , 2017, Cell.

[12]  Eytan Ruppin,et al.  Predicting selective drug targets in cancer through metabolic networks , 2011, Molecular Systems Biology.

[13]  Manal M. Hassan,et al.  Inactivation of Hippo Pathway Is Significantly Associated with Poor Prognosis in Hepatocellular Carcinoma , 2015, Clinical Cancer Research.

[14]  Ze-Guang Han,et al.  Transcriptomic Characterization of Hepatocellular Carcinoma with CTNNB1 Mutation , 2014, PloS one.

[15]  A. Barabasi,et al.  Lethality and centrality in protein networks , 2001, Nature.

[16]  Sang Yup Lee,et al.  Are We There Yet? How and When Specific Biotechnologies Will Improve Human Health , 2018, Biotechnology journal.

[17]  S. Thorgeirsson,et al.  A novel prognostic subtype of human hepatocellular carcinoma derived from hepatic progenitor cells , 2006, Nature Medicine.

[18]  I. Nookaew,et al.  Enriching the gene set analysis of genome-wide data by incorporating directionality of gene expression and combining statistical hypotheses and methods , 2013, Nucleic acids research.

[19]  A. Barabasi,et al.  Controllability analysis of the directed human protein interaction network identifies disease genes and drug targets , 2015, Proceedings of the National Academy of Sciences.

[20]  Ina Koch,et al.  Genome Scale Modeling in Systems Biology: Algorithms and Resources , 2014, Current genomics.

[21]  Ju-Seog Lee,et al.  Glutamine synthetase mediates sorafenib sensitivity in β-catenin-active hepatocellular carcinoma cells , 2018, Experimental & Molecular Medicine.

[22]  Derek Y. Chiang,et al.  Focal gains of VEGFA and molecular classification of hepatocellular carcinoma. , 2008, Cancer research.

[23]  Mingming Jia,et al.  COSMIC: somatic cancer genetics at high-resolution , 2016, Nucleic Acids Res..

[24]  S. Boyault,et al.  Differential effects of inactivated Axin1 and activated β-catenin mutations in human hepatocellular carcinomas , 2007, Oncogene.

[25]  Wen-Xu Wang,et al.  Exact controllability of complex networks , 2013, Nature Communications.

[26]  Increased Plasma Levels of Xanthurenic and Kynurenic Acids in Type 2 Diabetes , 2015, Molecular Neurobiology.

[27]  Robert J. Lonigro,et al.  Integrative Clinical Genomics of Metastatic Cancer , 2017, Nature.

[28]  X. Wang,et al.  Sixty‐five gene‐based risk score classifier predicts overall survival in hepatocellular carcinoma , 2012, Hepatology.

[29]  M. Weller,et al.  An endogenous tumour-promoting ligand of the human aryl hydrocarbon receptor , 2011, Nature.

[30]  S. Thorgeirsson,et al.  Classification and prediction of survival in hepatocellular carcinoma by gene expression profiling , 2004, Hepatology.

[31]  Jason A. Papin,et al.  Functional integration of a metabolic network model and expression data without arbitrary thresholding , 2011, Bioinform..

[32]  Falk Schreiber,et al.  Analysis of Biological Networks , 2008 .

[33]  Avlant Nilsson,et al.  Recon3D: A Resource Enabling A Three-Dimensional View of Gene Variation in Human Metabolism , 2018, Nature Biotechnology.

[34]  V. Mazzaferro,et al.  Wnt-Pathway Activation in Two Molecular Classes of Hepatocellular Carcinoma and Experimental Modulation by Sorafenib , 2012, Clinical Cancer Research.

[35]  G. Getz,et al.  Inferring tumour purity and stromal and immune cell admixture from expression data , 2013, Nature Communications.

[36]  Jason A. Papin,et al.  TIGER: Toolbox for integrating genome-scale metabolic models, expression data, and transcriptional regulatory networks , 2011, BMC Systems Biology.

[37]  A. Barabasi,et al.  Network biology: understanding the cell's functional organization , 2004, Nature Reviews Genetics.

[38]  J. Nielsen,et al.  New Challenges to Study Heterogeneity in Cancer Redox Metabolism , 2017, Front. Cell Dev. Biol..

[39]  Joshua M. Stuart,et al.  The Cancer Genome Atlas Pan-Cancer analysis project , 2013, Nature Genetics.

[40]  A. Barabasi,et al.  Network-based in silico drug efficacy screening , 2016, Nature Communications.

[41]  Ji-Shin Lee,et al.  Genetic alterations of Wnt signaling pathway–associated genes in hepatocellular carcinoma , 2007, Journal of gastroenterology and hepatology.

[42]  Albert-László Barabási,et al.  Controllability of complex networks , 2011, Nature.

[43]  M. Uhlén,et al.  Genome-scale metabolic modelling of hepatocytes reveals serine deficiency in patients with non-alcoholic fatty liver disease , 2014, Nature Communications.

[44]  A. Badawy Kynurenine Pathway of Tryptophan Metabolism: Regulatory and Functional Aspects , 2017, International journal of tryptophan research : IJTR.

[45]  I. Nookaew,et al.  Integration of clinical data with a genome-scale metabolic model of the human adipocyte , 2013, Molecular systems biology.

[46]  A. Barabasi,et al.  High-Quality Binary Protein Interaction Map of the Yeast Interactome Network , 2008, Science.

[47]  Jens Nielsen,et al.  Metabolic Network-Based Identification and Prioritization of Anticancer Targets Based on Expression Data in Hepatocellular Carcinoma , 2018, Front. Physiol..

[48]  Jens Nielsen,et al.  Network analyses identify liver‐specific targets for treating liver diseases , 2017, Molecular systems biology.

[49]  Derek Y. Chiang,et al.  Integrative transcriptome analysis reveals common molecular subclasses of human hepatocellular carcinoma. , 2009, Cancer research.

[50]  C. Lindskog,et al.  A pathology atlas of the human cancer transcriptome , 2017, Science.

[51]  A. Barabasi,et al.  Network medicine : a network-based approach to human disease , 2010 .

[52]  Vijay P. Singh,et al.  β‐Catenin is essential for ethanol metabolism and protection against alcohol‐mediated liver steatosis in mice , 2012, Hepatology.

[53]  J. Nielsen,et al.  Systems biology in hepatology: approaches and applications , 2018, Nature Reviews Gastroenterology & Hepatology.

[54]  H. Satoh,et al.  Teneligliptin Decreases Uric Acid Levels by Reducing Xanthine Dehydrogenase Expression in White Adipose Tissue of Male Wistar Rats , 2016, Journal of diabetes research.

[55]  J. Nielsen,et al.  Stratification of Hepatocellular Carcinoma Patients Based on Acetate Utilization. , 2015, Cell reports.

[56]  J. Willmann,et al.  β-Catenin regulates hepatic mitochondrial function and energy balance in mice. , 2012, Gastroenterology.

[57]  Jung-Hwan Yoon,et al.  Gene Expression–Based Recurrence Prediction of Hepatitis B Virus–Related Human Hepatocellular Carcinoma , 2008, Clinical Cancer Research.