Background: The objective of this study was to investigate the effect of dietary restriction and subsequent compensatory growth on the relative expression of genes involved in volatile fatty acid transport, metabolis...Background: The objective of this study was to investigate the effect of dietary restriction and subsequent compensatory growth on the relative expression of genes involved in volatile fatty acid transport, metabolism and cell proliferation in ruminal epithelial tissue of beef cattle. Sixty Holstein Friesian bulls(mean liveweight 370 ± 35 kg;mean age 479 ± 15 d) were assigned to one of two groups:(i) restricted feed allowance(RES; n = 30) for 125 d(Period 1) followed by ad libitum access to feed for 55 d(Period 2) or(ii) ad libitum access to feed throughout(ADLIB; n = 30). Target growth rate for RES was 0.6 kg/d during Period 1. At the end of each dietary period, 15 animals from each treatment group were slaughtered and ruminal epithelial tissue and liquid digesta harvested from the ventral sac of the rumen. Real-time q PCR was used to quantify m RNA transcripts of 26 genes associated with ruminal epithelial function. Volatile fatty acid analysis of rumen fluid from individual animals was conducted using gas chromatography.Results: Diet × period interactions were evident for genes involved in ketogenesis(BDH2, P = 0.017), pyruvate metabolism(LDHa, P = 0.048; PDHA1, P = 0.015) and cellular transport and structure(DSG1, P = 0.019; CACT, P = 0.027). Ruminal concentrations of propionic acid(P = 0.018) and n-valeric acid(P = 0.029) were lower in RES animals, compared with ADLIB, throughout the experiment. There was also a strong tendency(P = 0.064)toward a diet × period interaction for n-butyric with higher concentrations in RES animals, compared with ADLIB, during Period 1.Conclusions: These data suggest that following nutrient restriction, the structural integrity of the rumen wall is compromised and there is upregulation of genes involved in the production of ketone bodies and breakdown of pyruvate for cellular energy. These results provide an insight into the potential molecular mechanisms regulating ruminal epithelial absorptive metabolism and growth following nutrient restriction and subsequent compensatory growth.展开更多
Background: Studies have shown clear differences between dairy breeds in their feed intake and production efficiencies. The duodenum is critical in the coordination of digestion and absorption of nutrients. This stud...Background: Studies have shown clear differences between dairy breeds in their feed intake and production efficiencies. The duodenum is critical in the coordination of digestion and absorption of nutrients. This study examined gene transcript abundance of important classes of nutrient transporters in the duodenum of non lactating dairy cows of different feed efficiency potential, namely Holstein-Friesian (HF), Jersey (JE) and their F1 hybrid. Duodenal epithelial tissue was collected at slaughter and stored at -80℃. Total RNA was extracted from tissue and reverse transcribed to generate cDNA. Gene expression of the following transporters, namely nucleoside amino acid; sugar; mineral; and lipid transporters was measured using quantitative real-time RT-PCR. Data were statistically analysed using mixed models ANOVA in SAS. Orthogonal contrasts were used to test for potential heterotic effects and spearman correlation coefficients calculated to determine potential associations amongst gen, expression values and production efficiency variables. Results: While there were no direct effects of genotype on expression values for any of the genes examined, there was evidence for a heterotic effect (P 〈 0.05) on ABCGS, in the form of increased expression in the F1 genotype compared to either of the two parent breeds. Additionally, a tendency for increased expression of the amino acid transporters, SLC3A1 (P= 0.072), SLC3A2 (P= 0.081) and SLC6A 14 (P= 0.072) was also evident in the F1 genotype. A negative (P 〈 0.05) association was identified between the expression of the glucose transporter gene SLCSA1 and total lactational milk solids yield, corrected for body weight. Positive correlations (P 〈 0.05) were also observed between the expression values of genes involved in common transporter roles. Conclusion: This study suggests that differences in the expression of sterol and amino acid transporters in the duodenum could contribute towards the documented differences in feed efficiency between HF, JE and their F1 hybrid. Furthermore, positive associations between the expression of genes involved in common transporter roles suggest that these may be co-regulated. The study identifies potential candidates for investigation of genetic variants regulating nutrient transport and absorption in the duodenum in dairy cows, which may be incorporated into future breeding programmes.展开更多
基金funded through Science Foundation Ireland(SFI)contract no 09/RFP/GEN2447
文摘Background: The objective of this study was to investigate the effect of dietary restriction and subsequent compensatory growth on the relative expression of genes involved in volatile fatty acid transport, metabolism and cell proliferation in ruminal epithelial tissue of beef cattle. Sixty Holstein Friesian bulls(mean liveweight 370 ± 35 kg;mean age 479 ± 15 d) were assigned to one of two groups:(i) restricted feed allowance(RES; n = 30) for 125 d(Period 1) followed by ad libitum access to feed for 55 d(Period 2) or(ii) ad libitum access to feed throughout(ADLIB; n = 30). Target growth rate for RES was 0.6 kg/d during Period 1. At the end of each dietary period, 15 animals from each treatment group were slaughtered and ruminal epithelial tissue and liquid digesta harvested from the ventral sac of the rumen. Real-time q PCR was used to quantify m RNA transcripts of 26 genes associated with ruminal epithelial function. Volatile fatty acid analysis of rumen fluid from individual animals was conducted using gas chromatography.Results: Diet × period interactions were evident for genes involved in ketogenesis(BDH2, P = 0.017), pyruvate metabolism(LDHa, P = 0.048; PDHA1, P = 0.015) and cellular transport and structure(DSG1, P = 0.019; CACT, P = 0.027). Ruminal concentrations of propionic acid(P = 0.018) and n-valeric acid(P = 0.029) were lower in RES animals, compared with ADLIB, throughout the experiment. There was also a strong tendency(P = 0.064)toward a diet × period interaction for n-butyric with higher concentrations in RES animals, compared with ADLIB, during Period 1.Conclusions: These data suggest that following nutrient restriction, the structural integrity of the rumen wall is compromised and there is upregulation of genes involved in the production of ketone bodies and breakdown of pyruvate for cellular energy. These results provide an insight into the potential molecular mechanisms regulating ruminal epithelial absorptive metabolism and growth following nutrient restriction and subsequent compensatory growth.
基金funded by Teagasc as part of the Irish National Development Plan
文摘Background: Studies have shown clear differences between dairy breeds in their feed intake and production efficiencies. The duodenum is critical in the coordination of digestion and absorption of nutrients. This study examined gene transcript abundance of important classes of nutrient transporters in the duodenum of non lactating dairy cows of different feed efficiency potential, namely Holstein-Friesian (HF), Jersey (JE) and their F1 hybrid. Duodenal epithelial tissue was collected at slaughter and stored at -80℃. Total RNA was extracted from tissue and reverse transcribed to generate cDNA. Gene expression of the following transporters, namely nucleoside amino acid; sugar; mineral; and lipid transporters was measured using quantitative real-time RT-PCR. Data were statistically analysed using mixed models ANOVA in SAS. Orthogonal contrasts were used to test for potential heterotic effects and spearman correlation coefficients calculated to determine potential associations amongst gen, expression values and production efficiency variables. Results: While there were no direct effects of genotype on expression values for any of the genes examined, there was evidence for a heterotic effect (P 〈 0.05) on ABCGS, in the form of increased expression in the F1 genotype compared to either of the two parent breeds. Additionally, a tendency for increased expression of the amino acid transporters, SLC3A1 (P= 0.072), SLC3A2 (P= 0.081) and SLC6A 14 (P= 0.072) was also evident in the F1 genotype. A negative (P 〈 0.05) association was identified between the expression of the glucose transporter gene SLCSA1 and total lactational milk solids yield, corrected for body weight. Positive correlations (P 〈 0.05) were also observed between the expression values of genes involved in common transporter roles. Conclusion: This study suggests that differences in the expression of sterol and amino acid transporters in the duodenum could contribute towards the documented differences in feed efficiency between HF, JE and their F1 hybrid. Furthermore, positive associations between the expression of genes involved in common transporter roles suggest that these may be co-regulated. The study identifies potential candidates for investigation of genetic variants regulating nutrient transport and absorption in the duodenum in dairy cows, which may be incorporated into future breeding programmes.
