Hendra Virus Infection Dynamics in the Grey-Headed Flying Fox (Pteropus poliocephalus) at the Southern-Most Extent of Its Range: Further Evidence This Species Does Not Readily Transmit the Virus to Horses.

Hendra virus (HeV) is an important emergent virus in Australia known to infect horses and humans in certain regions of the east coast. Whilst pteropid bats ("flying foxes") are considered the natural reservoir of HeV, which of the four mainland species is the principal reservoir has been a source of ongoing debate, particularly as shared roosting is common. To help resolve this, we sampled a colony consisting of just one of these species, the grey-headed flying fox, (Pteropus poliocephalus), at the southernmost extent of its range. Using the pooled urine sampling technique at approximately weekly intervals over a two year period, we determined the prevalence of HeV and related paramyxoviruses using a novel multiplex (Luminex) platform. Whilst all the pooled urine samples were negative for HeV nucleic acid, we successfully identified four other paramyxoviruses, including Cedar virus; a henipavirus closely related to HeV. Collection of serum from individually caught bats from the colony showed that antibodies to HeV, as estimated by a serological Luminex assay, were present in between 14.6% and 44.5% of animals. The wide range of the estimate reflects uncertainties in interpreting intermediate results. Interpreting the study in the context of HeV studies from states to the north, we add support for an arising consensus that it is the black flying fox and not the grey-headed flying fox that is the principal source of HeV in spillover events to horses.

Henipavirus microsphere immuno-assays for detection of antibodies against Hendra virus.

Hendra and Nipah viruses (HeV and NiV) are closely related zoonotic pathogens of the Paramyxoviridae family. Both viruses belong to the Henipavirus genus and cause fatal disease in animals and humans, though only HeV is endemic in Australia. In general and due to the acute nature of the disease, agent detection by PCR and virus isolation are the primary tools for diagnostic investigations. Assays for the detection of antibodies against HeV are fit more readily for the purpose of surveillance testing in disease epidemiology and to meet certification requirements in the international movement of horses. The first generation indirect ELISA has been affected by non-specific reactions which must be resolved using virus neutralisation serology conducted at laboratory bio-safety level 4 containment (PC4). Recent developments have enabled improvements in the available serology assays. The production of an expressed recombinant truncated HeV G protein has been utilised in ELISA and in Luminex-based multiplexed microsphere assays. In the latter format, two Luminex assays have been developed for use in henipavirus serology: a binding assay (designed for antibody detection and differentiation) and a blocking assay (designed as a surrogate for virus neutralisation). Equine and canine field sera were used to evaluate the two Luminex assays relative to ELISA and virus neutralisation serology. Results showed that Luminex assays can be effective as rapid, sensitive and specific tests for the detection of HeV antibody in horse and dog sera. The tests do not require PC4 containment and are appropriate for high throughput applications as might be required for disease investigations and other epidemiological surveillance. Also, the results show that the Luminex assays detect effectively HeV vaccine-induced antibodies.

Emerging zoonotic viral diseases.

Zoonotic diseases are infectious diseases that are naturally transmitted from vertebrate animals to humans and vice versa. They are caused by all types of pathogenic agents, including bacteria, parasites, fungi, viruses and prions. Although they have been recognised for many centuries, their impact on public health has increased in the last few decades due to a combination of the success in reducing the spread of human infectious diseases through vaccination and effective therapies and the emergence of novel zoonotic diseases. It is being increasingly recognised that a One Health approach at the human-animal-ecosystem interface is needed for effective investigation, prevention and control of any emerging zoonotic disease. Here, the authors will review the drivers for emergence, highlight some of the high-impact emerging zoonotic diseases of the last two decades and provide examples of novel One Health approaches for disease investigation, prevention and control. Although this review focuses on emerging zoonotic viral diseases, the authors consider that the discussions presented in this paper will be equally applicable to emerging zoonotic diseases of other pathogen types.

Complete genome sequence of Nariva virus, a rodent paramyxovirus.

Nariva virus (NarPV) was isolated from forest rodents (Zygodontomys b. brevicauda) in eastern Trinidad in the early 1960s. Initial classification within the family Paramyxoviridae was based mainly on morphological observations including the structure of nucleocapsids and virion surface projections. Here, we report the characterization of the complete genome sequence of NarPV. The genome is 15,276 nucleotides in length, conforming to the rule-of-six, and has a genome organization typical of most members of the family, with six transcriptional units in the order 3'-N-P-M-F-H-L-5'. The gene junctions contain highly conserved gene start and stop signals and a tri-nucleotide intergenic sequence present in most members of the subfamily Paramyxovirinae. Sequence comparison studies indicate that NarPV is most closely related to Mossman virus, which was isolated from wild rats (Rattus leucopus) in Queensland, Australia, in 1970. This study confirmed the classification of NarPV as a member of the subfamily Paramyxovirinae and established the close genome organization and sequence relationship between the two rodent paramyxoviruses isolated almost a decade apart and from two locations separated by more than 15,000 km.

Full-length genome sequence and genetic relationship of two paramyxoviruses isolated from bat and pigs in the Americas.

Mapuera virus (MPRV) was isolated from a fruit bat in Brazil in 1979, but its host range and disease-causing potential are unknown. Porcine rubulavirus (PoRV) was identified as the aetiological agent of disease outbreaks in pigs in Mexico during early 1980s, but the origin of PoRV remains elusive. In this study, the completed genome sequence of MPRV was determined, and the complete genome sequence of PoRV was assembled from previously published protein-coding genes and the non-coding genome regions determined from this study. Comparison of sequence and genome organization indicated that PoRV is more closely related to MPRV than to any other members of the genus Rubulavirus. In the P gene coding region of both viruses, there is an ORF located at the 5' end of the P gene overlapping with the P protein coding region, similar to the C protein ORF present in most viruses of the subfamily Paramyxovirinae, but absent in other known rubulaviruses. Based on these findings, we hypothesise that PoRV may also originate from bats, and spillover events from bats to pigs, either directly or via an intermediate host, were responsible for the sporadic disease outbreaks observed in Mexico.

Pulau virus; a new member of the Nelson Bay orthoreovirus species isolated from fruit bats in Malaysia.

After the outbreak of Nipah virus (NiV) in 1998-99, which resulted in 105 human deaths and the culling of more than one million pigs, a search was initiated for the natural host reservoir of NiV on Tioman Island off the east coast of Malaysia. Three different syncytia-forming viruses were isolated from fruit bats on the island. They were Nipah virus, Tioman virus (a novel paramyxovirus related to Menangle virus), and a reovirus, named Pulau virus (PuV), which is the subject of this study. PuV displayed the typical ultra structural morphology of a reovirus and was neutralised by serum against Nelson Bay reovirus (NBV), a reovirus isolated from a fruit bat (Pteropus poliocephalus) in Australia over 30 years ago. PuV was fusogenic and formed large syncytia in Vero cells. Comparison of dsRNA segments between PuV and NBV showed distinct mobility differences for the S1 and S2 segments. Complete sequence analysis of all four S segments revealed a close relationship between PuV and NBV, with nucleotide sequence identity varying from 88% for S3 segment to 56% for the S1 segment. Similarly phylogenetic analysis of deduced protein sequences confirmed that PuV is closely related to NBV. In this paper we discuss the similarities and differences between PuV and NBV which support the classification of PuV as a novel mammalian, fusogenic reovirus within the Nelson Bay orthoreovirus species, in the genus Orthoreovirus, family Reoviridae.

RNA synthesis during infection by Hendra virus: an examination by quantitative real-time PCR of RNA accumulation, the effect of ribavirin and the attenuation of transcription.

Hendra virus is one of two virus species within the newly-formed genus Henipavirus, subfamily Paramxyovirinae. It is a designated select agent with potential biosecurity threat to both human and animal health. Quantitative real-time PCR was used to measure viral RNA synthesis in Vero cells infected by Hendra virus, and to examine the inhibitory effect of ribavirin. It was also used to determine the points of attenuation during transcription of the six viral genes N, P, M, F, G and L by targeting amplicons located towards the 3' end of each gene. Major increases in viral RNA and virus yield occurred between 4 to 8 h and 8 to 10 h post infection, respectively. The effect of ribavirin was examined at a range of concentrations up to 400 microm. At 50 microm, RNA synthesis was reduced 9 fold, and virus yield 58 fold. As expected for a member of the order Mononegavirales, a gradient of transcription was observed in Hendra virus-infected cells. There was significant attenuation at the M-F and G-L junctions, more closely resembling Sendai virus (genus Respirovirus) than measles virus (genus Morbillivirus).

Tioman virus, a novel paramyxovirus isolated from fruit bats in Malaysia.

A search for the natural host of Nipah virus has led to the isolation of a previously unknown member of the family Paramyxoviridae. Tioman virus (TiV) was isolated from the urine of fruit bats (Pteropus hypomelanus) found on the island of the same name off the eastern coast of peninsular Malaysia. An electron microscopic study of TiV-infected cells revealed spherical and pleomorphic-enveloped viral particles (100--500 nm in size) with a single fringe of embedded peplomers. Virus morphogenesis occurred at the plasma membrane of infected cells and morphological features of negative-stained ribonucleoprotein complexes were compatible with that of viruses in the family Paramyxoviridae. Serological studies revealed no cross-reactivity with antibodies against a number of known Paramyxoviridae members except for the newly described Menangle virus (MenV), isolated in Australia in 1997. Failure of PCR amplification using MenV-specific primers suggested that this new virus is related to but different from MenV. For molecular characterization of the virus, a cDNA subtraction strategy was employed to isolate virus-specific cDNA from virus-infected cells. Complete gene sequences for the nucleocapsid protein (N) and phosphoprotein (P/V) have been determined and recombinant N and V proteins produced in baculovirus. The recombinant N and V proteins reacted with porcine anti-MenV sera in Western blot, confirming the serological cross-reactivity observed during initial virus characterization. The lack of a C protein-coding region in the P/V gene, the creation of P mRNA by insertion of 2-G residues, and the results of phylogenetic analyses all indicated that TiV is a novel member of the genus Rubulavirus.

The cleavage activation and sites of glycosylation in the fusion protein of Hendra virus.

Hendra virus (HeV) is an unclassified member of the Paramyxoviridae family that causes systemic infections in humans, horses, cats, guinea pigs and flying foxes. The fusion protein (F(0)) of members of the Paramyxoviridae family that cause systemic infections in vivo contains a basic amino acid-rich region at which the protein is activated by cleavage into two subunits (F(1) and F(2)). HeV F(0) lacks such a domain. We have determined the cleavage site in HeV F(0) by sequencing the amino terminus of the F(1) subunit and in view of the potential effect of glycosylation on the cleavage process have ascertained the sites at which F(0) is glycosylated. The results indicate that unlike other members of the family that replicate in cultured cells and cause systemic infections in vivo, cleavage of HeV F(0) occurs at a single lysine (reside 109) in the sequence Asp-Val-Lys- downward arrow-Leu. Although HeV genotypically resembles members of the Respirovirus and Rubulavirus genera in having potential N-linked glycosylation sites in both the F(1) and F(2) subunits, we show that phenotypically HeV may more closely resemble members of the Morbillivirus genus that contain N-linked glycans only in the F(2) subunit.

A novel P/V/C gene in a new member of the Paramyxoviridae family, which causes lethal infection in humans, horses, and other animals.

In 1994, a new member of the family Paramyxoviridae isolated from fatal cases of respiratory disease in horses and humans was shown to be distantly related to morbilliviruses and provisionally called equine morbillivirus (K. Murray et al., Science 268:94-97, 1995). To facilitate characterization and classification, the virus was purified, viral proteins were identified, and the P/V/C gene was cloned and sequenced. The coding strategy of the gene is similar to that of Sendai and measles viruses, members of the Paramyxovirus and Morbillivirus genera, respectively, in the subfamily Paramyxovirinae. The P/V/C gene contains four open reading frames, three of which, P, C, and V, have Paramyxovirinae counterparts. The P and C proteins are larger and smaller, respectively, than are cognate proteins in members of the subfamily, and the V protein is made as a result of a single G insertion during transcription. The P/V/C gene has two unique features. (i) A fourth open reading frame is located between those of the C and V proteins and potentially encodes a small basic protein similar to those found in some members of the Rhabdoviridae and Filoviridae families. (ii) There is also a long untranslated 3' sequence, a feature common in Filoviridae members. Sequence comparisons confirm that although the virus is a member of the Paramyxovirinae subfamily, it displays only low levels of homology with paramyxoviruses and morbilliviruses and negligible homologies with rubulaviruses.

Differentiation of cognate dsRNA genome segments of bluetongue virus reassortants by temperature gradient gel electrophoresis.

The analysis of reassortant viruses has been a valuable tool in the investigation of protein interaction and function in double-stranded (ds) RNA virus research. The differentiation of cognate dsRNA genome segments of reassortants is conventionally achieved by SDS-polyacrylamide gel electrophoresis (SDS-PAGE). However, due to a high degree of sequence homology among different bluetongue virus (BTV) serotypes, it is not uncommon to find that certain cognate dsRNA segments cannot be differentiated by SDS-PAGE. Temperature gradient gel electrophoresis (TGGE) has been shown to be a much more sensitive method of differentiating RNA or DNA fragments of high sequence homology. Here we report the preliminary application of TGGE in analysis of genomic reassortants of two BTV serotypes, 1 and 23. While six out of ten genome segments between BTV-1 and BTV-23 could not be resolved by SDS-PAGE, all of them were differentiated by TGGE. The ability of TGGE to distinguish between dsRNA segments of high sequence homology may also make it useful in the search for BTV genes responsible for defined characteristics, such as virulence, by differentiating wild-type and mutated gene segments of viruses displaying altered phenotypes.

Major core protein VP7 of Australian bluetongue virus serotype 15: sequence and antigenicity divergence from other BTV serotypes.

Full-length cDNA of the RNA genome segment coding for the major core protein VP7 of Australian bluetongue virus serotype 15 (BTV-15) has been isolated by reverse transcription-PCR cloning. Comparative analysis indicated that the BTV-15 VP7 sequence had diverged significantly from that of other members of the BTV serogroup. At the amino acid level, BTV-15 VP7 exhibited sequence identities of 80 to 84% with VP7 molecules of other serotypes, significantly lower than the sequence identities of between 93 and 100% observed among other serotypes characterized to date. This was consistent with previous observations that there were significant immunological differences between BTV-15 and other BTV serotypes and that monoclonal antibodies raised against BTV-1 VP7 failed to react with BTV-15 VP7. Recombinant BTV-15 VP7 protein produced from Escherichia coli was largely insoluble, but maintained its immunogenicity. Polyclonal mouse sera raised against the recombinant VP7 protein reacted strongly with VP7 of BTV-15, but weakly with that of BTV-1.

The site of bluetongue virus attachment to glycophorins from a number of animal erythrocytes.

Bluetongue virus (BTV) was shown to agglutinate human, ovine and porcine erythrocytes. Removal of neuraminic acid (NA) from erythrocytes by Vibrio cholerae neuraminidase prevented their agglutination. Haemagglutination was also inhibited by N-acetyl neuraminic acid (NANA), N-glycol neuraminic acid (NGNA) and N-acetyl neuramin-lactose. The ability of BTV to agglutinate trypsin-treated human erythrocytes, which lack the amino-terminal domain and the single N-linked oligosaccharide of glycophorin A, suggests that the virus bound to human erythrocytes via NANA-containing, O-linked oligosaccharides. Glycoproteins with NA-containing oligosaccharides of known structure such as mucin, fetuin, alpha 1-acid glycoprotein, ovomucoid and ovine, porcine, human and equine glycophorin were examined for their ability to inhibit BTV-mediated agglutination of human, ovine and porcine erythrocytes. All glycoproteins containing NANA- or NGNA alpha 2-6GalNAc were capable of inhibiting the agglutination of human and porcine erythrocytes. Treatment of human erythrocytes with Newcastle disease virus neuraminidase and of porcine erythrocytes with Clostridium perfringens neuraminidase to cleave preferentially the NANA- and NGNA alpha 2-3Gal linkages respectively, were shown to have little effect on the ability of the erythrocytes to be agglutinated by BTV. The results suggested that BTV binds to NANA- and NGNA alpha 2-6GalNAc residues in the O-linked oligosaccharides of human and porcine glycophorins respectively and indicated the presence of different binding sites on the virus for erythrocytes from other species.