Conserve, Characterize, and Use of Genetic Resources
U.S. livestock are produced in a wide array of environments and management systems. The efficiency of livestock and poultry production has dramatically improved due to advances in genetic selection programs, however, intense and highly successful selection generally leads to narrowing the genetic base of a species. Maintaining genetic diversity is essential for providing animal food and fiber products in the future by having livestock and poultry that will perform efficiently in different climates, production systems, and when exposed to new diseases and provide quality products that meet the changing demands of consumers. The National Animal Germplasm Program will identify, preserve, characterize, and distribute germplasm for future use. The associated information will be stored in the animal component of the GRIN (Genetic Resources Information Network) database. DNA of relevant germplasm will be stored and provided to researchers for genomic characterization and analysis. Research is needed to improve the viability of cryopreserved germplasm for some species.
Product Quality (Pre-Harvest)
New knowledge is needed to understand the genetics affecting product quality and improve
the control and manipulation of physiological systems supporting muscling, growth, metabolism, and mammary function. Research will focus on identifying genes that influence product quality, factors directing nutrient partitions toward protein and less fat, enhanced nutrient composition in animal products and enhanced tenderness of meat.
Genomic Tools
Animal Genomics will play an increasingly important role in assuring the continued profitability and competitiveness of U.S. animal agriculture. Identifying, mapping, and understanding the function and control of genes will permit the development of new genetic technologies and increase our ability to realize the full genetic potential of agriculturally important, food animals. Microorganisms are also an integral component of animal production and understanding the genomes of these organisms will enable the development of new products or management systems that will enhance profitabiltiy, quality, and environmental impact animal production and quality and safety of animal products. The objectives of this program are to map, identify, and sequence genes, determine the function of genes that influence animal production, and identify, sequence and determine the function of microbial genes that influence animal production. The genomic information will used in genectic selection programs, to alter or develop management systems and develop new products for animal production or new meat, eggs and milk products for human consumption.
Growth and Development
Suboptimal growth and development are limiting factors in animal productivity. Basic
information regarding developmental processes in agriculturally important animals is largely lacking. The primary objective of the program is to increase our understanding of the biological mechanisms underlying normal animal growth development of the musculoskeletal system, lactation, digestion, and nutrient metabolism. New knowledge in these areas is needed to improve animal production and the control and manipulation of muscling, growth, metabolism, and mammary function. Research is also needed on specific nutrient regulated biological responses.
Nutrient Intake and Utilization
Nutrition is the single most costly component in modern animal production. Suboptimal
nutrition is a significant factor in the failure to realize genetic potential for production and increased susceptibility to disease. Economically optimizing nutrient supply and use is imperative for improving growth and reproduction, and to maximizing overall production efficiency. Research is needed in the following areas to improve animal nutrition: 1) chemical composition and availability of nutrients in feedstuffs, 2) nutritional requirements of grazing and non-grazing animals, 3) more efficient use of nutrients, 4) special attention to functions. (e.g., reproduction, growth, and lactation), and 5) minimize non-productive nutrient losses.