# Integrative Omics Defines Metabolic Biomarkers and Genetic Regulatory Mechanisms of Mortality Risk

**Authors:** Peihao Liu, Bingxing An, Jumei Zheng, Qiao Wang, Zhirui Yang, Zhengda Li, Dawei Liu, Fan Ying, Jie Wen, Lingzhao Fang, Guiping Zhao

PMC · DOI: 10.1002/advs.202514464 · Advanced Science · 2025-11-18

## TL;DR

This study uses multi-omics data from chickens to identify genetic and metabolic factors linked to mortality risk, offering new targets for breeding and human disease research.

## Contribution

The study identifies 45,585 metabolite QTLs and a 16-metabolite signature for mortality prediction in chickens, revealing conserved pathways with human relevance.

## Key findings

- A trade-off between inflammation and growth is observed in mortality-susceptible chickens.
- A 16-metabolite signature, including hexyl glucoside and pyrraline, accurately predicts mortality risk.
- Butyrate-mediated microbiota-host interactions and L-cysteine's antioxidant roles are critical regulatory mechanisms.

## Abstract

The genetic and metabolic architecture of mortality risk represents a fundamental, yet poorly understood, challenge in human medicine and livestock breeding. Here serum metabolomics and multi‐omics data is integrated in a designed 3‐generation chicken model (n = 1,277) with divergent mortality. The analysis reveals a trade‐off between heightened inflammatory responses and impaired growth in susceptible animals. To uncover the genetic underpinnings, 45,585 metabolite quantitative trait loci are identified, which are predominantly enriched among liver‐specific regulatory variants. Using a machine learning approach, a robust 16‐metabolite signature is established, including hexyl glucoside and pyrraline, that accurately predicts mortality risk. Importantly, these metabolites and their genetic loci offer practical targets for genomic selection in chicken breeding, providing a direct approach to enhance disease resistance and survival. Cross‐species comparison with human data revealed conserved metabolic dysregulation pathways, while also highlighting species‐specific immuno‐metabolic pathophysiology. Furthermore, the findings pinpoint butyrate‐mediated microbiota‐host interactions and the dual antioxidant functions of L‐cysteine as critical regulatory mechanisms. Together, these results delineate an evolutionarily conserved immuno‐metabolic framework for mortality risk, offering novel biomarkers for selective breeding and potential therapeutic targets for human metabolic diseases.

Understanding mortality mechanisms remains a fundamental challenge. Through multi‐omics analysis of a three‐generation chicken model, are identified 45,585 mQTLs and establish a 16‐metabolite predictor of mortality. An inflammation‐growth trade‐off and evolutionarily conserved pathways involving butyrate–microbiota interactions and L‐cysteine's dual antioxidant roles are revealed, providing targets for genomic selection to breeding disease‐resistant poultry.

## Linked entities

- **Chemicals:** hexyl glucoside (PubChem CID 181215), pyrraline (PubChem CID 122228), butyrate (PubChem CID 104775), L-cysteine (PubChem CID 581)

## Full-text entities

- **Diseases:** inflammatory (MESH:D007249), metabolic diseases (MESH:D008659)
- **Chemicals:** L-cysteine (MESH:D003545), hexyl glucoside (-), pyrraline (MESH:C059571), butyrate (MESH:D002087)
- **Species:** Gallus gallus (bantam, species) [taxon 9031], Homo sapiens (human, species) [taxon 9606]

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12806298/full.md

## References

99 references — full list in the complete paper: https://tomesphere.com/paper/PMC12806298/full.md

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Source: https://tomesphere.com/paper/PMC12806298