piggyBac Transposition and the Expression of Human Cystatin C in Transgenic Chickens.

A bioreactor can be used for mass production of therapeutic proteins and other bioactive substances. Although various methods have been developed using microorganisms and animal cells, advanced strategies are needed for the efficient production of biofunctional proteins. In microorganisms, post-translational glycosylation and modification are not performed properly, while animal cell systems require more time and expense. To overcome these problems, new methods using products from transgenic animals have been considered, such as genetically modified cow's milk and hen's eggs. In this study, based on a non-viral piggyBac transposition system, we generated transgenic bioreactor chickens that produced human cystatin C (hCST3). There were no differences in the phenotype or histochemical structure of the wild-type and hCST3-expressing transgenic chickens. Subsequently, we analyzed the hCST3 expression in transgenic chickens, mainly in muscle and egg white, which could be major deposition warehouses for hCST3 protein. In both muscle and egg white, we detected high hCST3 expression by ELISA and Western blotting. hCST3 proteins were efficiently purified from muscle and egg white of transgenic chickens using a His-tag purification system. These data show that transgenic chickens can be efficiently used as a bioreactor for the mass production of bioactive materials.

Muscle differentiation induced by p53 signaling pathway-related genes in myostatin-knockout quail myoblasts.

The myostatin (MSTN) gene is of interest in the livestock industry because mutations in this gene are closely related to growth performance and muscle differentiation. Thus, in this study, we established MSTN knockout (KO) quail myoblasts (QM7) and investigated the regulatory pathway of the myogenic differentiation process. We used clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9 to generate MSTN KO QM7 cells and subsequently isolated a single cell-derived MSTN KO QM7 subline with 10- and 16-nucleotide deletions that induced translational frameshift mutations. The differentiation capacity and proliferation rate of MSTN KO QM7 cells were enhanced. We conducted next-generation-sequencing (NGS) analysis to compare the global gene expression profiles of wild-type (WT) QM7 and MSTN KO QM7 cells. Intriguingly, NGS expression profiles showed different expression patterns of p21 and p53 in MSTN KO QM7 cells. Moreover, we identified downregulated expression patterns of leukemia inhibitory factor and DNA Damage Inducible Transcript 4, which are genes in the p53 signaling pathway. Using quantitative RT-PCR (qRT-PCR) analysis and western blotting, we concluded that p53-related genes promote the cell cycle by upregulating p21 and enhancing muscle differentiation in MSTN KO QM7 cells. These results could be applied to improve economic traits in commercial poultry by regulating MSTN-related networks.

Functional analyses of miRNA-146b-5p during myogenic proliferation and differentiation in chicken myoblasts.

BACKGROUND: In the poultry and livestock industries, precise genetic information is crucial for improving economic traits. Thus, functional genomic studies help to generate faster, healthier, and more efficient animal production. Chicken myoblast cells, which are required for muscle development and regeneration, are particularly important because chicken growth is closely related to muscle mass. RESULTS: In this study, we induced expression of microRNA-146b-5p mediated by the piggyBac transposon system in primary chicken myoblast (pCM) cells. Subsequently, we analyzed and compared the proliferation and differentiation capacity and also examined the expression of related genes in regular pCM (rpCM) cells and pCM cells overexpressing miRNA-146b-5p (pCM-146b OE cells). pCM-146b OE cells showed increased proliferation and upregulated gene expression related to cell proliferation. In addition, next-generation sequencing analyses were performed to compare global gene expression patterns between rpCM cells and pCM-146b OE cells. We found that the higher proliferation in pCM-146b OE cells was the result of upregulation of gene sets related to the cell cycle. Moreover, miRNA-146b-5p overexpression had inhibitory effects on myotube differentiation in pCM cells. CONCLUSIONS: Collectively these results demonstrate that miR-146b-5p is closely related to the proliferation and differentiation of chicken myogenic cells as a modulator of post-transcription.

Generation of myostatin-knockout chickens mediated by D10A-Cas9 nickase.

Many studies have been conducted to improve economically important livestock traits such as feed efficiency and muscle growth. Genome editing technologies represent a major advancement for both basic research and agronomic biotechnology development. The clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9 technical platform is a powerful tool used to engineer specific targeted loci. However, the potential occurrence of off-target effects, including the cleavage of unintended targets, limits the practical applications of Cas9-mediated genome editing. In this study, to minimize the off-target effects of this technology, we utilized D10A-Cas9 nickase to generate myostatin-knockout (MSTN KO) chickens via primordial germ cells. D10A-Cas9 nickase (Cas9n)-mediated MSTN KO chickens exhibited significantly larger skeletal muscles in the breast and leg. Degrees of skeletal muscle hypertrophy and hyperplasia induced by myostatin deletion differed by sex and muscle type. The abdominal fat deposition was dramatically lower in MSTN KO chickens than in wild-type chickens. Our results demonstrate that the D10A-Cas9 technical platform can facilitate precise and efficient targeted genome engineering and may broaden the range of applications for genome-edited chickens in practical industrialization and as animal models of human diseases.

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.

Muscle differentiation induced up-regulation of calcium-related gene expression in quail myoblasts.

OBJECTIVE: In the poultry industry, the most important economic traits are meat quality and carcass yield. Thus, many studies were conducted to investigate the regulatory pathways during muscle differentiation. To gain insight of muscle differentiation mechanism during growth period, we identified and validated calcium-related genes which were highly expressed during muscle differentiation through mRNA sequencing analysis. METHODS: We conducted next-generation-sequencing (NGS) analysis of mRNA from undifferentiated QM7 cells and differentiated QM7 cells (day 1 to day 3 of differentiation periods). Subsequently, we obtained calcium related genes related to muscle differentiation process and examined the expression patterns by quantitative reverse-transcription polymerase chain reaction (qRT-PCR). RESULTS: Through RNA sequencing analysis, we found that the transcription levels of six genes (troponin C1, slow skeletal and cardiac type [TNNC1], myosin light chain 1 [MYL1], MYL3, phospholamban [PLN], caveolin 3 [CAV3], and calsequestrin 2 [CASQ2]) particularly related to calcium regulation were gradually increased according to days of myotube differentiation. Subsequently, we validated the expression patterns of calcium-related genes in quail myoblasts. These results indicated that TNNC1, MYL1, MYL3, PLN, CAV3, CASQ2 responded to differentiation and growth performance in quail muscle. CONCLUSION: These results indicated that calcium regulation might play a critical role in muscle differentiation. Thus, these findings suggest that further studies would be warranted to investigate the role of calcium ion in muscle differentiation and could provide a useful biomarker for muscle differentiation and growth.