Phuc H. Pham

Differential effects of viral hemorrhagic septicaemia virus (VHSV) genotypes IVa and IVb on gill epithelial and spleen macrophage cell lines from rainbow trout (Oncorhynchus mykiss).

The two most prominent genotypes of viral hemorrhagic septicemia virus (VHSV) are -I in the Northeastern Atlantic region and -IV in North America, but much more is known about the cellular pathogenesis of genotype -I than -IV. VHSV genotype -IV is divided into -IVa from the Northeast Pacific Ocean and -IVb from the Great Lakes and both of which are less virulent to rainbow trout than genotype -I. In this work, infections of VHSV-IVa and -IVb have been studied in two rainbow trout cell lines, RTgill-W1 from the gill epithelium, and RTS11 from spleen macrophages. RTgill-W1 produced infectious progeny of both VHSV-IVa and -IVb. However, VHSV-IVa was more infectious than -IVb toward RTgill-W1: -IVa caused cytopathic effect (CPE) at a lower viral titre, elicited CPE earlier, and yielded higher titres. By contrast, no CPE and no increase in viral titre were observed in RTS11 cultures infected with either genotype. Yet in RTS11 all six VHSV genes were expressed and antiviral genes, Mx2 and Mx3, were up regulated by VHSV-IVb and -IVa. However, replication appeared to terminate at the translational stage as viral N protein, presumably the most abundant of the VSHV proteins, was not detected in either infected RTS11 cultures. In RTgill-W1, Mx2 and Mx3 were up regulated to similar levels by both viral genotypes, while VHSV-IVa induced higher levels of IFN1, IFN2 and LGP2A than VHSV-IVb.

Differential viral propagation and induction of apoptosis by grouper iridovirus (GIV) in cell lines from three non-host species.

Grouper iridovirus (GIV), belonging to the Ranavirus genus of the Iridoviridae family, was demonstrated to differentially express viral genes and induce apoptosis in three non-host fish cell lines rainbow trout monocyte/macrophage (RTS11), chinook salmon embryonic (CHSE-214) and fathead minnow Epithelioma papulosum cyprinid (EPC). These cells were challenged with GIV and virus entry into all three cell lines was confirmed by the expression of viral immediate early genes. The expression of the late major capsid protein gene was detected in CHSE-214 and EPC, but not in RTS11, suggesting an earlier termination in the viral replication cycle in RTS11. Approximately 12h after infection with GIV, cell death was prominent in all three non-host cell lines. Death was later confirmed to be apoptosis by the presence of chromosomal DNA fragmentation and phosphatidylserine externalization. To determine whether apoptosis was protein related or gene expression related, the three cell lines were challenged with heat-inactivated GIV and UV-treated GIV (GIV(UV)). The heat inactivation abolished apoptosis in all three cell lines, but each cell line responded differently to GIV(UV). Relative to GIV, GIV(UV) caused no apoptosis in CHSE-214, decreased apoptosis in RTS11, and increased apoptosis in EPC. These results suggest that early GIV gene expression was needed for apoptosis in CHSE-214 but impeded apoptosis in EPC. At the cellular level, only EPC is a permissive host as EPC was the only cell line of the three capable of producing a moderate increase in virus titer. The three non-host cell lines present a good system for potentially identifying different components of GIV-induced apoptotic pathways in future studies.

Senescence-associated β-galactosidase staining in fish cell lines and primary cultures from several tissues and species, including rainbow trout coelomic fluid and milt

Cell lines and primary cultures from several teleost tissues and species were stained for senescence-associated β-galactosidase (SA β-Gal), revealing four general outcomes. (1) For long-standing fish cell lines that can be considered immortal, little or no SA β-Gal staining was observed, regardless of the culture conditions. (2) For a new walleye cell line from the bulbus arteriosus (WEBA), most cells stained for SA β-Gal even after 40 passages. This suggested that high SA β-Gal activity was a unique property of WEBA, perhaps reflecting their endothelial character, rather than cellular senescence. (3) For cell lines developed from the walleye caudal fin and from somatic cells in rainbow trout coelomic fluid, no SA β-Gal staining was observed in the earliest cultures to over 70 passages later. This suggested that cells from these anatomical sites do not undergo senescence in vitro. (4) By contrast, for cell lines developed from the walleye brain and from somatic cells in rainbow trout milt, most cells in the early-stage cultures stained for SA β-Gal, but as these were developed into cell lines, SA β-Gal-negative cells became dominant. This suggested that if cellular senescence occurred in vitro, this happened early in these cultures and subsequently a few SA β-Gal-negative cells went onto to form the cell line. Overall, the presence of SA β-Gal-positive cells in cultures could be interpreted in several ways, whereas their absence predicted that in these cultures, cells would proliferate indefinitely.

The potential of waste items in aquatic environments to act as fomites for viral haemorrhagic septicaemia virus

Fomites are defined as inanimate surfaces that can retain and transmit infectious organisms from one host to another and are widely studied in human public health and in animal farming. The survival of many human and livestock pathogens on inanimate objects has been demonstrated, including but not limited to influenza survival on banknotes (Thomas, Vogel, Wunderli, Suter, Witschi, Koch, Tapparel & Kaiser 2008), HIV on glass coverslips (Van Bueren, Simpson, Jacobs & Cookson 1994), different strains of staphylococci on public computer keyboards (Kassem, Sigler & Esseili 2007), swine pseudorabies on cement (Schoenbaum, Freund & Beran 1991), porcine reproductive and respiratory syndrome virus on clothing such as boots and coveralls (Otake, Dee, Rossow, Deen, Joo, Molitor & Pijoan 2002) and avian reoviruses on cotton, wood, glass, rubber, polythene bag and metals (Savage & Jones 2003). However, to date, little attention has been given to the possible role of fomites in the aquatic environment, which is surprising given the increasing amounts of manmade waste in the ocean (Derraik 2002) and the impact of infectious agents on aquaculture and trade (FAO 2006). One class of waste is plastic. Plastic debris is a significant and increasing form of pollution in aquatic environments, especially in oceans (Derraik 2002). Debris items with diameters >1 cm are termed macrolitter and include plastic bottles, plastic bags and styrofoam containers (Thiel & Gutow 2005). However, the majority of the plastic debris in the oceans exists as small particles (<1 cm) and is termed microlitter (Thiel & Gutow 2005). Microlitter can arise from the abrasion of larger plastic debris (Eriksson & Burton 2003) but mostly from the tiny plastic pellets that are the raw material for manufacturing (Prutter 1987). Debris can be composed of polypropylene, polyvinyl chloride, polyethylene and polystyrene (Prutter 1987). Recently, we developed a novel and sensitive method for detecting the presence of infectious viruses adsorbed onto polystyrene (Pham, Jung & Bols 2011). The method was derived with plastic tissue culture vessels, such as 96-well plates and culture dishes. These were incubated with a solution of virus for 24 h, rinsed and then allowed to either dry or to remain wet for variable periods of time before cells susceptible to the virus were added. The cells attached and spread on the surface and over time developed cytopathic effect (CPE), indicating that the surface had adsorbed or attached virus that remained infectious. Infection appeared to involve direct surface to cell transfer of the virus. With this protocol, viruses were shown to adhere and remain infectious on polystyrene in either a wet or dry state for up to 15 days (Pham et al. 2011). Another source of waste comes from commercial and recreational fishing. Approximately 135 400 tons of fishing gears are lost or abandoned at sea per year along with an estimated amount of 600 000 plastic containers discarded by merchant vessels a Journal of Fish Diseases 2012, 35, 73–77 doi:10.1111/j.1365-2761.2011.01323.x

Invitromatics, invitrome, and invitroomics: introduction of three new terms for in vitro biology and illustration of their use with the cell lines from rainbow trout

The literature on cell lines that have been developed from rainbow trout (RT) (Oncorhynchus mykiss) is reviewed to illustrate three new terms: invitromatics, invitrome, and invitroomics. Invitromatics is defined as the history, development, characterization, engineering, storage, and sharing of cell lines. RT invitromatics differs from invitromatics for humans and other mammals in several ways. Nearly all the RT cell lines have developed through spontaneous immortalization. No RT cell line undergoes senescence and can be described as being finite, whereas many human cell lines undergo senescence and are finite. RT cell lines are routinely grown at 18–22°C in free gas exchange with air in basal media developed for mammalian cells together with a supplement of fetal bovine serum. An invitrome is defined as the grouping of cell lines around a theme or category. The broad theme in this article is all the cell lines that have ever been created from O. mykiss, or in other words, the RT invitrome. The RT invitrome consists of approximately 55 cell lines. These cell lines can also be categorized on the basis of their storage and availability. A curated invitrome constitutes all the cell lines in a repository and for RT consists of 11 cell lines. These consist of epithelial cell lines, such as RTgill-W1, and fibroblast cell lines, such as RTG-2. RTG-2 can be purchased from a scientific company and constitutes the commercial RT invitrome. Cell lines that are exchanged between researchers are termed the informally shared invitrome and for RT consists of over 35 cell lines. Among these is the monocyte/macrophage cell line, RTS11. Cell lines whose existence is in doubt are termed the zombie invitrome, and for RT, approximately 12 cell lines are zombies. Invitroomics is the application of cell lines to a scientific problem or discipline. This is illustrated with the use of the RT invitrome in virology. Of the RT invitrome, RTG-2 was the most commonly used cell line to isolate viruses. Fifteen families of viruses were studied with RT invitrome. RT cell lines were best able to support replication of viruses from the Herpesviridae, Iridoviridae, Birnaviridae, Togaviridae, and Rhabdoviridae families.

Use of cell lines and primary cultures to explore the capacity of rainbow trout to be a host for frog virus 3 (FV3)

The capacity of rainbow trout, Oncorhynchus mykiss, to be a host for frog virus 3 (FV3) was evaluated at the cellular level. Cell cultures from this species were tested for their ability to express FV3 major capsid protein (MCP) gene, to develop cytopathic effect (CPE), and to produce FV3. After FV3 addition, MCP transcripts were detected in six of six cell lines and in primary macrophage cultures. CPE developed in all cell culture systems, except primary lymphocytes. For the macrophage cell line, RTS11, and primary macrophages, cell death was by apoptosis because DNA laddering and Annexin staining were detected. By contrast, markers of apoptosis did not accompany CPE in three epithelial cell lines from the gill (RTgill-W1), intestine (RTgut-GC), and liver (RTL-W1) and in two fibroblast cell lines from gonads (RTG-2) and skin (RTHDF). Therefore, FV3 was able to enter and begin replicating in several cell types. Yet, FV3 was produced in only two cell lines, RTG-2 and RTL-W1, and only modestly. Overall, these results suggest that if tissue accessibility were possible, FV3 would have the capacity to induce injury, but the ability to replicate would be limited, likely making rainbow trout a poor host for FV3.

Atlantic salmon endothelial cells from the heart were more susceptible than fibroblasts from the bulbus arteriosus to four RNA viruses but protected from two viruses by dsRNA pretreatment

ABSTRACT Heart diseases caused by viruses are major causes of Atlantic salmon aquaculture loss. Two Atlantic salmon cardiovascular cell lines, an endothelial cell line (ASHe) from the heart and a fibroblast cell line (BAASf) from the bulbus arteriosus, were evaluated for their response to four fish viruses, CSV, IPNV, VHSV IVa and VHSV IVb, and the innate immune agonist, double‐stranded RNA mimic poly IC. All four viruses caused cytopathic effects in ASHe and BAASf. However, ASHe was more susceptible to all four viruses than BAASf. When comparing between the viruses, ASHe cells were found to be moderately susceptible to CSV and VHSV IVb, but highly susceptible to IPNV and VHSV IVa induced cell death. All four viruses were capable of propagating in the ASHe cell line, leading to increases in virus titre over time. In BAASf, CSV and IPNV produced more than one log increase in titre from initial infection, but VHSV IVb and IVa did not. When looking at the antiviral response of both cell lines, Mx proteins were induced in ASHe and BAASf by poly IC. All four viruses induced Mx proteins in BAASf, while only CSV and VHSV IVb induced Mx proteins in ASHe. IPNV and VHSV IVa suppressed Mx proteins expression in ASHe. Pretreatment of ASHe with poly IC to allow for Mx proteins accumulation protected the culture from subsequent infections with IPNV and VHSV IVa, resulting in delayed cell death, reduced virus titres and reduced viral proteins expression. These data suggest that endothelial cells potentially can serve as points of infections for viruses in the heart and that two of the four viruses, IPNV and VHSV IVa, have mechanisms to avoid or downregulate antiviral responses in ASHe cells. Furthermore, the high susceptibility of the ASHe cell line to IPNV and VHSV IVa can make it a useful tool for studying antiviral compounds against these viruses and for general detection of fish viruses. HighlightsAtlantic salmon heart endothelial cell line (ASHe) is very sensitive to IPNV and VHSV IVa.IPNV and VHSV IVa, but not CSV and VHSV IVb, suppressed Mx protein expression in ASHe.Poly IC pretreatment of ASHe protected the cells from IPNV and VHSV IVa infection.Atlantic salmon bulbus arteriosus fibroblast cell line (BAASf) is not as sensitive to the tested fish RNA viruses as ASHe.

Toxicity and safety aspects of nanoparticle spread in third generation photovoltaic device processing environments

Detection strategies for analysis of the nanomaterials toxicity, although challenging, will be in much demand as nanotechnology becomes more common-place in third generation photovoltaics (PV). Experimentally feasible approaches must be designed and engineered to detect quantum dots (QDs) and nanoparticles (NPs) in PV device processing environment. Identifying the level of risk to human body upon exposure to nanomaterials is another important factor that needs consideration. In this work evidence on the detection of aerosolized nanoparticles was experimentally verified using gold NP adsorbent, followed by spectroscopic measurements. Results from in-vitro cytotoxicity study with HeLa cell cultures and fluorescent plate reading also showed that core/shell CdSe/ZnS QDs are responsible for cell death following exposure.

Fish viruses stored in RNAlater can remain infectious and even be temporarily protected from inactivation by heat or by tissue homogenates

RNAlater is a commonly used transport and storage solution for samples collected for fish health investigations, particularly those potentially involving viruses. However, the infectivity of fish viruses after storage in RNAlater have not been determined. Nevertheless, knowledge of pathogen infectivity of preserved samples is crucial for ensuring safe transport and storage protocols. Therefore, the infectivity of three fish RNA viruses in RNAlater was examined at four temperatures: -80 °C, 4 °C, room temperature (RT, approximately 22 °C) and 37 °C. The viruses were viral hemorrhagic septicemia virus (VHSV), infectious pancreatic necrosis virus (IPNV) and chum salmon reovirus (CSV). Overall, three consistent outcomes were observed. First, all three viruses remained infectious in RNAlater at RT or lower. High log titres of these viruses remained over 30 d of storage in either RNAlater or PBS. Second, RNAlater delayed the thermal inactivation of these viruses when compared to PBS at 37 °C. For VHSV, the titre remained high in RNAlater after one day of incubation at 37 °C, but was inactivated to below threshold in PBS over the same period. For IPNV, the titre remained high in RNAlater after 30 d of incubation at 37 °C, but was inactivated to below threshold in PBS over the same period. For CSV, the titre was slightly higher in RNAlater than PBS at 37 °C over 7 d, and by day 30, only samples stored in RNAlater proved infectious at titres above the detection threshold. Third, RNAlater delayed the inactivation of these viruses when they were stored together with head kidney homogenates. For VHSV, infectious virus was recovered from samples stored at 4 °C in RNAlater by day 7 of incubation, whereas it was inactivated to below threshold in PBS over the same period. For both IPNV and CSV, infectious virus was recovered from samples stored at 37 °C in RNAlater for 7 d, but not so in PBS. In summary, fish viruses can remain infectious and are even temporarily protected from inactivation while in RNAlater. This makes RNAlater a potentially useful solution for the transport of fish viruses. At the same time, precautionary measures must be taken when transporting potentially infectious samples in RNAlater.

Effect of selenomethionine on cell viability and heat shock protein 70 levels in rainbow trout intestinal epithelial cells at hypo-, normo-, and hyper-thermic temperatures

As global warming and environmental pollution modify aquatic environments, the thermal biology of fish could be affected by interactions between temperature and pollutants, such as selenium (Se). Therefore, selenomethionine (SeMet) was studied for effects on cell viability and on heat shock protein 70 (HSP70) levels in the rainbow trout intestinal epithelial cell, RTgutGC, at hypothermic (4 °C), normothermic (14 and 18 °C) and hyperthermic (26 °C) temperatures. RTgutGC cultures remained viable for at least a week at all temperatures, although energy metabolism as measured with Alamar Blue (resazurin) was appreciably diminished at 4 °C. Over a 7-day incubation, HSP 70 levels in cultures remained steady at 4 °C, declined at 18 °C, and increased slightly at 26 °C. When 125 μM SeMet was present, cultures remained viable and HSP70 levels were neither increased nor decreased relative to control cultures, regardless of the temperature. With 500 and 1000 μM SeMet, cell viability was profoundly impaired after 7 days in cultures at 14, 18 and 26 °C but was unchanged at 4 °C. Overall the results suggest that only hypothermia modulated the response of rainbow trout cells to SeMet.