Developmental regulation of adipose tissue growth through hyperplasia and hypertrophy in the embryonic Leghorn and broiler.

The United States is a world leader in poultry production, which is the reason why achieving better performance and muscle growth each year is a necessity. Reducing accretion of adipose tissue is another important factor for poultry producers because this allows more nutrients to be directed toward muscle growth, but the effect of embryonic adipose growth on posthatch development has not been fully understood. The purpose of this study was to investigate the total DNA mass, morphological characteristics, differentiation markers, and triglyceride breakdown factors of embryonic adipose tissue, and their relation to hyperplastic and hypertrophic growth within layers (Leghorn) and meat-type chickens (broilers). After embryonic day (E) 12, broiler weight was significantly higher than Leghorn, and this trend continued throughout the rest of incubation and posthatch (P < 0.05). Neck and leg fat pad weights between the 2 breeds did not differ at most of the time points. A remarkable increase in total DNA mass was observed between E12 and E14 in both Leghorn and broilers (P < 0.05), indicating a high potential for hyperplastic growth during this time. Histological analysis revealed clusters of preadipocytes at E12; however, the majority of these cells differentiated by E14 and continued to grow until the time of hatch. The adipocyte sizes between both breeds did not generally differ, even though broilers are known to have larger adipocytes posthatch. Fatty acid-binding protein 4 expression levels in Leghorn and broilers continued to rise with each time point, which paralleled the expansion of mature adipocytes. Adipose triglyceride lipase was highly expressed at E20 and d 1 posthatch to mobilize triglyceride degradation for energy during hatching. Thus, embryonic chicken adipose tissue was found to develop by hyperplastic mechanisms followed by hypertrophy. At embryonic stages and early posthatch, layer- and meat-type chicken adipose growth does not differ, which suggests breed differences occur posthatch.

Selenium promotes adipogenic determination and differentiation of chicken embryonic fibroblasts with regulation of genes involved in fatty acid uptake, triacylglycerol synthesis and lipolysis.

Selenium (Se) has been utilized in the differentiation of primary pig and rat preadipocytes, indicating that it may have proadipogenic potential; however, some studies have also demonstrated that Se has antiadipogenic activity. In this study, chicken embryonic fibroblasts (CEFs) were used to investigate the role of Se in adipogenesis in vitro and in ovo. Se supplementation increased lipid droplet accumulation and inhibited proliferation of cultured CEFs isolated from 6-day-old embryos dose-dependently. This suggests that Se may play a role in cell cycle inhibition, thereby promoting the differentiation of fibroblasts to adipocytes. Se did not stimulate adipogenic differentiation of CEFs isolated from 9- to 12-day-old embryos, implying a permissive stage of adipogenic determination by Se at earlier embryonic ages. Microarray analysis comparing control and Se treatments on CEFs from 6-day-old embryos and confirmatory analysis by quantitative real-time polymerase chain reaction revealed that genes involved in adipocyte determination and differentiation, fatty acid uptake and triacylglycerol synthesis were up-regulated. In addition, up-regulation of an anti-lipolytic G0/G1 switch gene 2 and down-regulation of a prolipolytic monoglyceride lipase may lead to inhibition of lipolysis by Se. Both osteogenic and myogenic genes were down-regulated, and several genes related to oxidative stress response during adipogenesis were up-regulated. In ovo injection of Se at embryonic day 8 increased adipose tissue mass by 30% and caused adipocyte hypertrophy in 17-day-old chicken embryos, further supporting the proadipogenic role of Se during the embryonic development of chickens. These results suggest that Se plays a significant role in several mechanisms related to adipogenesis.