ALBERT

Description: Nitroethane (NE), 2-nitroethanol (NEOH) and 2-nitro-1-propanol (NPOH) were investigated in order to determine their inhibitory effects on in vitro ruminal fermentation and methane (CH4) production of a hay-rich substrate (alfalfa hay: maize meal = 4:1, w/w). The rumen liquor collected from cannulated Holstein dairy cows was incubated at 39 °C for 72 h. The addition of NE, NEOH and NPOH slowed down the fermentation process and notably decreased molar CH4 proportion by 96.8, 96.4 and 35.0%, respectively. The abundance of total methanogen and methanogens from the order Methanobacteriales were all decreased with NE, NEOH and NPOH supplementation. Meanwhile, the nitrocompound addition reduced mcrA gene expression, coenzyme F420 and F430 contents. The correlation analysis showed that CH4 production was correlated positively with the population abundance of total methanogens, Methanobacteriales, mcrA gene expression, coenzyme contents of F420 and F430. The nitrocompound addition decreased acetate concentration and increased propionate and butyrate concentrations in the culture fluid. In summary, both NE and NEOH addition presented nearly the same inhibitory effectiveness on in vitro CH4 production; they were more effective than NPOH. The results of the current study provide evidence that NE, NEOH and NPOH can dramatically decrease methanogen population, mcrA gene expression and the coenzyme content of F420 and F430 in ruminal methanogenesis.

Description: SUMMARYThe objective of the present study was to investigate the effect of dietary neutral detergent fibre (NDF) : crude protein (CP) ratio on duodenal microbial crude protein (MCP) flow and nitrogen (N) losses. The study was completed in a 5 × 5 Latin square design with five lactating Holstein dairy cows and 5 high-concentrate total mixed rations (TMR) with different forage combinations, typical for Northern China. The rations with a fixed forage-to-concentrate ratio (39 : 61) resulted in different dietary NDF : CP ratios: TMR1 3·03 : 1 (428·2 g NDF/kg : 141·4 g CP/kg); TMR2 2·74 : 1 (392·7 g NDF/kg : 143·2 g CP/kg); TMR3 2·55 : 1 (368·3 g NDF/kg : 144·4 g CP/kg); TMR4 1·84 : 1 (304·8 g NDF/kg : 165·8 g CP/kg); TMR5 1·60 : 1 (285·0 g NDF/kg : 178·0 g CP/kg). Rumen content, milk, blood, urine and faeces were sampled on the last 3 days of five 18-day periods. Purine derivatives in the urine samples were determined to estimate rumen MCP flow into the small intestine. Milk yield and milk protein yield increased linearly with decreasing dietary NDF : CP ratio although slight differences in dry matter intake were observed due to feed intake restriction. Diurnal ammonia N in the rumen and duodenal MCP flow increased linearly, but blood urea N, urinary N and faecal N linearly decreased with decreasing dietary NDF : CP ratio. The enhanced N utilization in the maize-silage-based TMRs (TMR4–5) in comparison with maize-stover-based TMRs (TMR1–3) increased milk yield and the synthesis of milk protein instead of milk fat in the lactating cows, probably due to high transfer of ammonia N into rumen MCP with a considerable increase of dietary non-fibre carbohydrate content and the decrease of NDF : CP ratio. The present results indicate that not only increasing dietary non-structural carbohydrate content but also adjusting the ratio of structural carbohydrate to CP ratio are important diet formulation strategies for mitigating N losses in lactating cows.