# Proposed Role of Circadian Clock Genes in Pathogenesis of HCC: Molecular Subtyping and Characterization

**Authors:** Zhikui Lu, Yi Zhou, Jian Luo, Zhicheng Liu, Zhenyu Xiao

PMC · DOI: 10.3390/biomedicines14030645 · Biomedicines · 2026-03-12

## TL;DR

This study identifies three distinct subtypes of hepatocellular carcinoma based on circadian clock genes, each with unique genetic, metabolic, and immune features that could guide personalized treatment strategies.

## Contribution

The novel contribution is the discovery of circadian clock gene-driven subtypes of HCC with distinct biological and clinical characteristics, including specific therapeutic vulnerabilities.

## Key findings

- Three reproducible HCC subtypes were identified based on circadian clock genes, with distinct survival rates and biological features.
- Cluster-3 showed high tumor mutational burden, immune suppression, and sensitivity to TKI drugs, while Cluster-1 exhibited metabolic stability and an immune-cold phenotype.
- Key circadian regulators like ALAS1, NONO, and CSNK1D were linked to subtype-specific tumor metabolism, proliferation, and immune modulation.

## Abstract

Background: Hepatocellular carcinoma (HCC) stands as a prevalent global health issue with increasing incidence and mortality rates. Hepatocellular carcinoma (HCC) exhibits profound molecular and clinical heterogeneity, which limits the effectiveness of current therapeutic strategies. Circadian rhythm disruption has been implicated in metabolic reprogramming, proliferation, and immune modulation in cancer, but its role in shaping HCC heterogeneity remains poorly defined. Methods: Four public HCC transcriptomic cohorts (TCGA-LIHC, CHCC, LIRI, LICA) were integrated using RMA normalization and ComBat for batch correction. Consensus clustering based on 31 core circadian clock genes (CCGs) identified robust molecular subtypes. Multi-omics characterization—including genomic alterations, pathway activity (GSEA/GSVA), immune microenvironment profiling (CIBERSORT, EPIC, MCP-counter, xCell), and drug-sensitivity prediction (pRRophetic/oncoPredict)—was performed to delineate subtype-specific biological properties. A nine-gene CCG-based RiskScore model was constructed using LASSO Cox regression to internally validate subtype robustness and intra-subtype risk stratification. Results: Using consensus clustering of 31 core CCGs in TCGA-LIHC and three independent validation cohorts (CHCC, LIRI, LICA), we identified three reproducible subtypes—Cluster-1 (metabolic–quiescent), Cluster-2 (transition–intermediate), and Cluster-3 (proliferation–inflammatory)—which were recapitulated across cohorts and showed distinct overall survival (Cluster-3 worst; log-rank p values significant across datasets). Multi-omic characterization revealed that Cluster-3 exhibits the highest tumor mutational burden and CNV burden with enrichment of TP53/AXIN1/TERT alterations, strong activation of cell-cycle, E2F, and G2M programs, and an immune-hot yet immunosuppressed microenvironment enriched for TAMs, Tregs and MDSCs. By contrast, Cluster-1 shows relative genomic stability, dominant hepatic metabolic signatures (fatty-acid oxidation, bile-acid and xenobiotic metabolism) and an immune-cold phenotype. Single-cell mapping linked ALAS1 expression to malignant hepatocytes predominating in Cluster-1, whereas NONO and CSNK1D localized to stromal (CAFs/TECs) and both malignant/immune compartments respectively in Cluster-3, providing a cellular mechanism for subtype-specific metabolism, angiogenesis and immune modulation. Finally, a nine-gene CCG-based RiskScore validated prognostic stratification and drug-sensitivity predictions indicated subtype-specific therapeutic vulnerabilities (notably increased predicted TKI sensitivity in Cluster-3). Conclusion: In conclusion, this study proposes a robust circadian rhythm-based molecular classification of hepatocellular carcinoma, revealing three biologically and clinically distinct subtypes characterized by divergent genomic alterations, metabolic programs, immune microenvironment states, and prognostic patterns. By integrating bulk and single-cell transcriptomic data, we identify subtype-specific roles of key circadian regulators—including ALAS1, NONO, and CSNK1D—in shaping tumor metabolism, proliferation, stromal remodeling, and immune suppression. These findings highlight circadian dysregulation as a potential upstream factor associated with HCC heterogeneity and provide a conceptual framework for developing subtype-tailored mechanistic studies and circadian-informed therapeutic strategies.

## Linked entities

- **Genes:** ALAS1 (5'-aminolevulinate synthase 1) [NCBI Gene 211], NONO (non-POU domain containing octamer binding) [NCBI Gene 4841], CSNK1D (casein kinase 1 delta) [NCBI Gene 1453], TP53 (tumor protein p53) [NCBI Gene 7157], AXIN1 (axin 1) [NCBI Gene 8312], TERT (telomerase reverse transcriptase) [NCBI Gene 7015]
- **Diseases:** hepatocellular carcinoma (MONDO:0007256), HCC (MONDO:0007256)

## Full-text entities

- **Genes:** AXIN1 (axin 1) [NCBI Gene 8312] {aka AXIN, CMDOH, PPP1R49}, TP53 (tumor protein p53) [NCBI Gene 7157] {aka BCC7, BMFS5, LFS1, P53, TRP53}, TERT (telomerase reverse transcriptase) [NCBI Gene 7015] {aka CMM9, DKCA2, DKCB4, EST2, PFBMFT1, TCS1}, CSNK1D (casein kinase 1 delta) [NCBI Gene 1453] {aka ASPS, CKI-delta, CKId, CKIdelta, FASPS2, HCKID}, NONO (non-POU domain containing octamer binding) [NCBI Gene 4841] {aka MRXS34, NMT55, NRB54, P54, P54NRB, PPP1R114}, ALAS1 (5'-aminolevulinate synthase 1) [NCBI Gene 211] {aka ALAS, ALAS-H, ALAS3, ALASH, MIG4}
- **Diseases:** HCC (MESH:D006528), inflammatory (MESH:D007249), cancer (MESH:D009369)
- **Chemicals:** fatty-acid (MESH:D005227), bile-acid (MESH:D001647)

## Full text

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## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/PMC13024568/full.md

## References

24 references — full list in the complete paper: https://tomesphere.com/paper/PMC13024568/full.md

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Source: https://tomesphere.com/paper/PMC13024568