Identification of a novel rhabdovirus in Spodoptera frugiperda cell lines.

UNLABELLED: The Sf9 cell line, derived from Spodoptera frugiperda, is used as a cell substrate for biological products, and no viruses have been reported in this cell line after extensive testing. We used degenerate PCR assays and massively parallel sequencing (MPS) to identify a novel RNA virus belonging to the order Mononegavirales in Sf9 cells. Sequence analysis of the assembled virus genome showed the presence of five open reading frames (ORFs) corresponding to the genes for the N, P, M, G, and L proteins in other rhabdoviruses and an unknown ORF of 111 amino acids located between the G- and L-protein genes. BLAST searches indicated that the S. frugiperda rhabdovirus (Sf-rhabdovirus) was related in a limited region of the L-protein gene to Taastrup virus, a newly discovered member of the Mononegavirales from a leafhopper (Hemiptera), and also to plant rhabdoviruses, particularly in the genus Cytorhabdovirus. Phylogenetic analysis of sequences in the L-protein gene indicated that Sf-rhabdovirus is a novel virus that branched with Taastrup virus. Rhabdovirus morphology was confirmed by transmission electron microscopy of filtered supernatant samples from Sf9 cells. Infectivity studies indicated potential transient infection by Sf-rhabdovirus in other insect cell lines, but there was no evidence of entry or virus replication in human cell lines. Sf-rhabdovirus sequences were also found in the Sf21 parental cell line of Sf9 cells but not in other insect cell lines, such as BT1-TN-5B1-4 (Tn5; High Five) cells and Schneider's Drosophila line 2 [D.Mel.(2); SL2] cells, indicating a species-specific infection. The results indicate that conventional methods may be complemented by state-of-the-art technologies with extensive bioinformatics analysis for identification of novel viruses. IMPORTANCE: The Spodoptera frugiperda Sf9 cell line is used as a cell substrate for the development and manufacture of biological products. Extensive testing has not previously identified any viruses in this cell line. This paper reports on the identification and characterization of a novel rhabdovirus in Sf9 cells. This was accomplished through the use of next-generation sequencing platforms, de novo assembly tools, and extensive bioinformatics analysis. Rhabdovirus identification was further confirmed by transmission electron microscopy. Infectivity studies showed the lack of replication of Sf-rhabdovirus in human cell lines. The overall study highlights the use of a combinatorial testing approach including conventional methods and new technologies for evaluation of cell lines for unexpected viruses and use of comprehensive bioinformatics strategies for obtaining confident next-generation sequencing results.

Identification of recombination in the envelope gene of simian foamy virus serotype 2 isolated from Macaca cyclopis.

The full-length sequence of simian foamy virus serotype 2 (SFVmcy-2), isolated from a Taiwanese macaque, was determined. SFVmcy-2 was highly related to SFV serotype 1 (SFVmcy-1), an isolate from the same species, except in the putative receptor binding domain (RBD) in env, which contained novel sequences related to SFV serotype 3 (SFVagm-3), isolated from an African green monkey. The results identify a potential region of neutralization in SFVs and demonstrate recombination between genetically divergent foamy viruses.

No evidence of xenotropic murine leukemia virus-related virus transmission by blood transfusion from infected rhesus macaques.

The discovery of xenotropic murine leukemia virus-related virus (XMRV) in human tissue samples has been shown to be due to virus contamination with a recombinant murine retrovirus. However, due to the unknown pathogenicity of this novel retrovirus and its broad host range, including human cell lines, it is important to understand the modes of virus transmission and develop mitigation and management strategies to reduce the risk of human exposure and infection. XMRV transmission was evaluated by whole-blood transfusion in rhesus macaques. Monkeys were infected with XMRV to serve as donor monkeys for blood transfers at weeks 1, 2, and 3 into naïve animals. The donor and recipient monkeys were evaluated for XMRV infection by nested PCR assays with nucleotide sequence confirmation, Western blot assays for development of virus-specific antibodies, and coculture of monkey peripheral blood mononuclear cells (PBMCs) with a sensitive target cell line for virus isolation. XMRV infection was demonstrated in the virus-injected donor monkeys, but there was no evidence of virus transmission by whole-blood transfusion to naïve monkeys based upon PCR analysis of PBMCs using XMRV-specific gag and env primers, Western blot analysis of monkey plasma up to 31 to 32 weeks after transfusion, and coculture studies using monkey PBMCs from various times after transfusion. The study demonstrates the lack of XMRV transmission by whole-blood transfusion during the acute phase of infection. Furthermore, analysis of PBMC viral DNA showed extensive APOBEC-mediated G-to-A hypermutation in a donor animal at week 9, corroborating previous results using macaques and supporting the possible restriction of XMRV replication in humans by a similar mechanism.

Chemical induction of endogenous retrovirus particles from the vero cell line of African green monkeys.

Endogenous retroviral sequences are present in high copy numbers in the genomes of all species and may be expressed as RNAs; however, the majority are defective for virus production. Although virus has been isolated from various Old World monkey and New World monkey species, there has been no report of endogenous retroviruses produced from African green monkey (AGM) tissues or cell lines. We have recently developed a stepwise approach for evaluating the presence of latent viruses by chemical induction (Khan et al., Biologicals 37:196-201, 2009). Based upon this strategy, optimum conditions were determined for investigating the presence of inducible, endogenous retroviruses in the AGM-derived Vero cell line. Low-level reverse transcriptase activity was produced with 5-azacytidine (AzaC) and with 5'-iodo-2'-deoxyuridine (IUdR); none was detected with sodium butyrate. Nucleotide sequence analysis of PCR-amplified fragments from the gag, pol, and env regions of RNAs, prepared from ultracentrifuged pellets of filtered supernatants, indicated that endogenous retrovirus particles related to simian endogenous type D betaretrovirus (SERV) sequences and baboon endogenous virus type C gammaretrovirus (BaEV) sequences were induced by AzaC, whereas SERV sequences were also induced by IUdR. Additionally, sequence heterogeneity was seen in the RNAs of SERV- and BaEV-related particles. Infectivity analysis of drug-treated AGM Vero cells showed no virus replication in cell lines known to be susceptible to type D simian retroviruses (SRVs) and to BaEV. The results indicated that multiple, inducible endogenous retrovirus loci are present in the AGM genome that can encode noninfectious, viruslike particles.

Investigation of xenotropic murine leukemia virus-related virus (XMRV) in human and other cell lines.

Xenotropic murine leukemia virus-related virus (XMRV) was discovered in human prostate tumors and later in some chronic fatigue syndrome (CFS) patients. However, subsequent studies have identified various sources of potential contamination with XMRV and other murine leukemia virus (MLV)-related sequences in test samples. Biological and nucleotide sequence analysis indicates that XMRV is distinct from known xenotropic MLVs and has a broad host range and cell tropism including human cells. Therefore, it is prudent to minimize the risk of human exposure to infection by evaluating XMRV contamination in cell lines handled in laboratory research and particularly those used in the manufacture of biological products. Nested DNA PCR assays were optimized for investigating XMRV gag and env sequences in various cell lines, which included MRC-5, Vero, HEK-293, MDCK, HeLa, and A549, that may be used in the development of some vaccines and other cell lines broadly used in research. The sensitivity of the DNA PCR assays was <10 copies in approximately 1.8 x 10(5) cells equivalent of human DNA. The results indicated the absence of XMRV in the cell lines tested; although in some cases DNA fragments identified as cellular sequences were seen following the first round of PCR amplification with the env primer pair.

Optimization of chemical induction conditions for human herpesvirus 8 (HHV-8) reactivation with 12-O-tetradecanoyl-phorbol-13-acetate (TPA) from latently-infected BC-3 cells.

Human herpesvirus 8 (HHV-8) persists as episomal DNA in latently-infected cells and can establish two alternative life cycles, latent or lytic. 12-O-tetradecanoyl-phorbol-13-acetate (TPA) is a known inducer of HHV-8 in several human primary effusion lymphoma cell lines and has been widely used for HHV-8 reactivation; however, induction conditions have differed, resulting in varying levels of virus expression. We have used HHV-8 latently-infected BC-3 cells as a model to determine critical parameters for optimizing virus reactivation by TPA. We found that cell growth properties and drug treatment conditions were important for maximum reactivation of HHV-8. Addition of TPA to cells in the early log phase of a sigmoidal growth curve, which was tightly associated with high percentage of the cells in early S phase and with lower histone deacetylase activity in the cells, provided the optimum cell conditions for latent virus to switch to lytic replication. Furthermore, increasing TPA concentration (up to 320 ng per ml) at 48 h exposure time resulted in increased virus production. The results demonstrate the use of a step-wise strategy with chemical induction that may facilitate broad detection of latent DNA viruses and novel virus discovery.

Proposed algorithm to investigate latent and occult viruses in vaccine cell substrates by chemical induction.

The recent urgency to develop new vaccines for emerging and re-emerging diseases, such as pandemic influenza, has necessitated the use of cell substrates not previously used in the manufacture of licensed vaccines. A major safety concern in the use of novel cell substrates is the presence of potential adventitious agents, such as latent and occult viruses, that may not be detected by currently used conventional assays. In cases where the novel cell substrate is known to be tumorigenic, there are additional safety issues related to tumorigenicity of intact cells and oncogenicity of residual cellular DNA. We have developed a strategy for evaluating vaccine cell substrates for the presence of latent/occult viruses, including endogenous retroviruses, latent RNA viruses and oncogenic DNA viruses, by optimizing conditions for chemical induction of viruses and using a combination of broad and specific assays to enable detection of known and novel viruses.

New technologies and challenges of novel virus detection.

The use of new cell substrates for the development of biologicals, particularly tumorigenic and tumor-derived cell lines, can pose a major regulatory challenge due to safety concerns related to the presence of novel viruses, latent and occult viruses including oncogenic viruses, and endogenous retroviruses, since these may not be detected by the currently recommended conventional assays. This report is a summary of our laboratory's experiences using advanced nucleic acid-based technologies to evaluate a Madin-Darby canine kidney (MDCK) cell line and the insect Sf9 cell line derived from Spodoptera frugiperda, and presents some ongoing efforts to address the challenges of novel virus detection.

Evaluation of the broad-range PCR-electrospray ionization mass spectrometry (PCR/ESI-MS) system and virus microarrays for virus detection.

Advanced nucleic acid-based technologies are powerful research tools for novel virus discovery but need to be standardized for broader applications such as virus detection in biological products and clinical samples. We have used well-characterized retrovirus stocks to evaluate the limit of detection (LOD) for broad-range PCR with electrospray ionization mass spectrometry (PCR/ESI-MS or PLEX-ID), RT-PCR assays, and virus microarrays. The results indicated that in the absence of background cellular nucleic acids, PLEX-ID and RT-PCR had a similar LOD for xenotropic murine retrovirus-related virus (XMRV; 3.12 particles per µL) whereas sensitivity of virus detection was 10-fold greater using virus microarrays. When virus was spiked into a background of cellular nucleic acids, the LOD using PLEX-ID remained the same, whereas virus detection by RT-PCR was 10-fold less sensitive, and no virus could be detected by microarrays. Expected endogenous retrovirus (ERV) sequences were detected in cell lines tested and known species-specific viral sequences were detected in bovine serum and porcine trypsin. A follow-up strategy was developed using PCR amplification, nucleotide sequencing, and bioinformatics to demonstrate that an RD114-like retrovirus sequence that was detected by PLEX-ID in canine cell lines (Madin-Darby canine kidney (MDCK) and Cf2Th canine thymus) was due to defective, endogenous gammaretrovirus-related sequences.

Influence of naturally occurring simian foamy viruses (SFVs) on SIV disease progression in the rhesus macaque (Macaca mulatta) model.

We have investigated the influence of naturally occurring simian foamy viruses (SFVs) on simian immunodeficiency virus (SIV) infection and disease in Indian rhesus macaques. Animals were divided into two groups based upon presence or absence of SFV; in each group, eight monkeys were injected with SIV(mac239) virus obtained from a molecular clone and four were injected with medium. Blood was collected every two weeks for evaluation of SIV infection based upon T cell-subsets, plasma viral load, development and persistence of virus-specific antibodies, and clinical changes by physical examination and hematology. Comparative analysis of SFV+/SIV+ and SFV-/SIV+ monkey groups indicated statistically significant differences in the plasma viral load between 6-28 weeks, particularly after reaching plateau at 20-28 weeks, in the CD4+ and CD8+ T-cell numbers over the entire study period (2-43 weeks), and in the survival rates evaluated at 49 weeks. There was an increase in the plasma viral load, a decreasing trend in the CD4+ T cells, and a greater number of animal deaths in the SFV+/SIV+ group. The results, although based upon a small number of animals, indicated that pre-existing SFV infection can influence SIV infection and disease outcome in the rhesus macaque model. The study highlights consideration of the SFV status in evaluating results from SIV pathogenesis and vaccine challenge studies in monkeys and indicates the potential use of the SFV/SIV monkey model to study the dynamics of SFV and HIV-1 dual infections, recently reported in humans.