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IntroductionIt has been reported that approximately 37 million metric tons of forage protein were consumed by animals to produce an estimated 5.4 million tons of animal protein for human consumption every year in the United States (Pimental et al., 1980). Among animals, ruminants are the predominant forage utilizers (Wedin et al., 1975). Forages provide 83% of the protein requirements of beef cattle and 90% of the protein requirements of sheep (Griffith, 1978).Forage protein serves as a source of metabolizable protein to the ruminant by providing both ruminally degradable protein for microbial growth, and some ruminally undegradable protein for intestinal digestion . Because of rapid and extensive degradauon of forages in the rumen (Brown and Pitman, 1991), escape protein concentrations of forages are usually low . One approach to increase the amount of protein which reaches the small intestine is to improve efficiency of microbial protein synthesis in animals fed forages.Efficiency of microbial growth is dependent on amounts and types of nitrogen and carbohydrate sources of the diet , the feed intake by the animals , as well as the concentrations of trace minerals and vitamins in the diet . Concentrations of nitrogen, fiber fractions and readily fermentable carbohydrates significantly differ between legume and grass species and even within legume 2 and grass species (Brown and Pitman, 1991). Although ruminal nitrogen degradation is extensive, low absolute quantities of ruminally soluble and degradable nitrogen may limit microbial growth in ruminants fed grass diets (Brown and Pitman, 1991). A lack of readily fermentable carbohydrate sources in forage is another limitation for optimal microbial gr...
