Primary Chicken Embryonic Fibroblasts Research Articles

Single Amino Acid Substitution in the Matrix Protein of Rabies Virus Is Associated with Neurovirulence in Mice.

Rabies is a fatal encephalitic infectious disease caused by the rabies virus (RABV). RABV is highly neurotropic and replicates in neuronal cell lines in vitro. The RABV fixed strain, HEP-Flury, was produced via passaging in primary chicken embryonic fibroblast cells. HEP-Flury showed rapid adaptation when propagated in mouse neuroblastoma (MNA) cells. In this study, we compared the growth of our previously constructed recombinant HEP (rHEP) strain-based on the sequence of the HEP (HEP-Flury) strain-with that of the original HEP strain. The original HEP strain exhibited higher titer than rHEP and a single substitution at position 80 in the matrix (M) protein M(D80N) after incubation in MNA cells, which was absent in rHEP. In vivo, intracerebral inoculation of the rHEP-M(D80N) strain with this substitution resulted in enhanced viral growth in the mouse brain and a significant loss of body weight in the adult mice. The number of viral antigen-positive cells in the brains of adult mice inoculated with the rHEP-M(D80N) strain was significantly higher than that with the rHEP strain at 5 days post-inoculation. Our findings demonstrate that a single amino acid substitution in the M protein M(D80N) is associated with neurovirulence in mice owing to adaptation to mouse neuronal cells.

Differential analysis of IBV-infected primary chicken embryonic fibroblasts and immortalized DF-1.

Infectious bronchitis virus (IBV) is responsible for high morbidity and mortality as well as substantial economic losses worldwide. Transcriptome sequencing of IBV-infected chicken embryonic fibroblast and DF-1 cells revealed that the virus elicits antiviral immunity in cells after viral infection, but IBV cannot activate DF-1 cells to produce sufficient amounts of viral structures to assemble into complete virions, which may be caused by the interactions between cytokines. The study of IBV cellular adaptations is important for vaccine development and investigation of the pathogenesis of IBV.

Efficacy of a recombinant turkey herpesvirus (H9) vaccine against H9N2 avian influenza virus in chickens with maternal-derived antibodies.

Although vaccines have been widely used for many years, they have failed to control H9N2 avian influenza virus (AIV) in the field in China. The high level of maternal-derived antibodies (MDAs) against H9N2 virus contributes to the H9N2 influenza vaccine failure in poultry. The study aimed to generate a new vaccine to overcome MDAs interference in H9N2 vaccination in chickens. We used turkey herpesvirus (HVT) as a vaccine vector to express H9 hemagglutinin (HA) proteins. The recombinant HVT expressing H9 HA proteins (rHVT-H9) was successfully generated and characterized in primary chicken embryonic fibroblasts (CEFs). Western blot and indirect immunofluorescence assay (IFA) showed that the rHVT-H9 consistently expressed HA proteins. In addition, the rHVT-H9 had similar growth kinetics to the parent HVT. Preliminary animal experiments showed that compared to the conventional inactivated whole virus (IWV) vaccine, the rHVT-H9 stimulated robust humoral immunity in chickens with passively transferred antibodies (PTAs) that were used to mimic MDAs. Transmission experiments showed that the rHVT-H9 induced both humoral and cellular immunity in chickens with PTAs. Furthermore, we used mathematical models to quantify the vaccine's efficacy in preventing the transmission of H9N2 AIV. The results showed that the rHVT-H9 reduced the virus shedding period and decreased the reproduction ratio (R) value in chickens with PTAs after homologous challenge. However, the vaccination in this trial did not yet bring R < 1. In summary, we generated a new rHVT-H9 vaccine, which stimulated strong humoral and cellular immunity, reducing virus shedding and transmission of H9N2 AIV even in the presence of PTAs in chickens.

Research Note: Potential usage of DF-1 cell line as a new cell model for avian adipogenesis

Current research of avian adipogenesis has been dependent on primary preadipocytes culture due to the lack of commercially available immortal preadipocyte cell lines in avian species. In addition to primary stromal vascular cells, primary chicken embryonic fibroblasts (CEF) were suggested as new in vitro models for adipogenesis study, because CEF can be differentiated into adipocytes by a combination of fatty acids and insulin (FI), or all-trans retinoic acid (atRA) alone in the media containing chicken serum (CS). However, there are decreases in differentiation of primary cells due to diverse population of cell types and low adipogenic potential of cells after passages. In the present study, adipogenic differentiation of DF-1 cells, immortal fibroblasts derived from an embryonic chicken, was tested with 4 different medium; 10% fetal bovine serum (FBS), 10% CS, 10% CS with FI, and 10% CS with FI and atRA. Lipid droplets stained with Oil Red O were not shown in DF-1 cells under 10% FBS, appeared with very small sizes under 10% CS, significantly increased under 10% CS with FI, and most significantly accumulated under 10% CS with FI and atRA. In addition, expressions of markers for adipogenesis (Znf423, C/ebpβ, Pparγ, and Fabp4), fatty acid uptake (CD36), triglyceride synthesis (Gpd1, Dgat2), and lipid droplet stabilization (Plin1) were significantly upregulated by supplementation of 10% CS with FI and atRA. Morphological evidence for formation of lipid droplets and dramatic induction of adipogenic marker genes support the adipogenic potential of DF-1 cells, offering DF-1 cells as a new cell model to investigate various research studies involving avian adipogenesis.

M Gene Reassortment in H9N2 Influenza Virus Promotes Early Infection and Replication: Contribution to Rising Virus Prevalence in Chickens in China.

Segment reassortment and base mutagenesis of influenza A viruses are the primary routes to the rapid evolution of high-fitness virus genotypes. We recently described a predominant G57 genotype of avian H9N2 viruses that caused countrywide outbreaks in chickens in China during 2010 to 2013, which led to the zoonotic emergence of H7N9 viruses. One of the key features of the G57 genotype is the replacement of the earlier A/chicken/Beijing/1/1994 (BJ/94)-like M gene with the A/quail/Hong Kong/G1/1997 (G1)-like M gene of quail origin. We report here the functional significance of the G1-like M gene in H9N2 viruses in conferring increased infection severity and infectivity in primary chicken embryonic fibroblasts and chickens. H9N2 virus housing the G1-like M gene, in place of the BJ/94-like M gene, showed an early surge in viral mRNA and viral RNA (vRNA) transcription that was associated with enhanced viral protein production and with an early elevated release of progeny virus comprising largely spherical rather than filamentous virions. Importantly, H9N2 virus with the G1-like M gene conferred extrapulmonary virus spread in chickens. Five highly represented signature amino acid residues (37A, 95K, 224N, and 242N in the M1 protein and 21G in the M2 protein) encoded by the prevalent G1-like M gene were demonstrated to be prime contributors to enhanced infectivity. Therefore, the genetic evolution of the M gene in H9N2 virus increases reproductive virus fitness, indicating its contribution to the rising virus prevalence in chickens in China.IMPORTANCE We recently described the circulation of a dominant genotype (genotype G57) of H9N2 viruses in countrywide outbreaks in chickens in China, which was responsible, through reassortment, for the emergence of H7N9 viruses that cause severe human infections. A key feature of the genotype G57 H9N2 virus is the presence of the quail-origin G1-like M gene, which had replaced the earlier BJ/94-like M gene. We found that H9N2 virus with the G1-like M gene, but not the BJ/94-like M gene, showed an early surge in progeny virus production and more severe pathology and extrapulmonary virus spread in chickens. Five highly represented amino acid residues in the M1 and M2 proteins derived from the G1-like M gene were shown to mediate enhanced virus infectivity. These observations enhance what we currently know about the roles of reassortment and mutations in virus fitness and have implications for assessing the potential of variant influenza viruses that can cause a rising prevalence in chickens.

A chicken homologue of nectin-4 functions as a measles virus receptor

Measles virus (MV) vaccine strains use CD46, signaling lymphocyte activation molecule, and nectin-4 in human cells as receptors. Meanwhile, many of them are propagated in primary chicken embryonic fibroblasts (CEFs). Our data revealed that CEFs express a nectin-4 homologous molecule (CEF nectin-4) containing well-conserved motifs in the FG and BC loops, but not in the C′C″ loop. MV infected CHO cells expressing CEF nectin-4 and induced syncytia in these cells, confirming that CEF nectin-4 functions as an MV receptor and that the C′C″ loop is not critical for this function. Nectin-4-blind mutations in MV H protein reduced the infectivity of MV in CEF nectin-4-expressing cells. Infection of CEFs with the MV vaccine AIK-C strain was partially blocked by an anti-nectin-4 antibody, indicating that CEF nectin-4 plays a role for propagation of MV vaccines in CEFs.

Changes in the NS1 gene of avian influenza viruses isolated in Thailand affect expression of type I interferon in primary chicken embryonic fibroblast cells

The non-structural protein 1 (NS1) of avian influenza virus was defined as one of the virulent factors. To understand the effect of NS1 protein of influenza virus H5N1 isolated in Thailand on type I (α/β) interferon (IFN) synthesis, five reverse genetic viruses were constructed and used as models. The viruses were generated using NS genomic segment from A/Peurto Rico/8/1934 (H1N1) and four avian influenza viruses isolated from the first outbreak in Thailand. All the viruses have the rest of the genome from A/Peurto Rico/8/1934 (H1N1). The constructed viruses were named (1) NS1 PR8/34, (2) NS1 wild type, (3) NS1 L15FD53G, (4) NS1 N171I and (5) NS1 E71K, respectively. The type I (α/β) IFN gene expression in control and infected primary chicken embryonic fibroblast cells were analyzed by quantitative polymerase chain reaction. The results show that the inhibition of IFN-β gene expression by NS1 wild type infected cells is stronger than NS1 N171I, NS1 E71K, NS1 PR8/34 and NS1 L15FD53G, respectively. The data suggest that the difference of amino acid sequence of NS1 protein contributes to the IFN-β antagonist. In contrast, the difference of the NS1 protein does not influence in the IFN-α antagonistic activity.

Chicken IL-17F: Identification and comparative expression analysis in Eimeria-infected chickens

Interleukin-17F (IL-17F) is a proinflammatory cytokine, which plays an important role in gut homeostasis. A full-length chicken IL-17F (chIL-17F) cDNA with a 510-bp coding region was identified from ConA-activated chicken splenic lymphocytes. ChIL-17F shares 53% amino acid sequence identity with the previously described chicken IL-17 (chIL-17A) and 38–43% with mammalian homologues. The locus harboring chIL-17 and chIL-17F displayed inverted order compared to those of mammals. ChIL-17F transcript expression was high in lymphoblast cell line CU205 and at moderate levels in small and large intestines and liver. ChIL-17F and chIL-17 expression profiles were examined by quantitative real-time RT-PCR in mitogen-stimulated splenic lymphocytes and intestinal areas affected by Eimeria maxima and Eimeria tenella infections. Expression levels of chIL-17F, like chIL-17, were elevated in mitogen-activated splenic lymphocytes. ChIL-17F, but not chIL-17, expression was upregulated in intestinal tissues affected by E. maxima and E. tenella infections. Recombinant chIL-17F biological activities were similar to that of chIL-17 in primary chicken embryonic fibroblasts. These results suggest that chIL-17F is a unique member of the IL-17 family of cytokines.

Avian reovirus triggers autophagy in primary chicken fibroblast cells and Vero cells to promote virus production

Avian reovirus (ARV) is an important cause of disease in poultry. Although ARV is known to induce apoptosis in infected cells, the interaction between ARV and its target cells requires further elucidation. In this report, we show that the ARV isolate strain GX/2010/1 induces autophagy in both Vero and primary chicken embryonic fibroblast (CEF) cells based on the appearance of an increased number of double-membrane vesicles, the presence of GFP-microtubule-associated protein 1 light chain 3 (GFP-LC3) dot formation, and the elevated production of LC3II. We further demonstrate that the class I phosphoinositide 3-kinase (PI3K)/Akt/mTOR pathway contributes to autophagic induction by ARV infection. Moreover, treatment of ARV-infected cells with the autophagy inducer rapamycin increased viral yields, while inhibition of the autophagosomal pathway using chloroquine led to a decrease in virus production. Altogether, our studies strongly suggest that autophagy may play a critical role in determining viral yield during ARV infection.

Assessment of Bioactivity of a Recombinant Chicken Interferon-Gamma Expressed Using a Baculovirus Expression System

The full-length coding sequence of chicken interferon-γ (ChIFN-γ) was cloned into a baculovirus nonfusion vector, pFastBacDual, and expressed in Sf21 insect cells. Recombinant ChIFN-γ (rChIFN-γ) protein was found to be expressed both intracellularly as well as in the culture supernatants. The affinity-purified rChIFN-γ contained 14, 17, and 28 kDa proteins, possibly representing both glycosylated and nonglycosylated protein forms of ChIFN-γ. The bioactivity of rChIFN-γ was confirmed in vitro by production of nitric oxide in a chicken macrophage cell line (HD11) and antiviral activity against vesicular stomatitis virus in primary chicken embryonic fibroblast cells. Further, HD11 cells stimulated with rChIFN-γ showed significant upregulation of inducible nitric oxide synthases, IFN-γ, interleukin-1β, interleukin-12p35, signal transducers and activators of transcription 1, class II, major histocompatibility complex, transactivator, and major histocompatibility complex II-β chain (BL-B) transcripts. In conclusion, the present study provides information on the ability of functionally active rChIFN-γ expressed in a baculovirus system in inducing significant transcriptional upregulation of various immune system-related genes, including those that encode cytokines, antigen-presenting molecules, and transcription factors involved in the major histocompatibility complex and IFN-signaling pathway.

Metabolic properties of chicken embryonic stem cells

Cellular energy metabolism correlates with cell fate, but the metabolic properties of chicken embryonic stem (chES) cells are poorly understood. Using a previously established chES cell model and electron microscopy (EM), we found that undifferentiated chES cells stored glycogen. Additionally, undifferentiated chES cells expressed lower levels of glucose transporter 1 (GLUT1) and phosphofructokinase (PFK) mRNAs but higher levels of hexokinase 1 (HK1) and glycogen synthase (GYS) mRNAs compared with control primary chicken embryonic fibroblast (CEF) cells, suggesting that chES cells direct glucose flux towards the glycogenic pathway. Moreover, we demonstrated that undifferentiated chES cells block gluconeogenic outflow and impede the accumulation of glucose-6-phosphate (G6P) from this pathway, as evidenced by the barely detectable levels of pyruvate carboxylase (PCX) and mitochondrial phosphoenolpyruvate carboxykinase (PCK2) mRNAs. Additionally, cell death occurred in undifferentiated chES cells as shown by Hoechst 33342 and propidium iodide (PI) double staining, but it could be rescued by exogenous G6P. However, we found that differentiated chES cells decreased the glycogen reserve through the use of PAS staining. Moreover, differentiated chES cells expressed higher levels of GLUT1, HK1 and PFK mRNAs, while the level of GYS mRNA remained similar in control CEF cells. These data indicate that undifferentiated chES cells continue to synthesize glycogen from glucose at the expense of G6P, while differentiated chES cells have a decreased glycogen reserve, which suggests that the amount of glycogen is indicative of the chES cell state.

Apoptosis induction by avian reovirus through p53 and mitochondria-mediated pathway

Although induction of apoptosis by avian reovirus has been demonstrated in primary chicken embryonic fibroblast and several cell lines, to date, the potential significance of avian reovirus (ARV)-induced apoptosis and its pathways in cultured cells are still largely unknown. We now provide the first evidence of upregulation of p53 and Bax and specifically for Bax translocation from cytosol to mitochondria following infection with a cytoplasmically replicating RNA virus. Bax translocation to the mitochondria led to the release of mitochondrial proapoptic factors cytochrome c and Smac/DIABLO from mitochondria to the cytosol, but not the release of apoptosis-inducting factor. Activation of caspases-9 and -3 which cleaves the enzyme poly(ADP-ribose) polymerase in ARV-infected BHK-21 cells was also detected. Internucleosomal DNA cleavage was prevented by caspase inhibitors, further demonstrating that ARV-induced apoptosis was executed through caspase-dependent mechanisms. Stable expression of human bcl-2 in BHK-21 cells not only blocked ARV-induced apoptosis and DNA fragmentation but also reduced the level of infectious virus production and its spread in BHK-21 cells infected with ARV at a low multiplicity of infection. All our data suggest that p53 and the mitochondria-mediated pathway played an important regulatory role in ARV-induced apoptosis in BHK-21 cells. To further study the pathogenesis of ARV infection, a dual-labeling assay was used for the simultaneous detection of cells containing viral antigen and apoptotic cells. Dual-labeling assay revealed that the majority of antigen-expressing cells were not apoptotic. Remarkably, some apoptotic but non-antigen-expressing cells were frequently located in the vicinity of antigen-expressing cells. Syncytium formation in ARV-infected BHK-21 cells undergoing apoptosis, was apparent in large syncytia at late infection times, indicating a correlation between virus replication and apoptosis in cultured cells.

Replacement of primary chicken embryonic fibroblasts (CEF) by the DF-1 cell line for detection of avian leucosis viruses

International regulations prescribe that the absence of avian leucosis viruses (ALV) in avian live virus vaccines has to be demonstrated. Primary chicken embryo fibroblasts (CEF) from special SPF chicken lines are normally used for detection of ALV. The suitability of the DF-1 cell line for ALV-detection, as alternative for primary CEF, was studied in three types of experiments: (1) in titration experiments without cell passage, (2) in experiments with passages in cell cultures according to European Pharmacopoeia requirements, and (3) in experiments with commercial live avian vaccines that had been spiked with known amounts of ALV. In all tests the sensitivity of ALV-A and ALV-J detections on DF-1 cells was at least as high as on primary CEF. The sensitivity of ALV-B detection was always superior when DF-1 cells were used. ALV were detected earlier in all comparative tests when DF-1 cells were used. ALV-A, ALV-B and ALV-J all induced CPE on DF-1 cells, whereas no clear CPE was seen on CEF-cells. For reasons of sensitivity, standardisation as well as reduction of animal use, the data support the use of DF-1 cells to monitor absence of ALV in vaccine virus seed lots or finished products.

The Investigation of Cell Culture Conditions to Maintain Chicken Embryonic Stem Cells as Totipotent Cells

The ES cell can provide a useful system for studying differentiation and development in vitro and a powerful tool for producing transgenic animalds. To investigate the culture condition of chicken embryonic stem (CES) cells which can retain their multipotentiality or totipotency, three kinds of feeder layer cells, SNL cells, primary mice embryonic fibroblasts (PMEF) cells and primary chicken embryonic fibroblasts (PCEF) cells, were used as the feeder cells in media of DMEM supplemented with leukemia inhibitory factor (LIF), basic fibroblast growth factor (bFGF) and stem cell factor (SCF) for co-culture with blastoderm cells from stage X embryos of chicken. The alkaline phosphatase (AKP) test, differentiation experiment in vitro and chimeric chicken production were carried out. The results showed that culture on feeder layer of PMEF yielded high quality CES cell colonies. The typical CES cells clone shape revealed as follows: nested aggregation (clone) with clear edge and round surface as well as close arrangement within the clone. Strong alkaline phosphatase (AKP) reactive cells were observed in the fourth passage cells. On the other hand, the fourth passage CES cells could differentiate into various cells in the absence of feeder layer cells and LIF in vitro. The third and fourth passage cells were injected into the subgerminal cavity of recipient embryos at stage X. Of 269 Hailan embryos injected with CES cells of Shouguang Chickens, 8.2% (22/269) survived to hatching, 5 feather chimeras had been produced. This suggests that an effective culture system established in this study can promote the growth of CES cells and maintain them in the state of undifferentiated and development, which lays a solid foundation for the application of CES cells and may provide an alternative tool for genetic modification of chickens.

Expression of a specific marker of avian programmed cell death in both apoptosis and necrosis.

Apoptosis and necrosis are two types of cell death with different morphologic features. We report here the isolation of a monoclonal antibody, BV2, that specifically recognizes cells undergoing developmental programmed cell death in different tissues of the chicken and zebra-finch embryos. The antigen recognized by BV2 monoclonal antibody is detected in vitro in primary chicken embryonic fibroblasts induced to die by actinomycin D, as well as fibroblasts induced to die by chemical anoxia. The expression of this specific antigen during necrosis appears to require active protein synthesis. These findings provide evidence that cells from different embryonic tissues undergoing programmed cell death during vertebrate development express similar antigens and indicate that apoptosis and necrosis may share similar biochemical features.

Use of Avian Cytokines in Mammalian Embryonic Stem Cell Culture

Mouse blastocyst-derived embryonic stem (ES) cells are multipotent cells that can be used in vitro as models of differentiation and in vivo can contribute to all embryonic tissues including the germ line. The culture of ES cells requires a source of leukemia inhibitory factor (LIF), often provided by culture with a mouse fibroblast (STO) feeder layer, buffalo rat liver cell-conditioned media (BRL-CM), or the addition of recombinant LIF. To date, all of the ES cell culture systems use mammalian sources of LIF. We found that mouse ES cells can be maintained for over 10 passages in an undifferentiated state with media conditioned by a chicken liver cell line (LMH-CM) or on a feeder layer made with primary chicken embryonic fibroblasts (CEF). These ES cells can undergo both spontaneous and induced differentiation, which is associated with the disappearance or reduction of the expression of alkaline phosphatase and SSEA-1, similar to that observed for ES cells cultured with BRL-CM or STO feeder layers. The ES cells cultured in LMH-CM did not express cytokeratin Endo-A antigen recognized by TROMA-1, but their differentiated progeny did express this antigen. In contrast to LMH-CM, Endo-A was expressed in ES cells cultured on CEF feeder layers and in differentiated progeny. These results indicate that avian cells can produce a LIF-like cytokine that is active in inhibiting the differentiation of mouse ES cells. This could provide a biological end point for the isolation and characterization of avian LIF.