Abstract
Although extensive advancements have been made in treatment against hepatocellular carcinoma (HCC), the prognosis of HCC patients remains unsatisfied. It is now clearly established that extensive epigenetic changes act as a driver in human tumors. This study exploits HCC epigenetic deregulation to define a novel prognostic model for monitoring the progression of HCC. We analyzed the genome-wide DNA methylation profile of 374 primary tumor specimens using the Illumina 450 K array data from The Cancer Genome Atlas. We initially used a novel combination of Machine Learning algorithms (Recursive Features Selection, Boruta) to capture early tumor progression features. The subsets of probes obtained were used to train and validate Random Forest models to predict a Progression Free Survival greater or less than 6 months. The model based on 34 epigenetic probes showed the best performance, scoring 0.80 accuracy and 0.51 Matthews Correlation Coefficient on testset. Then, we generated and validated a progression signature based on 4 methylation probes capable of stratifying HCC patients at high and low risk of progression. Survival analysis showed that high risk patients are characterized by a poorer progression free survival compared to low risk patients. Moreover, decision curve analysis confirmed the strength of this predictive tool over conventional clinical parameters. Functional enrichment analysis highlighted that high risk patients differentiated themselves by the upregulation of proliferative pathways. Ultimately, we propose the oncogenic MCM2 gene as a methylation-driven gene of which the representative epigenetic markers could serve both as predictive and prognostic markers. Briefly, our work provides several potential HCC progression epigenetic biomarkers as well as a new signature that may enhance patients surveillance and advances in personalized treatment.
Highlights
Hepatocellular carcinoma (HCC) is one of the leading causes of cancer deaths worldwide
Low risk patients showed a significant advantage in progression-free survival (PFS) time compared to high risk patients (Figure 4B). These results demonstrated that our model can provide an accurate risk stratification system and reveal that the methylation level of these cytosine-phosphate-guanine dinucleotides (CpGs) probes could affect the prognosis of hepatocellular carcinoma (HCC) patients
To assess the adequacy and the clinical advantages of our signature over currently used parameters, we performed a decision curve analysis proving that our method showed a significantly improved performance when compared to in-use conventional clinical parameters, indicating a more powerful and dynamic reflection of HCC heterogeneity
Summary
Hepatocellular carcinoma (HCC) is one of the leading causes of cancer deaths worldwide. According to the 2018 statistical report of global cancer burden (GLOBOCAN), HCC is the sixth for incidence and the fourth for mortality cancer, accounting for 841,080 new cases and 781,631 deaths per year worldwide [1]. HCC lesions originate from chronic liver fibrosis and cirrhosis, which arise from repeated cycles of injury and repair. The survival of HCC patients that are not eligible for curative therapy (i.e., resection, local ablation and liver transplantation) depends on their response to the less efficient systemic chemotherapy [5,6]. HCC patient stratification into homogeneous progression groups is critical for the identification of potential biological processes involved in cancer progression, which form the bases for the selection of the most appropriate treatment or possibly shed new light on novel druggable biological targets
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