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Porcine epidemic diarrhea virus (PEDV) is a porcine enteropathogenic coronavirus that has received increasing attention since the emergence of a PEDV variant worldwide. Previous studies have shown that PEDV ORF3 encodes an ion channel protein. However, its influence on cell cycle and subcellular structure still require more research. In this study, we developed a Vero cell line that stably expresses PEDV ORF3 gene. Subcellular localization and influences of PEDV ORF3 on host cells were investigated. We further verified whether or not this gene enhances virus production. The results showed that PEDV ORF3 protein localizes in the cytoplasm and affects cell cycle progression by prolonging the S phase. In addition, the ORF3-expressing Vero cells had more vesicles than the host Vero cells. Furthermore, the attenuated PEDV rather than virulent PEDV could grow better in ORF3-expressing Vero cells. The expression level of the PEDV nucleocapsid protein also increased. These results provided information on the function of PEDV ORF3 and were helpful in understanding the mechanisms of PEDV replication.

Mechanical properties of cells depend on various external and internal factors, like substrate stiffness and surface modifications, cell ageing and disease state. Some other currently unknown factors may exist. In this study we used force spectroscopy by AFM, confocal microscopy and flow cytometry to investigate the difference between single non-confluent and confluent (in monolayer) Vero cells. In all cases the stiffness values were fitted by log-normal rather than normal distribution. Log-normal distribution was also found for an amount of cortical actin in cells by flow cytometry. Cells in the monolayer were characterized by a significantly lower (1.4–1.7 times) Young's modulus and amount of cortical actin than in either of the single non-confluent cells or cells migrating in the experimental wound. Young's modulus as a function of indentation speed followed a weak power law for all the studied cell states, while the value of the exponent was higher for cells growing in monolayer. These results show that intercellular contacts and cell motile state significantly influence the cell mechanical properties.

MicroRNA expression appears to capture the process of neoplastic development in vitro in the VERO line of African green monkey kidney (AGMK) cells (Teferedegne et al. PLoS One 2010;5(12):e14416). In that study, specific miRNA signatures were correlated with the transition, during serial tissue-culture passage, of low-density passaged 10–87 VERO cells from a non-tumorigenic phenotype at passage (p) 148 to a tumorigenic phenotype at p256. In the present study, six miRNAs (miR-376a, miR-654-3p, miR-543, miR-299-3p, miR-134 and miR-369-3p) were chosen from the identified signature miRNAs for evaluation of their use as potential biomarkers to track the progression of neoplastic development in VERO cells. Cells from the 10–87 VERO cell line at passage levels from p148 to p256 were inoculated into newborn and adult athymic nude mice. No tumors were observed in animals inoculated with cells from p148 to p186. In contrast, tumor incidences of 20% developed only in newborn mice that received 10–87 VERO cells at p194, p234 and p256. By qPCR profiling of the signature miRNAs of 10–87 VERO cells from these cell banks, we identified p194 as the level at which signature miRNAs elevated concurrently with the acquisition of tumorigenic phenotype with similar levels expressed beyond this passage. In wound-healing assays at 10-passage intervals between p150 to p250, the cells displayed a progressive increase in migration from p165 to p186; beginning at p194 and higher passages thereafter, the cells exhibited the highest rates of migration. By qPCR analysis, the same signature miRNAs were overexpressed with concomitant acquisition of the tumorigenic phenotype in another lineage of 10–87 VERO cells passaged independently at high density. Correlation between the passages at which the cells expressed a tumorigenic phenotype and the passages representing peaks in expression levels of signature miRNAs indicates that these miRNAs are potential biomarkers for the expression of the VERO cell tumorigenic phenotype.

Subcultivation of Vero cells grown in a proprietary animal component-free medium named IPT-AFM, on microcarriers, was studied. TrypLE Select, a non-animal-derived protease, was used as an alternative to trypsin for cell passaging. We first studied the effect of increasing concentrations of TrypLE Select toward cell growth and then studied the inactivation of the protease using either soybean trypsin inhibitor (STI) or the soy hydrolysate Hypep 1510, in six-well plates. Data showed that cell growth was impaired by residual level of TrypLE Select; STI was identified as an efficient agent to neutralize this effect. To restore cell growth and inactivate TrypLE Select, STI should be added to the medium at least at 0.2 g L −1 . Cells were also grown in spinner flask on 2 g L −1 Cytodex1 in IPT-AFM. In these conditions, the cell detachment yield was equal to 78 ± 8 %. Furthermore, cells exhibited a typical growth profile when using the dislodged cells to seed a new culture. A cell detachment yield of 70 ± 19 % was also achieved when the cells were grown in a 2-L stirred bioreactor in IPT-AFM, on 3 g L −1 Cytodex1. This protocol can be of great interest to scale-up the process of Vero cells cultivation in IPT-AFM on Cytodex1 from one stirred bioreactor culture to another.

With the development of nanotechnology, nanoscale products that are smaller than several hundred nanometers have been applied to all areas of science and technology. Nanoscale products, including carbon nanotubes, fullerene derivatives, and nanocrystal quantum dots (QDs), are wide spread as novel tools in various fields, not only in materials engineering, electronics, plastics, and the automobile and aerospace industries, but also in molecular biology and medicine. At present, QDs have been widely used in biological and medical studies because of their superior photoemission and photostability. Although the physical and chemical properties of QDs have been circumstantially investigated, little is known about any harmful effects of QDs on human health. Here we report on the toxicity and biological behavior of QDs in vitro and in vivo. The toxicity of the core constituent chemicals such as cadmium and selenium has been identified. Recently, the surface molecules surrounding QDs have been intensively investigated. Accumulating evidence that toxic surface-covering molecules showed their cytotoxicity and biomolecules conjugated with QDs maintained their biological effects indicates that at least the biological properties of QDs are attributable to the QD-capping material rather than to the core metalloid complex itself.

The actin cytoskeleton is a dynamic network that is composed of a variety of F-actin structures. To understand how these structures are produced, we tested the capacity of proteins to direct actin polymerization in a bead assay in vitro and in a mitochondrial-targeting assay in cells. We found that human zyxin and the related protein ActA of Listeria monocytogenes can generate new actin structures in a vasodilator-stimulated phosphoprotein-dependent (VASP) manner, but independently of the Arp2/3 complex. These results are consistent with the concept that there are multiple actin-polymerization machines in cells. With these simple tests it is possible to probe the specific function of proteins or identify novel molecules that act upon cellular actin polymerization.

Between April 1996 and March 1997 we examined 5093 samples of raw beef and lamb products for the presence of E. coli O157. Samples were purchased from 81 small butchers' shops in south Yorkshire. In March 1997 we also examined five samples of dried mint for the presence of E. coli O157. Strains of E. coli O157 were isolated by enrichment culture in modified buffered peptone water followed by immunomagnetic separation and culture of magnetic beads onto cefixime tellurite sorbitol MacConkey agar. Strains were characterized by phage typing, toxin genotyping and plasmid analysis. Strains of E. coli O157 were isolated from 72 (1·4%) of 5093 samples; it was isolated from 36 (1·1%) of 3216 samples of beef products and from 29 (2·9%) samples of lamb products. The highest prevalence was found in lamb sausages and lamb burgers where E. coli O157 was isolated from 3 (4·1%) of 73 and 18 (3·7%) of 484 samples respectively. Strains of E. coli O157 were isolated most frequently during early summer. Strains of E. coli O157 were also isolated from 2 of 5 samples of dried mint although we did not determine how the mint had become contaminated. All isolates of E. coli O157 were Verocytotoxin-producing as determined by both Vero cell assay and DNA hybridization for the genes encoding Verocytotoxin and all were positive for the eaeA gene. A combination of phage typing, toxin genotyping and plasmid profile subdivided the 72 strains of E. coli isolated into 20 different subtypes, of which 18 were indistinguishable from strains isolated previously from cattle and sheep; of these 18 strains, 8 were indistinguishable from strains isolated from human cases of infection during the study period.

1. We have demonstrated for the first time that the helicase of a ribonucleic acid virus, the SARS coronavirus (SARS-CoV), is a valid target for drug development. 2. Using high throughput screen and chemical synthesis, several lead compounds targeting the SARS-CoV helicase have been identified. We have shown that these compounds can inhibit SARS-CoV helicase activity and viral growth in cell culture systems. These compounds can potentially be used to target other viruses.

1. We have generated monoclonal antibodies against the SARS coronavirus (SARS-CoV) X1/3a protein (3a), which are suitable for western blotting, immunocytochemistry, and immunohistochemistry. 2. We have established and characterised an in-vivo 3a transgenic Drosophila model, and demonstrated its usefulness in studying SARS-CoV 3a gene function. 3. We validated our in-vivo findings on 3a gene function in mammalian Vero E6 cells. 4. Our findings raise the possibility of using ion channel blockers as a novel approach to suppress SARS-CoV-induced cell death.

1. The adenovirus-mediated overexpression of SARS coronavirus (SARS-CoV) spike protein (S) and its C-terminal domain (S2) induce apoptosis in Vero E6 cells. 2. Such apoptosis in Vero E6 cells is time- and dose-dependent. 3. The adenovirus-mediated overexpression of SARS-CoV N-terminal domain (S1) and other structural proteins, including E,M and N protein, do not induce apoptosis.