Brian J. Shiell

The Exceptionally Large Genome of Hendra Virus: Support for Creation of a New Genus within the Family Paramyxoviridae

ABSTRACT An outbreak of acute respiratory disease in Hendra, a suburb of Brisbane, Australia, in September 1994 resulted in the deaths of 14 racing horses and a horse trainer. The causative agent was a new member of the family Paramyxoviridae. The virus was originally called Equine morbillivirus but was renamed Hendra virus (HeV) when molecular characterization highlighted differences between it and members of the genusMorbillivirus. Less than 5 years later, the closely relatedNipah virus (NiV) emerged in Malaysia, spread rapidly through the pig population, and caused the deaths of over 100 people. We report the characterization of the HeV L gene and protein, the genome termini, and gene boundary sequences, thus completing the HeV genome sequence. In the highly conserved region of the L protein, the HeV sequence GDNE differs from the GDNQ found in almost all other nonsegmented negative-strand (NNS) RNA viruses. HeV has an absolutely conserved intergenic trinucleotide sequence, 3′-GAA-5′, and highly conserved transcription initiation and termination sequences similar to those of respiroviruses and morbilliviruses. The large genome size (18,234 nucleotides), the unique complementary genome terminal sequences of HeV, and the limited homology with other members of theParamyxoviridae suggest that HeV, together with NiV, should be classified in a new genus in this family. The large genome of HeV also fills a gap in the spectrum of genome sizes observed with NNS RNA virus genomes. As such, it provides a further piece in the puzzle of NNS RNA virus evolution.

Chloroquine Administration Does Not Prevent Nipah Virus Infection and Disease in Ferrets

ABSTRACT Hendra virus and Nipah virus, two zoonotic paramyxoviruses in the genus Henipavirus, have recently emerged and continue to cause sporadic disease outbreaks in humans and animals. Mortality rates of up to 75% have been reported in humans, but there are presently no clinically licensed therapeutics for treating henipavirus-induced disease. A recent report indicated that chloroquine, used in malaria therapy for over 70 years, prevented infection with Nipah virus in vitro. Chloroquine was assessed using a ferret model of lethal Nipah virus infection and found to be ineffective against Nipah virus infection in vivo.

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.

Sites of phosphorylation of P and V proteins from Hendra and Nipah viruses: newly emerged members of Paramyxoviridae

Hendra (HeV) and Nipah (NiV) viruses are newly emerged, zoonotic viruses and their genomes have nucleotide and predicted amino acid homologies placing them in the subfamily Paramyxoviridae. The polymerase-associated phosphoproteins (P proteins) of paramyxoviruses have been shown, by direct and indirect methods, to be highly phosphorylated. In this study, a comprehensive comparison of in vivo phosphorylation of HeV and NiV P proteins, derived from virus particles, was achieved by a direct approach using electrospray ionization ion trap mass spectrometry (ESI-IT-MS). Phosphorylation sites for the P proteins were determined at Ser-224 and Thr-239 in HeV and at Ser-240 and Ser-472 in NiV. These phosphorylation patterns do not appear to be consistent with those reported for other paramyxoviruses. Protein V, a product of a frame shift in the P protein gene, was identified by specific antibodies in HeV preparations but not in NiV. HeV V protein was found to contain phosphoserine but not phosphothreonine. In addition, P proteins from both viruses were found to be modified by N-terminal acetylation.

Determination of the intramolecular disulfide bond arrangement and biochemical identification of the glycosylation sites of the nonstructural protein NS1 of Murray Valley encephalitis virus

The 12 cysteine residues in the flavivirus NS1 protein are strictly conserved, suggesting that they form disulfide bonds that are critical for folding the protein into a functional structure. In this study, we examined the intramolecular disulfide bond arrangement of NS1 of Murray Valley encephalitis virus and elucidated three of the six cysteine-pairing arrangements. Disulfide linkages were identified by separating tryptic-digested NS1 by reverse-phase high pressure liquid chromatography and analysing the resulting peptide peaks by protein sequencing, amino acid analysis and/or electrospray mass spectrometry. The pairing arrangements between the six amino-terminal cysteines were identified as follows: Cys(4)-Cys(15), Cys(55)-Cys(143) and Cys(179)-Cys(223). Although the pairing arrangements between the six carboxy-terminal cysteines were not determined, we were able to eliminate several cysteine-pairing combinations. Furthermore, we demonstrated that all three putative N-linked glycosylation sites of NS1 are utilized and that the Asn(207) glycosylation site contains a mannose-rich glycan.

RECOMBINANT CHICKEN IFN-GAMMA EXPRESSED IN ESCHERICHIA COLI. ANALYSIS OF C-TERMINAL TRUNCATION AND EFFECT ON BIOLOGIC ACTIVITY

Interferon-gamma (IFN-gamma) possesses potent immunostimulatory properties, and it has recently been shown to have potential therapeutic properties. Recombinant protein technology is frequently used for commercial production of therapeutics, such as IFN. Biologically active recombinant chicken IFN-gamma (rChIFN-gamma) constructs bearing an N-terminal poly-His tag were expressed in Escherichia coli. Preparations of rChIFN-gamma contained varying ratios of a full-length and a truncated protein species (18 and 16 kDa, respectively). Amino acid sequence analysis of the full-length protein corroborated the sequence previously predicted from the cDNA sequence. Full-length rChIFN-gamma contains two cysteine residues at the C-terminus, and these were labeled by reduction and subsequent specific alkylation with fluorescent tag (5-I-AEDANS) to distinguish between full-length and C-terminally truncated forms of rChIFN-gamma. Comparative peptide mapping, amino acid sequencing, and mass spectrometry revealed that the 16 kDa protein was truncated at Lys133. It was also observed that the 18 kDa rChIFN-gamma protein was infrequently contaminated with small quantities of protein truncated at Arg141. A truncated recombinant construct (His1-Lys133) was also expressed in E. coli and had biologic activity comparable with that of the full-length construct. The 3-D structure of rChIFN-gamma was deduced by comparative modeling with bovine and human IFN-gamma crystallographic structures. Analysis of sequences and comparison of structures have revealed that the 3-D structure of rChIFN-gamma is similar to those of bovine and human molecules despite an overall amino acid identity of only 32%.

Strategies for analysis of electrophoretically separated proteins and peptides

Abstract Electrophoresis methodology is unsurpassed in separating individual proteins and peptides from a mixture and is regarded by the majority of protein biochemists as the methodology of choice. Proteins can be eluted into solution or electroblotted onto a membrane and subjected to direct sequencing, amino acid composition and post-translational modification analyses. Applications of highly reproducible 2D electrophoresis, “in-gel” and “on-blot” fragmentation procedures, high sensitivity N-terminal sequencing and a variety of mass spectrometric methods (post-source decay MALDI–MS, LC–ESI MS/MS and CE–MS) provide invaluable tools for characterisation of recombinant proteins and identification and characterisation of unknown proteins. In this article we overview strategies employed in recent years for analysis of proteins and peptides separated by various electrophoretic techniques. Methodological approach used in characterisation of proteins from a newly emerged virus is presented as an example of an effective strategy.

Site occupancy and glycan compositional analysis of two soluble recombinant forms of the attachment glycoprotein of Hendra virus

Hendra virus (HeV) continues to cause morbidity and mortality in both humans and horses with a number of sporadic outbreaks. HeV has two structural membrane glycoproteins that mediate the infection of host cells: the attachment (G) and the fusion (F) glycoproteins that are essential for receptor binding and virion-host cell membrane fusion, respectively. N-linked glycosylation of viral envelope proteins are critical post-translation modifications that have been implicated in roles of structural integrity, virus replication and evasion of the host immune response. Deciphering the glycan composition and structure on these glycoproteins may assist in the development of glycan-targeted therapeutic intervention strategies. We examined the site occupancy and glycan composition of recombinant soluble G (sG) glycoproteins expressed in two different mammalian cell systems, transient human embryonic kidney 293 (HEK293) cells and vaccinia virus (VV)-HeLa cells, using a suite of biochemical and biophysical tools: electrophoresis, lectin binding and tandem mass spectrometry. The N-linked glycans of both VV and HEK293-derived sG glycoproteins carried predominantly mono- and disialylated complex-type N-glycans and a smaller population of high mannose-type glycans. All seven consensus sequences for N-linked glycosylation were definitively found to be occupied in the VV-derived protein, whereas only four sites were found and characterized in the HEK293-derived protein. We also report, for the first time, the existence of O-linked glycosylation sites in both proteins. The striking characteristic of both proteins was glycan heterogeneity in both N- and O-linked sites. The structural features of G protein glycosylation were also determined by X-ray crystallography and interactions with the ephrin-B2 receptor are discussed.

Comparison of the effects of acylation and amidation on the antimicrobial and antiviral properties of lactoferrin

Aims:  To compare amidation and acylation of lactoferrin (LF) from bovine milk, as a means of enhancing its antimicrobial and antiviral properties.

Detection of antibodies specific for sheeppox and goatpox viruses using recombinant capripoxvirus antigens in an indirect enzyme-linked immunosorbent assay.

Viruses in the genus Capripoxvirus, family Poxviridae, cause sheeppox, goatpox and lumpy skin disease, which are the most serious poxvirus diseases of production animals. Despite the considerable threat that these viruses pose to livestock production and global trade in sheep, goats, cattle and their products, convenient and effective serodiagnostic tools are not readily available. To develop a more effective antibody detection capability, selected open reading frames from capripoxvirus DNA were amplified and expressed in Escherichia coli as His-tagged fusion proteins. By screening 42 candidate antigens, two sheeppox virus virion core proteins that were expressed efficiently, purified readily using affinity chromatography and reactive against capripoxvirus immune sera in an indirect enzyme-linked immunosorbent assay (ELISA) were identified. The ELISA performed favourably when sera from sheep and goats infected experimentally with virulent capripoxvirus isolates were tested, with sensitivity and diagnostic specificity ranging between 95 and 97%, but it was unable to detect antibodies reliably in vaccinated sheep or goats. Furthermore, no cross-reactivity with antibodies against orf virus was detected. This assay offers the prospect of a convenient and standardised ELISA-based serodiagnostic test, with no requirement for infectious reagents, that is well suited to high-throughput capripoxvirus surveillance on a flock or herd basis.