Abstract
Two experiments were done to evaluate the effect of increasing levels of dietary digestible methionine (Met) and Met:cysteine (Met:Cys) ratio on the productivity of Hy-Line W-36 laying hens fed sorghum- and soybean meal-based diets. In Exp. 1, 160 hens from 68 to 75 weeks of age were assigned to four dietary levels of digestible Met (0.20 0.24, 0.28 and 0.32%). The digestible total sulfur amino acids:Lysine (TSAA:Lys) ratios were: 62, 68, 76 and 84%. In Exp. 2, 192 hens from 76-83 weeks of age were assigned to four dietary digestible Met:Cys ratios (160, 116.7, 85.7 and 62.5%). The digestible TSAA:Lys ratio was kept constant across diets (80%). Results were subjected to ANOVA and linear regression analyses. In Exp. 1, optimal egg production, egg mass, and feed efficiency responses were observed at 0.30 and 0.50% of dietary digestible Met and TSAA, respectively (quadratic effect, p<0.05). Live performance was maximized with digestible Met and TSAA in takes of 288 and 478 mg/hen/d, respectively. In Exp. 2, optimal egg production and feed efficiency responses were observed at 151 and 150% of dietary digestible Met:Cys ratios, respectively (quadratic effect, p<0.05). The digestible Met, Cys and TSAA intake to maximize egg production and feed efficiency were 313, 207 and 510 mg/hen/d, respectively. The requirements for sulfur AA in Hy-Line W-36 hens from 68 to 83 weeks of age fed sorghum- and soybean meal-based diets fell inside the range of the requirements previously estimated in hens fed corn-soybean meal based diets.
Highlights
The results indicate a quadratic response (p< 0.05) of egg production (y = - 14.975 + 658.13x -1109.4x2; R2 = 0.95), egg mass (y = - 45.87 + 584.5x -937.5x2; R2 = 0.98), and feed efficiency (y = - 0.4828 + 6.1526x -9.8684x2; R2 = 0.98) to increasing dietary digestible Met levels
It was assumed that AA requirements for egg production were the same, regardless of the age of the hens
The NRC (1994) recommends a single requirement for each AA during the first and the second cycles of egg production, given that the changes in AA requirements are regulated by changes in the level of feed intake of the hens
Summary
Sorghum tolerates heat and salinity better than corn, and can grow in a wide variety of soils with a limited supply of nutrients (Dendy & Dobraszczyk, 2001; Gómez et al, 2009). Given the advantages of sorghum, its production is strategic in several parts of the world and is one of the best animal feeding alternatives in places where other crops have poorer yields or their production is not feasible. Due to the declining global grain stocks due to global warming, it is expected that in the near future heat resistant crops such as sorghum are routinely utilized as food and feed resources for humans and animals (Selle et al, 2010; García et al, 2013)
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