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. 2025 Aug:358:199589.
doi: 10.1016/j.virusres.2025.199589. Epub 2025 Jun 4.

Identification and evaluation of biomarkers for diagnosis of chronic hepatitis B using RNA-seq

Hong Hong  1 Xintong Han  2 Qiuxiang Hu  3 Huafeng Song  4 Bing Han  5
Affiliations

Identification and evaluation of biomarkers for diagnosis of chronic hepatitis B using RNA-seq

Hong Hong et al. Virus Res. 2025 Aug.

Abstract

Background & aim: Chronic hepatitis B (CHB) is a global public health problem affecting hundreds of millions of people and is associated with significant morbidity and mortality of liver cancer. Exosomes originate from cells and their detection in biofluids provides valuable insights into cellular and tissue alterations, thus reflecting underlying pathological states. The aim of this study was to provide exosomal RNA biomarkers of CHB and develop a machine learning model for the non-invasive diagnosis of CHB patients.

Methods: The differentially expressed genes (DEGs) were screened according to the RNA-seq data of normal and CHB liver tissues. The biomarkers were selected according to the analysis of pathway enrichment and functional annotation. The correlation of biomarkers' expression level with the inflammation stage of CHB patients was analyzed. The non-invasive diagnostic value of the potential RNA biomarkers was evaluated by checking their different expression level in the plasma exosome of healthy individuals and CHB patients. A machine learning model was constructed to diagnose CHB by combining three identified biomarkers.

Results: A total of 1,006 differential expressed genes (569 upregulated and 437 downregulated) were screened between normal and CHB tissues. The GO and KEGG results showed the DEGs were mainly enriched in inflammation-related pathways. Among these genes, the expression of 4 upregulated genes and 27 downregulated genes showed consistent trends with the inflammation stage utilizing an independent CHB dataset. Three (PXN-AS1, RAD9A, SLC17A9) of 27 downregulated genes were found significantly decreased in plasma exosome of CHB patients. ROC analysis revealed that PXN-AS1, RAD9A and SLC17A9 exhibited moderate diagnostic performance in distinguishing CHB from healthy controls, with AUC values of 0.743, 0.762, and 0.665 respectively. A machine learning model, Adaboost classifier, was constructed to detect CHB by combining exosomal expression of PXN-AS1, RAD9A and SLC17A9. The AUC of the model was 0.983 and 0.924 for CHB detection in train and test dataset respectively.

Conclusion: Based on multiple RNA-seq data of tissues and plasma exosomes, we identified PXN-AS1, RAD9A, SLC17A9 as diagnostic biomarkers for CHB detection. The model based on three biomarkers showed potential diagnostic value for detecting CHB. Additional validation with a larger sample size is essential to thoroughly assess the reliability of these three biomarkers and the model's performance.

Keywords: Bioinformatics analysis; Chronic hepatitis B; Exosome RNA-seq; Non-invasive diagnosis; Serum biomarkers.

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Conflict of interest statement

Declaration of competing interest The authors declare no competing interests. QXH is the employee of Suzhou BamRock Biotechnology Ltd. All authors agree that Suzhou BamRock Biotechnology Ltd. holds the patent rights for inventions and commercialization value associated with this study.

Figures

Fig 1
Fig. 1
Differentially expressed genes in Chronic hepatitis B. (A) Volcano plot of DEGs in Chronic hepatitis B and Normal. The red dots in the plot represents upregulated genes and blue dots represents downregulated genes with statistical significance. Black dots represent no differentially expressed genes. (B) Heatmap of significantly DEGs in Chronic hepatitis B and Normal. The color from blue to red represents the progression from low expression to high expression. Abbreviation: DEGs, differentially expressed genes.
Fig 2
Fig. 2
Functional enrichment of upregulated genes in DEGs. (A) Gene ontology analysis (Top 10). The Fig. represents biological process (BP), cellular component (CC) and molecular function (MF). (B) The most significant Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways (Top 10).
Fig 3
Fig. 3
Functional enrichment of downregulated genes in DEGs. (A) Gene ontology analysis (Top 10). The Fig. represents biological process (BP), cellular component (CC) and molecular function (MF). (B) The most significant Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways (Top 10).
Fig 4
Fig. 4
The expression of candidate DEG in different liver inflammation stage in an independent CHB samples. (A- B) The expression of 30 candidate genes exhibit a consistent trend with the degree of inflammation, with green boxplot representing mild inflammation (stage 1 - 2) and red boxplot representing severe inflammation (stage 3 - 4).
Fig 5
Fig. 5
Evaluation of potential diagnostic value of biomarkers in Chronic hepatitis B plasma. (A-B) Percentage of normal and abnormal level of plasma ALT/AST in different inflammation stage of Chronic hepatitis B. (C-E) Boxplot analysis of 3 candidate genes in s plasma exosome of Chronic hepatitis B and healthy individuals. (F) Correlation analysis between the expression of 3 candidate gene and clinical parameters. (G) ROC curve of 3 single candidate genes in distinguishing Chronic hepatitis B and healthy controls utilizing exosomal RNA expression data. (H) ROC curve of model by combining 3 genes (PXN-AS1, RAD9A, SLC17A9) in distinguishing Chronic hepatitis B and healthy controls utilizing their exosomal RNA data.
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