Mode of protection of mice against herpes simplex virus type 2 infection by Propionibacterium

We compared various strains of Propionibacterium with regard to protection of young adult mice against lethal infection with herpes simplex virus type 2 (HSV-2). Propionibacterium acnes, P. granulosum, and P. avidum were protective, while P. acidi-propionici and P. lymphophilum were ineffective. The protective effect proved to be in the cell wall fraction. Attempts were made to elucidate possible mechanisms of the protection using both effective and ineffective strains. The results strongly suggest that induction of interferon rather than activation of macrophages and natural killer cells by Propionibacterium pretreatment plays a crucial role, directly or indirectly, in protection against infection by herpes simplex virus. Propionibacterium only moderately protected newborn mice against HSV-2 infection.     

Role of NK cells in protection of mice against herpes simplex virus-1 infection

Natural killer (NK) cells have been implicated in the recognition and killing of a variety of virus infected target cells in vitro, yet their role in vivo remains uncertain. In these experiments, the role of NK cells in the regulation of resistance to herpes simplex virus-1 (HSV-1) was studied. Adult C57BL/6 mice are resistant to HSV-1 (HFEM strain), but are rendered highly susceptible by treatment with cyclophosphamide 24 hr prior to infection. In this model, passive transfer of 10(8) normal spleen cells or 10(7) poly I:C-treated spleen cells provided protection for 72% of the recipients. Spleen cells from NK cell-deficient beige mice similarly treated failed to engender passive protection. The phenotype of the cells responsible for transferring protection was NK1.1+, and asialo GM1+. Transfer of NK cells resulted in marked reduction of HSV titers in the livers and brains of recipients. These experiments provide direct evidence for a role for NK cells in protection against development of fatal HSV infection in mice.     

Chromatin control of herpes simplex virus lytic and latent infection

Herpes simplex viruses (HSV) can undergo a lytic infection in epithelial cells and a latent infection in sensory neurons. During latency the virus persists until reactivation, which leads to recurrent productive infection and transmission to a new host. How does HSV undergo such different types of infection in different cell types? Recent research indicates that regulation of the assembly of chromatin on HSV DNA underlies the lytic versus latent decision of HSV. We propose a model for the decision to undergo a lytic or a latent infection in which HSV encodes gene products that modulate chromatin structure towards either euchromatin or heterochromatin, and we discuss the implications of this model for the development of therapeutics for HSV infections.     

Dendritic cells from mice neonatally vaccinated with modified vaccinia virus Ankara transfer resistance against herpes simplex virus type I to naive one-week-old mice

Modified vaccinia Ankara (MVA) is an attenuated virus. MVA induces the production of IFN and Flt3-L (FL), which results in the expansion of dendritic cells (DC) and enhanced resistance against viral infections. We report on the interplay among IFN, FL, and DC in the resistance against heterologous virus after injection of neonatal mice with MVA. The induction of serum FL was tested on day 2, and the expansion of DC was tested 1 wk after treatment with MVA. At this time point the resistance against infection with heterologous virus was also determined. After MVA treatment, serum FL was enhanced, and DC, including plasmacytoid cells in spleen, were increased in number. Mice that lacked functional IFN type I and II systems failed to increase both the concentration of FL and the number of DC. Treatment with MVA enhanced resistance against HSV-1 in wild-type animals 100-fold, but animals without a functional IFN system were not protected. Transfer of CD11c(+) cells from MVA-treated mice into naive animals protected against lethal infection with HSV-1. Thus, although the increased resistance could be largely attributed to the increase in activation of IFN-producing plasmacytoid cells, this, in turn, depends on a complex interplay between the DC and T cell systems involving both FL and IFNs.     

The role of dendritic cells in immune responses against vaginal infection by herpes simplex virus type 2

Herpes simplex virus type 2 is a leading cause of genital ulcers that affects more women than men worldwide. Recent evidence indicates that protective immunity can be generated by specialized dendritic cells in the female genital mucosa. This article aims to provide an overview of the effector immunity required for protection from genital herpes, and to discuss the mechanism by which specific subsets of dendritic cells mediate induction of adaptive immunity following genital infection with herpes simplex virus type 2 in vivo.     

Characterization of acute and latent herpes simplex virus infection of dorsal root ganglia in rats.

The characteristics of HSV type-1 infection following subcutaneous inoculation in the dorsum of one hind paw of Sprague-Dawley rats were studied to determine whether infection in rats might more closely parallel the infection in man than is seen in other animals. The serologic and virologic characteristics of acute and latent ganglion infection conformed to those of human infection. Immunohistochemical studies suggested that sensory ganglion infection arose via centripetal axonal migration of virus as is hypothesized in man. In rat, small type B neuronal cell bodies appeared central to the maintenance of latent infection and reactivation observed during cocultivation of lumbar ganglia. Acute and latent lumbar sensory ganglion infection in rats after subcutaneous hind paw injection of HSV-1 appears to be another suitable model of this infection in man.     

Encephalitis resulting from reactivation of latent herpes simplex virus in mice.

Herpes simplex virus (HSV) encephalitis was produced in mice from reactivation of latent virus. Two experimental models were used: the trigeminal model after corneal inoculation of HSV, and the hypoglossal model after tongue inoculation of HSV. In the trigeminal model, cyclophosphamide treatment induced reactivation of latent virus in ganglia but not in central nervous system tissue. Spread of the reactivated virus from ganglia to brain occurred only in mice deficient in anti-HSV antibody. In the hypoglossal model, sectioning of the hypoglossal nerve provoked chromatolysis in the corresponding central nervous system motor neurons and occasionally reactivated latent HSV in the brains of mice. These results suggest that HSV encephalitis can result from the spread of reactivated virus from ganglia to brain and also from in situ reactivation in brain.     

Mechanism of antibody-mediated protection against herpes simplex virus infection in athymic nude mice: requirement of Fc portion of antibody

Experiments were performed to investigate the resistance of the host due to antibody-mediated mechanisms to herpes simplex virus (HSV) infection. Transfer of hyperimmune anti-HSV mouse serum inhibited the development of skin lesions and prolonged the survival of lethally HSV-infected nude mice. Relatively high concentrations of antibody were required to achieve this protection. Antisera prepared in heterologous animals were also effective, while administration of anti-cowpox virus serum or interferon provided no protection. This type of protection is therefore due to specific antibody and cannot be attributed to interferon. In order to delineate the requirement for antibody in antibody-mediated protection, human gamma globulin preparations were transferred to lethally HSV-infected nude mice. Transfer of intact human gamma globulin (GG) was effective in controlling infection. S-sulfonation of GG did not diminish the protective ability. However, purified F(ab')2 did not have any protective action even when it was administered frequently to maintain serum neutralizing antibody titer. GG was effective in C5-deficient mice lethally infected with HSV. These results indicate that in vivo antibody-mediated protection to HSV infection requires the Fc region of the intact IgG molecule and suggest that antibody-dependent cell-mediated cytotoxicity may be operative in vivo.     

Protection by polyI:polyC against infection with herpes simplex virus in mice pretreated with Corynebacterium parvum

The effect of Corynebacterium parvum on the protection by polyinosinic-polycytidylic acid (polyI:polyC) against lethal infection with Herpes simplex virus type 1 (HSV) was studied in mice. Pretreatment with C. parvum resulted in prolonged survival times in all experiments. One third of the mice survived an infection with 100 LD50, whereas all mice died when treated with polyI:polyC alone. Increased protection was observed up to 6 weeks after pretreatment and only seen when both C. parvum and polyI:polyC were given at the same site of injection (intraperitoneally). Protection against HSV correlated with increased interferon (IFN) activities induced by polyI:polyC in the peritoneal cavity of C. parvum-pretreated mice. In these mice, natural killer cell activity of peritoneal exudate cells (PEC) was also augmented in response to polyI:polyC. Protection was markedly decreased by intraperitoneal injection of silica or of an antiserum against murine IFN. It appears that increased local levels of IFN presumably produced by macrophages in response to polyI:polyC in C. parvum-pretreated mice play the major role in the antiviral defence in our model and that activation of NK cells may be a secondary effect of IFN.     

The role of natural killer cells and interferon in resistance to acute infection of mice with herpes simplex virus type 1

The relative roles of interferon (IFN) and natural killer (NK) cells in herpes simplex virus type 1 (HSV-1) infection of mice were examined. Adoptive transfer of adult mouse leukocytes into 4- to 6-day-old suckling mice protected the recipients from HSV-1 infection, as judged by viral titers in the spleen 2 days postinfection. Protection was mediated by several classes of leukocytes, including those depleted of NK cell activity by antibody to asialo GM1 and those depleted of macrophages by size separation. Mice receiving these leukocytes produced significantly higher levels of IFN 6 hr postinfection (early IFN) than did HSV-1-infected mice not receiving donor leukocytes. Antibody to IFN, under conditions that blocked early but not late IFN synthesis, greatly enhanced HSV-1 synthesis in mice receiving leukocytes and completely removed the protective effect mediated by leukocytes. High doses of anti-asialo GM1 blocked both NK cell activity and early IFN production and resulted in high titers of HSV-1. This effect on virus synthesis was not seen if mice were given antibody 1 day postinfection. Lower doses of anti-asialo GM1, which still depleted NK cell activity but had no effect on early IFN production, did not enhance HSV-1 synthesis. Depletion of NK cell activity with a low dose of antibody had no effect on the reduced HSV-1 synthesis resulting from prophylactic IFN treatment or on the enhanced HSV-1 synthesis resulting from antibody to IFN treatment. Thus, resistance to acute HSV-1 infection in mice correlates with early IFN production but not with NK cell activity, suggesting that NK cells are not major mediators of natural resistance in this model and that the antiviral effect of IFN is not mediated by NK cells.     

Modulation of acute and latent herpes simplex virus infection in C57BL/6 mice by adoptive transfer of immune lymphocytes with cytolytic activity

The ability of highly lytic herpes simplex virus (HSV) cytolytic T lymphocytes to modulate the interaction between the murine host (adult C57BL/6 [H-2b] mice) and HSV type 1 Patton resulting in acute infection in the footpad and latent infection in the sensory lumbosacral dorsal root ganglia (L6, L5, L4, and L3) innervating the footpad was investigated. Results indicated that a critical threshold level of infectious HSV was required to establish infection. The adoptive transfer of cytolytic T lymphocytes derived from in vitro cultures after restimulation with HSV-infected, syngeneic stimulator cells exhibiting class I H-2-restricted, L3T4- Lyt-2+ HSV-specific cytolytic activity immediately before infection with a high dose of HSV reduced the levels of infectious HSV recovered from the footpad tissue during acute infection and the levels of latent HSV reactivated from the dorsal root ganglia to levels expected from mice infected with a low dose. Depletion of Lyt-2+ cells from the transferred population abrogated the protective ability, while depletion of L3T4+ cells had little effect. These results suggest that functionally lytic HSV-specific cytolytic T lymphocytes present at the time of HSV infection have the potential to participate in the control of the acute infection and in the subsequent establishment of latent infection.     

Cellular proteins expressed in herpes simplex virus transformed cells also accumulate on herpes simplex virus infection.

The cell proteins expressed in rat embryo cells transformed by herpes simplex virus (HSV) have been analysed by immunoprecipitation assays to determine those polypeptides which can be identified by immunoprecipitation with the sera of tumour-bearing animals and also with antisera to herpes simplex infected cells. Cell polypeptides commonly recognised by both these sera have been further characterised using a monoclonal antibody directed against a cellular polypeptide which accumulates on HSV-2 lytic infection. This monoclonal antibody recognises in HSV-transformed cells polypeptides of mol. wts. 90 000, 40 000 and 32 000. Further studies show that the accumulation of these polypeptides in HSV-transformed cells is not HSV specific but is a common feature of transformation or of cells which have been immortalised. We suggest that cellular polypeptides accumulating as a result of HSV infection may be of importance in the initiation of transformation by HSV, i.e., at the level of immortalisation of cells.     

Cutting edge: a NK complex-linked locus governs acute versus latent herpes simplex virus infection of neurons

Herpes simplex causes latent infections that periodically reactivate. Specific immunization attempts are failing to control herpes, prompting a fresh look at which host responses predominate. We report a NK complex-linked genetic locus, Rhs1, whose alleles influence the magnitude of experimental herpes simplex. Rhs1 provided rapid control of primary infection but caused a reciprocal increase in the number of latently infected neurons. Thus, in principle, establishment of latency is a consequence of efficient front line defense against herpesvirus infection. Based on conservation between human and mouse NK complexes, the data predict the presence of a human Rhs1 orthologue on chromosome 12p12-13.     

Vaccine protection against simian immunodeficiency virus by recombinant strains of herpes simplex virus

An effective vaccine for AIDS may require development of novel vectors capable of eliciting long-lasting immune responses. Here we report the development and use of replication-competent and replication-defective strains of recombinant herpes simplex virus (HSV) that express envelope and Nef antigens of simian immunodeficiency virus (SIV). The HSV recombinants induced antienvelope antibody responses that persisted at relatively stable levels for months after the last administration. Two of seven rhesus monkeys vaccinated with recombinant HSV were solidly protected, and another showed a sustained reduction in viral load following rectal challenge with pathogenic SIVmac239 at 22 weeks following the last vaccine administration. HSV vectors thus show great promise for being able to elicit persistent immune responses and to provide durable protection against AIDS.     

Protection of neonatal mice against herpes simplex virus infection: probable in vivo antibody-dependent cellular cytotoxicity

Infant mice are extremely susceptible to fatal Herpes simplex virus (HSV) infection. They are unable to produce antibody to HSV, and their leukocytes cannot mediate antibody-dependent cellular cytotoxicity (ADCC) to HSV-infected cells. In order to avoid H-2-dependent effector mechanisms and instead analyze possible in vivo ADCC, a murine model employing adoptive transfer of antibody and human leukocytes was developed. Administration of either human immune globulin or leukocytes i.p. from HSV immune or nonimmune humans could not protect infant C57BL/6 mice from fatal HSV infection. In contrast, a combination of a subneutralizing dilution of globulin and leukocytes from nonimmune or immune human donors, given one day before inoculation, was highly protective against lethal HSV infection. The cells involved included lymphocytes or monocyte-macrophages. At least 5 X 10(6) viable leukocytes (or 1 X 10(6) monocyte-macrophages) and immune serum globulin concentrations as low as 10(-8) were protective. Infected cell monolayer adsorption and DEAE column fractionation demonstrated that the protection by globulin was due to specific antiviral IgG antibody. Protection was n ot seen in animals receiving virus before immune transfer. Protection did not involve synergistic viral neutralization by antibody and cells, as shown by in vitro experiments. Animals receiving globulin and cells, unlike normal infant mice, had circulating antiviral antibody and peritoneal leukocytes able to mediate ADCC to HSV-infected cells. This is the first in vivo evidence for the role of human ADCC. This model also allows for the in vivo evaluation of the ability of cells from immunocompromised humans to curb viral infection.