Suppression of Herpes Simplex Virus Infection by Phosphonoacetic Acid

Disodium phosphonoacetate when administered orally or topically to mice experimentally infected with herpes simplex virus was able to significantly reduce the mortality associated with the agent. In addition, this compound was able to reduce herpesvirus lesions on the corneas of infected rabbits.     

Interleukin-18 Protects Mice against Acute Herpes Simplex Virus Type 1 Infection

We examined the effects of interleukin-18 (IL-18) in a mouse model of acute intraperitoneal infection with herpes simplex virus type 1 (HSV-1). Four days of treatment with IL-18 (from 2 days before infection to 1 day after infection) improved the survival rate of BALB/c, BALB/c nude, and BALB/c SCID mice, suggesting innate immunity. One day after infection, HSV-1 titers were higher in the peritoneal washing fluid of control BALB/c mice than in that of IL-18-treated mice. A genetic deficiency of gamma interferon (IFN-γ), however, diminished the survival rate and the inhibition of HSV-1 growth at the injection site in the mice. Anti-asialo GM1 treatment had no influence on the protective effect of IL-18 in infected mice. IL-18 augmented IFN-γ release in vitro by peritoneal cells from uninfected mice, while no appreciable IFN-γ production was found in uninfected mice administered IL-18. Although IFN-γ has the ability to induce nitric oxide (NO) production by various types of cells, administration of the NO synthase inhibitor N^G-monomethyl-l-arginine resulted in superficial loss of the improved survival, but there was no influence on the inhibition of HSV-1 replication at the injection site in IL-18-treated mice. Based on these results, we propose that IFN-γ produced before HSV-1 infection plays a key role as one of the IL-18-promoted protection mechanisms and that neither NK cells nor NO plays this role.Interleukin-18 (IL-18) is a newly cloned murine and human cytokine (28, 36) previously called gamma interferon (IFN-γ)-inducing factor. It is synthesized by activated macrophages and has a structural relationship to the IL-1 family (5). Precursor IL-18 is processed by IL-1β-converting enzyme and is cleaved into mature IL-18 (11). IL-18 induces IFN-γ production by murine helper T cells and NK cells and stimulates T-cell proliferation and NK activation (18, 28). Moreover, IL-18 augments the Fas ligand-mediated cytotoxic activity of the Th1 clone and the NK cell clone (8, 35). Thus, IL-18 shares some biological activities with IL-12, although no significant homology between the two cytokines has been detected at the protein level (34). Furthermore, treatment with IL-12 and IL-18 has a synergistic effect on IFN-γ production (2, 14, 38, 40).According to a review by Nash (27), not only nonspecific or innate immunity, such as that from IFN, NK cells, or macrophages, but also specific or adaptive immunity is important in protection against herpesvirus infection. Herpes simplex virus is known to be an IFN inducer (13). IFN is produced at an early stage of virus infection. In addition to the direct inhibition of viral replication, it enhances the efficiency of the adaptive (specific) immune response by stimulating increased expression of major histocompatibility complex class I and II or by activating macrophages and NK cells. In protection from infection by herpesviruses, especially cytomegalovirus, NK cells have been major effector cells because of the correlation of increased susceptibility to cytomegalovirus infection with the absence or reduction of NK cell activity, as seen in Chediak-Higashi syndrome patients and beige mice (27). Upon target cell disruption, NK and cytotoxic T cells share not only the perforin but also the Fas ligand as an effector molecule (4, 20, 37). Recently, nitric oxide (NO) was reported to be involved in host defense against bacteria, fungi, parasites, and viruses (10, 16, 19, 39). NO produced by herpes simplex virus type 1 (HSV-1)-infected macrophages is reported to inhibit viral replication (7). CD4⁺ T cells, macrophages, IFN-γ, and tumor necrosis factor (TNF) are important in adaptive immunity against HSV-1 infection. The Th2 response exacerbates HSV-1-induced disease (25).Recently a protective role of IL-18 was reported in microbial infections (6, 17). Here, we demonstrate that IL-18 treatment protects mice from acute viral infection via both IFN-γ-dependent and -independent pathways. Although IFN-γ has the ability to induce NO production by a variety of cells, including macrophages (9), it is not likely to be important, at least in the inhibition of HSV-1 proliferation at the injection site of IL-18-treated mice. Furthermore, the protective effect of IL-18 on HSV-1 infection also does not seem to require complete NK cell activity in our experimental system, whereas our colleagues have already reported that deletion of NK cells by administration of anti-asialo GM1 antibody resulted in lowering of the improved survival rate of tumor-bearing mice treated with IL-18 (23).     

Early Events in Herpes Simplex Virus Infection: a Radioautographic Study

The early events in herpes simplex virus infection were studied by means of radio-autography. The virus was rapidly taken up by the host cells and uncoated. Viral deoxyribonucleic acid (DNA) reached the nuclear sites of replication in 15 to 30 min after infection. The viral DNA occasionally associated with chromosomes or condensed chromatin but was more frequently found to be randomly distributed. Viral progeny appeared 3 hr after infection. These particles did not show any particular spatial relationship to the parental DNA. The morphological latent period lasted 2.5 hr.     

灵芝多糖GLP的抗疱疹病毒作用机理

从灵芝菌丝体中分离得到的多糖GLP具有抑制单纯疱疹病毒Ⅰ型感染的作用,并对GLP抑制疱疹病毒复制的作用机制进行了初步探讨.GLP对Vero细胞的CC50值大于2 000μg/mL,GLP在疱疹病毒感染细胞前、感染后和病毒感染细胞时加入到细胞悬液中的EC50分别为4.6、50和17μg/mL;而如果将GLP与细胞共同孵育后再用病毒去感染,其EC50为11μg/mL.同时,GLP抑制病毒感染的选择指数分别为435、40、118和182.如果在病毒感染细胞后加入GLP,在病毒的生物大分子的合成完成后而子代病毒粒子还未释放出来前去掉GLP,这时GLP对病毒感染就没有抑制作用.定量PCR试验进一步证明GLP发挥抑制疱疹病毒感染作用是通过阻断病毒感染细胞早期与细胞表明蛋白的吸附来实现的.     

灵芝多糖GLP的抗疱疹病毒作用机理

从灵芝菌丝体中分离得到的多糖GLP具有抑制单纯疱疹病毒I型感染的作用,并对GLP抑制疱疹病毒复制的作用机制进行了初步探讨。GLP对Vero细胞的CC50值大于2000μg/mL,GLP在疱疹病毒感染细胞前、感染后和病毒感染细胞时加入到细胞悬液中的EC50分别为4.6、50和17μg/mL;而如果将GLP与细胞共同孵育后再用病毒去感染,其EC50为11μg/mL。同时,GLP抑制病毒感染的选择指数分别为435、40、118和182。如果在病毒感染细胞后加入GLP,在病毒的生物大分子的合成完成后而子代病毒粒子还未释放出来前去掉GLP,这时GLP对病毒感染就没有抑制作用。定量PCR试验进一步证明GLP发挥抑制疱疹病毒感染作用是通过阻断病毒感染细胞早期与细胞表明蛋白的吸附来实现的。     

Houttuynia cordata Targets the Beginning Stage of Herpes Simplex Virus Infection

Herpes simplex virus (HSV), a common latent virus in humans, causes certain severe diseases. Extensive use of acyclovir (ACV) results in the development of drug-resistant HSV strains, hence, there is an urgent need to develop new drugs to treat HSV infection. Houttuynia cordata (H. cordata), a natural herbal medicine, has been reported to exhibit anti-HSV effects which is partly NF-κB-dependent. However, the molecular mechanisms by which H. cordata inhibits HSV infection are not elucidated thoroughly. Here, we report that H. cordata water extracts (HCWEs) inhibit the infection of HSV-1, HSV-2, and acyclovir-resistant HSV-1 mainly via blocking viral binding and penetration in the beginning of infection. HCWEs also suppress HSV replication. Furthermore, HCWEs attenuate the first-wave of NF-κB activation, which is essential for viral gene expressions. Further analysis of six compounds in HCWEs revealed that quercetin and isoquercitrin inhibit NF-κB activation and additionally, quercetin also has an inhibitory effect on viral entry. These results indicate that HCWEs can inhibit HSV infection through multiple mechanisms and could be a potential lead for development of new drugs for treating HSV.     

Ex Vivo Organotypic Corneal Model of Acute Epithelial Herpes Simplex Virus Type I Infection

Herpes keratitis is one of the most severe pathologies associated with the herpes simplex virus-type 1 (HSV-1). Herpes keratitis is currently the leading cause of both cornea-derived and infection-associated blindness in the developed world. Typical presentation of herpes keratitis includes infection of the corneal epithelium and sometimes the deeper corneal stroma and endothelium, leading to such permanent corneal pathologies as scarring, thinning, and opacity ¹.Corneal HSV-1 infection is traditionally studied in two types of experimental models. The in vitro model, in which cultured monolayers of corneal epithelial cells are infected in a Petri dish, offers simplicity, high level of replicability, fast experiments, and relatively low costs. On the other hand, the in vivo model, in which animals such as rabbits or mice are inoculated directly in the cornea, offers a highly sophisticated physiological system, but has higher costs, longer experiments, necessary animal care, and a greater degree of variability. In this video article, we provide a detailed demonstration of a new ex vivo model of corneal epithelial HSV-1 infection, which combines the strengths of both the in vitro and the in vivo models. The ex vivo model utilizes intact corneas organotypically maintained in culture and infected with HSV-1. The use of the ex vivo model allows for highly physiologically-based conclusions, yet it is rather inexpensive and requires time commitment comparable to that of the in vitro model.     

Inactivation of Herpes Simplex Virus by Concanavalin A

The infectivity of herpes simplex virus type 1 (HSV-1) was inactivated after treatment with either concanavalin A (ConA) or periodate. Phytohemagglutinin, wheat germ agglutinin, pokeweed mitogen, and neuraminidase failed to inactivate the virus. The effect of ConA could be specifically inhibited or reversed by the addition of α-methyl-d-glucoside or α-methyl-d-mannoside. Evidence was obtained that HSV-1 inactivated by ConA could adsorb to host cells. Viral aggregation was not a major mechanism in the inactivation of HSV-1 by ConA. Under the experimental conditions employed, inactivation of HSV-1 was faster by ConA than by antiserum and less temperature dependent. A ConA-resistant fraction was detected which appeared to adsorb less quickly than untreated virus, and penetration of ConA-resistant fraction was strikingly slow. The presence of aggregates in the virus preparation did not appear to account for the ConA-resistant fraction. Inactivation of viral infectivity by ConA was obtained only with enveloped viruses, since HSV-1, HSV-2, pseudorabies, and vesicular stomatitis virus were inactivated and vaccinia and echovirus type 6 were not.     

Ex Vivo Infection of Murine Epidermis with Herpes Simplex Virus Type 1

To enter its human host, herpes simplex virus type 1 (HSV-1) must overcome the barrier of mucosal surfaces, skin, or cornea. HSV-1 targets keratinocytes during initial entry and establishes a primary infection in the epithelium, which is followed by latent infection of neurons. After reactivation, viruses can become evident at mucocutaneous sites that appear as skin vesicles or mucosal ulcers. How HSV-1 invades skin or mucosa and reaches its receptors is poorly understood. To investigate the invasion route of HSV-1 into epidermal tissue at the cellular level, we established an ex vivo infection model of murine epidermis, which represents the site of primary and recurrent infection in skin. The assay includes the preparation of murine skin. The epidermis is separated from the dermis by dispase II treatment. After floating the epidermal sheets on virus-containing medium, the tissue is fixed and infection can be visualized at various times postinfection by staining infected cells with an antibody against the HSV-1 immediate early protein ICP0. ICP0-expressing cells can be observed in the basal keratinocyte layer already at 1.5 hr postinfection. With longer infection times, infected cells are detected in suprabasal layers, indicating that infection is not restricted to the basal keratinocytes, but the virus spreads to other layers in the tissue. Using epidermal sheets of various mouse models, the infection protocol allows determining the involvement of cellular components that contribute to HSV-1 invasion into tissue. In addition, the assay is suitable to test inhibitors in tissue that interfere with the initial entry steps, cell-to-cell spread and virus production. Here, we describe the ex vivo infection protocol in detail and present our results using nectin-1- or HVEM-deficient mice.     

单纯疱疹病毒的PCR直接基因分型

本文利用ＰＣＲ技术建立一种对ＨＳＶ直接基因分型的方法。在ＨＳＶ－Ⅰ、Ⅱ两型的ＤＮＡ多聚酶基因上设计了一条两型共同的上游引物（ＨＤＰ－Ｂ）和两条型特异的下游引物（ＨＤＰ－１、ＨＤＰ－２）。三条引物共同组成一个扩增反应体系,在ＨＳＶ－Ⅰ产生５４３ｂｐ条带,ＨＳＶ－Ⅱ产生３７２ｂｐ条带,据此在基因水平上对ＨＳＶ进行分型。５株不同来源的ＨＳＶ（２株Ⅰ型,３株Ⅱ型）分型结果与病毒分离及血清学方法完全一致。该反应体系与其它来源的ＤＮＡ不产生特异反应,敏感性可达１ｆｇ。应用该法对１５１份临床可疑ＨＳＶ感染的标本进行检测并分型,结果与免疫学方法完全一致。     

Latent Herpes Simplex Virus from Trigeminal Ganglia of Rabbits with Recurrent Eye Infection

LATENTLY infected sensory ganglia have been thought to be the source of virus for various clinical manifestations of recurrent herpetic disease in man^1,2. In direct support of this concept, we recently showed that herpes simplex virus can induce a latent infection in the spinal ganglia of mice³. This murine infection has not, however, been shown to be accompanied by recurrent disease. Recurrent herpetic eye infection can be produced in the rabbit⁴. If sensory ganglia are involved in recurrent disease, then trigeminal ganglia from rabbits undergoing such recurrent infection would be expected to harbour latent virus. We now report that herpes simplex virus does indeed induce latent infection in trigeminal ganglia of rabbits presenting recurrent eye infection. As in the experiments with mice, infectious virus could not be recovered directly; it was only found when ganglia were established as organ cultures in vitro.