Cytoskeleton-associated glycoproteins from chicken sympathetic neurons and chicken embryo brain

A non-ionic detergent-insoluble fraction was obtained from pure cultures of chicken sympathetic neurons and further purified at the 10%-30% interface of a discontinuous density gradient. This fraction contains actin as its major component and approximately 20 further polypeptides some of which are glycosylated. Two conspicuous glycoproteins in this fraction, of molecular masses 130 kDa and 90 kDa, have been shown to bind to concanavalin A; in cultured neurons the 130-kDa glycoprotein may also be labelled with [3H]glucosamine and [3H]fucose. Both are restricted to one interface of the stepped sucrose gradient when cells are lysed in low ionic strength buffer and eluted with actin in the void volume of a Sepharose 6B column. Glycoproteins of the same molecular weight have been obtained by the same isolation procedure from 10-day-old chicken embryo brains. One-dimensional peptide maps show that the carbohydrate-containing peptides from brain and sympathetic neurons are closely similar if not identical. The glycoproteins are also present in sciatic nerve but cannot be detected in a detergent-insoluble form in rounded neurons - lacking axons - or fibroblasts. They might, therefore, be involved in the linkage of the axonal cytoskeleton to the plasma membrane.     

Adipogenic differentiation of chicken epithelial oviduct cells using only chicken serum

Chicken epithelial oviduct cells (COCs) are part of important supportive tissues in chicken reproductive organs responsible for secretion of the majority of chicken egg protein. In chickens, the biological process of adipocyte differentiation has been extensively studied in vitro using a number of cell types including a preadipocyte precursor cell line, a number of other undifferentiated cell lines, and chicken embryonic fibroblasts. On the contrary, adipogenic differentiation in epithelial cells has not yet been achieved. In our study, we induced COCs to differentiate into adipocytes using chicken serum at concentrations of 5% and 10%. After a 24-h culture period at 37°C in a humidified 5% CO₂ atmosphere, oviduct cell morphology changed dramatically through formation of lipid droplets, observed by Oil Red O staining. Also, chicken serum strongly induced 3T3-L1 preadipocyte cell differentiation into adipocyte. In addition, mRNA expression levels of peroxisome proliferator-activated receptor gamma, adipocyte fatty acid-binding protein (aP2), and CCAAT-enhancer-binding protein alpha were significantly increased 48 h after induction. These results suggest that COCs can be induced to differentiate into adipocyte-like cells. Moreover, through this study, we confirmed that chicken serum is an effective adipocyte differentiation-inducing agent. Our findings may provide a unique model for studying and applying chicken transdifferentiation and adipocyte differentiation.     

Isolation of chicken embryonic stem cell and preparation of chicken chimeric model

Chicken embryonic stem cells (ESCs) were separated from blastoderms at stage-X and cultured in vitro. Alkaline phosphatase activity and stage-specific embryonic antigen-1 staining was conducted to detect ESCs. Then, chicken ESCs were transfected with linearized plasmid pEGFP-N1 in order to produce chimeric chicken. Firstly, the optimal electrotransfection condition was compared; the results showed the highest transfection efficiency was obtained when the field strength and pulse duration was 280 V and 75 μs, respectively. Secondly, the hatchability of shedding methods, drilling a window at the blunt end of egg and drilling a window at the lateral shell of egg was compared, the results showed that the hatchability was the highest for drilling a window at the lateral shell of egg. Thirdly, the hatchability of microinjection (ESCs was microinjected into chick embryo cavity) was compared too, the results showed there were significant difference between the injection group transfected with ESCs and that of other two groups. In addition, five chimeric chickens were obtained in this study and EGFP gene was expressed in some organs, but only two chimeric chicken expressed EGFP gene in the gonad, indicating that the chimeric chicken could be obtained through chick embryo cavity injection by drilling a window at the lateral shell of egg.     

Identification of microRNAs from different tissues of chicken embryo and adult chicken

We report for the first time the identification of 25 microRNAs from tissues originating from chicken embryo and adult chicken. Most of the cloned microRNAs are expressed in both adult chickens and chicken embryos. Fourteen were identified without any prior prediction. One microRNA, miR-757, is thought to be chicken-specific. Three of the microRNAs appear to be extremely tissue specific.     

Control of chicken coccidiosis

Coccidiosis could potentially cause enormous economic loss to the poultry industry, especially in the production of broiler chickens (see Box 1). Losses are currently minimized by chemotherapeutic treatment but the effectiveness of many drugs seems to be declining. In this article, Peter Long and Tom Jeffers discuss the future for coccidial chemotherapy, and the potential for immunological control methods.     

鸡microRNA的研究进展

microRNA (miRNA)是参与基因转录后调控的一类重要的非编码小RNA分子.以下简要总结鸡miRNA的数量与染色体分布,同时概述了鸡miRNA对免疫、胚胎发育和病毒感染的调控作用,最后对鸡miRNA的应用前景也进行了简单探讨,以期为miRNA在禽业生产中的深入研究和应用提供参考.     

Lipids of chicken epidermis

The lipids from chicken epidermis were analyzed by a combination of quantitative thin-layer and gas-liquid chromatography and by chemical and spectroscopic methods. The lipid groups present included wax diesters (34%), triglycerides (32%), sterols (11%), phospholipids (11%), nonphosphorus-containing sphingolipids (3%), beta-D-glucosylsterols (3%), 6-O-acyl-beta-D-glucosylsterols (2%), steryl esters (1%), cholesteryl sulfate (1%), and free fatty acids (1%). The major phospholipids were phosphatidylcholine, phosphatidylethanolamine, and sphingomyelin, and the sphingolipids included ceramides, glucosylceramides, O-acylceramides, and O-acylglucosylceramides. Glucosylsterols and acylglucosylsterols have not been found in mammalian skin, and may be relevant to the evolutionary history of the epidermal water barrier. The wax diesters contained mainly 16-, 18-, and 20-carbon saturated fatty acids esterified to 20- through 24-carbon threo and erythro 2,3-diols, while the chicken epidermal triglycerides contained some very long-chain (26-40 carbon) saturated fatty acids. These wax diesters and unusual triglycerides may be of significance in human health.     

The chicken SLAM family

The signaling lymphocytic activation molecule (SLAM) family of receptors is critically involved in the immune regulation of lymphocytes but has only been detected in mammals, with one member being present in Xenopus. Here, we describe the identification, cloning, and analysis of the chicken homologues to the mammalian SLAMF1 (CD150), SLAMF2 (CD48), and SLAMF4 (CD244, 2B4). Two additional chicken SLAM genes were identified and designated SLAMF3like and SLAM5like in order to stress that those two receptors have no clear mammalian counterpart but share some features with mammalian SLAMF3 and SLAMF5, respectively. Three of the chicken SLAM genes are located on chromosome 25, whereas two are currently not yet assigned. The mammalian and chicken receptors share a common structure with a V-like domain that lacks conserved cysteine residues and a C2-type Ig domain with four cysteines forming two disulfide bonds. Chicken SLAMF2, like its mammalian counterpart, lacks a transmembrane and cytoplasmic domain and thus represents a glycosyl-phosphatidyl-inositol-anchored protein. The cytoplasmic tails of SLAMF1 and SLAMF4 display two and four conserved immunoreceptor tyrosine-based switch motifs (ITSMs), respectively, whereas both chicken SLAMF3like and SLAMF5like have only a single ITSM. We have also identified the chicken homologues of the SLAM-associated protein family of adaptors (SAP), SAP and EAT-2. Chicken SAP shares about 70 % identity with mammalian SAP, and chicken EAT-2 is homologous to mouse EAT-2, whereas human EAT-2 is much shorter. The characterization of the chicken SLAM family of receptors and the SAP adaptors demonstrates the phylogenetic conservation of this family, in particular, its signaling capacities.     

On hemangioblasts in chicken

Hemangioblasts are bi-potential precursors for blood and endothelial cells (BCs and ECs). Existence of the hemangioblast in vivo by its strict definition, i.e. a clonal precursor giving rise to these two cell types after division, is still debated. Using a combination of mitotic figure analysis, cell labeling and long-term cell tracing, we show that, in chicken, cell division does not play a major role during the entire ventral mesoderm differentiation process after gastrulation. One eighth of cells do undergo at least one round of division, but mainly give rise to daughter cells contributing to the same lineage. Approximately 7% of the dividing cells that contribute to either the BC or EC lineage meet the criteria of true hemangioblasts, with one daughter cell becoming a BC and the other an EC. Our data suggest that hemangioblast-type generation of BC/EC occurs, but is not used as a major mechanism during early chicken development. It remains unclear, however, whether hemangioblast-like progenitor cells play a more prominent role in later development.     

Molecular cloning of chicken prepro-orexin cDNA and preferential expression in the chicken hypothalamus

Chicken prepro-orexin cDNA has been cloned, sequenced and characterized. The predicted amino acid sequence of chicken prepro-orexin cDNA revealed that orexin-A and -B are highly conserved among vertebrate species. In situ hybridization and immunohistochemistry localized orexin-positive cell bodies in the periventricular hypothalamic nucleus extending into the lateral hypothalamic area. Comparisons of orexin gene expression in the brains of 24-h-fasted and ad libitum-fed chickens were made using semi-quantitative RT-PCR. No significant differences in orexin mRNA expression were observed.     

New, rapid methods for purifying alpha-actinin from chicken gizzard and chicken pectoral muscle

We introduce two new, rapid procedures. One is specifically designed for isolating alpha-actinin from skeletal and the other for isolating alpha-actinin from smooth muscle. Approximately 20 mg of greater than 95% pure alpha-actinin can be obtained/100 g of ground chicken pectoral muscle in just 4 days. The smooth muscle protocol yields 2.7 mg of greater than 99% pure alpha-actinin/100 g of ground gizzard after just 5 days. Differences in protein contaminants and in the extractability of alpha-actinin necessitated the development of separate isolation procedures for the two muscle types. Antibody prepared against the purified gizzard alpha-actinin reacted with alpha-actinin from skeletal, cardiac, and smooth muscle in immunodiffusion. Anti-alpha-actinin reacted only with alpha-actinin from crude extracts of skeletal and smooth muscle on Staph A gels. Anti-alpha-actinin stained Z-bands from skeletal muscle in indirect immunofluorescence microscopy and stress fibers from baby hamster kidney fibroblasts and mouse mammary epithelial cells in the characteristic punctate pattern observed by other workers (Lazarides, E., and Burridge, K. (1975) Cell 6, 289-298). These two methods for purifying alpha-actinin from skeletal and smooth muscle represent a significant improvement over that published previously.