Background <p>Breast muscle yield is a key economic trait in broilers, directly affecting carcass value and profitability, and has been significantly improved by intensive selection and exploiting heterosis through crossbreeding. Our previous work showed that synergy between the gut microbiota and host genome underlies breast muscle heterosis in crossbred progeny (CR) derived from Cornish (CC) and White Plymouth Rock (RR) lines. However, the molecular mechanisms by which the gut microbiota contributes to heterosis in breast muscle yield remain poorly understood. Here, we integrated cecal microbiome, metabolome, and transcriptome data from 266 birds at 42&#xa0;days of age to elucidate the potential gut microbiota–mediated molecular mechanisms underlying breast muscle yield heterosis.</p> Results <p>To assess whether heterosis extends beyond productive traits to the gut microbiota and their metabolites in broilers, we compared the cecal microbial and metabolic profiles of CR with those of their parental lines. The gut microbiota of CR were clearly distinct from those of both parental lines and exhibited heterosis characteristics, with 88 genera displaying heterotic patterns that collectively accounted for approximately 85% of the total microbial abundance. Heterosis was also evident in the cecal metabolites of CR birds. Differential abundance analysis across groups identified 868 cecal metabolites, and abundance-pattern classification showed that approximately 75% exhibited nonadditive patterns in the crossbred progeny. These nonadditive metabolites were predominantly host–microbiota co-metabolites and were mainly enriched in amino acid and lipid metabolic pathways. Importantly, seven of the nine genera previously identified in association with breast muscle yield exhibited heterosis in the crossbred progeny. At the metabolomic level, yield-associated genera were linked to a distinct set of 35 cecal metabolites, dominated by sphingolipids, ether-linked phospholipids, and acyl-homoserine lactones. These metabolites formed coordinated associations with the expression of 269 host genes, which were functionally enriched in MAPK signaling and focal adhesion pathways.</p> Conclusions <p>These findings suggest that heterosis exists not only in productive traits but also in gut microbiota and their metabolites, the latter in turn contributed to breast muscle yield, which offers valuable guidance for elucidating the molecular basis of heterosis in animals.</p>

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Gut microbiota and their metabolites contribute to the heterosis of breast muscle yield in broilers

  • Qiang Huang,
  • Chaoliang Wen,
  • Shuang Gu,
  • Yuchen Jie,
  • Guangqi Li,
  • Yiyuan Yan,
  • Guiqin Wu,
  • Ning Yang

摘要

Background

Breast muscle yield is a key economic trait in broilers, directly affecting carcass value and profitability, and has been significantly improved by intensive selection and exploiting heterosis through crossbreeding. Our previous work showed that synergy between the gut microbiota and host genome underlies breast muscle heterosis in crossbred progeny (CR) derived from Cornish (CC) and White Plymouth Rock (RR) lines. However, the molecular mechanisms by which the gut microbiota contributes to heterosis in breast muscle yield remain poorly understood. Here, we integrated cecal microbiome, metabolome, and transcriptome data from 266 birds at 42 days of age to elucidate the potential gut microbiota–mediated molecular mechanisms underlying breast muscle yield heterosis.

Results

To assess whether heterosis extends beyond productive traits to the gut microbiota and their metabolites in broilers, we compared the cecal microbial and metabolic profiles of CR with those of their parental lines. The gut microbiota of CR were clearly distinct from those of both parental lines and exhibited heterosis characteristics, with 88 genera displaying heterotic patterns that collectively accounted for approximately 85% of the total microbial abundance. Heterosis was also evident in the cecal metabolites of CR birds. Differential abundance analysis across groups identified 868 cecal metabolites, and abundance-pattern classification showed that approximately 75% exhibited nonadditive patterns in the crossbred progeny. These nonadditive metabolites were predominantly host–microbiota co-metabolites and were mainly enriched in amino acid and lipid metabolic pathways. Importantly, seven of the nine genera previously identified in association with breast muscle yield exhibited heterosis in the crossbred progeny. At the metabolomic level, yield-associated genera were linked to a distinct set of 35 cecal metabolites, dominated by sphingolipids, ether-linked phospholipids, and acyl-homoserine lactones. These metabolites formed coordinated associations with the expression of 269 host genes, which were functionally enriched in MAPK signaling and focal adhesion pathways.

Conclusions

These findings suggest that heterosis exists not only in productive traits but also in gut microbiota and their metabolites, the latter in turn contributed to breast muscle yield, which offers valuable guidance for elucidating the molecular basis of heterosis in animals.