Functional efficacy analysis of Angelica gigas Nakai on chicken myoblast cells through cell-based in vitro assay.

The value-added products in livestock industry is one of the key issues in order to maximize the revenue and to create a new business model. Numerous studies have suggested application of herbal plants as feed additives to increase health, productivity, and/or high-quality product in livestock. In this study, the first experiment was designed to develop in vitro evaluation system by using primary chicken myoblast (pCM) cells isolated from pectoralis major of 10-day-old male embryos. Subsequently, to evaluate effects of Korean Danggui Angelica gigas Nakai (AGN), we optimized the concentration of AGN root extract for treatment of primary pCM cells. After the treatment of AGN root extract, we compared proliferation and differentiation capacity, and also examined the gene expression. In the second experiment, the next generation sequencing analysis was performed to compare the different patterns of the global gene expression in pCM cells treated with AGN extract. Three up-regulated (pancreas beta cells, fatty acid metabolism and glycolysis) and one down-regulated (adipogenesis) gene sets were characterized suggesting that the AGN extract affected the metabolic pathways for the utilization of fat and glucose in chicken muscle cells. Furthermore, we validated the expression patterns of the up-regulated genes (GCLC, PTPN6, ISL1, SLC25A13, TGFBI, and YWHAH) in the AGN-treated pCM cells by quantitative RT-PCR. These results demonstrated that the treatment of AGN extract decreased proliferation and differentiation of pCM cells, and affected the metabolic pathways of glucose and fatty acids. Moreover, AGN extract derived from byproducts such as stem and leaf also showed the reduced proliferation patterns on AGN-treated pCM cells. Taken together, pCM cell-based in vitro assay system could be primarily and efficiently applied for evaluating the biofunctional efficacy of various feed additive candidates.

Effects of Angelica gigas Nakai on the production of decursin- and decursinol angelate-enriched eggs.

BACKGROUND: The livestock industry requires high-quality products, as well as improved productivity. There have been many studies regarding the utilization of feed additives aiming to increase productivity, enhance immune functions and prevent infectious diseases in livestock. Biofunctional feed additives would be beneficial not only for animal health, but also for consumers. In the present study, we utilized root and byproduct (stem and leaf) powders of Angelica gigas Nakai (AGN, Korean Danggui) as feed additives and examined the deposition of biofunctional compounds, such as decursin and decursinol angelate, into egg white and yolk. RESULTS: We optimized the detection system for decursin and decursinol angelate, and determined the amounts of decursin and decursinol angelate derived from AGN byproducts (stem and leaf) as well as root. In Experiment 1, laying hens were fed with the dried AGN root powder and the effective compounds were detected in egg white and yolk. Subsequently, in Experiment 2, we examined AGN byproducts as an alternative feeding supplement. Additionally, biochemical parameters were analyzed to evaluate changes in the health of the hens by feeding AGN root powder. The results obtained indicated that decursin and decursinol angelate were stably transferred into egg white and yolk by feeding AGN byproducts as well as root. Intriguingly, plasma cholesterol levels were significantly decreased in a dose-dependent manner, and those of interleukin-1ß, as an immune-related biomarker, were considerably increased in the treated hens. CONCLUSION: These results indicated that AGN root and byproducts (stem and leaf) could be utilized for the production of value-added eggs and improving the health of hens in the poultry industry. © 2018 Society of Chemical Industry.

Prepubertal growth and single nucleotide polymorphism analysis of the growth hormone gene of low birth weight Holstein calves.

Holstein calves weighing less than 20 kg at birth have been noted in Korea. Due to insufficient information, we raised small calves with age-matched normal birth weight Holstein calves and determined body weights before puberty. In addition, 3 single nucleotide polymorphisms (SNPs) of the growth hormone (GH) gene were analyzed. Up to 10 months of age, low birth weight calves were smaller than normal weight calves. In exon 5 of the GH gene, SNP genotype variation was detected in some small calves; however, this did not appear to be the only factor inducing low birth weight and slow growth.