Demands for animal products are projected to increase in the future, and animal production is key to agricultural sustainability and food security; consequently, enhancing ruminant livestock production efficiencies in sustainable ways is a major goal for the livestock industry. Developmental programming is the concept that various stressors, including compromised maternal nutrition during critical developmental windows will result in both short- and long-term changes in the offspring. Ruminant models of developmental programming indicate that compromised maternal nutrition, including global under and over-nutrition, macronutrients, and specific micronutrients, including amino acids (Met and Arg), vitamins (folate, B12, and choline), and minerals (sulfur, cobalt, and selenium) can alter offspring outcomes. Data also suggest that maternal histotrophic composition, placental function, and likely fetal nutrient supply are altered by compromised maternal nutrition. Likewise, in offspring, visceral organ mass and function, metabolism, growth, and reproduction are affected. Findings from multi-omics approaches demonstrate that compromised maternal nutrition alters transcript abundance, metabolomic profiles, and multiple metabolic pathways. The underlying mechanisms of developmental programming are driven by epigenetic events, which depend on one-carbon metabolism and micronutrient supply. Current findings indicate that developmental programming in ruminants is real, that maternal nutrition can be a major driver of developmental programming, and that genomic and metabolomic changes in offspring are modulated by altered maternal nutrition during critical windows of development. Research needs in the area of developmental programming in ruminants include: enhanced understanding of the underlying mechanisms, practical relevance to production systems, impacts on short- and long-term animal health including longevity, interrelationships between maternal and paternal influences, intergenerational impacts, and interrelationships with the host microbiome. Additionally, strategic supplementation and precision nutrition approaches should be developed to foster the positive and mitigate the negative aspects of developmental programming to improve the efficiency and sustainability of ruminant livestock production systems.
Keywords: beef cattle; developmental programming; epigenetics; nutrition.
The Authors. Published by Elsevier Inc. on behalf of the American Dairy Science Association®. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).