Cloning and fine mapping the DNA of equine herpesvirus type one defective interfering particles

Deletion of the UL4 gene sequence of equine herpesvirus 1 precludes the generation of defective interfering particles

Serial, high multiplicity passage of equine herpesvirus 1 (EHV-1) leads to the generation of defective interfering particles (DIP). EHV-1 DIP inhibit and interfere with the replication of standard EHV-1, establishing a state of persistent infection. These DIP package severely truncated and rearranged forms of the standard viral genome. Contained within the DIP genome are only three genes: UL3, UL4, and a unique hybrid gene (Hyb). The hybrid gene forms through a recombination event that fuses portions of the early regulatory IR4 and UL5 genes and is essential for DIP-mediated interference. The UL4 gene is an early gene dispensable for lytic replication and inhibits viral and cellular gene expression. However, the contribution of the UL4 gene during DIP-mediated persistent infection is unknown. Here, we describe the generation of a completely deleted UL4 virus and its use to investigate the role of the UL4 gene in the generation of the defective genome. Deletion of the UL4 gene resulted in delayed virus growth at late times post-infection. Cells infected with a mutant EHV-1 that lacked expression of the UL4 protein due to an inserted stop codon in the UL4 gene produced defective particles, while cells infected with a mutant EHV-1 that had the complete UL4 gene sequence deleted were unable to produce DIP. These data suggest that the UL4 gene sequence, but not the UL4 protein, is critical for the generation of defective interfering particles.

The early UL3 gene of equine herpesvirus-1 encodes a tegument protein not essential for replication or virulence in the mouse

The UL3 gene of equine herpesvirus-1 (EHV-1) is retained in the genome of defective interfering particles and encodes a ~33kDa myristylated protein. Further characterization showed that the UL3 gene is trans-activated only by the sole immediate early (IE) protein and encodes an early protein that is dispensable for EHV-1 replication and localizes in the tegument of purified virions. UL3-deleted EHV-1 (vL11ΔUL3) exhibits properties of host cell tropism, plaque size, and growth kinetics similar to those of the parental virus. Expression levels of EHV-1 proteins representative of all three gene classes in vL11ΔUL3-infected cells were identical to those in cells infected with parental virus. Mice intranasally infected with vL11ΔUL3 and parental virus showed no significant difference in mortality or virus lung titers. These findings suggest that the UL3 protein does not play a major role in the biology of EHV-1 in cell culture or virulence in the mouse.

The UL4 protein of equine herpesvirus 1 is not essential for replication or pathogenesis and inhibits gene expression controlled by viral and heterologous promoters

Defective interfering particles (DIP) of equine herpesvirus 1 (EHV-1) inhibit standard virus replication and mediate persistent infection. The DIP genome is comprised of only three genes: UL3, UL4, and a hybrid gene composed of portions of the IR4 (EICP22) and UL5 (EICP27) genes. The hybrid gene is important for DIP interference, but the function(s) of the UL3 and UL4 genes are unknown. Here, we show that UL4 is an early gene activated solely by the immediate early protein. The UL4 protein (UL4P) was detected at 4hours post-infection, was localized throughout the nucleus and cytoplasm, and was not present in purified virions. EHV-1 lacking UL4P expression was infectious and displayed cell tropism and pathogenic properties in the mouse model similar to those of parental and revertant viruses. Reporter assays demonstrated that the UL4P has a broad inhibitory function, suggesting a potential role in establishing and/or maintaining DIP-mediated persistent infection.

Biological and genotypic properties of defective interfering particles of equine herpesvirus 1 that mediate persistent infection

Infection with equine herpesvirus 1 (EHV-1) preparations enriched for defective interfering particles (DIP) leads to a state of persistent infection in which infected cells become lysis resistant and release both infectious (standard) virus and DIP. EHV-1 DIP are unique in that the recombination events that generate DIP genomes produce new open reading frames (ORFs; Hyb1.0 and Hyb2.0) consisting of 5' sequences of varying lengths of the early regulatory gene IR4 fused to 3' sequences of varying lengths of the UL5 regulatory gene. Only two additional ORFs (UL3 and UL4) are conserved. Because persistently infected cells release a heterogeneous mixture of DIP, characterization of the elements responsible for this altered state of infection has proved difficult. Here we describe a method for studying persistent infection using recombinant DIP (rDIP). Infection with rDIP resulted in the production of recombinant DIP that replicated faithfully to, at least, five passages and mediated a rapid progression to persistent infection as measured by: 1) production of cells resistant to lysis by the standard virus; and 2) infected cells that released both standard virus and DIP. High concentrations of rDIP also resulted in interference with the standard virus replication, another hallmark of persistent infection. rDIP deleted of UL3, UL4, and either Hyb gene, the only functional genes conserved in the DIP genome, replicated but exhibited markedly reduced ability to interfere with standard virus replication. Restoring only the Hyb genes (either Hyb1.0 or Hyb2.0), the IR4 gene, or specific portions of the IR4 gene restored interference. These data suggest that residues 144 to 196 of the IR4 protein within the HYB proteins are important for DIP interference and that persistent infection results from recombination events that produce DIP genomes.

Genetic Complexity of EHV-1 Defective Interfering Particles and Identification of Novel IR4/UL5 Hybrid Proteins Produced During Persistent Infection

This study examined the genetic complexity of three equine herpesvirus 1 (EHV-1) defective interfering particles (DIP) and found the DIP genomes to range from 5.9 kbp to 7.3 kbp in total size. Each DIP contains an identical 5' end ( approximately 1.9 kb) that harbors UL3 and UL4 genes that are 100% identical to those of the infectious virus. DIP2 and DIP3 contain a previously described unique IR4/UL5 (EICP22/EICP27) hybrid gene (Hyb1.0). The DIP1 genome, however, appears to be generated from a different recombination event which results in the formation of a new distinct hybrid ORF. The new ORF (Hyb2.0) is comprised of 684 bp from the 5' end of IR4 fused to 45 bp from the 3' terminus of UL5. In contrast to Hyb1.0, the UL5 sequences present in Hyb2.0 are not in-frame. Thus, the Hyb2.0 protein is comprised of 228 residues from IR4 linked to a sequence of 15 amino acids that result from a frameshifted reading of UL5 sequences. Western blot analysis confirmed that the Hyb2.0 ORF is expressed during persistent infection to produce a family of proteins that migrate at 36-42 kDa. Fluorescence microscopy revealed that both Hyb proteins display diffuse cytoplasmic localization patterns dissimilar to the nuclear localization patterns of both IR4 and UL5. Neither Hyb protein, however, disrupts the nuclear entry of the EHV-1 immediate-early, IR4, or UL5 proteins or cellular TATA box binding protein (TBP) previously shown to interact with both IR4 or UL5 in productive infection. DIP genomic segments ( approximately 3.5-5.0 kbp) downstream of the 100% conserved origin of replication are highly variable among the three DIP genomes and contain large areas of repetitive sequences. The possibility that the non-coding sequences play a role in viral interference and/or persistent infection remains to be determined.

The defective interfering particles of equine herpesvirus 1 encode an ICP22/ICP27 hybrid protein that alters viral gene regulation

The genomes of equine herpesvirus 1 (EHV-1) defective interfering (DI) particles that mediate persistent infection were shown to encode a unique hybrid open reading frame composed of sequences that encode the 196 N-terminal amino acids of ICP22 linked in-frame to the C-terminal 68 amino acids of ICP27. Previous studies demonstrated that this hybrid gene, designated as ICP22/ICP27. was expressed abundantly at both the mRNA and the protein levels in DI particle-enriched infections, but not in standard EHV-1 infection (Chen et al., 1996 J. Virol. 70, 313-320). Since the ICP22/ICP27 hybrid protein contains portions of two EHV-1 early regulatory proteins, its effect on EHV-1 gene regulation was investigated. In EHV-1-infected cells, the ICP22/ICP27 hybrid protein expressed from plasmid vectors significantly reduced expression of a reporter gene under the control of the EHV-1 immediate-early (IE) gene promoter and early gene promoter, such as the viral ICP27 gene. In uninfected cells, the ICP22/ICP27 hybrid protein moderately down-regulated the IE and ICP22 promoters, up-regulated late gene promoters such as IR5, and altered the regulatory function of the IE and 1CP22 proteins in co-transfected cells. These results demonstrated that DI particles might alter viral gene regulation by expression of a unique hybrid gene encoded on the DI particle genome.

Expression of an equine herpesvirus 1 ICP22/ICP27 hybrid protein encoded by defective interfering particles associated with persistent infection

Defective interfering (DI) particles of equine herpesvirus type 1 (EHV-1) are capable of mediating persistent infection (S. A. Dauenhauer, R. A. Robinson, and D. J. O'Callaghan, J. Gen. Virol. 60:1-14, 1982; R. A. Robinson, R. B. Vance, and D. J. O'Callaghan, J. Virol. 36:204-219, 1980). Sequence analysis of cloned DI particle DNA revealed that portions of two regulatory genes, ICP22 (IR4) and ICP27 (UL3), are linked in frame to form a unique hybrid open reading frame (ORF). This hybrid ORF, designated as the IR4/UL3 gene, encodes the amino-terminal 196 amino acids of the IR4 protein (ICP22 homolog) and the carboxy-terminal 68 amino acids of the UL3 protein (ICP27 homolog). Portions of DNA sequences encoding these two regulatory proteins, separated by more than 115 kbp in the standard virus genome, were linked presumably by a homologous recombination event between two identical 8-bp sequences. Reverse transcriptase-PCR and S1 nuclease analyses revealed that this unique ORF is transcribed by utilizing the transcription initiation site of ICP22 and the polyadenylation signal of ICP27 in DI particle-enriched infection. Immunoprecipitation and Western blot (immunoblot) analyses with antisera to the ICP22 and ICP27 proteins demonstrated that a 31-kDa hybrid protein was synthesized in the DI particle-enriched infection but not in standard virus infection. This 31-kDa hybrid protein was expressed at the same time as the ICP22 protein in DI particle-enriched infection and migrated at the same location on polyacrylamide gel electrophoresis as the protein expressed from a cloned IR4/UL3 expression vector. These observations suggested that the unique IR4/UL3 hybrid gene is expressed from the DI particle genome and may play a role in DI particle-mediated persistent infection.

Characterization of the myristylated polypeptide encoded by the UL1 gene that is conserved in the genome of defective interfering particles of equine herpesvirus 1

Equine herpesvirus 1 (EHV-1, Kentucky A strain) preparations enriched for defective interfering particles (DIPs) can readily establish persistent infection. The UL1 gene, which is conserved in the genome of DIPs that mediate persistent infection, maps between nucleotides 1418 and 2192 (258 amino acids) from the L (long) terminus. UL1 has no homology with any known gene encoded by herpes simplex virus type 1 but has limited homology to open reading frame 2 of varicella-zoster virus and the "circ" gene of bovine herpesvirus type 1. Previous work showed that the EHV-1 UL1 gene belongs to the early kinetic class and is transcribed as a 1.2-kb polyadenylated mRNA (R. N. Harty, R. R. Yalamanchili, and D. J. O'Callaghan, Virology 183:830-833, 1991). In this report, the UL1 protein was identified and characterized as a 33-kDa polypeptide in EHV-1-infected cells by using rabbit polyclonal antiserum raised against a TrpE-UL1 fusion protein (amino acids 7 to 258 of UL1) synthesized in Escherichia coli. Results from Western blot (immunoblot), immunoprecipitation, indirect immunofluorescence, and biochemical analyses indicated that the UL1 polypeptide (i) is more abundant in cells infected with DIP-enriched virus than in cells infected with standard EHV-1, (ii) is synthesized as early as 3 h postinfection (p.i.) in infection with standard virus or in infection with DIP-enriched virus preparations and increases in abundance up to 12 h p.i., (iii) appears to be associated with the rough endoplasmic reticulum-Golgi apparatus early in infection (3 to 4 h p.i.), while a diffuse cytoplasmic pattern of fluorescence is observed late in infection (7 to 8 h p.i.), (iv) is modified by myristic acid as it contains a consensus N-terminal myristylation site and is readily labeled with [3H]myristic acid, and (v) is associated with mature EHV-1 virions.

Identification and transcriptional mapping of genes encoded at the IR/Us junction of equine herpesvirus type 1

Two open reading frames (ORFs) encoded at the inverted repeat unique short (Us) junction of the Short (S) region of the equine herpesvirus type 1 genome were identified by DNA sequencing of a 2876 base pair (bp) genomic segment, and transcripts encoding these ORFs were characterized by Northern blot, S1 nuclease, and primer extension analyses. These studies also established the size of each inverted repeat to be 12,768 nucleotides (nts). The IR6 ORF (816 bp), mapping at nts 12,317-11,502 of the S region, is the last gene completely encoded within each inverted repeat and encodes a predicted 30.1-kDa protein of 272 amino acids, which does not exhibit homology to other alphaherpesvirus proteins. IR6 is expressed as an early transcript of 1.2 kb which is detected initially at 1.5 hr p.i. and up to 12 hr p.i. The transcription initiation and termination sites of IR6 were mapped by primer extension and S1 nuclease analyses to nts 12,465 and 11,408, respectively. The first ORF encoded within the Us segment (909 bp; EUS1), mapping at nts 13,397-12,489, encodes a predicted 33.5-kDa protein of 303 amino acids that exhibits 29% identity to the US2 protein of herpes simplex virus 1. EUS1 is expressed as a 2.3-kb mRNA of the gamma-1 class, as its synthesis begins prior to viral DNA replication at 4 hr p.i. but is retarded by phosphonoacetic acid, an inhibitor of viral DNA replication. The Tci and Tct sites of EUS1 were mapped by S1 nuclease analyses to nts 13,637 and 11,408, respectively. Interestingly, this termination site is also utilized by three late mRNAs of 5.8, 3.8, and 1.7 kb which originate within the Us and overlap the IR6 mRNA encoded in the terminal inverted repeat (TR) of the prototype genomic isomer. EUS1 is 3' coterminal with IR6 in the inverted repeat, whereas, the 5.8, 3.8, and 1.7 kb transcripts are 3' coterminal with IR6 of the TR.

Identification and transcriptional analyses of the UL3 and UL4 genes of equine herpesvirus 1, homologs of the ICP27 and glycoprotein K genes of herpes simplex virus

The DNA sequence of 3,240 nucleotides of the XbaI G fragment located in the unique long (UL) region of the equine herpesvirus 1 genome revealed two major open reading frames (ORFs) designated UL3 and UL4. The UL3 ORF of 470 amino acids (aa) maps at nucleotides (nt) 4450 to 3038 from the long terminus, and its predicted 51.4-kDa protein product exhibits significant homology to the ICP27 alpha regulatory protein of herpes simplex virus type 1 (HSV-1; 32% identity) and to the ORF4 protein of varicella-zoster virus (13% identity). Interestingly, a zinc finger motif is conserved in the C-terminal domains of both ICP27 of HSV-1 (aa 483 to 508) and UL3 of equine herpesvirus 1 (aa 441 to 466). The UL4 ORF of 343 aa maps at nt 5618 to 4587 and could encode a protein of 38.1 kDa which exhibits significant homology to the UL53 protein (cell fusion protein or glycoprotein K) of HSV-1 (26% identity) and to the ORF5 protein of varicella-zoster virus (33% identity). Analyses of the UL4 amino acid sequence revealed domains characteristic of a membrane-bound glycoprotein and included potential signature sequences for (i) a signal sequence, (ii) two N-linked glycosylation sites, and (iii) four transmembrane domains. Nucleotide sequence analyses also revealed potential TATA boxes located upstream of the UL3 and UL4 ORFs. However, only a single polyadenylation signal (nt 2988 to 2983) was detected downstream of the UL3 ORF. Northern (RNA) blot hybridization and S1 nuclease analyses were used to map and characterize the UL3 and UL4 mRNAs. Metabolic inhibitors were used to identify the kinetic class of these two genes. The data revealed that UL3 is an early gene that encodes a 1.6-kb mRNA, while UL4 is a late gene encoding a 3.8-kb mRNA that overlaps the UL3 transcript. Both transcripts were shown by S1 nuclease analyses to initiate 24 to 26 nt downstream of their respective TATA boxes and to have a common transcription termination signal as a pair of 3'-coterminal mRNAs.

Identification and expression of the UL1 gene product of equine herpesvirus 1

Sequences encoding the UL1 gene of equine herpesvirus type 1 (EHV-1) are conserved in the genome of EHV-1 defective interfering particles (DIPs) that mediate oncogenic transformation and persistent infection. The UL1 protein was identified by in vitro transcription/translation and hybrid-arrest translation analyses which employed a UL1/pGEM-3Z construct designated pGEML1. SDS-PAGE analyses of in vitro translation products synthesized from UL1-specific RNA revealed that the UL1 ORF encodes a 30 kDa protein which corresponds in size to the 258 amino acid protein predicted by DNA sequence analyses. This result was confirmed by arresting translation of the in vitro transcribed UL1 RNA with an oligodeoxynucleotide complementary to UL1 coding sequences. The UL1 protein is a homolog of the predicted protein encoded by the ORF2 gene of varicella-zoster virus, but UL1 has no homolog in herpes simplex virus type 1. The UL1 protein contains a region conforming to a 'PEST' (Proline, Glutamic acid, Serine, and Threonine) sequence, which is commonly found in proteins with half-lives of less than two hours.

Open reading frames encoding a protein kinase, homolog of glycoprotein gX of pseudorabies virus, and a novel glycoprotein map within the unique short segment of equine herpesvirus type 1

DNA sequence analysis of the unique short (Us) segment of the genome of equine herpesvirus type 1 Kentucky A strain (EHV-1) by our laboratory and strains Kentucky D and AB1 by other workers identifies a total of nine open reading frames (ORF). In this report, we present the DNA sequence of three of these newly identified ORFs, designated EUS 2, EUS 3, and EUS 4. The EUS 2 ORF is 1146 nucleotides (nt) in length and encodes a potential protein of 382 amino acids. Cis-regulatory sequences upstream of the putative ATG start codon include a G/C box 112 nt upstream and two potential TATA-like elements located between 15 and 90 nt before the ATG. The EUS 2 translation product exhibits significant homology to Ser/Thr protein kinases encoded within the Us segments of other herpesviruses, such as herpes simplex virus (26% homology) and pseudorabies virus (PRV), (45% homology), and possesses sequence domains conserved in protein kinases of cellular and viral origin. The EUS 3 ORF begins 127 nt downstream from the EUS 2 stop codon and ends at a stop codon 1119 nt further downstream. A single TATA-like element maps 61 nt upstream of the ORF. This ORF encodes a potential protein of 373 amino acids and is a homolog of glycoprotein gX of PRV, as judged by overall homology of amino acid residues, cysteine displacement, and presence of potential glycosylation sites and signal sequence. Interestingly, the EUS 4 ORF encodes a potential membrane glycoprotein that does not exhibit homology to any reported protein sequence. The EUS 4 ORF encodes a 383 amino acid polypeptide with a sequence indicative of a signal sequence at its amino terminal end, glycosylation sites for N-linked oligosaccharides, and a transmembrane domain near its carboxyl terminus. Several cis-acting regulatory sequences lie upstream of this ORF. These findings support the observation that the short region of alphaherpesviruses show considerable variation in their genetic content and gene organization.

Analysis of immediate-early transcripts of equine cytomegalovirus

Equine cytomegalovirus (ECMV) contains a linear, double-stranded DNA genome composed of a 146-kbp unique region flanked by a pair of 18-kbp direct repeat (DR) sequences at the termini. Cycloheximide, actinomycin D, and phosphonoacetic acid were applied to infected cell cultures to divide viral transcription into immediate-early (IE), early, and late phases. Eight IE transcripts were identified and mapped to two regions (I and II) of the viral genome. Two of these IE RNAs (13.0 and 5.5 kb in size) were transcribed from region I, which is located within the DR regions; these IE genes are diploid. The other IE transcripts (17.0, 9.0, 7.2, 6.8, 4.5, and 4.2 kb) originated from region II. IE region II is adjacent to region I and spans both unique and DR sequences at the left terminus of the genome. Region II IE transcripts are spliced and transcribed in the opposite direction from region I IE transcripts. IE transcripts from region I were present throughout the replication cycle, whereas those from region II were more abundant during the IE stage than at the early and late stages of infection. These studies demonstrate that ECMV differs from other herpesviruses in the organization and unusually large transcription units of its IE genes.

Transcriptional analysis of the UL1 gene of equine herpesvirus 1: a gene conserved in the genome of defective interfering particles

Defective interfering particles (DIPs) of equine herpesvirus type 1 (EHV-1) are biologically active, in that they mediate the coestablishment of oncogenic transformation and persistent infection in permissive, primary hamster embryo fibroblasts. The DIP genome is composed of EHV-1 sequences originating from the L-terminus (mapping units (m.u.) 0.00-0.023), the junction of the unique long (UL) region and the internal inverted repeat (IR) (m.u. 0.78-0.79 and 0.99-1.00), and the central portion of the IR (m. u. 0.83-0.87 and 0.91-0.95). The nature of one of the genes (UL1) mapping at the L-terminus was analyzed at the RNA level by Northern blot hybridization and S1 nuclease analyses. These data, and DNA sequencing analyses reported previously revealed that the UL1 gene: (1) contains a major open reading frame (ORF) of 258 amino acids, (2) is a homologue of the ORF2 gene of varicella zoster virus (VZV), (3) is conserved in the genome of DIPs of EHV-1, (4) encodes a 1.2-kb early (E) mRNA that is transcribed toward the short region of the genome, (5) utilizes a transcription initiation site approximately 1,120 nucleotides from the L-terminus, and (6) utilizes a transcription termination site approximately 2211 nucleotides from the L-terminus. These initial studies serve as the basis of future work to determine the function of the UL1 gene in cytolytic infection, and its potential role in EHV-1 persistent infection.

An early gene maps within and is 3' coterminal with the immediate-early gene of equine herpesvirus 1

The immediate-early (IE) gene (IR1 gene) of equine herpesvirus 1 (EHV-1) encodes a single, spliced 6.0-kb mRNA during cytolytic infection. However, under early (in the presence of phosphonoacetic acid) and late (8 h postinfection; no metabolic inhibitors) conditions, in addition to the 6.0-kb IE mRNA, a 4.4-kb early (E) mRNA is transcribed from the IE gene region beginning at approximately 4 h postinfection. To map and characterize the 4.4-kb E mRNA and the protein product of this early gene (IR2 gene), Northern (RNA) blot hybridization, S1 nuclease, primer extension, and in vitro transcription and translation analyses were used. The data from RNA mapping analyses revealed that the 4.4-kb E IR2 mRNA (i) maps at nucleotides 4481 to 635 within each of the inverted repeats of the short region and thus is encoded by sequences that lie entirely within the IE gene, (ii) is transcribed in the same direction as the IE mRNA, initiating at nucleotide 4481, which lies 25 bp downstream of a putative TATA-like sequence and 1,548 bp downstream of the transcription initiation site of the IE mRNA, and (iii) is 3' coterminal with the IE mRNA which terminates at nucleotide 635 of the inverted repeats. The IR2 open reading frame was inserted into the transcription expression vector pGEM-3Z, and the RNA transcribed from this construct (pGEM44) was shown to be a 4.2-kb transcript that contained all IR2 sequences. In vitro translation of the 4.2-kb RNA yielded a major protein of approximately 130 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis. This protein corresponds to the predicted IR2 product of 1,165 amino acids that would be in frame with the major IE polypeptide (IE1 = 200 kDa; 1,487 amino acids) and thus would be a 5'-truncated form of the IE1 polypeptide. The presence and potential role of the IR2 gene embedded within the IR1 gene increase the complexity of the regulation of the IE gene region during various stages of a productive infection.

Equine herpesvirus 1 sequence near the left terminus codes for two open reading frames

We have previously reported the sequence of the equine herpesvirus one genomic termini that are homologous to the genomic termini of other herpesviruses. In this paper, we present the nucleotide sequence adjacent to the left terminus sequence (map units 0.0087 to 0.0237). This sequence codes for two open reading frames (ORF) which are homologous to ORF2 and ORF3 of the varicella-zoster virus genome and are located at colinear positions. The L region sequence presented here also contains a segment that is involved in the generation of the genome of EHV-1 DI particles through recombination with sequences mapping within the internal portion of the inverted repeat sequences of the short region.

Organization and function of the ORIs sequence in the genome of EHV-1 DI particles

Equine herpesvirus type 1 (EHV-1) cultures enriched for defective interfering particles (DIP) mediate oncogenic transformation and persistent infection in permissive hamster embryo fibroblasts. We have recently demonstrated that an origin of replication (ORI) is located within the central portion (map units 0.828 and 0.948) of the inverted repeat sequence (IRs) of the short region of the standard EHV-1 genome. In the generation of the genome of EHV-1 DI particles, sequences from this internal portion of the IRs recombine with sequences at the long region terminus at nucleotides 3244-3251. In this paper we report that the ORIs sequence is precisely conserved in the DIP genome, that direct repeat sequences near the ORIs sequence which may enhance DNA replication are mutated in the DIP genome, and that the ORI sequence of DIP DNA is functional in DNA replication assays.

Cell culture amplification of a defective Marek's disease virus

A highly amplified 4-kb EcoRI fragment was present in DNA isolated from high cell culture passaged stocks (greater than 93 passages) of 281MI/1, a serotype 2 Marek's disease virus (MDV). The isolated 4-kb fragment is amplified in the presence of MDV, replicating as a high molecular weight, head-to-tail concatemer. When the 4-kb fragment was cloned into pUC18 and cotransfected with MDV DNA into chicken embryo fibroblast cells, the plasmid clone also replicated as a high molecular weight concatemer.

Identification of the site of recombination in the generation of the genome of DI particles of equine herpesvirus type 1

Defective interfering particles (DIPs) are generated by serial, undiluted propagation of equine herpesvirus type 1 (EHV-1). DIP-rich preparations of EHV-1 mediate oncogenic transformation and persistent infection in permissive hamster embryo fibroblasts. The defective genomes consist of reiterations of sequences from the left terminus (0.00 to 0.04 map units) of the long (L) region covalently linked to sequences from the inverted repeats (0.78 to 0.79, 0.83 to 0.87, 0.91 to 0.95, and 0.99 to 1.00 map units) of the short (S) region of the standard genome. We have identified and determined the nucleotide sequences of these segments of the standard genome as well as the component of the defective DNA that contains the site at which these two viral sequences recombined. Comparison of these sequences revealed that there is an 8-nucleotide sequence that is common to both the left terminus sequences and the inverted repeat sequences. These 8-nucleotide identical sequences are located at 3.25 kbp from the left terminus and at 9 kbp downstream of the L-S junction. The recombination between the left terminus and the inverted repeat sequences occurred at the site of homology and resulted in the generation of a novel open reading frame. The last 97 amino acids of an open reading frame of 469 amino acids encoded by sequences within the inverted repeats were replaced by a sequence of 68 amino acids encoded by a 204-bp sequence mapping at 0.023 map units. It will be of interest to determine whether this altered open reading frame, generated by recombination of sequences separated by more than 110,000 bp in the standard genome, plays a role in the varied outcomes of infection mediated by EHV-1 DIPs.

Sequence and organization of the genomic termini of equine herpesvirus type 1

The nucleotide sequence and organization of the genomic termini and of the junction of the long (L) and short (S) regions of the equine herpesvirus type 1 genome were determined. Sequencing of the XbaI-Q fragment (1441 nucleotides) revealed that the left terminus contains sets of inverted repeat and direct repeat sequences. The terminal sequence is described as DR1-UC-DR4 (18, 60, and 16 nucleotides, respectively) because of its homology to these elements of the 'a' sequence of herpes simplex virus. Located at each terminus of the S region as part of the inverted repeats is a 54 nucleotide sequence with homology to the Ub element of the HSV 'a' sequence. Thus, these data suggest that fusion of the EHV-1 genomic termini during replication will generate a sequence equivalent to Ub-DR1-Uc-DR4, which is known to be an ideal cleavage/packaging signal in herpesviral DNAs. Eighty-seven nucleotides of the L region left terminus sequence are repeated in an inverted fashion at nucleotide 892; also a 32 basepair portion, DR1-Uc (18 and 14 basepairs respectively), is reiterated 20 times in an inverted fashion as part of a 54 basepair tandem repeat located at the other L region terminus (L-S junction). It is not known whether these small inverted repeats at the L termini mediate isomerization of the L region at a very low level. The organization of the terminal sequences of the EHV-1 genome and the similarity of these sequences to the cleavage/packaging elements of other herpesviruses are discussed.

Mapping the termini and intron of the spliced immediate-early transcript of equine herpesvirus 1

Equine herpesvirus 1 (EHV-1) has been shown to synthesize a 6.0-kilobase (kb) species of immediate-early (IE) mRNA in productively infected cells. This IE gene region maps within the outer portion (map units 0.79 to 0.83 and 0.96 to 1.00) of the two inverted repeat segments of the short genomic region, and elucidation of its DNA sequence has revealed multiple potential open reading frames (ORFs), including a major ORF of 4,461 nucleotides (F. J. Grundy, R. P. Baumann, and D. J. O'Callaghan, Virology 172:223-236, 1989). Analyses of IE polypeptides synthesized in EHV-1-infected cells (in vivo) and in vitro translation of hybrid-selected IE mRNA indicated that multiple species of IE proteins are encoded by this IE mRNA species. To address the nature of the 6.0-kb IE RNA species, Northern (RNA) blot hybridization, S1 nuclease mapping, and primer extension analyses have been employed. These data revealed that no major introns were detected within the body of the IE transcript. However, the IE mRNA was shown to be spliced at the 5' terminus, such that a 372-base intron containing two small ORFs (19 and 51 amino acids) was removed from the leader region of the transcript. This splicing event reduced the leader region from 625 to 253 bases. S1 and primer extension analyses of the 5' terminus of this transcript revealed that the transcription initiation site is located 24 to 26 bases downstream of the consensus TATAAA motif. The 3' transcription termination site was mapped by S1 nuclease analysis to approximately 10 to 20 bases downstream of the polyadenylation signal, AATAAA. The distance from the stop codon of the major ORF to the polyadenylation site is approximately 300 bases. Results from S1 nuclease experiments indicated that splicing does not occur at the 3' terminus. These studies indicated that the EHV-1 6.0-kb IE mRNA is spliced at the 5' terminus and that alternative splicing of this transcript may function in regulating translation of the IE mRNA species.

Viral transcripts in cells infected with defective interfering particles of equine herpesvirus type 1

Equine herpesvirus type 1 (EHV-1) preparations enriched in defective interfering particles (DIPs) have previously been demonstrated to mediate the coestablishment of persistent infection and oncogenic transformation in primary hamster embryo fibroblasts. In this study, it was demonstrated that infection of a rabbit kidney (RK) cell line with EHV-1 DIP-enriched preparations also results in the establishment of persistent infection. Viral transcription was characterized in RK cells infected with DIP-enriched stocks and compared to viral transcription in RK cells infected with standard (STD) EHV-1. During the first 8 hr of infection with the DIP-enriched EHV-1 preparation, viral DNA sequences which are conserved in the DIP genome were predominantly expressed. Thus, these transcripts originate from DNA sequences that contain the components of the defective genome which originates from DNA sequences mapping at 0.00-0.04 of the Long region terminus and within two portions of the Short region inverted repeats (IR), 0.78-0.79 and 0.83-0.865 of the internal IRs and 0.99-1.00 and 0.915-0.95 of the terminal IRs. The overwhelming majority of viral transcripts that were synthesized in the DIP-enriched infections appeared to correspond to transcripts expressed in STD infection as assessed by Northern hybridization analysis but the synthesis of transcripts originating from sequences not conserved in the defective genome was significantly delayed. However, some high molecular weight RNA species that were synthesized in STD infections were not detected in DIP-enriched infections. Studies utilizing metabolic inhibitors indicated that viral transcription in DIP-enriched infections, like that of STD cytocidal infection, is regulated in an immediate early, early and late manner.

Functional mapping and DNA sequence of an equine herpesvirus 1 origin of replication

The genome of equine herpesvirus 1 (EHV-1) defective interfering (DI) particle DNA originates from discrete regions within the standard (STD) EHV-1 genome: the left terminus (0.0 to 0.04 map units) and the inverted repeats (0.78 to 0.79 and 0.83 to 0.87 map units of the internal inverted repeat; 0.91 to 0.95 and 0.99 to 1.00 map units of the terminal inverted repeat). Since DI DNA must contain cis-acting DNA sequences, such as replication origins, which cannot be supplied in trans by the STD EHV-1 virus, regions of the EHV-1 genome shown to be in DI DNA were assayed for the presence of a viral origin of DNA replication. Specifically, STD EHV-1 DNA fragments encompassing the genomic regions present in DI particle DNA were inserted into the vector pAT153, and individual clones were tested by transfection assays for the ability to support the amplification and replication of plasmid DNA in EHV-1-infected cells. The Sma-1 subfragment of the internal inverted repeat sequence (0.83 to 0.85 map units) was shown to contain origin of replication activity. Subcloning and BAL 31 deletion analysis of the 2.35-kilobase-pair (kbp) Sma-1 fragment delineated a 200-bp fragment that contained origin activity. The origin activities of all EHV-1 clones which were positive by the transfection assay were confirmed by methylation analysis by using the methylation-sensitive restriction enzymes DpnI and MboI. DNA sequencing of the 200-bp fragment which contained an EHV-1 origin of replication indicated that this region has significant homology to previously characterized origins of replication of human herpesviruses. Furthermore, comparison of known origin sequences demonstrated that a 9-bp sequence, CGTTCGCAC, which is conserved among all origins of replication of human lytic herpesviruses and which is contained within the 18-bp region in herpes simplex virus type 1 origins shown by others to be protected by an origin-binding protein (P. Elias, M. E. O'Donnell, E. S. Mocarski, and I. R. Lehman, Proc. Natl. Acad. Sci. USA 83:6322-6326) is also conserved across species in the EHV-1 origin of replication.

Characterization of equine herpesvirus type 1 immediate early proteins

EHV-1 immediate early (IE) gene expression in lytic infection results in the production of four high mol wt immediate early polypeptides (IEPs), designated IE1, IE2, IE2, and IE4; however, IE transcription is limited to the synthesis of a single 6-kb mRNA. Together, these findings raised questions as to whether the four IEPs were related products of the same gene. In the present study the IEPs were characterized with respect to their structural similarities, antigenic relatedness, and postsynthetic modifications. IE1 was the most abundant IEP, in that it accounted for approximately 80% of the IEP-incorporated radiolabel in infected rabbit kidney cells labeled under IE conditions with [35S]methionine or 14C-labeled amino acid mixtures. IE1 also was the major phosphorylated species. Limited proteolytic digestion of isolated radiolabeled IEP bands with Staph V8 protease yielded virtually identical fragment profiles in SDS-PAGE, as did digestions with chymotrypsin and N-chlorosuccinimide. Monospecific rabbit antisera raised against each of the four isolated IEPs reacted with all the IEP species in immunoblotting assays. Pulse-chase experiments indicated that all the IEPs were detectable immediately after a 15-min pulse and that several alterations in the IEP profile occurred during subsequent chase periods. Thus, the EHV-1 IEPs are closely related structurally and antigenically and appeared to be either produced simultaneously or processed to yield the individual forms immediately.

Characterization and mapping of equine herpesvirus type 1 immediate early, early, and late transcripts

Northern blot analysis was used to characterize and map equine herpesvirus type 1 (EHV-1) immediate early (IE), early, and late transcripts. Genomic EHV-1 DNA and cloned EHV-1 restriction endonuclease fragments, representing the entire genome, were 32P-labeled and hybridized to immobilized total cell RNA isolated from EHV-1 infected rabbit kidney cells incubated in the presence or absence of metabolic inhibitors. A single 6.0 kilobase (kb) IE transcript mapped to viral inverted repeat sequences. Approximately 41-45 early transcripts ranging in size from 0.8 to 6.4 kb and 18-20 late transcripts ranging in size from 0.8 to 10.0 kb were identified. These findings demonstrate that EHV-1 gene expression is regulated at the level of transcription, although regulation at the level of translation is also possible. The results provide a basis for examining alterations in viral gene expression in EHV-1 oncogenically transformed and persistently infected cells.

Equine herpesvirus type 1 defective-interfering (DI) particle DNA structure: the central region of the inverted repeat is deleted from DI DNA

The inverted repeat (IRs) component of the genome of equine herpesvirus type 1 (EHV-1) is an important region of structure and function. It is a major constituent of the DNA of EHV-1 defective-interfering (DI) particles which have been shown to mediate the coestablishment of oncogenic transformation and persistent infection of hamster embryo cells. In addition, the IRs encodes the single EHV-1 immediate early gene and the 31.5K very early protein. DNA sequences encompassing EHV-1 internal IRs and the joint between the long (L) and short (S) regions were subcloned into the plasmid vectors pBR322 and pUC12. A total of 22 subclones were derived, including six Sa/l subclones in pBR322 and 12 SmaI subclones in pUC12. Individual subclones were employed in Southern blot hybridizations to define subclone homology to repeated, unique, or heterogeneous (het) DNA sequences within the EHV-1 genome. These studies revealed that the EHV-1 het region is contained entirely within the unique long region of the viral genome and is separated from the L/S junction by approximately 1.8 MDa of completely unique DNA sequences. Furthermore, these IRs subclones were employed in blot hybridizations to analyze the integrity of IRs DNA sequences within the cloned DNA of EHV-1 DI particles. These analyses demonstrated that IRs DNA sequences present in DI DNA were extensively rearranged and contained major deletions (0.80-0.83 map units) which removed a large portion of the single EHV-1 immediate early gene (0.78-0.83 and 0.95-1.00 map units) located in the IRs. Thus, these data and those previous studies (R. P. Baumann et al., 1984, J. Virol. 50, 13-21; R. P. Baumann, J. Staczek, and D. J. O-Callaghan, 1986, Virology 153, 188-200) indicate that the major subunits of the DI DNA molecule are comprised of selected sequences from the IRs component and a highly conserved short sequence located at the terminus of the L region of the standard viral genome.