Evaluation of consistency in quantification of gene copy number by real‐time reverse transcription quantitative polymerase chain reaction and virus titer by plaque‐forming assay for human respiratory syncytial virus

The plaque‐forming assay is the standard technique for determining viral titer, and a critical measurement for investigating viral replication. However, this assay is highly dependent on experimental technique and conditions. In the case of human respiratory syncytial virus (RSV) in particular, it can be difficult to objectively confirm the accuracy of plaque‐forming assay because the plaques made by RSV are often small and unclear. In recent studies, RT‐qPCR methods have emerged as a supportive procedure for assessment of viral titer, yielding highly sensitive and reproducible results. In this report, we compare the viral replication, as determined by plaque‐forming assay, and the copy numbers of RSV genes NS1, NS2, N, and F, as determined by RT‐qPCR. Two real‐time PCR systems, SYBR Green and TaqMan probe, gave highly similar results for measurement of copy numbers of RSV N genes of virus subgroups A. We determined the RSV gene copy numbers in the culture cell supernatant and cell lysate measured at various multiplicities of infection. We found that copy number of the RSV N gene in the culture supernatant and cell lysate was highly correlated with plaque‐forming units. In conclusion, RT‐qPCR measurement of RSV gene copy number was highly dependent on viral titer, and the detailed comparison between each gene copy number and virus titer should be useful and supportive in confirming RSV plaque‐forming assay and virus dynamics. The technique may also be used to estimate the amount of RSV present in clinical specimens.

     

Production of helper-dependent adenovirus vector relies on helper virus structure and complementing

Background

The helper‐dependent (HD) adenoviral (Ad) vector relies on a helper virus to provide viral proteins for vector amplification. HD‐Ad vectors can significantly increase therapeutic gene expression and improve safety. However, the yield of an HD‐Ad vector is generally lower than that of an E1‐deleted first‐generation vector, likely due to the alterations in viral E3 or packaging regions of a helper virus that attenuate its replication and complementing for an HD‐Ad vector.

Methods

To study this question and improve HD‐Ad vector production, we have generated four different helper viruses with a wild‐type or deleted E3 region, and with a relocated loxP. We have also constructed a first‐generation vector with a wild‐type E3 region and without the loxP site. We compared the replication of these viruses in Cre‐positive and ‐negative cells and studied their complementing for HD‐Ad vector production.

Results

Viruses with deleted E3 formed smaller plaques and produced lower titer compared with viruses containing the E3 region. The site where a loxP is inserted can also affect virus replication. Higher yield of HD‐Ad vector was obtained when a helper virus with wild‐type E3 was used. We also showed that deletion of the packaging signal in a helper virus through loxP/Cre interaction decreased the viral DNA complementing ability.

Conclusions

Although the E3 region is not essential for adenovirus replication in vivo, deletion of this region attenuates virus replication. Production of HD‐Ad vector can be further improved by modifications in helper virus structure. Copyright © 2002 John Wiley & Sons, Ltd.

     

Masters of manipulation: Viral modulation of the immunological synapse

In order to thrive, viruses have evolved to manipulate host cell machinery for their own benefit. One major obstacle faced by pathogens is the immunological synapse. To enable efficient replication and latency in immune cells, viruses have developed a range of strategies to manipulate cellular processes involved in immunological synapse formation to evade immune detection and control T‐cell activation. In vitro, viruses such as human immunodeficiency virus 1 and human T‐lymphotropic virus type 1 utilise structures known as virological synapses to aid transmission of viral particles from cell to cell in a process termed trans‐infection. The formation of the virological synapse provides a gateway for virus to be transferred between cells avoiding the extracellular space, preventing antibody neutralisation or recognition by complement. This review looks at how viruses are able to subvert intracellular signalling to modulate immune function to their advantage and explores the role synapse formation has in viral persistence and cell‐to‐cell transmission.     

Cutting edge: paradoxical roles of BST2/tetherin in promoting type I IFN response and viral infection

Bone marrow stromal Ag 2 (BST2) is a transmembrane protein that prevents virus release from infected cells. It was also reported that BST2 inhibits type I IFN production by plasmacytoid dendritic cells. To determine BST2 impact on antiviral responses in vivo, we generated BST2(-/-) mice. Following infection with a murine retrovirus, BST2(-/-) mice had slightly elevated viral loads; however, infection with other enveloped viruses revealed unexpected roles of BST2. BST2(-/-) mice showed reduced type I IFN production by plasmacytoid dendritic cells. Moreover, BST2(-/-) mice had lower viral titers in lungs following intranasal infection with vesicular stomatitis virus expressing OVA and influenza B and increased numbers of virus-specific CD8 T cells in the lungs, suggesting that BST2 may facilitate entry and/or replication of enveloped viruses and modulate priming of CD8 T cells. These findings suggest complex roles of BST2 beyond retroviral control in vivo, possibly reflecting the involvement of BST2 in endocytosis and intracellular trafficking of viruses, viral nucleic acids, and Ags.     

Viral Subversion of Nucleocytoplasmic Trafficking

Trafficking of proteins and RNA into and out of the nucleus occurs through the nuclear pore complex (NPC). Because of its critical function in many cellular processes, the NPC and transport factors are common targets of several viruses that disrupt key constituents of the machinery to facilitate viral replication. Many viruses such as poliovirus and severe acute respiratory syndrome (SARS) virus inhibit protein import into the nucleus, whereas viruses such as influenza A virus target and disrupt host mRNA nuclear export. Current evidence indicates that these viruses may employ such strategies to avert the host immune response. Conversely, many viruses co‐opt nucleocytoplasmic trafficking to facilitate transport of viral RNAs. As viral proteins interact with key regulators of the host nuclear transport machinery, viruses have served as invaluable tools of discovery that led to the identification of novel constituents of nuclear transport pathways. This review explores the importance of nucleocytoplasmic trafficking to viral pathogenesis as these studies revealed new antiviral therapeutic strategies and exposed previously unknown cellular mechanisms. Further understanding of nuclear transport pathways will determine whether such therapeutics will be useful treatments for important human pathogens.      

Toll-Like Receptor 4-Mediated Activation of p38 Mitogen-Activated Protein Kinase Is a Determinant of Respiratory Virus Entry and Tropism

Respiratory viruses exert a heavy toll of morbidity and mortality worldwide. Despite this burden there are few specific treatments available for respiratory virus infections. Since many viruses utilize host cell enzymatic machinery such as protein kinases for replication, we determined whether pharmacological inhibition of kinases could, in principle, be used as a broad antiviral strategy for common human respiratory virus infections. A panel of green fluorescent protein (GFP)-expressing recombinant respiratory viruses, including an isolate of H1N1 influenza virus (H1N1/Weiss/43), was used to represent a broad range of virus families responsible for common respiratory infections (Adenoviridae, Paramyxoviridae, Picornaviridae, and Orthomyxoviridae). Kinase inhibitors were screened in a high-throughput assay that detected virus infection in human airway epithelial cells (1HAEo-) using a fluorescent plate reader. Inhibition of p38 mitogen-activated protein kinase (MAPK) signaling was able to significantly inhibit replication by all viruses tested. Therefore, the pathways involved in virus-mediated p38 and extracellular signal-regulated kinase (ERK) MAPK activation were investigated using bronchial epithelial cells and primary fibroblasts derived from MyD88 knockout mouse lungs. Influenza virus, which activated p38 MAPK to approximately 10-fold-greater levels than did respiratory syncytial virus (RSV) in 1HAEo- cells, was internalized about 8-fold faster and more completely than RSV. We show for the first time that p38 MAPK is a determinant of virus infection that is dependent upon MyD88 expression and Toll-like receptor 4 (TLR4) ligation. Imaging of virus-TLR4 interactions showed significant clustering of TLR4 at the site of virus-cell interaction, triggering phosphorylation of downstream targets of p38 MAPK, suggesting the need for a signaling receptor to activate virus internalization.Respiratory virus infections cause considerable morbidity and mortality worldwide; it was recently reported that hospitalizations due to respiratory syncytial virus (RSV) exceed 2 million per year in the Unites States alone (16). An H1N1 swine influenza pandemic took place during the 2009-2010 winter season (14), and there is the lingering threat of an H5N1 avian influenza pandemic, with mortality due to direct bird-to-human H5N1 infection in hospitalized patients between 30 and 100% (3). The severe acute respiratory syndrome (SARS)-associated coronavirus, isolated in 2003, resulted in devastating respiratory tract infections with few treatment options (40). For most common respiratory viruses, treatment is symptomatic, and for pathogens such as influenza viruses for which specific treatments are available, oseltamivir (Tamiflu)- and amantidine-resistant strains are emerging and being transmitted globally (33).All functions within a cell are triggered and regulated by cell signaling cues. Since viruses are obligate intracellular parasites, they rely upon cell signaling to regulate all processes within the cell that drive virus replication. In this study we investigated the effects of kinase inhibitors as a therapeutic strategy and to investigate the roles played by some kinases during virus replication. The extracellular signal-regulated kinase (ERK) and p38 mitogen-activated protein kinases (MAPKs) have been shown by us and others to play important roles during virus replication in vitro (19, 20, 26, 30, 42), and we have recently reported that inhibition of p38 MAPK activation is an effective and novel antiviral strategy in vivo (29). The significance of p38 MAPK activity in vivo is such that inadvertent and coincident activation of this kinase by some pharmaceutical agents enhances virus replication (29). Antiviral strategies may exist whereby inhibition of host cell kinases may stem the spread and replication of numerous different viral species. Such broad antiviral strategies would permit administration of kinase inhibitors to patients suspected of having respiratory viral infection, and to health care workers or inhabitants within the locale of a viral outbreak, prior to the availability of results from laboratory diagnostic testing.The activation of p38 MAPK by pattern recognition receptors (PRRs) has been studied in the context of the antiviral immune response (reviewed in reference 22). We report here that viruses usurp these responses for the benefit of virus replication through activation of p38 MAPK, mediated by a PRR (Toll-like receptor 4 [TLR4]) and MyD88, providing the basis for a broad-spectrum antiviral.     

Molecular Mechanism of BST2/Tetherin Downregulation by K5/MIR2 of Kaposi's Sarcoma-Associated Herpesvirus

K3/MIR1 and K5/MIR2 of Kaposi''s sarcoma-associated herpesvirus (KSHV) are viral members of the membrane-associated RING-CH (MARCH) ubiquitin ligase family and contribute to viral immune evasion by directing the conjugation of ubiquitin to immunostimulatory transmembrane proteins. In a quantitative proteomic screen for novel host cell proteins downregulated by viral immunomodulators, we previously observed that K5, as well as the human immunodeficiency virus type 1 (HIV-1) immunomodulator VPU, reduced steady-state levels of bone marrow stromal cell antigen 2 (BST2; also called CD317 or tetherin), suggesting that BST2 might be a novel substrate of K5 and VPU. Recent work revealed that in the absence of VPU, HIV-1 virions are tethered to the plasma membrane in BST2-expressing HeLa cells. By targeting BST2, K5 might thus similarly overcome an innate antiviral host defense mechanism. Here we establish that despite its type II transmembrane topology and carboxy-terminal glycosylphosphatidylinositol (GPI) anchor, BST2 represents a bona fide target of K5 that is downregulated during primary infection by and reactivation of KSHV. Upon exit of the protein from the endoplasmic reticulum, lysines in the short amino-terminal domain of BST2 are ubiquitinated by K5, resulting in rapid degradation of BST2. Ubiquitination of BST2 is required for degradation, since BST2 lacking cytosolic lysines was K5 resistant and ubiquitin depletion by proteasome inhibitors restored BST2 surface expression. Thus, BST2 represents the first type II transmembrane protein targeted by K5 and the first example of a protein that is both ubiquitinated and GPI linked. We further demonstrate that KSHV release is decreased in the absence of K5 in a BST2-dependent manner, suggesting that K5 contributes to the evasion of intracellular antiviral defense programs.Bone marrow stromal cell antigen 2 (BST2) was recently identified as a host cell restriction factor that prevents the release of retroviral and filoviral particles from infected host cells (23). Human immunodeficiency virus type 1 (HIV-1) counteracts this antiviral function of BST2 by expressing the viral auxiliary protein VPU (41, 53). In the absence of VPU, virus particles are prevented from budding off the cellular membrane in cells that express BST2, resulting in virions being tethered to the plasma membrane. BST2 was therefore renamed tetherin (41), although questions still remain as to whether BST2 acts as the actual tether and whether BST2-dependent tethering occurs in all BST2-expressing cell types (36). Independently, BST2 was shown to be induced by type I and type II interferons (IFNs) (7), suggesting that BST2 is part of the innate antiviral response triggered in infected cells.Using a quantitative membrane proteomic approach, we observed that BST2 is underrepresented in plasma membranes from cells expressing not only VPU (14) but also the K5 protein of Kaposi''s sarcoma-associated herpesvirus (KSHV) (4). K5 is a viral homologue of a family of cellular transmembrane ubiquitin ligases, termed membrane-associated RING-CH (MARCH) proteins (3), that mediate the ubiquitination of the cytoplasmic portion of transmembrane proteins (reviewed in reference 40). Each member of this family targets a subset of cellular membrane proteins with both unique and shared specificities (4, 56). One of the functions of cellular MARCH proteins is to modulate antigen presentation by mediating the ubiquitin-dependent turnover of major histocompatibility complex (MHC) class II molecules in dendritic cells, B cells, and monocytes/macrophages (43, 52). In contrast, viral homologues of MARCH proteins encoded by KSHV, murine herpesvirus 68, and the leporipoxvirus myxomavirus all share the ability to mediate the destruction of MHC-I (reviewed in reference 16) but not MHC-II molecules. Thus, one of the functions of the viral proteins is to promote viral escape from immune clearance by CD8⁺ T lymphocytes (50). Furthermore, each viral MARCH homologue specifically eliminates additional host cell proteins, so each plays multiple roles in viral pathogenesis. KSHV carries two viral MARCH proteins, K3 and K5, also known as MIR1 and MIR2, which both support viral escape from T-cell, NK-cell, and NKT-cell recognition by eliminating the corresponding ligands from the surfaces of infected cells (reviewed in reference 10). In endothelial cells (ECs), K5 additionally downregulates EC-specific adhesion molecules that play an essential role in the formation of adhesive platforms and adherens junctions (31, 32). Since Kaposi''s sarcoma is a tumor of EC origin, K5 might thus also contribute to tumorigenesis by disrupting normal EC barrier function and by modulating the interaction of ECs with inflammatory leukocytes.The downregulation of BST2 by K5 further suggests that K5 also counteracts innate antiviral responses, which might benefit KSHV. However, most transmembrane proteins targeted by viral or cellular MARCH proteins are type I transmembrane proteins that belong to the immunoglobulin superfamily. In contrast, BST2 is a type II transmembrane protein that is also glycosylphosphatidylinositol (GPI) anchored (25). Thus, BST2 has a short cytoplasmic amino terminus followed by an outside-in transmembrane domain, a large glycosylated extracellular portion, and a GPI anchor. The additional propensity of BST2 to form homodimers (44) was speculated to be crucial for the tethering function of BST2 in that self-association of BST2 molecules in the viral envelope with plasma membrane BST2 could prevent viral exit (19). The unusual topology of BST2 and its multimerization raised the question of whether BST2 is a bona fide target of K5 or whether its downregulation is a downstream effect of K5 eliminating other transmembrane proteins. Additionally, it is not clear whether BST2 would be downregulated in the context of a normal viral infection and, particularly, whether virally expressed K5 would be able to overcome the high expression levels of BST2 observed upon IFN induction. We now demonstrate that KSHV efficiently downregulates IFN-induced BST2 both during primary infection and upon reactivation from latency in ECs. IFN-induced BST2 is ubiquitinated by K5 upon exiting the endoplasmic reticulum (ER) and is rapidly degraded by a pathway that is sensitive to proteasome inhibitors but resistant to inhibitors of lysosomal acidification. These data suggest that despite its unusual topology, BST2 is directly targeted by K5. We further demonstrate that BST2 reduces KSHV release upon inhibition of K5 expression by small interfering RNA (siRNA), suggesting that BST2 is part of the IFN-induced innate immune response to KSHV. Thus, in addition to contributing to viral evasion of cellular immune responses and remodeling EC function, K5 also counteracts the innate immune defense of the host cell.     

Bending of the BST‐2 coiled‐coil during viral budding

BST‐2/tetherin is a human extracellular transmembrane protein that serves as a host defense factor against HIV‐1 and other viruses by inhibiting viral spreading. Structurally, BST‐2 is a homo‐dimeric coiled‐coil that is connected to the host cell membrane by N and C terminal transmembrane anchors. The C‐terminal membrane anchor of BST‐2 is inserted into the budding virus while the N‐terminal membrane anchor remains in the host cell membrane creating a viral tether. The structural mechanism of viral budding and tethering as mediated by BST‐2 is not clear. To more fully describe the mechanism of viral tethering, we created a model of BST‐2 embedded in a membrane and used steered molecular dynamics to simulate the transition from the host cell membrane associated form to the cell‐virus membrane bridging form. We observed that BST‐2 did not transition as a rigid structure, but instead bent at positions with a reduced interface between the helices of the coiled‐coil. The simulations for the human BST‐2 were then compared with simulations on the mouse homolog, which has no apparent weak spots. We observed that the mouse homolog spread the bending across the ectodomain, rather than breaking at discrete points as observed with the human homolog. These simulations support previous biochemical and cellular work suggesting some flexibility in the coiled‐coil is necessary for viral tethering, while also highlighting how subtle changes in protein sequence can influence the dynamics and stability of proteins with overall similar structure.     

Infection of differentiated porcine airway epithelial cells by influenza virus: differential susceptibility to infection by porcine and avian viruses

Background

Swine are important hosts for influenza A viruses playing a crucial role in the epidemiology and interspecies transmission of these viruses. Respiratory epithelial cells are the primary target cells for influenza viruses.

Methodology/Principal Findings

To analyze the infection of porcine airway epithelial cells by influenza viruses, we established precision-cut lung slices as a culture system for differentiated respiratory epithelial cells. Both ciliated and mucus-producing cells were found to be susceptible to infection by swine influenza A virus (H3N2 subtype) with high titers of infectious virus released into the supernatant already one day after infection. By comparison, growth of two avian influenza viruses (subtypes H9N2 and H7N7) was delayed by about 24 h. The two avian viruses differed both in the spectrum of susceptible cells and in the efficiency of replication. As the H9N2 virus grew to titers that were only tenfold lower than that of a porcine H3N2 virus this avian virus is an interesting candidate for interspecies transmission. Lectin staining indicated the presence of both α-2,3- and α-2,6-linked sialic acids on airway epithelial cells. However, their distribution did not correlate with pattern of virus infection indicating that staining by plant lectins is not a reliable indicator for the presence of cellular receptors for influenza viruses.

Conclusions/Significance

Differentiated respiratory epithelial cells significantly differ in their susceptibility to infection by avian influenza viruses. We expect that the newly described precision-cut lung slices from the swine lung are an interesting culture system to analyze the infection of differentiated respiratory epithelial cells by different pathogens (viral, bacterial and parasitic ones) of swine.     

Investigation of HIV‐1 Assembly and Release Using Modern Fluorescence Imaging Techniques

The replication of HIV‐1, like that of all viruses, is intimately connected with cellular structures and pathways. For many years, bulk biochemical and cell biological methods were the main approaches employed to investigate interactions between HIV‐1 and its host cell. However, during the past decade advancements in fluorescence imaging technologies opened new possibilities for the direct visualization of individual steps occurring throughout the viral replication cycle. Electron microscopy (EM) methods, which have traditionally been employed for the study of viruses, are complemented by fluorescence microscopy (FM) techniques that allow us to follow the dynamics of virus–cell interaction. Subdiffraction fluorescence microscopy, as well as correlative EM/FM approaches, are narrowing the fundamental gap between the high structural resolution provided by EM and the high temporal resolution and throughput accomplished by FM. The application of modern microscopy to the study of HIV‐1–host cell interactions has provided insights into the biology of the virus which could not easily, or not at all, have been gained by other methods. Here, we review how modern fluorescence imaging techniques enhanced our knowledge of the dynamic and structural changes involved in HIV‐1 particle formation.      

Herpesviruses and Chromosomal Integration

Herpesviruses are members of a diverse family of viruses that colonize all vertebrates from fish to mammals. Although more than one hundred herpesviruses exist, all are nearly identical architecturally, with a genome consisting of a linear double-stranded DNA molecule (100 to 225 kbp) protected by an icosahedral capsid made up of 162 hollow-centered capsomeres, a tegument surrounding the nucleocapsid, and a viral envelope derived from host membranes. Upon infection, the linear viral DNA is delivered to the nucleus, where it circularizes to form the viral episome. Depending on several factors, the viral cycle can proceed either to a productive infection or to a state of latency. In either case, the viral genetic information is maintained as extrachromosomal circular DNA. Interestingly, however, certain oncogenic herpesviruses such as Marek''s disease virus and Epstein-Barr virus can be found integrated at low frequencies in the host''s chromosomes. These findings have mostly been viewed as anecdotal and considered exceptions rather than properties of herpesviruses. In recent years, the consistent and rather frequent detection (in approximately 1% of the human population) of human herpesvirus 6 (HHV-6) viral DNA integrated into human chromosomes has spurred renewed interest in our understanding of how these viruses infect, replicate, and propagate themselves. In this review, we provide a historical perspective on chromosomal integration by herpesviruses and present the current state of knowledge on integration by HHV-6 with the possible clinical implications associated with viral integration.Integration of viral genomes into the host''s chromosomes is mandatory for the successful completion of the life cycles of several viruses, including retroviruses and adeno-associated viruses (AAV). In contrast, herpesviruses maintain their genomes as extrachromosomal circular episomes in the nuclei of infected cells without the need for integration. However, there have been several reports of chromosomally integrated herpesvirus (CIHHV) DNA over the years, suggesting that herpesviruses can indeed integrate into the host''s chromosomes under certain conditions. In addition, for a virus such as human herpesvirus 6 (HHV-6), found integrated into the germ lines of approximately 1% of the world''s population, integration may represent more than a sporadic or anecdotal event.Considering that replication of nonintegrated herpesvirus DNA occurs through the well-accepted rolling-circle mechanism, yielding long DNA concatemers that are subsequently cleaved into single-genome equivalents during nucleic acid encapsidation, how replication of linear CIHHV DNA can occur (if it does) remains unknown. In this document, we review cases and reports of integrated nonhuman and human herpesviruses and discuss the outcomes of such events on the life cycles of the viruses and the potential medical consequences of integration.Chromosomal insertions of alphaherpesvirus DNA segments, including those from herpes simplex viruses and equine herpesvirus types 1 and 3, have been reported on numerous occasions in the past (10, 11, 71, 77, 81, 87, 106). In most instances, these events were detected following infection with defective interfering particles or UV-irradiated viral preparations or transfection of sheared or subgenomic viral DNA fragments. The integrated viral genome therefore consists mostly of subgenomic fragments, and there is no possibility for the production of infectious viral particles to occur. Many of the cells carrying integrated viral DNA displayed a transformed phenotype, fueling hypotheses on the oncogenic nature of these viruses. Although the integration of foreign (viral) DNA into chromosomes can cause several anomalies, the intent of this review is to focus on viruses for which integration of full-length viral DNA is documented and to raise, at least theoretically, the possibility that viral replication can occur following integration. Viruses that meet these criteria include Marek''s disease virus (MDV), Epstein-Barr virus (EBV), and HHV-6.     

Viruses and asthma

Background

Viral respiratory infection has long been known to influence the occurrence of asthma exacerbations. Over the last 20 years much effort has been put into clarifying the role that viral respiratory infections play in the eventual development of asthma.

Scope of review

In this review we give a general background of the role of viruses in the processes of asthma exacerbation and asthma induction. We review recent additions to the literature in the last 3 years with particular focus on clinical and epidemiologic investigations of influenza, rhinovirus, bocavirus, respiratory syncytial virus, and metapneumovirus.

Major conclusions

The development of asthma emerges from a complex interaction of genetic predisposition and environmental factors with viral infection likely playing a significant role in the effect of environment on asthma inception. This article is part of a Special Issue entitled: Biochemistry of Asthma.

General significance

Further understanding of the role that viruses play in asthma exacerbation and inception will contribute to decreased asthma morbidity in the future. This article is part of a Special Issue entitled: Biochemistry of Asthma.     

Henipaviruses: Gaps in the Knowledge of Emergence

Over the past 10 years many new viruses have been identified in Australia and the Asian region. The viruses have been isolated from, and/or identified in, a range of animals; some of these viruses are of veterinary and medical importance while others are new threats to biodiversity. Of these viruses, Hendra and Nipah viruses have emerged as significant zoonotic agents belonging to the family Paramyxoviridae and genus Henipavirus. These agents cause fatalities in a range of animals including horses, pigs, and humans. Both viruses have been isolated from flying foxes (genus Pteropus; suborder Megachiroptera), which are accepted as their natural hosts. Although some research has been undertaken on the viruses and their hosts, little is known about how these viruses emerge. We have attempted to investigate the current knowledge of the bat-Henipavirus ecology by discussing the range of bat viruses that exist (viral assemblage), the significance of evolving viruses, possible functional role(s) of viruses, the ecology of viruses and their hosts, and identifying possible drivers (selection pressures) that may culminate with the overlap of new potential viral hosts thereby facilitating the replication of fit viral populations in a new host–virus continuum(s). By undertaking such an analysis, we have attempted to identify key questions, which should be investigated if the factors involved in driving Henipavirus emergence are to be understood.     

Impact of defective interfering particles on virus replication and antiviral host response in cell culture-based influenza vaccine production

During the replication of influenza viruses, defective interfering particles (DIPs) can be generated. These are noninfectious deletion mutants that require coinfection with a wild-type virus but interfere with its helper virus replication. Consequently, coinfected cells mainly produce DIPs. Little is known about how such noninfectious virus particles affect the virus yield of cell culture-based influenza vaccine production. We compared infections of Madin-Darby canine kidney cells with two seed virus preparations of the influenza virus strain A/Puerto Rico/8/34 that contain different amounts of DIPs. A combination of conventional RT-PCR, RT-qPCR, and flow cytometry revealed that DI genomes indeed strongly accumulate in coinfected cells and impede the viral RNA synthesis. Additionally, cells infected at the higher DIP concentration showed a stronger antiviral response characterized by increased interferon-β expression and apoptosis induction. Furthermore, in the presence of DIPs, a significant fraction of cells did not show any productive accumulation of viral proteins at all. Together, these effects of DIPs significantly reduce the virus yield. Therefore, the accumulation of DIPs should be avoided during influenza vaccine production which can be achieved by quality controls of working seed viruses based on conventional RT-PCR. The strategy for the depletion of DIPs presented here can help to make cell culture-based vaccine production more reliable and robust.     

Selection of H5N1 Influenza Virus PB2 during Replication in Humans

Highly pathogenic H5N1 influenza viruses continue to cause concern, even though currently circulating strains are not efficiently transmitted among humans. For efficient transmission, amino acid changes in viral proteins may be required. Here, we examined the amino acids at positions 627 and 701 of the PB2 protein. A direct analysis of the viral RNAs of H5N1 viruses in patients revealed that these amino acids contribute to efficient virus propagation in the human upper respiratory tract. Viruses grown in culture or eggs did not always reflect those in patients. These results emphasize the importance of the direct analysis of original specimens.Given the continued circulation of highly pathogenic H5N1 avian influenza viruses and their sporadic transmission to humans, the threat of a pandemic persists. However, for H5N1 influenza viruses to be efficiently transmitted among humans, amino acid substitutions in the avian viral proteins may be necessary.Two positions in the PB2 protein affect the growth of influenza viruses in mammalian cells (3, 11, 18): the amino acid at position 627 (PB2-627), which in most human influenza viruses is lysine (PB2-627Lys) and most avian viruses is glutamic acid (PB2-627Glu), and the amino acid at position 701. PB2-627Lys is associated with the efficient replication (16) and high virulence (5) of H5N1 viruses in mice. Moreover, an H7N7 avian virus isolated from a fatal human case of pneumonia possessed PB2-627Lys, whereas isolates from a nonfatal human case of conjunctivitis and from chickens during the same outbreak possessed PB2-627Glu (2).The amino acid at position 701 in PB2 is important for the high pathogenicity of H5N1 viruses in mice (11). Most avian influenza viruses possess aspartic acid at this position (PB2-701Asp); however, A/duck/Guangxi/35/2001 (H5N1), which is highly virulent in mice (11), possesses asparagine at this position (PB2-701Asn). PB2-701Asn is also found in equine (4) and swine (15) viruses, as well as some H5N1 human isolates (7, 9). Thus, both amino acids appear to be markers for the adaptation of H5N1 viruses in humans (1, 3, 17).Massin et al. (13) reported that the amino acid at PB2-627 affects viral RNA replication in cultured cells at low temperatures. Recently, we demonstrated that viruses, including those of the H5N1 subtype, with PB2-627Lys (human type) grow better at low temperatures in cultured cells than those with PB2-627Glu (avian type) (6). This association between the PB2 amino acid and temperature-dependent growth correlates with the body temperatures of hosts; the human upper respiratory tract is at a lower temperature (around 33°C) than the lower respiratory tract (around 37°C) and the avian intestine, where avian influenza viruses usually replicate (around 41°C). The ability to replicate at low temperatures may be crucial for viral spread among humans via sneezing and coughing by being able to grow in the upper respiratory organs. Therefore, the Glu-to-Lys mutation in PB2-627 is an important step for H5N1 viruses to develop pandemic potential.However, there is no direct evidence that the substitutions of PB2-627Glu with PB2-627Lys and PB2-701Asp with PB2-701Asn occur during the replication of H5N1 avian influenza viruses in human respiratory organs. Therefore, here, we directly analyzed the nucleotide sequences of viral genes from several original specimens collected from patients infected with H5N1 viruses.