Detection of antibodies against viral capsid proteins of human herpesvirus 8 in AIDS-associated Kaposi's sarcoma.

Sequences of a new herpesvirus with homology to gammaherpesvirinae were recently identified in AIDS-associated Kaposi's sarcoma (KS). Subsequently this novel virus, called KS-associated virus (KSHV) or human herpesvirus (HHV) 8 was detected in classical KS and AIDS-associated body cavity based lymphomas by polymerase chain reaction. In this report major and minor capsid proteins of HHV-8 were molecularly cloned and produced as recombinant proteins in Escherichia coli. Sera from 69 HIV-1 infected patients with KS, 30 HIV-1 infected patients without KS and 106 control individuals were tested by enzyme-linked immunosorbent assay for anti-HHV-8 capsid IgM and IgG antibodies. Sera from four patients were tested over periods ranging from 18 months to 6 years. IgG antibodies directed against HHV-8 capsid antigens were detected in patients with AIDS-associated KS and in some AIDS patients without KS. Seroconversion with IgM and IgG antibodies directed against HHV-8 capsid proteins occurred more than 1 year prior to diagnosis of KS. In a considerable portion of KS patients no IgM or IgG antibodies against HHV-8 capsid proteins were detected. In these patients there was an inverse relationship between antibodies against HHV-8orf26 and the CD4/CD8 ratio, suggesting that the inconsistency of anti-HHV-8orf26 antibodies is due at least partly to an impaired immune response. No reactivity against HHV-8 capsid antigens was detected in the vast majority of sera from HIV-negative control individuals. Our findings indicate that a specific humoral immune response against capsid proteins is raised in HHV-8 infected individuals, and that anti-capsid antibodies can be used to diagnose HHV-8 infection. The correlation between occurrence of anti-HHV-8 antibodies and KS supports the hypothesis of a causative role of HHV-8.

Restitution of the UL56 gene expression of HSV-1 HFEM led to restoration of virulent phenotype; deletion of the amino acids 217 to 234 of the UL56 protein abrogates the virulent phenotype.

Recently it was shown that the avirulent phenotype of HSV-1 strain HFEM is correlated to the lack of DNA sequences of the promoter region of the UL56 gene. In order to investigate the role of the UL56 gene of HSV-1 in the process of viral pathogenicity in more detail, a complete copy of the UL56 gene of the virulent HSV-1 strain 17 was inserted within the DNA sequences of the incomplete UL56 gene of the genome of HSV-1 strain HFEM. The UL56 gene of HSV-1 strain 17 comprises 1428 bp corresponding to the nucleotide positions (NP) 11,5967-117,395 of the genome of HSV-1 strain 17 (SacII-DNA fragment) containing the promoter region and the entire UL56 gene with identical transcription termination signals. This particular DNA fragment was inserted into the corresponding region of the genome of HSV-1 strain HFEM by co-transfection experiments in which the beta-galactosidase gene served as reporter gene. Those recombinant viruses with the ability to express the UL56 gene were tested for their pathogenicity in vivo. The results of these experiments indicate that the restoration of the viral UL56 gene expression led to the restitution of the virulent phenotype of HSV-1 strain HFEM. The UL56 protein which has been shown to be a component of the virion possesses several characteristic signatures e.g. a hydrophobic domain at the carboxy-terminus between amino acid residues 217 and 234 (VFGVVAIVVVIILVFLWR). In order to investigate the role of this particular signature of the UL56 protein in the process of viral pathogenicity, site-specific mutagenesis was performed for removing the carboxy-terminus of the UL56 protein. The deleted region of the DNA sequences of the UL56 gene between NP 1122-1175 corresponds to NP 116 220-116 373 of the viral genome. The DNA sequences of the UL56 gene of virulent HSV-1 strain 17 and F were replaced by DNA sequences of the truncated UL56 gene by co-transfection experiments in which the beta-galactosidase gene served as a reporter gene. Those recombinant viruses with the ability to express the truncated UL56 gene were examined for their pathogenicity in vivo. The analysis revealed that the expression of the truncated UL56 protein (without hydrophobic domain 217-234 aa) was not sufficient for the maintenance of the virulent phenotype of HSV-1 strains.

In vitro expression of UL56 gene of herpes simplex virus type 1; detection of UL56 gene product in infected cells and in virions.

In order to investigate the functional properties of the UL56 gene of herpes simplex virus type 1 (HSV-1), it was necessary to express the UL56 protein in vitro. The DNA sequences corresponding to the open reading frame of the UL56 gene of HSV-1 strain F were amplified from genomic viral DNA by PCR using primers corresponding to the translational start and termination regions of the UL56 ORF. The PCR product (705 bp) was inserted into the EcoRI/XbaI recognition sites of the bacterial expression vector pMal-c2. This procedure allowed the expression of the viral UL56 gene fused to the maltose-binding protein (MBP) of Escherichia coli, and subsequent cleavage of the fusion protein with the specific protease factor Xa. The induced fusion protein was purified by affinity chromatography using amylose columns. The apparent molecular weight of the fusion protein was about 70 kDa. Factor Xa cleaves the fusion protein into two subfragments of 42 kDa (MBP) and 30 kDa (UL56). Rabbit antisera induced against recombinant UL56 protein were used for detection of the UL56 gene product during the infection cycles of HSV-1. The presence of the UL56 protein was detected in infected cells and in HSV-1 virions by Western blot experiments and by immunofluorescence assays. A strong and increasing cytoplasmic fluorescence was observed in RC-37 cells infected with HSV-1 strain F between 6 and 16 h post-infection. In addition it was found that human HSV-1 IgM/IgG positive convalescent sera recognized the recombinant UL56 protein.

Antigenic domains of the HIV-1 vif protein as recognized by human sera and murine monoclonal antibodies.

To analyze the vif antibody response in individuals infected with the human immunodeficiency virus type 1 (HIV-1) and to determine antigenic epitopes on the vif protein, 104 HIV-1+ sera were screened for reactivity with a recombinant vif protein; 30 (28.8%) of these sera recognized the recombinant vif protein in immunoblot and were employed, together with 17 HIV-1/vif-negative control sera, in an enzyme immunoassay (EIA)-based epitope scanning assay with 183 overlapping decapeptides that covered the complete amino acid sequence of the HIV-1 vif protein (strain BH10). Of the 30 HIV-1/vif+ sera, 87% reacted with decapeptides comprising the two following epitopes: IEWRKKRY (vif amino acids 87-94) or DRWNKPQ (vif amino acids 172-178). The two epitopes were 89% and 100% conserved among different HIV-1 strains and their antigenicity could be confirmed by computer-assisted predictions of vif antigenic determinants. All the sera reactive with recombinant vif protein and with vif peptides originated from patients in CDC stages III or IV. Two murine anti-vif monoclonal antibodies reacted only with the seven C-terminal amino acids of the vif protein (SHTMNGH), which were not recognized by any of the human sera. Our results may be useful for further studies of vif seroreactivity and for the production of anti-vif mono- or polyclonal antibodies using vif peptides.

Herpes simplex virus encephalitis: long-term comparative study of viral load and the expression of immunologic nitric oxide synthase in mouse brain tissue.

In the brain tissue of 21 mice infected with herpes simplex virus type 1 (HSV-1) strain F we determined the expression of immunologic nitric oxide synthase (iNOS) as a potential mediator of neuronal injury with a semiquantitative reverse transcription polymerase chain reaction. Viral burden in brain tissue was quantitated with a dilutional polymerase chain reaction assay. Viral burden and iNOS-expression peaked at day 7 following infection. Thereafter viral burden declined to a low baseline value at 6 months following infection, whereas iNOS-expression was still 4-fold increased compared to baseline levels. In experimental herpes simplex virus encephalitis iNOS, as one potent mediator of neuronal injury, is upregulated in the acute and chronic disease. In future, in addition to antiviral treatment, inhibitors of iNOS might offer new therapeutic strategies in herpes simplex virus encephalitis.

Herpes simplex virus encephalitis: cranial magnetic resonance imaging and neuropathology in a mouse model.

We performed a long-term magnetic resonance imaging (MRI) study in a mouse model of herpes simplex virus encephalitis. Mice were infected with herpes simplex virus type 1 (HSV-1) strain F. A 1.5-T cranial MRI scanner with standard spin-echo sequences was used. Neuropathological studies included immunohistochemistry. The presence of HSV DNA in brain tissue was determined with a polymerase chain reaction assay. Clinical assessment was performed daily: within the first 2 weeks the animals were severely affected and recovered thereafter. MRI and histopathological abnormalities corresponded well. HSV DNA was detectable initially and at 6 months. Extent and severity of structural abnormalities increased at 6 months. MRI offers a new in vivo approach for the detection of structural changes in the disease course of experimental herpes simplex virus encephalitis.

A mouse model of herpes simplex virus encephalitis: diagnostic brain imaging by magnetic resonance imaging.

Herpes simplex virus encephalitis is a severe sporadic encephalitis in man with high mortality and morbidity. A critical step in the establishment of therapy is early diagnosis. Magnetic resonance imaging is a noninvasive, accurate diagnostic test for the detection of central nervous system disease. In an effort to monitor morphological changes in vivo we present a new diagnostic neuroimaging model of experimental herpes simplex virus encephalitis. A mouse model of herpes simplex virus encephalitis was used. 40 SJL mice were intranasally inoculated with an infectious dose of wild-type strain HSV-I F. Morphological abnormalities were studied by cranial magnetic resonance imaging (MRI). These findings were correlated with sequential neuropathological studies. 95% of animals developed cerebral abnormalities on MRI. resembling human HSVE. Areas of increased signal intensity on T2-weighted sequences and focal pathological contrast enhancement were mostly found in the frontal and temporal lobes and thalamic and cerebellar regions. All animals with MRI abnormalities had neuropathological signs of neuronal degeneration and reactive astrocytosis in corresponding regions. The described monitoring system offers a new approach for studies on neurovirulence and therapeutic strategies.

A new technique: serial puncture of the cisterna magna for obtaining cerebrospinal fluid in the mouse--application in a model of herpes simplex virus encephalitis.

This report describes a new technique for obtaining cerebrospinal fluid from the living mouse (SJL/NBom) in a model of herpes simplex virus encephalitis which is also applicable to other mouse models. The puncture technique was performed in living animals which had been infected with Herpes Simplex Virus Type I strain F in the living animal. The cisterna magna was micro-surgically prepared: The neck muscles were dissected microscopically down to the dura which subsequently was punctured by a glass micropipette. This newly developed minimally invasive technique was performed in a group of living animals (n = 20) and results compared with those of a second group of perfusion fixed animals (n = 20). For the first time, repeated cerebrospinal fluid punctures of individual, living animals are possible. This is of great value for the assessment of new therapeutic and diagnostic strategies in experimental research using mouse models. In addition, this refined methodology significantly reduces the number of experimental animals.

Identification of the UL56 protein of herpes simplex virus type 1 within the virion by immuno electron microscopy.

Recently the UL56 protein of herpes simplex virus type 1 (HSV-1) was shown to be associated with the virion of HSV-1 as determined by Western blot analysis. The detection of the UL56 protein in infected cells and its association with virions of HSV-1 is of particular importance, pointing to a possible involvement of UL56 protein in virus-host interactions. In order to investigate the properties of the UL56 protein further immuno-localization was performed using rabbit hyperimmune serum against fusion recombinant UL56 protein and purified virions of HSV-1 strain F. The UL56 protein was detected in the HSV-1 virions by immuno gold negative staining.

Molluscum contagiosum virus expresses late genes in primary human fibroblasts but does not produce infectious progeny.

Molluscum contagiosum virus (MCV), a member of the family Poxviridae, can be isolated from skin-lesion material of patients with molluscum contagiosum infection. MCV replicates efficiently in human keratinocytes in vivo but viral replication has not been observed in vitro in cell or tissue culture systems. We investigated a variety of established cell lines for productive MCV infection and found that: (i) MCV induces a typical cytopathogenic effect (CPE) only in human primary fibroblast cells (MRC5 ATCC-CCL 171 and HEPM ATCC-CRL 1486) but not in permanent eucaryotic cell lines of human or simian origin; (ii) UV irradiated MCV virions and heat inactivated virions do not induce a CPE; (iii) decreasing amounts of MCV viral DNA are detectable in infected human embryonic fibroblasts for at least 14 days post infection (p.i.); (iv) MCV early mRNAs are detectable by RT-PCR between one and two hours p.i. and remain detectable upon passaging of the infected cells; (iv) transcripts of viral late genes (mc095L and mc106L) are detectable by RT-PCR from day 5 p.i.; (v) MCV viral antigens can be detected on the surface of infected cells using human and rabbit polyclonal antisera against MCV from 24 h p.i.; (vi) a CPE can not be observed if cell free supernatants or homogenizates of MCV infected cells are used to try passage of the virus onto uninfected human embryonic fibroblasts, indicating that infectious viral progeny is not produced. This is the first report demonstrating long time persistence of MCV viral DNA and expression of late proteins in an in vitro cell culture system.

Is the major capsid protein of iridoviruses a suitable target for the study of viral evolution?

Iridoviruses are large cytoplasmic DNA viruses that are specific for different insect or vertebrate hosts. The major structural component of the non-enveloped icosahedral virus particles is the major capsid protein (MCP) which appears to be highly conserved among members of the family Iridoviridae, Phycodnaviridae, and African swine fever virus. The amino acid sequences of the known MCPs were used in comparative analyses to elucidate the phylogenic relationships between different cytoplasmic DNA viruses including three insect iridoviruses (Tipula iridescent virus, Simulium iridescent virus, Chilo iridescent virus), seven vertebrate iridoviruses isolated either from fish (lymphocystis disease virus, rainbow trout virus, European catfish virus, doctor fish virus), amphibians (frog virus 3), or reptiles (turtle virus 3, turtle virus 5), one member of the family Phycodnaviridae (Paramecium bursaria Chlorella virus type 1), and African swine fever virus. These analyses revealed that the amino acid sequence of the MCP is a suitable target for the study of viral evolution since it contains highly conserved domains, but is sufficiently diverse to distinguish closely related iridovirus isolates. Furthermore the results suggest that a substantial revision of the taxonomy of iridoviruses based on molecular phylogeny is required.

Identification of the gene encoding the DNA (cytosine-5) methyltransferase of lymphocystis disease virus.

The gene encoding the DNA (cytosine-5) methyltransferase (m5C-MTase) of lymphocystis disease virus (flounder isolate, LCDV-1) has been identified by polymerase chain reaction (PCR) using oligonucleotide primers synthesized corresponding to different regions of the m5C-MTase gene of frog virus 3 (FV3). A DNA fragment of 487 bp was amplified using oligonucleotide primers L3 and R4 which correspond to the nucleotide positions 87 to 109 and 530 to 550 of the m5C-MTase gene of FV3, respectively. The DNA nucleotide sequence of the PCR product was determined by direct cycle sequencing. The alignment of the deduced amino acid sequence derived from the PCR product and the m5C-MTase protein of FV3 revealed a homology of 55.4% identity and 29.1% similarity. The amino acid sequence which was found to be significantly homologous to the amino acid sequence deduced from the nucleotide sequence of the PCR product was located at the amino acid position 37 to 175 of the m5C-MTase of FV3 indicating the specificity of the amplified PCR product. The DNA nucleotide sequence of the LCDV-1 genome corresponding to the 5' and 3' termini of the m5C-MTase gene was determined by primer walking. The locus of the m5C-MTase gene of LCDV-1 was identified within the EcoRI DNA fragment G of LCDV-1 (7.9 kbp; 0.947 to 0.034 map units). The m5C-MTase gene of LCDV-1 comprises 684 nucleotides coding for a putative protein of 228 amino acid residues. A high degree of amino acid sequence homology (53.3% identity and 25.8% similarity) was detected between the m5C-MTase of LCDV-1 and FV3.

Bovine aortic endothelial cells are susceptible to hantavirus infection; a new aspect in hantavirus ecology.

Hantaviruses are enveloped RNA viruses that belong to the family Bunyaviridae. They are the causative agents of hemorrhagic fever with renal syndrome (HFRS) and hantavirus pulmonary syndrome (HPS). Hantaviruses show a worldwide distribution with specific rodent species as natural hosts. It is known that rodents can transmit the virus via feces, urine, saliva, or bites to humans. Additionally, antibodies against different hantaviruses were also found in domestic animals, For example, Danes et al. documented hantavirus-specific IgG titers in 2% of examined cattle [Ceskoslov. Epidemiol. Mikrobiol. Imunol. 41 (1992) 15]. In order to clarify the possibility of a nonrodent and nonhuman hantavirus infection, the susceptibility of bovine aortic endothelial cells (BAEC) to Hantavirus serotype Puumala infection was investigated. The hantaviral nucleocapsid protein was detected in 95% of infected BAEC at the fourth cell culture passage 12 weeks after initial infection by immunofluorescence assay (IFA). The presence of Puumala virus (PUU) nucleocapsid protein and the viral glycoproteins G1 and G2 in infected cells were additionally confirmed by Western blot analysis. The viral RNA genome was identified in infected BAEC cultures and in cell-free culture medium at the fourth passage by reverse transcription polymerase chain reaction (RT-PCR), verified by cDNA nucleotide sequence analysis, showing a 98-100% homology to the input virus. The infected BAEC cultures were shown to express alpha(V)beta(3)-integrin surface receptors that are known to mediate virus entry in human cells and revealed no major cytopathic effects (CPEs) as assayed by immunofluorescence staining of the cytoskeletal components actin and microtubules. In the present study, we documented for the first time that a nonrodent and nonhuman aortic endothelial cell culture of bovine origin (BAEC) can be efficiently infected with a hantavirus. This finding is of particular importance because it adds new aspects to questions dealing with host species barrier, viral reservoir, virus transmission, and ecology of hantaviruses.

Bovine aortic endothelial cells are susceptible to Hantaan virus infection.

Hantavirus serotype Hantaan (HTN) is one of the causative agents of hemorrhagic fever with renal syndrome (HFRS, lethality up to 10%). The natural host of HTN is Apodemus agrarius. Recent studies have shown that domestic animals like cattle are sporadically seropositive for hantaviruses. In the present study, the susceptibility of bovine aortic endothelial cells (BAEC) expressing alpha(V)beta(3)-integrin to a HTN infection was investigated. Viral nucleocapsid protein and genomic RNA segments were detected in infected BAEC by indirect immunofluorescence assay, Western blot analysis, and reverse transcription-polymerase chain reaction (RT-PCR), respectively. The results of this study strongly support our previous observation on Puumala virus (PUU) that has been propagated efficiently in BAEC. These findings open a new window to contemplate the ecology of hantavirus infection and transmission route from animal to man.

Identification and characterization of the Tupaia herpesvirus DNA polymerase gene.

Tupaia herpesviruses (THVs) have been isolated from malignant lymphomas and from degenerating lung or spleen cell cultures of tree shrews (Tupoia spp.), but because of a lack of genetic information the final classification of THVs is still open. In the present work the viral DNA polymerase (DPOL) gene was mapped within the genome of the different THV strains using PCR and degenerate oligonucleotide primers. Nucleotide sequences of the DPOL genes of THV strains 1 to 5 were determined and used for comparative analyses. The transcriptional activity of the THV-2 DPOL gene was confirmed by RT-PCR. It was found that the different THV strains are very closely related to each other. When compared to other herpesviruses the highest amino acid sequence identities detected were with DPOLs of the murine and human cytomegaloviruses. These results justify the conclusion that THVs are members of the subfamily Betaherpes-virinae.

TT virus as a human pathogen: significance and problems.

In 1997 TTV was detected using representational difference analysis (RDA) in serum of a patient with posttransfusion hepatitis unrelated to known hepatitis viruses. The genome of TTV is a circular single-stranded DNA molecule of 3852 nt with negative polarity. TTV possibly can be grouped either into the existing family Circoviridae or into a recently established virus family "Circinoviridae". Analysis of the complete DNA nucleotide sequence of TTV identified three partially overlapping open reading frames (ORFs). Neither DNA nucleotide nor corresponding amino acid sequences of TTV do show significant homologies to known sequences. TTV DNA nucleotide sequences amplified by PCR from sera of different patients show considerable sequence variations. Although the natural route of transmission of TTV is still unknown, there is clear evidence for a transmission of TTV through blood and blood products. TTV DNA can be detected in the feces of infected individuals suggesting that it may be possible to attract TTV infection from environmental sources. Since the discovery of TTV, numerous studies have investigated the prevalence of TTV infections in different human population groups all over the world. All these studies are based on PCR detection systems, but the technical aspects of the PCR systems vary significantly between the different investigators. The results of the epidemiological studies do not show a clear picture. The discovery of TTV as a viral agent and particularly the identification of a high percentage of infected carriers in the healthy human population raises the following questions: Firstly, what is the origin and molecular relatedness of TT virus. Secondly, what is the significance of TTV as a human pathogen. And thirdly, what are the exact molecular mechanisms of viral replication. To answer these questions it will be necessary to determine the primary structure and the coding capacity of several TTV patient isolates.

Stable expression of nucleocapsid proteins of Puumala and Hantaan virus in mammalian cells.

The development of an in vitro-system for the stable expression and the analysis of native hantavirus proteins using hantaviral cDNA is of particular interest. As a first step the expression of the hantavirus nucleocapsid (N) proteins in mammalian cells was studied in more detail. The cDNA of the S-RNA segment of Puumala virus strain CG-1820 and Hantaan virus strain 76-118 was used for the construction of eucaryotic expression vectors that allow the generation and selection of mammalian cells harboring and expressing the N protein genes of hantaviruses. A variety of conventional and novel expression vectors as well as different mammalian cell lines were screened. The expression of the N protein of Puumala virus using the pGRE5-1 vector in which the transcription is under control of inducible glucocorticoid responsive elements (GRE) revealed that the Puumala virus N protein can be expressed in Vero E6 cells efficiently without any detectable cell toxicity. From the variety of expression vectors tested, it was found that pCR3.1 is the vector of choice for stable expression of hantavirus N proteins. The successful establishment of different mammalian cell lines expressing considerable amounts of Puumala and Hantaan virus N protein indicates that the stable and efficient expression of this particular viral protein in the cell lines of three evolutionary distinct species (human, monkey, and mouse) is possible. The system described here represents the experimental basis for further studies of hantavirus infection, replication, and pathogenesis using a reverse genetics approach.

Large envelope glycoprotein and nucleocapsid protein of equine arteritis virus (EAV) induce an immune response in Balb/c mice by DNA vaccination; strategy for developing a DNA-vaccine against EAV-infection.

Equine arteritis virus (EAV) is a member of the Arteriviridae family, that includes lactate dehydrogenase-elevating virus (LDV), porcine reproductive and respiratory syndrome virus (PRRSV), and simian haemorrhagic fever virus (SHFV). Equine arteritis is a contagious disease of horses and is spread via respiratory or reproductive tract. The objective of the present study is to evaluate the possibility for developing a model system for prevention horses against an EAV infection by DNAvaccination. A cDNA bank from the RNA of EAV was established. This gene library contains the translation unit of the EAV open reading frames (ORF) 1 to 7. The identity of the cDNA was confirmed by nucleotide sequence analysis. Using this defined EAV cDNA gene library the cDNA sequence of the viral ORFs were molecularly cloned into the corresponding sites of well characterized and powerful expression vectors (pCR3.1, pDisplay, and/or pcDNA3.1/HisC). The capability of these recombinant plasmids expressing the gene products of the individual viral ORFs 3 to 5, and 7 in induction of an immune response in mouse system was investigated. The Balb/c mice (ten mice per assay) were inoculated with the DNA of the constructed expression vectors harboring and expressing the EAV cDNA of the viral ORFs. The Balb/c mice were injected with about 100 microg DNA diluted in 100 microl PBS. The DNA was injected subcutaneously and into the tibialis cranialis muscle (Musculus gastrocnemius). The mice were boosted 3 to 5 times with the same quantities of DNA and under the same conditions at about two week intervals. Control mice received the same amount of parental expression vectors via an identical route and frequency. The pre- and post-vaccinated sera of the individual animals were screened by neutralization tests (NT). Neutralizing antibodies against EAV were detected when the animals were inoculated with the DNA of the expression vectors harboring cDNA of the EAV ORFs 5 and 7. Highest NT-titers were observed when the animals were administered with the cDNA of ORF 5 and/or with the cDNA of the neutralization determinants of EAV that is located on the N-terminal ectodomain of the gene product of ORF 5 between the amino acid positions 1-121. These results obtained from these studies justified proofing the capability of the EAV cDNA sequences of the viral genes including ORFs 5 and 7 in the autologous animal system horse.

Herpes simplex virus encephalitis: chronic progressive cerebral MRI changes despite good clinical recovery and low viral load - an experimental mouse study.

Cranial magnetic resonance imaging (MRI) is a sensitive diagnostic tool for the in vivo detection of morphological abnormalities in herpes simplex virus encephalitis (HSVE). We performed a long-term MRI study in a mouse model of HSVE. Cranial MRI findings were compared with the viral load within brain tissue, the presence of HSV DNA in the cerebrospinal fluid (CSF), a daily clinical assessment and post-mortem neurohistopathological studies. A 1.5 T cranial MRI scanner with standard spin-echo sequences was used. Viral load within the brain and the presence of HSV DNA in cerebrospinal fluid were determined by a polymerase chain reaction assay. Clinically, animals were severely affected within the first 2 weeks and recovered thereafter. Focal histopathological and MRI abnormalities involved predominantly limbic structures, a pattern that mimics human disease. Severity and extent of abnormalities had increased at 6 months despite clinical improvement. HSV DNA was present in CSF during the acute disease only. Brain viral load peaked at day 10 and declined thereafter. MRI as an in vivo monitoring approach may reveal chronic progressive changes in HSVE, despite clinical recovery and low viral load in the brain. Secondary, not directly virus-mediated, mechanisms of tissue damage may contribute to tissue damage of HSVE.