# Multi-omics characterization of RNA modification enzymes identifies NAT10 as a functionally validated prognostic biomarker in hepatocellular carcinoma

**Authors:** Qianqian Zhan, Huihui Sun, Xiangting Wang, Xiaolin Liang

PMC · DOI: 10.3389/fimmu.2026.1764106 · 2026-01-28

## TL;DR

This study explores RNA modification enzymes in cancer, identifying NAT10 as a key biomarker for predicting outcomes in liver cancer.

## Contribution

The study introduces a 12-RME diagnostic signature and a 6-gene prognostic model for cancer, with NAT10 validated as a functional biomarker in hepatocellular carcinoma.

## Key findings

- RMEs are broadly upregulated in cancers and linked to copy number variations.
- NAT10 knockdown reduces HCC cell proliferation, validated by EdU and IHC assays.
- A 6-gene model shows strong prognostic power and treatment response predictions.

## Abstract

RNA modification enzymes (RMEs) are key post-transcriptional regulators that impact RNA stability, translation, and splicing. Dysregulation of RMEs is closely associated with tumor initiation and progression. However, their global regulatory patterns and clinical relevance across cancer types remain incompletely characterized.

We conducted an integrative multi-omics analysis of RME expression, copy number variation (CNV), and clinical outcomes across multiple cancers. Machine learning algorithms were employed to identify tumor-discriminating RME signatures. Single-cell RNA sequencing (scRNA-seq) characterized tumor microenvironmental heterogeneity. A LASSO-derived prognostic model was established and validated in independent cohorts. Drug sensitivity prediction and supportive functional assays (EdU assays, qRT-PCR, immunohistochemistry) were performed for representative RMEs.

RMEs were broadly upregulated across cancers and showed strong associations with CNV gains. Machine learning identified 12 RMEs that reliably discriminated tumor from normal tissues. Single-cell transcriptomic analysis showed that 10 of the 12 selected RMEs (DKC1, METTL1, NAT10, TRMT1, RPUSD1, PUS1, WDR4, TRMU, ADAT2, GTPBP3) exhibited higher expression in tumor-infiltrating cells compared with adjacent normal tissues. T-cell subpopulations displayed marked heterogeneity, with ADAT2 preferentially enriched in regulatory T cells. CellChat analysis revealed T cell subsets as key mediators of intercellular communication via multiple immune-related pathways. A 6-gene prognostic model exhibited independent prognostic power and was integrated into a well-calibrated nomogram. Drug-response prediction revealed that high-risk patients exhibited enhanced sensitivity to microtubule-targeting agents and kinase inhibitors, whereas low-risk patients showed preferential response to epigenetic modulators. Importantly, supportive functional assays showed that NAT10 knockdown, validated by qRT-PCR, was associated with reduced proliferative activity in HCC cells as evidenced by EdU assays, and IHC validation further corroborated its overexpression in clinical tumor specimens compared to adjacent normal tissues.

This study delineates a CNV-associated landscape of RME dysregulation across cancers and establishes a 12-RME diagnostic signature and a 6-gene prognostic model with robust predictive performance. Single-cell analyses reveal tumor- and cell-type-specific expression patterns of RMEs, while supportive functional data suggest a potential biological relevance of NAT10 in HCC. Collectively, these findings provide an association-based framework for understanding the potential roles of RNA modification programs in cancer progression and clinical stratification.

## Linked entities

- **Genes:** NAT10 (N-acetyltransferase 10) [NCBI Gene 55226], DKC1 (dyskerin pseudouridine synthase 1) [NCBI Gene 1736], METTL1 (methyltransferase 1, tRNA methylguanosine) [NCBI Gene 4234], TRMT1 (tRNA methyltransferase 1) [NCBI Gene 55621], RPUSD1 (RNA pseudouridine synthase domain containing 1) [NCBI Gene 113000], PUS1 (pseudouridine synthase 1) [NCBI Gene 80324], WDR4 (WDR4 tRNA N7-guanosine methyltransferase non-catalytic subunit) [NCBI Gene 10785], TRMU (tRNA mitochondrial 2-thiouridylase) [NCBI Gene 55687], ADAT2 (adenosine deaminase tRNA specific 2) [NCBI Gene 134637], GTPBP3 (GTP binding protein 3, mitochondrial) [NCBI Gene 84705]
- **Diseases:** hepatocellular carcinoma (MONDO:0007256), cancer (MONDO:0004992)

## Full-text entities

- **Genes:** DKC1 (dyskerin pseudouridine synthase 1) [NCBI Gene 1736] {aka CBF5, CHINE1, DKC, DKCX, NAP57, NOLA4}, METTL1 (methyltransferase 1, tRNA methylguanosine) [NCBI Gene 4234] {aka C12orf1, TRM8, TRMT8, YDL201w}, NAT10 (N-acetyltransferase 10) [NCBI Gene 55226] {aka ALP, Kre33, NET43}, TRMU (tRNA mitochondrial 2-thiouridylase) [NCBI Gene 55687] {aka LCAL3, MTO2, MTU1, TRMT}, PUS1 (pseudouridine synthase 1) [NCBI Gene 80324] {aka MLASA1}, GTPBP3 (GTP binding protein 3, mitochondrial) [NCBI Gene 84705] {aka COXPD23, GTPBG3, MSS1, MTGP1, THDF1}, RPUSD1 (RNA pseudouridine synthase domain containing 1) [NCBI Gene 113000] {aka C16orf40, RLUCL}, ADAT2 (adenosine deaminase tRNA specific 2) [NCBI Gene 134637] {aka DEADC1, TAD2, dJ20N2, dJ20N2.1}, WDR4 (WDR4 tRNA N7-guanosine methyltransferase non-catalytic subunit) [NCBI Gene 10785] {aka GAMOS6, MIGSB, TRM82, TRMT82, Wuho, hWH}, TRMT1 (tRNA methyltransferase 1) [NCBI Gene 55621] {aka MRT68, TRM1, hTRM1}
- **Diseases:** HCC (MESH:D006528), cancer (MESH:D009369)
- **Chemicals:** EdU (MESH:C022811)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12891137/full.md

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Source: https://tomesphere.com/paper/PMC12891137