Abstract
The effects of birth weight (BiW; low BiW [LBW] vs. high BiW [HBW]) and estimated breeding value (EBV) for protein deposition (low EBV [LBV] vs. high EBV [HBV]) on N retention, N efficiency, and concentrations of metabolites in plasma and urine related to N efficiency in growing pigs were studied. At an age of 14 wk, 10 LBW–LBV (BiW: 1.07 ± 0.09 [SD] kg; EBV: −2.52 ± 3.97 g/d, compared with an average crossbred pig with a protein deposition of 165 g/d), 10 LBW–HBV (BiW: 1.02 ± 0.13 kg; EBV: 10.47 ± 4.26 g/d), 10 HBW–LBV (BiW: 1.80 ± 0.13 kg; EBV: −2.15 ± 2.28 g/d), and 10 HBW–HBV (BiW: 1.80 ± 0.15 kg; EBV: 11.18 ± 3.68 g/d) male growing pigs were allotted to the experiment. The pigs were individually housed in metabolism cages and were subjected to an N balance study in two sequential periods of 5 d, after an 11-d dietary adaptation period. Pigs were assigned to a protein adequate (A) or protein restricted (R, 70% of A) regime in a change-over design. Pigs were fed 2.8 times the energy requirements for maintenance. Nontargeted metabolomics analyses were performed in urine and blood plasma samples. The N retention (in g/d) was higher in the HBW than in the LBW pigs (P < 0.001). The N retention (in g/[kg metabolic body weight (BW0.75) · d]) and N efficiency, however, were not affected by the BiW of the pigs. The N retention (P = 0.04) and N efficiency (P = 0.04) were higher in HBV than in LVB pigs on the A regime but were not affected by EBV in pigs on the R regime. Restricting the dietary protein supply with 30% decreased the N retention (P < 0.001) but increased the N efficiency (P = 0.003). Nontargeted metabolomics showed that a hexose, free amino acids (AA), and lysophosphatidylcholines were the most important metabolites in plasma for the discrimination between HBV and LBV pigs, whereas metabolites of microbial origin contributed to the discrimination between HBV and LBV pigs in urine. This study shows that BiW does not affect N efficiency in the later life of pigs. Nitrogen efficiency and N retention were higher in HBV than in LBV pigs on the A regime but similar in HBV and LBV pigs on the R regime. In precision feeding concepts aiming to further optimize protein and AA efficiency in pigs, the variation in EBV for protein deposition of pigs should be considered as a factor determining N retention, growth performance, and N efficiency.
Highlights
Optimizing nitrogen (N) efficiency is essential to increase the sustainability of pig production systems (FAO, 2006) and to reduce the environmental impact
Nontargeted metabolomics showed that a hexose, free amino acids (AA), and lysophosphatidylcholines were the most important metabolites in plasma for the discrimination between high EBV (HBV) and low EBV (LBV) pigs, whereas metabolites of microbial origin contributed to the discrimination between HBV and LBV pigs in urine
In the first balance period data of two low birth weight (LBW)–HBV pigs and one high birth weight (HBW)–HBV pig and, in the second balance period data of two LBW–LBV pigs were excluded from the results because these pigs refused more than 15% of their daily feed allowance
Summary
Optimizing nitrogen (N) efficiency is essential to increase the sustainability of pig production systems (FAO, 2006) and to reduce the environmental impact. LBW piglets have a lower number of muscle fibers at birth (Alvarenga et al, 2013) and eat and grow less during the weaning and growing period (Rehfeldt et al, 2008; Alvarenga et al, 2013) compared with high birth weight (HBW) piglets. This may result in differences in N retention between LBW and HBW pigs in the growing phase. HBW pigs showed lower plasma concentrations of α-amino N and metabolites derived from AA, suggesting a higher protein deposition in these pigs
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