Phenotypic Characterization of Recombinant Marek's Disease Virus in Live Birds Validates Polymorphisms Associated with Virulence.

Marek's disease (MD) is a highly infectious lymphoproliferative disease in chickens with a significant economic impact. Mardivirus gallidalpha 2, also known as Marek's disease virus (MDV), is the causative pathogen and has been categorized based on its virulence rank into four pathotypes: mild (m), virulent (v), very virulent (vv), and very virulent plus (vv+). A prior comparative genomics study suggested that several single-nucleotide polymorphisms (SNPs) and genes in the MDV genome are associated with virulence, including nonsynonymous (ns) SNPs in eight open reading frames (ORF): UL22, UL36, UL37, UL41, UL43, R-LORF8, R-LORF7, and ICP4. To validate the contribution of these nsSNPs to virulence, the vv+MDV strain 686 genome was modified by replacing nucleotides with those observed in the vMDV strains. Pathogenicity studies indicated that these substitutions reduced the MD incidence and increased the survival of challenged birds. Furthermore, using the best-fit pathotyping method to rank the virulence, the modified vv+MDV 686 viruses resulted in a pathotype similar to the vvMDV Md5 strain. Thus, these results support our hypothesis that SNPs in one or more of these ORFs are associated with virulence but, as a group, are not sufficient to result in a vMDV pathotype, suggesting that there are additional variants in the MDV genome associated with virulence, which is not surprising given this complex phenotype and our previous finding of additional variants and SNPs associated with virulence.

Viral proteogenomic and expression profiling during productive replication of a skin-tropic herpesvirus in the natural host.

Efficient transmission of herpesviruses is essential for dissemination in host populations; however, little is known about the viral genes that mediate transmission, mostly due to a lack of natural virus-host model systems. Marek's disease is a devastating herpesviral disease of chickens caused by Marek's disease virus (MDV) and an excellent natural model to study skin-tropic herpesviruses and transmission. Like varicella zoster virus that causes chicken pox in humans, the only site where infectious cell-free MD virions are efficiently produced is in epithelial skin cells, a requirement for host-to-host transmission. Here, we enriched for heavily infected feather follicle epithelial skin cells of live chickens to measure both viral transcription and protein expression using combined short- and long-read RNA sequencing and LC/MS-MS bottom-up proteomics. Enrichment produced a previously unseen breadth and depth of viral peptide sequencing. We confirmed protein translation for 84 viral genes at high confidence (1% FDR) and correlated relative protein abundance with RNA expression levels. Using a proteogenomic approach, we confirmed translation of most well-characterized spliced viral transcripts and identified a novel, abundant isoform of the 14 kDa transcript family via IsoSeq transcripts, short-read intron-spanning sequencing reads, and a high-quality junction-spanning peptide identification. We identified peptides representing alternative start codon usage in several genes and putative novel microORFs at the 5' ends of two core herpesviral genes, pUL47 and ICP4, along with strong evidence of independent transcription and translation of the capsid scaffold protein pUL26.5. Using a natural animal host model system to examine viral gene expression provides a robust, efficient, and meaningful way of validating results gathered from cell culture systems.

The alphaherpesvirus conserved pUS10 is important for natural infection and its expression is regulated by the conserved Herpesviridae protein kinase (CHPK).

Conserved Herpesviridae protein kinases (CHPK) are conserved among all members of the Herpesviridae. Herpesviruses lacking CHPK propagate in cell culture at varying degrees, depending on the virus and cell culture system. CHPK is dispensable for Marek's disease herpesvirus (MDV) replication in cell culture and experimental infection in chickens; however, CHPK-particularly its kinase activity-is essential for horizontal transmission in chickens, also known as natural infection. To address the importance of CHPK during natural infection in chickens, we used liquid chromatography-tandem mass spectrometry (LC-MS/MS) based proteomics of samples collected from live chickens. Comparing modification of viral proteins in feather follicle epithelial (FFE) cells infected with wildtype or a CHPK-null virus, we identified the US10 protein (pUS10) as a potential target for CHPK in vivo. When expression of pUS10 was evaluated in cell culture and in FFE skin cells during in vivo infection, pUS10 was severely reduced or abrogated in cells infected with CHPK mutant or CHPK-null viruses, respectively, indicating a potential role for pUS10 in transmission. To test this hypothesis, US10 was deleted from the MDV genome, and the reconstituted virus was tested for replication, horizontal transmission, and disease induction. Our results showed that removal of US10 had no effect on the ability of MDV to transmit in experimentally infected chickens, but disease induction in naturally infected chickens was significantly reduced. These results show CHPK is necessary for pUS10 expression both in cell culture and in the host, and pUS10 is important for disease induction during natural infection.

ICTV Virus Taxonomy Profile: Herpesviridae 2021.

Members of the family Herpesviridae have enveloped, spherical virions with characteristic complex structures consisting of symmetrical and non-symmetrical components. The linear, double-stranded DNA genomes of 125-241 kbp contain 70-170 genes, of which 43 have been inherited from an ancestral herpesvirus. In general, herpesviruses have coevolved with and are highly adapted to their hosts, which comprise many mammalian, avian and reptilian species. Following primary infection, they are able to establish lifelong latent infection, during which there is limited viral gene expression. Severe disease is usually observed only in the foetus, the very young, the immunocompromised or following infection of an alternative host. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the family Herpesviridae, which is available at ictv.global/report/herpesviridae.

Comparative Molecular Characterization of Three Gallid alphaherpesvirus Type 3 Strains 301B/1, HPRS24, and SB-1.

Marek's disease (MD) is a highly contagious lymphoproliferative disease of chickens caused by Gallid alphaherpesvirus type 2. Gallid alphaherpesvirus type 3 (GaHV-3) strain 301B/1 was previously shown to be an effective MD vaccine with synergistic efficacy when used as a bivalent vaccine with turkey herpesvirus. Since the nucleotide sequences of only two GaHV-3 strains have been determined, we sought to sequence the 301B/1 genome using Illumina MiSeq technology. Phylogenomic analysis indicated that 301B/1 is more closely related to other GaHV-3 strains (SB-1 and HPRS24) than to virulent or attenuated strains of GaHV-2. One hundred and twenty-six open reading frames (ORFs) have been identified within the 301B/1 genome with 108 ORFs showing a high degree of similarity to homologs found in the genomes of SB-1 and HPRS24; 14 ORFs are highly homologous (> 90% identity) with the corresponding ORFs within the SB-1 genome. The R-LORF8 and R-LORF9 genes are the most dissimilar to the collinear genes found in the SB-1 genome but are highly homologous (99%-100% identity) with those within the HPRS24 genome. Overall the 301B/1 genome is most similar to the SB-1 virus genome (99.1%) and to a lesser degree with the HPRS24 virus genome (97.7%). However, six 301B/1 ORFs (UL47, UL48, UL52, pp38, ICP4, and US10) have been identified that contain nonsynonymous substitutions relative to homologs found in the SB-1 genome. Notably, unlike the avian retrovirus long terminal repeat sequences found within the SB-1 genome, none were identified within the 301B/1 genome.

Caracterización molecular comparativa de cepas de Alfaherpesvirus del pollo tipo 3 cepas 301B/1, HPRS24 y SB-1. La enfermedad de Marek (MD) es una enfermedad linfoproliferativa altamente contagiosa de los pollos causada por el Alfaherpesvirus del pollo tipo 2. Se demostró previamente que la cepa 301B/1 del Alfaherpesvirus del pollo tipo 3 (GaHV-3) es una vacuna eficaz contra la enfermedad de Marek con eficacia sinérgica cuando se usa como una vacuna bivalente con el herpesvirus del pavo. Dado que se han determinado las secuencias de nucleótidos de solo dos cepas de GaHV-3, se buscó secuenciar el genoma de la cepa 301B/1 utilizando la tecnología Illumina MiSeq. El análisis filogenómico indicó que la cepa 301B/1 está más estrechamente relacionado con otras cepas de GaHV-3 (SB-1 y HPRS24) en comparación con cepas virulentas o atenuadas de GaHV-2. Se han identificado 126 marcos de lectura continuos (ORF) dentro del genoma de la cepa 301B/1 con 108 marcos de lectura continuos que muestran un alto grado de similitud con los secuencias homólogas encontrados en los genomas de las cepas SB-1 y HPRS24; 14 marcos de lectura continuo son altamente similares (> 90% de identidad) con los correspondientes dentro del genoma de SB-1. Los genes R-LORF8 y R-LORF9 fueron los más diferentes a los genes colineales encontrados en el genoma de SB-1, pero son altamente similares (99% -100% de identidad) con aquellos dentro del genoma HPRS24. En general, el genoma de la cepa 301B/1 es más similar al genoma del virus SB-1 (99.1%) y en menor grado con el genoma del virus HPRS24 (97.7%). Sin embargo, se han identificado seis marcos de lectura continuos en 301B/1 (UL47, UL48, UL52, pp38, ICP4 y US10) que contienen sustituciones no sinónimas en relación con las secuencias homólogas encontradas en el genoma SB-1. Notablemente, a diferencia de las secuencias repetidas terminales largas del retrovirus aviar encontradas dentro del genoma de SB-1, ninguna se identificó dentro del genoma 301B/1.

Vaccinal efficacy of molecularly cloned Gallid alphaherpesvirus 3 strain 301B/1 against very virulent Marek's disease virus challenge.

Marek's disease virus (MDV), a causative agent of Marek's disease, has evolved its virulence partly because the current control strategies fail to provide sterilizing immunity. Gallid alphaherpesvirus 3 (GaHV-3) and turkey herpesvirus have been developed as bivalent vaccines to improve upon the level of protection elicited by single formulations. Since the in vitro passage of vaccines can result in attenuation, a GaHV-3 strain 301B/1 was cloned as a bacterial artificial chromosome (BAC) by inserting the mini-F replicon into the virus genome. A fully infectious virus, v301B-BAC, was reconstituted from the 301B/1 BAC clone and had similar growth kinetics comparable to that of the parental 301B/1 virus with strong reactivity against anti-301B/1 chicken sera. Protective efficacies of v301B-BAC, parental 301B/1, and SB-1 vaccine were evaluated against a very virulent MDV Md5 challenge. Clinical signs were significantly lower in the v301B-BAC vaccinated groups (24-25 %), parental 301B/1 (29 %) compare to that of non-vaccinated control (100%) and the removal of BAC sequences from v301B-BAC genome further reduced this to 17 %. The protective indices of v301B-BACs (75-76 %) were comparable with those of both the 301B/1 and the SB-1 vaccine (71%). Removal of the mini-F replicon resulted in a reconstituted virus with a protective index of 83 %. The shedding of challenge virus was notably lower in the v301B-BAC, and v301B-delBAC vaccinated groups. Overall, the protective efficacy of the 301B-BAC-derived vaccine virus against a very virulent MDV challenge was comparable to that of the parental 301B/1 virus as well as the SB-1 vaccine virus.

MinION sequencing to genotype US strains of infectious laryngotracheitis virus.

Over the last decade the US broiler industry has fought long-lasting outbreaks of infectious laryngotracheitis (ILTV). Previously, nine genotypes (I-IX) of ILTVs have been recognized using the polymerase chain reaction-restriction fragment length polymorphisms (PCR-RFLP) method with three viral alleles (gB, gM and UL47/gG). In this study, the genotyping system was simplified to six genotypes by amplicon sequencing and examining discriminating single nucleotide polymorphisms (SNPs) within these open reading frames. Using phylogenomic analysis of 27 full genomes of ILTV, a single allele (ORF A/ORF B) was identified containing SNPs that could differentiate ILTVs into genotypes congruent with the phylogenetic partitioning. The allelic variations allowed for the cataloging of the 27 strains into 5 genotypes: vaccinal TCO, vaccinal CEO, virulent CEO-like, virulent US and virulent US backyard flocks from 1980 to 1990, correlating with the PCR-RFLP genotypes I/ II/ III (TCO), IV (CEO), V (virulent CEO-like), VI (virulent US) and VII/VIII/IX (virulent US backyard flock isolates). With the unique capabilities of third generation sequencing, we investigated the application of Oxford Nanopore MinION technology for rapid sequencing of the amplicons generated in the single-allele assay. This technology was an improvement over Sanger-based sequencing of the single allele amplicons due to a booster amplification step in the MinION sequencing protocol. Overall, there was a 90% correlation between the genotyping results of the single-allele assay and the multi-allele assay. Surveillance of emerging ILTV strains could greatly benefit from real-time amplicon sequencing using the single-allele assay and MinION sequencing. RESEARCH HIGHLIGHTS A multi-allelic assay identified nine ILTV genotypes circulating in the US Single-allele genotyping is congruent with whole genome phylogenetic partitioning US ILTV strains can be grouped into five genotypes using the single-allele assay The single-allele assay can be done using MinION sequencing of barcoded amplicons.

A phylogenomic analysis of Marek's disease virus reveals independent paths to virulence in Eurasia and North America.

Virulence determines the impact a pathogen has on the fitness of its host, yet current understanding of the evolutionary origins and causes of virulence of many pathogens is surprisingly incomplete. Here, we explore the evolution of Marek's disease virus (MDV), a herpesvirus commonly afflicting chickens and rarely other avian species. The history of MDV in the 20th century represents an important case study in the evolution of virulence. The severity of MDV infection in chickens has been rising steadily since the adoption of intensive farming techniques and vaccination programs in the 1950s and 1970s, respectively. It has remained uncertain, however, which of these factors is causally more responsible for the observed increase in virulence of circulating viruses. We conducted a phylogenomic study to understand the evolution of MDV in the context of dramatic changes to poultry farming and disease control. Our analysis reveals evidence of geographical structuring of MDV strains, with reconstructions supporting the emergence of virulent viruses independently in North America and Eurasia. Of note, the emergence of virulent viruses appears to coincide approximately with the introduction of comprehensive vaccination on both continents. The time-dated phylogeny also indicated that MDV has a mean evolutionary rate of ~1.6 × 10-5 substitutions per site per year. An examination of gene-linked mutations did not identify a strong association between mutational variation and virulence phenotypes, indicating that MDV may evolve readily and rapidly under strong selective pressures and that multiple genotypic pathways may underlie virulence adaptation in MDV.

Molecular characterization of the complete genome of falconid herpesvirus strain S-18.

Falconid herpesvirus type 1 (FaHV-1) is the causative agent of falcon inclusion body disease, an acute, highly contagious disease of raptors. The complete nucleotide sequence of the genome of FaHV-1 has been determined using Illumina MiSeq sequencing. The genome is 204,054 nucleotides in length and has a class E organization. The genome encodes approximately 130 putative protein-coding genes, of which 70 are orthologs of conserved alphaherpesvirus and Mardivirus proteins. Three FaHV-1 genes (UL3.5, UL44.5 and CIRC) were identified that encode protein homologues unique to Mardivirus and Varicellovirus. The genome also encodes homologues to the Mardivirus genes LORF2, LORF3, LORF4, LORF5, SORF3 and SORF4. An opal mutation resulting in premature termination was identified in the FaHV-1 UL43 gene. Phylogenetically, FaHV-1 resides in a monophyletic group with the other Mardiviruses but, along with anatid herpesvirus 1, represents a more distant divergence from the rest of the Mardivirus genus.

Identification and characterization of the genomic termini and cleavage/packaging signals of gallid herpesvirus type 2.

Herpesvirus replication within host cells results in concatemeric genomic DNA, which is cleaved into unit-length genomes and packaged into the capsid by a complex of proteins. The sites of cleavage have been identified for many herpesviruses, and conserved signaling sequences involved in cleavage and packaging have been characterized. The cleavage/packaging motifs pac-1, pac-2, and DR1 and two distinct groups of telomeric repeat sequences (static TRS and variable TRS) have been identified. By sequencing the termini of the gallid herpesvirus type 2 (GaHV-2) strain CU-2, two different cleavage sites (classical and aberrant) have been identified. Unlike classical cleavage of human herpesvirus type 1, which occurs within the DR1 site, classical cleavage of the GaHV-2 concatemers occurs 8.5 bp upstream of the DR1 site and results in an S-terminus containing telomeric repeats. Aberrant cleavage occurs the same distance from the DR1 site and generates a telomeric S-terminus but an L-terminus lacking an a sequence. These results are consistent with previous findings in other herpesviruses and should prove useful in the future study and manipulation of the GaHV-2 genome.

Expression of chicken parvovirus VP2 in chicken embryo fibroblasts requires codon optimization for production of naked DNA and vectored meleagrid herpesvirus type 1 vaccines.

Meleagrid herpesvirus type 1 (MeHV-1) is an ideal vector for the expression of antigens from pathogenic avian organisms in order to generate vaccines. Chicken parvovirus (ChPV) is a widespread infectious virus that causes serious disease in chickens. It is one of the etiological agents largely suspected in causing Runting Stunting Syndrome (RSS) in chickens. Initial attempts to express the wild-type gene encoding the capsid protein VP2 of ChPV by insertion into the thymidine kinase gene of MeHV-1 were unsuccessful. However, transient expression of a codon-optimized synthetic VP2 gene cloned into the bicistronic vector pIRES2-Ds-Red2, could be demonstrated by immunocytochemical staining of transfected chicken embryo fibroblasts (CEFs). Red fluorescence could also be detected in these transfected cells since the red fluorescent protein gene is downstream from the internal ribosome entry site (IRES). Strikingly, fluorescence could not be demonstrated in cells transiently transfected with the bicistronic vector containing the wild-type or non-codon-optimized VP2 gene. Immunocytochemical staining of these cells also failed to demonstrate expression of wild-type VP2, indicating that the lack of expression was at the RNA level and the VP2 protein was not toxic to CEFs. Chickens vaccinated with a DNA vaccine consisting of the bicistronic vector containing the codon-optimized VP2 elicited a humoral immune response as measured by a VP2-specific ELISA. This VP2 codon-optimized bicistronic cassette was rescued into the MeHV-1 genome generating a vectored vaccine against ChPV disease.

Dynamic equilibrium of Marek's disease genomes during in vitro serial passage.

Attenuation of Gallid herpesvirus-2 (GaHV-2), the causative agent of Marek's disease, can occur through serial passage of a virulent field isolate in avian embryo fibroblasts. In order to gain a better understanding of the genes involved in attenuation and associate observed changes in phenotype with specific genetic variations, the genomic DNA sequence of a single GaHV-2 virulent strain (648A) was determined at defined passage intervals. Biological characterization of these "interval-isolates" in chickens previously indicated that the ability to induce transient paralysis was lost by passages 40 and the ability to induce persistent neurological disease was lost after passage 80, coincident with the loss of neoplastic lesion formation. Deep sequencing of the interval-isolates allowed for a detailed cataloguing of the mutations that exist within a single passage population and the frequency with which a given mutation occurs across passages. Gross genetic alterations were identified in both novel and well-characterized genes and cis-acting regions involved in replication and cleavage/packaging. Deletions in genes encoding the virulence factors vLipase, vIL8, and RLORF4, as well as a deletion in the promoter of ICP4, appeared between passages 61 and 101. Three mutations in the virus-encoded telomerase which predominated in late passages were also identified. Overall, the frequency of mutations fluctuated greatly during serial passage and few genetic changes were absolute. This indicates that serial passage of GaHV-2 results in the generation of a collection of genomes with limited sequence heterogeneity.

Genotypic characterization of two bacterial artificial chromosome clones derived from a single DNA source of the very virulent gallid herpesvirus-2 strain C12/130.

The identification of specific genetic changes associated with differences in the pathogenicity of Marek's disease virus strains (GaHV-2) has been a formidable task due to the large number of mutations in mixed-genotype populations within DNA preparations. Very virulent UK isolate C12/130 induces extensive lymphoid atrophy, neurological manifestations and early mortality in young birds. We have recently reported the construction of several independent full-length bacterial artificial chromosome (BAC) clones of C12/130 capable of generating fully infectious viruses with significant differences in their pathogenicity profiles. Two of these clones (vC12/130-10 and vC12/130-15), which showed differences in virulence relative to each other and to the parental strain, had similar replication kinetics both in vitro and in vivo in spite of the fact that vC12/130-15 was attenuated. To investigate the possible reasons for this, the nucleotide sequences of both clones were determined. Sequence analysis of the two genomes identified mutations within eight genes. A single 494 bp insertion was identified within the genome of the virulent vC12/130-10 clone. Seven non-synonymous substitutions distinguished virulent vC12/130-10 from that of attenuated vC12/130-15. By sequencing regions of parental DNA that differed between the two BAC clones, we confirmed that C12/130 does contain these mutations in varying proportions. Since the individual reconstituted BAC clones were functionally attenuated in vivo and derived from a single DNA source of phenotypically very virulent C12/130, this suggests that the C12/130 virus population exists as a collection of mixed genotypes.

Comparative genomic sequence analysis of the Marek's disease vaccine strain SB-1.

Marek's disease virus (MDV), an oncogenic alphaherpesvirus, induces a rapid onset T-cell lymphoma and demyelinating disease in chickens. Since the 1970s the disease has been controlled through mass vaccination with herpesvirus of turkeys [meleagrid herpesvirus type 1 (MeHV-1)]. Over time this vaccine's efficacy decreased, and in the 1980s a bivalent vaccine consisting of MeHV-1 and a non-oncogenic gallid herpesvirus type 3 (GaHV-3) strain known as SB-1 was introduced. The complete DNA sequence (165,994 bp) of this GaHV-3 strain was determined using 454 pyrosequencing. A total of 524 open reading frames (ORFs) were examined for homology to protein sequences present in GenBank using BLAST (E-values <0.9). Of the 128 ORF hits, 75 ORFs showed homology to well-characterized alphaherpesviral proteins. Phylogenetically, this strain partitions in its own branch along with the GaHV-3 strain HPRS24 and shows more relatedness to MeHV-1 than gallid herpesvirus type 2 (GaHV-2, Marek's disease virus). When comparing the GaHV-3 ORFs to their homologues in MeHV-1 and GaHV-2, a greater percentage of amino acid similarity was found with homologous ORFs in the genome of SB-1 than with those in the HPRS24 genome. Overall, twice as many of the 75 ORFs within the SB-1 genome showed greater sequence identities and similarities to homologous ORFs in the Marek's disease genome than those within the HPRS24 genome. This paper describes the sequence difference between the two GaHV-3 genomes. Overall 19 ORFs differ in the number of predicted amino acids; of these, eight (U(L)3.5, U(L)5, U(L)9, U(L)28, U(L)30, U(L)36, U(L)37, and U(L)50) encode well-characterized alphaherpesviral proteins A sequence within the unique short region of the SB-1 genome exhibited significant sequence homology to long terminal repeat (LTR) sequences of avian retroviruses. This sequence was only found in the SB-1 genome and not the HPRS24 genome.

Accumulation of attenuating mutations in varying proportions within a high passage very virulent plus strain of Gallid herpesvirus type 2.

Marek's disease (MD) is controlled through mass vaccination. Although these vaccines reduce or delay tumor formation they fail to induce sterilizing immunity and prevent virus shedding. Relatively little is known about the genetic changes that lead to attenuation. It has been established that serial passage of virulent strains in avian cell lines results in the generation of attenuated progeny at some undefined passage level. A detailed cataloging of the mutations needed for attenuation will be important for advancing our understanding of MD biology and should facilitate the development of better vaccines. Using deep sequencing, the complete nucleotide sequence of the very virulent plus (vv+) strain 648A representing the 101 st passage was determined. Pathotyping studies have indicated that 648Ap101 is indeed attenuated. Comparative sequence analysis with the 648A strain at passage 11 has identified numerous gross genetic changes and subtle single nucleotide polymorphisms scattered throughout the genome. Relative to the strain (648Ap11), deletions were identified in MD-specific genes located in the repeat long (R(L)), unique long (U(L)) and repeat short (R(S)) regions. A deletion in the R(L) region, present in 33% of the p101 sequences, mapped to the genes encoding viral interleukin 8 (vIL8), RLORF4 and RLORF5. An R(S) deletion was mapped to the Meq oncoprotein binding site within the ICP4 promoter and was present in 97.8% of the p101 sequences. A short deletion in the U(L) region mapped to the 3' terminus of the gene encoding vLipase and was present in 54% of the p101 sequences. The cis-acting sites involved in DNA replication and packaging also contained deletions in varying proportions (64% and 100%, respectively). Three mutations, present in 100% of p101 sequences, were identified in the overlapping genes encoding the Arg-rich protein (MDV002/079) and the virus-encoding telomerase (vTR). Varying proportions of 12 single nucleotide polymorphisms (SNPs) were identified within 11 open reading frames (ORFs) and 3 noncoding regions. This comparative sequencing study has provided a wealth of information regarding genetic changes which have occurred during the attenuation process and has indicated that serial passage results in the generation of mixed populations.

Purification of DNA from the cell-associated herpesvirus Marek's disease virus for 454 pyrosequencing using micrococcal nuclease digestion and polyethylene glycol precipitation.

Methods for the isolation of DNA from cell-associated herpesviruses have often yielded samples contaminated with host cellular DNA. Because 2nd and 3rd generation nucleotide sequencers do not rely on molecular cloning of viral DNA, there is a need to develop methods for isolating highly pure DNA from these viruses. The cell-associated alphaherpesvirus Marek's disease virus (MDV-1) was chosen as a test virus for the development of such methodologies. The genomes of six MDV-1 strains have previously been sequenced using both Sanger dideoxy sequencing and 454 Life Sciences pyrosequencing. These genomes largely represent cell culture adapted strains due to the difficulty in obtaining large quantities of DNA from true low passage isolates. There are clear advantages in analyzing MDV-1 virus taken directly from infected tissues or low passage isolates since serial passage attenuates the virus. Procedures using an ATP-dependent exonuclease and Phi29 DNA polymerase to degrade host DNA selectively and amplify MDV-1 DNA enzymatically from total DNA preps were attempted without much success. Ultimately, however, a protocol was developed for purification of low passage MDV-1 DNA from infected avian fibroblasts. The method builds upon and extends available protocols based on hypotonic lysis to release virus particles followed by micrococcal nuclease treatment to degrade cellular DNA. Intact high-molecular weight viral DNA is purified away from an excess of degraded cellular DNA using polyethylene glycol precipitation. 454-based pyrosequencing of viral DNA purified in this manner has generated data containing as little as 2.3% host sequence. On average, DNA preparations were 70% (+/-20%) pure yielding a genome coverage range of 25-74-fold.

Clustering of mutations within the inverted repeat regions of a serially passaged attenuated gallid herpesvirus type 2 strain.

Marek's disease (MD) is the leading cause of losses in chicken production in the world. Over the past 40 years significant progress has been made in the control of MD through the use of vaccines which reduce or delay tumor formation in vaccinated flocks. However, these vaccines fail to induce an immune response that protects against infection and virus shedding. Little is known about the genetic changes that lead to attenuation and are necessary for the generation of vaccine strains. Previous research has demonstrated that serial passage of virulent strains in cell culture results in the generation of attenuated progeny. Obtaining detailed knowledge of the changes which are needed for attenuation will be important for advancing our understanding of MD biology and should facilitate the development of more potent vaccines. We have determined the complete nucleotide sequence of a bacterial artificial chromosome (BAC) construct representing the 80th passage of a very virulent plus (vv+) MD virus strain termed 584A. Pathotyping studies have indicated that this strain (584Ap80) is indeed attenuated. Bioinformatic analysis of the sequencing data has identified numerous gross genetic changes clustering in the inverted repeat regions of the genome, as well as subtle changes (single nucleotide polymorphisms or SNPs) scattered throughout the genome. Relative to the parental strain (584Ap9), insertional mutations were identified in the MD-specific genes encoding RLORF1, RLORF3, RLORF6, 23 kDa, RLORF7 (Meq), vIL8, vLip, RSORF1, and five uncharacterized novel genes. Deletions were found in four locations within the 584Ap80 genome. A large deletion (297nt) was found in the diploid genes 85.6/98.6 and a 321 nt deletion within the intergenic region between the U(L)3 and U(L)3.5 genes is predicted to create a fusion polypeptide. A single nucleotide deletion was identified within the origin of replication. Both insertions and deletions were found in the dipoid genes MDV3.4/78.3 encoding the virulence factor RLORF4. The sequencing of the attenuated strain 584Ap80 and comparison to that of the virulent parent 584A passage 9 (584Ap9) has provided a wealth of information regarding genetic changes which have occurred during the attenuation process.

High titer growth of human and avian influenza viruses in an immortalized chick embryo cell line without the need for exogenous proteases.

The current method of growing influenza virus for vaccine production is through the use of embryonated chicken eggs. This manufacturing system yields a low concentration of virus per egg, requires significant downstream production for purification, and demands a considerable amount of time for production. We have demonstrated an immortalized chick embryo cell line, termed PBS-1, is capable of growing unmodified recent isolates of human and avian influenza A and B viruses to extremely high titers. In many cases, PBS-1 cells out perform primary chick embryo kidney (CEK) cells, Madin-Darby Canine Kidney (MDCK) cells and African green monkey kidney cells (Vero) in growth of recent influenza isolates. PBS-1 cells are free of any exogenous agents, are non-tumorigenic, and are readily adaptable to a variety of culture conditions, including growth on microcarrier beads. Influenza viruses grown in PBS-1 cells are released into the culture fluid without the need for exogenous proteases, thus simplifying downstream processing. In addition to offering a significant improvement in vaccine production, PBS-1 cells should prove valuable in diagnostics and as a cell line of choice for influenza virus research.

Sequence determination of a mildly virulent strain (CU-2) of Gallid herpesvirus type 2 using 454 pyrosequencing.

The complete DNA sequence of the mildly virulent Gallid herpesvirus type 2 strain CU-2 was determined and consists of 176,922 bp with an overall gene organization typical of class E herpesviruses. Phylogenetically, this strain partitions in its own branch between the virulent strains RB-1B, Md11, and Md5, and the vaccine strain CVI988. Overall, the genome of CU-2 is more similar to that of CVI988, with identically sized unique short regions of 11,651 bp. As in CVI988, an insertion of 177 bp was identified in the overlapping genes encoding the Meq, RLORF6, and 23 kDa proteins within the repeat long region of the genome. A total of 15 single nucleotide polymorphisms (SNPs) common to both CU-2 and CVI988, and not occurring in virulent strains, were identified in the genes encoding UL29, UL45, UL50, UL52, LORF10, RLORF14a, RLORF12, Meq(RLORF7), 23kDa, ICP4, US3, and two hypothetical proteins MDV071.4 and MDV076.4. Each gene encoding UL29 and Meq contained two SNPs. Only one major open reading frame (ORF) encoding UL41, the virus host shutoff (VHS) ribonuclease, was disrupted in the CU-2 genome. An additional cytosine after the 25 codon is predicted to produce a truncated protein of 97 aa. Since GaHV-2 mutants lacking UL41 have been reported to retain their virulence, other factors are likely responsible for the low virulence of CU-2. It is largely suspected that SNPs in common with CVI988 along with the insertions in the Meq loci are responsible for its phenotype. Conversely, we identified 43 nonsynonymous mutations (within 23 genes) that may contribute to the virulence of CU-2. These SNPs are shared exclusively with all sequenced virulent strains (Md5, Md11, and RB-1B) and not present within the CVI988 genome. Although most occur in proteins of unknown function, a significant percentage is in proteins involved in virion assembly.

Comparative sequence analysis of a highly oncogenic but horizontal spread-defective clone of Marek's disease virus.

Marek's disease virus (MDV) is a cell-associated alphaherpesvirus that induces rapid-onset T-cell lymphomas in poultry. MDV isolates vary greatly in pathogenicity. While some of the strains such as CVI988 are non-pathogenic and are used as vaccines, others such as RB-1B are highly oncogenic. Molecular determinants associated with differences in pathogenicity are not completely understood. Comparison of the genome sequences of phenotypically different strains could help to identify molecular determinants of pathogenicity. We have previously reported the construction of bacterial artificial chromosome (BAC) clones of RB-1B from which fully infectious viruses could be reconstituted upon DNA transfection into chicken cells. MDV reconstituted from one of these clones (pRB-1B-5) showed similar in vitro and in vivo replication kinetics and oncogenicity as the parental virus. However, unlike the parental RB-1B virus, the BAC-derived virus showed inability to spread between birds. In order to identify the unique determinants for oncogenicity and the ''non-spreading phenotype'' of MDV derived from this clone, we determined the full-length sequence of pRB-1B-5. Comparative sequence analysis with the published sequences of strains such as Md5, Md11, and CVI988 identified frameshift mutations in RLORF1, protein kinase (UL13), and glycoproteins C (UL44) and D (US6). Comparison of the sequences of these genes with the parental virus indicated that the RLORF1, UL44, and US6 mutations were also present in the parental RB-1B stock of the virus. However with regard to UL13 mutation, the parental RB-1B stock appeared to be a mixture of wild type and mutant viruses, indicating that the BAC cloning has selected a mutant clone. Although further studies are needed to evaluate the role of these genes in the horizontal-spreading defective phenotype, our data clearly indicate that mutations in these genes do not affect the oncogenicity of MDV.