Non-invasive bioluminescence imaging for monitoring herpes simplex virus type 1 hematogenous infection

Traditional studies on viral neuroinvasiveness and pathogenesis have generally relied on murine models that require the sacrifice of infected animals to determine viral distributions and titers. The present paper reports the use of in vivo bioluminescence imaging to monitor the replication and tropism of KOS strain HSV-1 viruses expressing the firefly luciferase reporter protein in hematogenously infected mice. Following intraperitoneal injection, a comparison was made between real-time PCR determinations of HSV-1 DNA concentrations (requiring the sacrifice of the experimental animals) and in vivo bioluminescence emissions in living animals. For further comparison, in vitro light emission was also measured in the ovaries and adrenal glands of sacrificed mice. After infection, HSV-1 spread preferentially to the ovaries and adrenal glands (these organs showed the highest virus levels). Both the PCR and bioluminescence methods detected low viral loads in the nervous system, where the virus was restricted to the spinal cord. The concentrations of viral DNA measured correlated with the magnitude of bioluminescence in vivo, and with the photon flux determined by the in vitro luciferase enzyme assay. The results show that bioluminescence imaging can be used for non-invasive, real-time monitoring of HSV-1 hematogenous infection in living mice, but that coupling this methodology with conventional techniques aids in the characterization of the infection.     

Herpes simplex virus type 1 mutant strain in1814 establishes a unique, slowly progressing infection in SCID mice.

Ocular infection of immunocompetent (BALB/c) mice with wild-type herpes simplex virus type 1 (HSV-1) 17+ may lead to acute fatal encephalitis; however, in surviving animals, a latent (nonproductive) infection of the nervous system is established. In contrast, 17+ infection invariably kills mice with severe combined immunodeficiency (SCID mice) within 2 weeks. Ocular infection of immunocompetent mice with a mutant HSV-1 strain, in1814, which does not produce a functional alpha-transinducing protein, results in no detectable viral replication in the nervous system during the time corresponding to the acute phase of infection, no mortality, and the establishment of latency. In SCID mice, however, the in1814 virus establishes a unique, slowly progressing infection. In studying the courses of in1814 infection in SCID and BALB/c mice, we found that although intact B- and/or T-lymphocytic functions were required for the control of viral replication in the nervous system, some of the infected neurons of SCID mice seemed to be able to restrict in1814 replication and harbor the virus in a latent state.     

Immunogenicity,Protective Efficacy,and Non-Replicative Status of the HSV-2 Vaccine Candidate HSV529 in Mice and Guinea Pigs

HSV-2 vaccine is needed to prevent genital disease, latent infection, and virus transmission. A replication-deficient mutant virus (dl5-29) has demonstrated promising efficacy in animal models of genital herpes. However, the immunogenicity, protective efficacy, and non-replicative status of the highly purified clinical vaccine candidate (HSV529) derived from dl5-29 have not been evaluated. Humoral and cellular immune responses were measured in mice and guinea pigs immunized with HSV529. Protection against acute and recurrent genital herpes, mortality, latent infection, and viral shedding after vaginal HSV-2 infection was determined in mice or in naïve and HSV-1 seropositive guinea pigs. HSV529 replication and pathogenicity were investigated in three sensitive models of virus replication: severe combined immunodeficient (SCID/Beige) mice inoculated by the intramuscular route, suckling mice inoculated by the intracranial route, and vaginally-inoculated guinea pigs. HSV529 immunization induced HSV-2-neutralizing antibody production in mice and guinea pigs. In mice, it induced production of specific HSV-2 antibodies and splenocytes secreting IFNγ or IL-5. Immunization effectively prevented HSV-2 infection in all three animal models by reducing mortality, acute genital disease severity and frequency, and viral shedding. It also reduced ganglionic viral latency and recurrent disease in naïve and HSV-1 seropositive guinea pigs. HSV529 replication/propagation was not detected in the muscles of SCID/Beige mice, in the brains of suckling mice, or in vaginal secretions of inoculated guinea pigs. These results confirm the non-replicative status, as well as its immunogenicity and efficacy in mice and guinea pigs, including HSV-1 seropositive guinea pigs. In mice, HSV529 produced Th1/Th2 characteristic immune response thought to be necessary for an effective vaccine. These results further support the clinical investigation of HSV529 in human subjects as a prophylactic vaccine.     

Effect of apolipoprotein E on the cerebral load of latent herpes simplex virus type 1 DNA

Herpes simplex virus type 1 (HSV-1) is neurotropic and enters a latent state lasting the lifetime of the host. This pathogen has recently been proposed as a risk factor for Alzheimer's disease (AD) in conjunction with apolipoprotein E4 (ApoE4). In a murine acute infection model, we showed that viral neuroinvasiveness depends directly on the overall ApoE dosage and especially on the presence of isoform ApoE4. If an interaction between ApoE and HSV-1 is involved in AD, it may occur during latency rather than during acute infection. Certainly, ApoE plays an important role in late-onset AD, i.e., at a time in life when the majority of people harbor HSV-1 in their nervous system. In the present work, wild-type, APOE knockout, APOE3, and APOE4 transgenic mice were used to analyze the influence of the ApoE profile on the levels of latent virus DNA. The knockout mice had significantly lower concentrations of the virus in the nervous system than the wild-type mice, while the APOE4 mice had very high levels in the brain compared to the APOE3 animals. ApoE4 seems to facilitate HSV-1 latency in the brain much more so than ApoE3. The APOE dosage correlated directly with the HSV-1 DNA concentration in the brain, strengthening the hypothesis that HSV-1, together with ApoE, might be involved in AD.     

Herpesvirus entry mediator and nectin-1 mediate herpes simplex virus 1 infection of the murine cornea

Herpes simplex virus 1 (HSV-1) is a ubiquitous human pathogen that enters cells by the receptor-mediated fusion of the viral envelope with a host cell membrane. The envelope glycoprotein gD of HSV must bind to one of its receptors for entry to take place. Recent studies using knockout (KO) mice demonstrated that the gD receptors herpesvirus entry mediator (HVEM) and nectin-1 are the primary entry receptors for HSV-2 in the mouse vagina and brain. Nectin-1 was most crucial for the neuronal spread of HSV-2, particularly in the brain. HVEM was dispensable for infection in these models, but when both HVEM and nectin-1 were absent, infection was completely prevented. We sought to determine the receptor requirements of HSV-1 in an ocular model of infection using knockout mice. Wild-type, HVEM KO, nectin-1 KO, and HVEM/nectin-1 double-KO mice were infected via corneal scarification and monitored for clinical signs of infection and viral replication in various tissues. We report that either HVEM or nectin-1 must be present for HSV-1 infection of the cornea. Additionally, we observed that the infection was attenuated in both HVEM KO and nectin-1 KO mice. This is in contrast to what was reported for studies of HSV-2 in vagina and brain and suggests that receptor requirements for HSV vary depending on the route of inoculation and/or serotype.     

The Influence of Stress Factors on the Reactivation of Latent Herpes Simplex Virus Type 1 in Infected Mice

This study shows that the influence of different stress factors impacts the reactivation of latent herpes simplex virus type 1 (HSV-1) specifically in the trigeminal ganglion of infected mice. Different stress factors including hyperthermia, hypothermia, fatigue, and immunosuppression were exerted on mice infected with HSV-1. These viral antigens were then detected in the trigeminal ganglion region of infected mice under the influence of each stress factor, with hyperthermia having the most influence on reactivation. Interestingly, an increase in IL-6 was also detected in mice subjected to hyperthermia. These studies therefore suggest that stress can induce the reactivation of latent HSV-1, possibly through the induction of IL-6, in the trigeminal ganglion region of infected mice. This reveals a new insight on the pathogenesis of relapse infection of HSV-1.     

A herpes simplex virus type 1 mutant containing a nontransinducing Vmw65 protein establishes latent infection in vivo in the absence of viral replication and reactivates efficiently from explanted trigeminal ganglia.

Vmw65, a herpes simplex virus type 1 (HSV-1) tegument protein, in association with cellular proteins, transactivates viral immediate early genes. In order to examine the role of Vmw65 during acute and latent infection in vivo, a mutant virus (in1814), containing a 12-base-pair insertion in the Vmw65 gene, which lacks the transactivating function of Vmw65 (C. I. Ace, T. A. McKee, J. M. Ryan, J. M. Cameron, and C. M. Preston, J. Virol. 63:2260-2269, 1989) was examined in mice. Following corneal inoculation, the parental virus (17+) and the revertant (1814R) replicated effectively in eyes and trigeminal ganglia with 30 to 60% mortality. At either equal PFU or equal particle numbers, in1814 did not replicate in trigeminal ganglia and none of the infected mice died. Although in1814 did not replicate following corneal inoculation, it established latent infection in trigeminal ganglia. HSV-1 in1814 reactivated at explant as efficiently and rapidly as did 17+ and 1814R. Even low amounts of inoculated in1814 (10(2) PFU) were sufficient to establish latent infection in some animals. Since infectious in1814 was not detected at any time in mouse trigeminal ganglia, in1814 provided a unique opportunity to determine how soon after primary infection latency begins. Latent in1814 infection was detected shortly after virus reached the sensory ganglia, between 24 to 48 h postinfection. Thus, though Vmw65 may be required for lytic infection in vivo, it is dispensable for the establishment of and reactivation from latent infection. These data support the hypotheses that the latent and lytic pathways of HSV-1 are distinct and that latency is established soon after infection without a requirement for viral replication. However, the levels of Vmw65 reaching neuronal nuclei may be a critical determinant of whether HSV-1 forms a lytic or latent infection.     

Rates of reactivation of latent herpes simplex virus from mouse trigeminal ganglia ex vivo correlate directly with viral load and inversely with number of infiltrating CD8+ T cells

Herpes simplex viruses (HSV) reactivate at rates proportional to the viral loads in latently infected ganglia. However, these rates vary substantially among infected animals. We assessed whether the numbers of HSV-specific CD8(+) T cells infiltrating latently infected ganglia also affect reactivation rates and contribute to their variability. Following corneal infection of mice with HSV type 2 (HSV-2), we quantified the latent viral loads in dissociated trigeminal ganglia by real-time PCR, the numbers of infiltrating CD8(+) T cells by flow cytometry, and the rates of reactivation by the detection of cell-free virus released from ganglion cells cultured in 96-well plates. The reactivation rates correlated directly with the latent viral loads (P = 0.001) but did so more strongly (P = 10(-7)) when cultures were depleted of CD8(+) T cells. Reactivation rates were reduced in a dose-dependent fashion by adding back ganglion CD8(+) T cells to the cultures (P = 0.003). We related the latent viral loads, numbers of CD8(+) T cells, and reactivation rates by mathematical equations. The rates of reactivation predicted from latent viral loads and numbers of infiltrating CD8(+) T cells in dissociated ganglia correlated with the observed rates of reactivation (P = 0.04). The reactivation of HSV-2 from ganglia ex vivo is determined both by the latent viral load and the number of infiltrating CD8(+) T cells.     

Role of peptidergic neurons in ocular herpes simplex infection in mice

Peptide-containing nerve fibers (peptidergic fibers) abundantly innervate the mammalian cornea. We investigated their role in ocular herpes simplex infection in mice by using capsaicin, which causes degeneration and permanent loss of peptidergic neurons in neonates and temporary peptide depletion in adult animals. The corneas of neonatally denervated BALB/c mice were observed for capsaicin-induced keratitis at 11-14 wk of age and were then infected bilaterally with herpes simplex virus 1 (HSV-1); trigeminal (TG) ganglia were cocultivated 6 wk later to establish the rate of latent infection. We also applied capsaicin eye drops to adult BALB/c mice that had been infected with HSV-1 6 wk earlier, and measured viral shedding before, and 3 days and 2 months after, administration of capsaicin drops; TG ganglia of these animals were cocultivated at 3 days and 2 months after capsaicin application. Neurotrophic keratitis was found in 81% of neonatally denervated animals; mortality rate due to HSV-1 infection was reduced from 80% in the controls to 24% in the capsaicin-treated group, and recovery of latent virus by cocultivation was reduced by 50%. Viral shedding could not be produced by capsaicin eye drops in adult animals infected with HSV-1. However, recovery of latent virus was significantly reduced in TG ganglia sampled 3 days and 2 months after capsaicin drops were instilled. Our findings suggest 1) that peptidergic fibers play a crucial role in the establishment of trigeminal HSV-1 latency and 2) that reactivation of latently infected ganglia can be inhibited by topical capsaicin.     

CD8(+) T-cell attenuation of cutaneous herpes simplex virus infection reduces the average viral copy number of the ensuing latent infection

During an initial encounter with herpes simplex virus type 1 (HSV-1) it takes several days for an adaptive immune response to develop and for herpes-specific CD8(+) T cells to infiltrate sites of infection. By this time the virus has firmly established itself within the innervating sensory nervous system where it then persists indefinitely. Preventing the establishment of viral latency would require blocking the skin to nervous system transmission of the virus. We wished to examine if CD8(+) T cells present early during acute HSV-1 infection could block this transmission. We show that effector CD8(+) T cells failed to prevent the establishment of HSV latency even when present prior to infection. This lack of blocking likely reflects the delayed infiltration of the CD8(+) T cells into the infected skin. Examination of the kinetics of HSV-1 infection highlighted the rapidity at which the virus infects the sensory ganglia and singled out early viral replication within the skin as an important factor in determining the magnitude of the ensuing latent infection. Though unable to prevent the establishment of latency, CD8(+) T cells could reduce the average viral copy number of the residual latent infection by dampening the skin infection and thus limiting the skin-to-nerve transmission of virus.     

Hematogenous vertical transmission of herpes simplex virus type 1 in mice

Herpes simplex virus type 1 (HSV-1) is a neurotropic virus that causes severe disease and death in newborn humans but, to date, it remains unclear how neonatal infection occurs. We show here that the vertical transmission of HSV-1 in mice is mainly hematogenous and involves the colonization of the neonate central nervous system (CNS). HSV-1 DNA was mainly detected in the blood and CNS of the offspring born to latently infected mothers; no significant differences were seen between the viral DNA concentrations in the blood of these mothers and their female progeny (either neonate or adult). The administration of acyclovir during gestation reduced or eliminated both the maternal and the neonatal viral DNA in the blood. Embryo transfer was performed to ensure (as far as possible) that only vertical hematogenous infection took place. Immunohistochemical analysis detected viral proteins in the encephalon of the offspring. Immunofluorescence studies provided immunoreactive evidence of HSV-1 proteins in the neurons of the hippocampus and showed that these viruses can molecularly reactivate after hyperthermia. Neonatal HSV-1 infection therefore appears to be mainly caused by hematogenous vertical transmission, and the viruses that colonize the offspring CNS are capable of molecular reactivation after a period of latency.     

Noninvasive bioluminescence imaging of herpes simplex virus type 1 infection and therapy in living mice

Mouse models of herpes simplex virus type 1 (HSV-1) infection provide significant insights into viral and host genes that regulate disease pathogenesis, but conventional methods to determine the full extent of viral spread and replication typically require the sacrifice of infected animals. To develop a noninvasive method for detecting HSV-1 in living mice, we used a strain KOS HSV-1 recombinant that expresses firefly (Photinus pyralis) and Renilla (Renilla reniformis) luciferase reporter proteins and monitored infection with a cooled charge-coupled device camera. Viral infection in mouse footpads, peritoneal cavity, brain, and eyes could be detected by bioluminescence imaging of firefly luciferase. The activity of Renilla luciferase could be imaged after direct administration of substrate to infected eyes but not following the systemic delivery of substrate. The magnitude of bioluminescence from firefly luciferase measured in vivo correlated directly with input titers of recombinant virus used for infection. Treatment of infected mice with valacyclovir, a potent inhibitor of HSV-1 replication, produced dose-dependent decreases in firefly luciferase activity that correlated with changes in viral titers. These data demonstrate that bioluminescence imaging can be used for noninvasive, real-time monitoring of HSV-1 infection and therapy in living mice.     

Immunization with replication-defective mutants of herpes simplex virus type 1: sites of immune intervention in pathogenesis of challenge virus infection.

Replication-defective mutants of herpes simplex virus type 1 (HSV-1) were used as a new means to immunize mice against HSV-1-mediated ocular infection and disease. The effects of the induced immune responses on pathogenesis of acute and latent infection by challenge virus were investigated after corneal inoculation of immunized mice with virulent HSV-1. A single subcutaneous injection of replication-defective mutant virus protected mice against development of encephalitis and keratitis. Replication of the challenge virus at the initial site of infection was lower in mice immunized with attenuated, wild-type parental virus (KOS1.1) or replication-defective mutant virus than in mice immunized with uninfected cell extract or UV-inactivated wild-type virus. Significantly, latent infection in the trigeminal ganglia was reduced in mice given one immunization with replication-defective mutant virus and was completely prevented by two immunizations. Acute replication in the trigeminal ganglia was also prevented in mice immunized twice with wild-type or mutant virus. The level of protection against infection and disease generated by immunization with replication-defective mutant viruses was comparable to that of infectious wild-type virus in all cases. In addition, T-cell proliferative and neutralizing antibody responses following immunization and corneal challenge were of similar strength in mice immunized with replication-defective mutant viruses or with wild-type virus. Thus, protein expression by forms of HSV-1 capable of only partially completing the replication cycle can induce an immune response in mice that efficiently decreases primary replication of virulent challenge virus, interferes with acute and latent infection of the nervous system, and inhibits the development of both keratitis and systemic neurologic disease.