PSV-10 Effects of Rumen-Bypass Protein Supplement on Growth Performance, Hepatic Mitochondrial Function and Immune Gene Expression of Beef Steers with Divergent Residual Feed Intake Phenotype

Abstract

Abstract We examined the effects of rumen-bypass protein supplement on growth performance, hepatic mitochondrial Electron Transport Chain (ETC) activities, and mRNA expression of innate and adaptive immune genes of beef steers with divergent residual feed intake (RFI) phenotype. Thirty-nine crossbred beef steers (average BW = 492 ± 36 kg) were used in a generalized randomized block design with a 2 × 2 factorial arrangement of treatments for a 42-d experimental period. The factors evaluated were 1) RFI classification [low-RFI (-2.12kg/d) vs. high-RFI (2.02kg/d)], and 2) feed additive: rumen-bypass protein supplement (RCP; 227 g· steer-1· day-1) vs. Control diet (CON; 0 g/d), resulting in four treatments: Low-RFI-CON (n = 10), low-RFI-RCP (n = 9), high-RFI-CON (n = 10), and high-RFI-RCP (n = 10). The rumen-bypass protein supplement (84% CP) is a blend of hydrolyzed feather meal, porcine blood meal, and DL-methionine hydroxy analogue. The beef steers were stratified by BW and randomly assigned to treatments and housed in four pens equipped with two GrowSafe feed bunks each to measure individual DMI. Body weight was measured every 7 days. Liver tissue was sampled on d 42 from all animals using a liver biopsy needle for mRNA expression analysis of 84 immune genes and analysis of mitochondrial ETC activities of complexes I – V. No effects of supplemental feed additive or RFI × feed additive interactions were observed (P > 0.05) for ADG and DMI. Compared with high-RFI, low-RFI beef steers tended to have less DMI (13.6 vs 12.9 kg/d; P = 0.09) but ADG was similar for the two RFI groups. Feed additive × RFI interactions were observed (P ≤ 0.05) for mitochondrial activities of Complexes IV, V, and mRNA expressions of some immune genes. Supplemental RCP increased Complex IV (39.2 nmol/min/mg) activity and reduced that of Complex V (94.1 nmol· min-1· mg-1) in high-RFI beef steers whereas the activity of Complex IV (13.1 nmol· min-1· mg-1) was reduced and that of Complex V (120 nmol· min-1· mg-1) was increased in low-RFI beef steers. Supplemental RCP increased (P < 0.05) the mRNA expression of TLR2 [fold change (FC) = 1.17 vs 0.98], TLR3 (FC = 1.49 vs 0.97), NFKB1 (FC = 1.02 vs 0.90), and IL23A (FC = 1.35 vs 1.07) in high-RFI beef steers but the expression of these genes were not altered in low-RFI beef steers. In conclusion, RCP supplementation did not affect the growth performance and the observed effects on hepatic immune gene expression and activities of mitochondrial ETC complexes are dependent on the RFI phenotype of the beef steers. Further research should explore the mechanism responsible for the interactions between RCP supplementation and RFI status.