Multi-tissue gene expression profiling of cows with a genetic predisposition for low and high milk urea levels

Multi-tissue gene expression profiling of cows with a genetic predisposition for low and high milk urea levels

Milk urea (MU) concentration is proposed as an indicator trait for breeding toward reduced nitrogen (N) emissions and leaching in dairy. We selected 20 German Holstein cows based on MU breeding values, with 10 cows each having low (LMUg) and high (HMUg) MU genetic predisposition. Using RNA-seq, we c...

Full description

Saved in:
Bibliographic Details
Main Authors: Henry Reyer, Hanne Honerlagen, Michael Oster, Siriluck Ponsuksili, Björn Kuhla, Klaus Wimmers
Format: Article
Language:English
Published: Taylor & Francis Group 2024-12-01
Series:Animal Biotechnology
Subjects:
RNAseq
nitrogen emissions
mammary gland
liver
kidney
Online Access:https://www.tandfonline.com/doi/10.1080/10495398.2024.2322542
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Milk urea (MU) concentration is proposed as an indicator trait for breeding toward reduced nitrogen (N) emissions and leaching in dairy. We selected 20 German Holstein cows based on MU breeding values, with 10 cows each having low (LMUg) and high (HMUg) MU genetic predisposition. Using RNA-seq, we characterized these cows to unravel molecular pathways governing post-absorptive body N pools focusing on renal filtration and reabsorption of nitrogenous compounds, hepatic urea formation and mammary gland N excretion. While we observed minor adjustments in cellular energy metabolism in different tissues associated with different MU levels, no transcriptional differences in liver ammonia detoxification were detected, despite significant differences in MU between the groups. Differential expression of AQP3 and SLC38A2 in the kidney provides evidence for higher urea concentration in the collecting duct of LMU cows than HMU cows. The mammary gland exhibited the most significant differences, particularly in tricarboxylic acid (TCA) cycle genes, amino acid transport, tRNA binding, and casein synthesis. These findings suggest that selecting for lower MU could lead to altered urinary urea (UU) handling and changes in milk protein synthesis. However, given the genetic variability in N metabolism components, the long-term effectiveness of MU-based selection in reducing N emissions remains uncertain.
ISSN:1049-5398
1532-2378

Similar Items