Attenuation of natural killer cell functions by capsaicin through a direct and TRPV1-independent mechanism.

The assessment of the biological activity of capsaicin, the compound responsible for the spicy flavor of chili pepper, produced controversial results, showing either carcinogenicity or cancer prevention. The innate immune system plays a pivotal role in cancer pathology and prevention; yet, the effect of capsaicin on natural killer (NK) cells, which function in cancer surveillance, is unclear. This study found that capsaicin inhibited NK cell-mediated cytotoxicity and cytokine production (interferon-γ and tumor necrosis factor-α). Capsaicin impaired the cytotoxicity of NK cells, thereby inhibiting lysis of standard target cells and gastric cancer cells by modulating calcium mobilization in NK cells. Capsaicin also induced apoptosis in gastric cancer cells, but that effect required higher concentrations and longer exposure times than those required to trigger NK cell dysfunction. Furthermore, capsaicin inhibited the cytotoxicity of isolated NK cells and of an NK cell line, suggesting a direct effect on NK cells. Antagonists of transient receptor potential vanilloid subfamily member 1 (TRPV1), a cognate capsaicin receptor, or deficiency in TRPV1 expression failed to prevent the defects induced by capsaicin in NK cells expressing functional TRPV1. Thus, the mechanism of action of capsaicin on NK cells is largely independent of TRPV1. Taken together, capsaicin may have chemotherapeutic potential but may impair NK cell function, which plays a central role in tumor surveillance.

Antiviral effects of small interfering RNA simultaneously inducing RNA interference and type 1 interferon in coxsackievirus myocarditis.

Antiviral therapeutics are currently unavailable for treatment of coxsackievirus B3, which can cause life-threatening myocarditis. A modified small interfering RNA (siRNA) containing 5'-triphosphate, 3p-siRNA, was shown to induce RNA interference and interferon activation. We aimed to develop a potent antiviral treatment using CVB3-specific 3p-siRNA and to understand its underlying mechanisms. Virus-specific 3p-siRNA was superior to both conventional virus-specific siRNA with an empty hydroxyl group at the 5' end (OH-siRNA) and nonspecific 3p-siRNA in decreasing viral replication and subsequent cytotoxicity. A single administration of 3p-siRNA dramatically attenuated virus-associated pathological symptoms in mice with no signs of toxicity, and their body weights eventually reached the normal range. Myocardial inflammation and fibrosis were rare, and virus production was greatly reduced. A nonspecific 3p-siRNA showed relatively less protective effect under identical conditions, and a virus-specific OH-siRNA showed no protective effects. We confirmed that virus-specific 3p-siRNA simultaneously activated target-specific gene silencing and type I interferon signaling. We provide a clear proof of concept that coxsackievirus B3-specific 3p-siRNA has 2 distinct modes of action, which significantly enhance antiviral activities with minimal organ damage. This is the first direct demonstration of improved antiviral effects with an immunostimulatory virus-specific siRNA in coxsackievirus myocarditis, and this method could be applied to many virus-related diseases.

Characterization of infections of human leukocytes by non-polio enteroviruses.

To elucidate the detailed susceptibilities of leukocytes to clinically important non-polio enteroviruses (EVs), primary monocytes and various human leukocyte cell lines were infected with coxsackievirus A24 (CVA24), coxsackievirus B3 (CVB3), and enterovirus 70 (EV70). The permissiveness was then assessed by determining virus replication and resultant cytopathic effects. Different EVs varied markedly in their ability to infect leukocyte cell lines. CVB3 replicated effectively in leukocytes of B-cell, T-cell, and monocyte origin, CVA24 in leukocytes of B-cell and monocyte origin, and EV70 in leukocytes of monocyte origin. Primary monocytes, as well as monocyte-derived U-937 cells, were permissive to all three EVs. We observed a positive correlation between cytotoxicity and active virus replication, except in CVB3-infected monocytes. U-937 cells efficiently generated CVB3 progeny virus without severe cellular damage, including cell death. Moreover, infectivity on leukocytes was not absolutely associated with the availability of viral receptors. These findings suggest that the susceptibility of human leukocytes to non-polio EVs may be responsible for virus transport during the viremic phase, particularly to secondary target organs, and that active replication of CVB3 in all human leukocyte lineages leads to greater dissemination, in agreement with the ability of CVB to cause systemic diseases.

An ex vivo model of coxsackievirus infection using multilayered human conjunctival epithelial cells.

BACKGROUND: The purpose of this study was to establish an ex vivo model of coxsackievirus infection since there seems to be no suitable disease model currently. METHODS: Human conjunctival epithelial cells (HCECs) were cultured for 2 weeks in a serum-free air-liquid interface system to produce a multilayered structure. The cells were infected with coxsackievirus A24 (CVA24). Histological changes were investigated by staining the cells with H&E and DAPI, and apoptosis was evaluated using the TUNEL technique. Virus replication was measured in HeLa cells infected with viral progeny from multilayered HCECs, after 1 and 3 days, using the TCID(50) method. RESULTS: Cultured HCECs formed multiple layers. The cells showed characteristics of conjunctival epithelial cells and goblet cells, being immunohistochemically positive for CK19 and MUC5AC, respectively. CVA24 replicated readily in cultured multilayered HCECs. A mild cytopathic effect was noted 1 day after viral inoculation. Cell damage was extensive at 3 days. TUNEL imaging confirmed that the cytopathology was attributable to apoptosis. The TCID(50) data from HeLa cells indicated that the virus was actively replicating at both 1 and 3 days after inoculation. CONCLUSIONS: This novel infection model may be useful in investigating the pathogenesis of acute hemorrhagic conjunctivitis and the effectiveness of antiviral treatments.

Gene therapeutic approach for inhibiting hepatitis C virus replication using a recombinant protein that controls interferon expression.

The hepatitis C virus (HCV) is a continuing threat to public health. The systemic administration of interferon alpha with ribavirin is the only currently approved treatment. However, this treatment is associated with a wide spectrum of systemic side effects that limits its effectiveness; thus, there is an urgent need for new treatment modalities. In this study, we describe a novel anti-HCV strategy employing a recombinant transcription factor that we have engineered in such a way that NS3/4a viral protease controls its intracellular localization, thereby restoring interferon secretion specifically in cells infected with HCV. Proof-of-concept experiments validated the strategy, showing that the recombinant transcription factor was triggered to stimulate interferon promoter by NS3/4A and remained inactive in cells without NS3/4a. Using an adenovirus-associated viral vector delivery system, we found that the recombinant transcription factor inhibited HCV replication effectively in vitro in cultured cells.

A novel program to design siRNAs simultaneously effective to highly variable virus genomes.

A major concern of antiviral therapy using small interfering RNAs (siRNAs) targeting RNA viral genome is high sequence diversity and mutation rate due to genetic instability. To overcome this problem, it is indispensable to design siRNAs targeting highly conserved regions. We thus designed CAPSID (Convenient Application Program for siRNA Design), a novel bioinformatics program to identify siRNAs targeting highly conserved regions within RNA viral genomes. From a set of input RNAs of diverse sequences, CAPSID rapidly searches conserved patterns and suggests highly potent siRNA candidates in a hierarchical manner. To validate the usefulness of this novel program, we investigated the antiviral potency of universal siRNA for various Human enterovirus B (HEB) serotypes. Assessment of antiviral efficacy using Hela cells, clearly demonstrates that HEB-specific siRNAs exhibit protective effects against all HEBs examined. These findings strongly indicate that CAPSID can be applied to select universal antiviral siRNAs against highly divergent viral genomes.

Antiviral potency of a siRNA targeting a conserved region of coxsackievirus A24.

Coxsackievirus A24 (CVA24) is responsible for acute hemorrhagic conjunctivitis, a highly contagious eye disease for which no prevention or treatment is currently available. We thus assessed the antiviral potential of a small interfering RNA (siRNA) targeting CVA24. HeLa cells with or without four different siRNAs complementary to 2C or 3D genome region, were challenged with various CVA24s. Among several siRNAs, a siRNA targeting the highly conserved genome region called the cis-acting replication element (CVA24-CRE), was the only siRNA that decreased virus replication and subsequent cytotoxicity by both CVA24 variant and clinical isolates. Furthermore, CVA24-CRE had effective antiviral activity against CVA24 in primary human conjunctival cells. In addition, CVA24-CRE was highly resistant to the emergence of genetically altered escape mutants. Collectively, the present study provides evidence that CVA24-CRE targeting a conserved viral genome region had universal, prolonged anti-CVA24 activity. This siRNA may thus hold a potential to act clinically as a novel anti-CVA24 agent.

Mutation variants generated from nonvirulent coxsackievirus B3 acquire virulence phenotypes by active virus replication.

OBJECTIVE: To understand coxsackievirus B3 (CVB3) virulence at the molecular level. METHOD: A mutation library was generated from noncardiovirulent CVB3/0. Highly virulent mutation variants were recovered and characterized both phenotypically and genotypically. RESULTS: The variants consistently caused destruction of multiple tissues together with active virus production and induced severe mortality in vivo. The extent of infectious virus generation was directly correlated with that of histopathological aberration. Genotypic analysis of the entire genome indicated that the virulent viruses encode nucleotide substitutions in the 5'-nontranslated region, which have previously been identified in other virulent CVB3s. CONCLUSION: The present study provides evidence that particular nucleotide substitutions in the 5'-nontranslated region of nonvirulent CVB3 can lead to active virus replication, which is sufficient to induce virulence.

Contributions of 3'-overhang to the dissociation of small interfering RNAs from the PAZ domain: molecular dynamics simulation study.

RNA interference (RNAi) is a 'knock-down' reaction to reduce expression of a specific gene through highly regulated, enzyme-mediated processes. Small interfering RNAs (siRNAs) are RNA molecules that play an effector role in RNAi and can bind the PAZ domains present in Dicer and RISC. We investigated the interaction between the PAZ domain and the siRNA-like duplexes through dissociation molecular dynamics (DMD) simulations. Specifically, we focused on the response of the PAZ domain to various 3'-overhang structures of the siRNA-like duplexes. We found that the siRNA-like duplex with the 3' UU-overhang made relatively more stable complex with the PAZ domain compared to those with 3' CC-, AA-, and GG-overhangs. The siRNA-like duplex with UU-overhang was easily dissociated from the PAZ domain once the structural stability of the complex is impaired. Interestingly, the 3' UU-overhang spent the least time at the periphery region of the binding pocket during the dissociation process, which can be mainly attributable to UU-overhang's smallest number of hydrogen bonds.

Oncolysis of human gastric cancers by an E1B 55 kDa-deleted YKL-1 adenovirus.

Advanced gastric cancer cannot be treated with surgery or conventional cancer therapy, which has prompted a search for new therapeutic modalities. Previously, we and other groups showed that E1B 55 kDa-deleted recombinant adenoviruses, such as YKL-1, effectively replicate and induce cytotoxicity in p53-deficient cancer cells while sparing normal cells. Here, we investigated selective YKL-1 replication and resultant cytolysis in human gastric cancer cells. The cytopathic effects were obvious in all five gastric cancer cell lines we examined. Evaluation of p53 expression indicated that only the AGS cell line retained functionally normal p53. Nevertheless, AGS was 10-fold more sensitive to YKL-1 than the other cell lines. Transmission electron microscopy showed typical morphological alterations along with efficient replication of YKL-1 in AGS cells. Therefore, YKL-1 induces preferential cytotoxic effects in human gastric cancer cells in a p53-independent manner, making YKL-1 a promising therapeutic agent for human gastric cancers.

Construction of a vector generating both siRNA and a fluorescent reporter: a siRNA study in cultured neurons.

RNA interference is an important tool for gene silencing. However, its application to primary cultured cells has been limited by low transfection efficiencies. In this work we developed a vector which encodes both siRNA and red fluorescent protein. Using this vector we could markedly suppress green fluorescent protein (GFP) and bim an endogenous gene. Primary cultured cortical neurons transfected with siRNA against doublecortin showed that doublecortin expression was significantly inhibited in nearly all the transfected neurons. This vector identifies the transfected cells and should be useful for loss-of-gene function studies in neurons.

Differential amplifying RT-PCR: a novel RT-PCR method to differentiate mRNA from its DNA lacking intron.

A major problem with reverse transcription-polymerase chain reaction (RT-PCR) is that the products amplified from RNA and DNA are not distinguishable. The use of a primer set targeted for an intron-containing sequence or RNA extract without contaminating DNA has been established to overcome this problem. However, an intron sequence does not always exist in the target region and complete removal of DNA during RNA extraction is not practical. For these reasons, we developed differential amplifying RT-PCR (DART-PCR) based on differences in reaction temperatures between RT and PCR, as well as in architectures between RNA and DNA. DART-PCR was designed to differentiate products amplified from RNA and DNA regardless of the presence of introns. DART-PCR can be readily applied for diagnosis of active infection of human cytomegalovirus by detection of glycoprotein B mRNA, which gene lacks introns. Other advantages of DART-PCR were as follows: there is no need for separation of RNA from DNA, simultaneous/differential detection in a single tube and possibility of determination of relative amounts of RNA and DNA.

Coxsackievirus B4-induced neuronal apoptosis in rat cortical cultures.

Enterovirus infections of the central nervous system (CNS) are common and important causes of morbidity in immunocompromised children and adults. In this study we identify and characterize coxsackievirus B4-induced neuronal death. To investigate the CNS pathophysiology resulting from this viral infection, cultured rat neurons were infected with coxsackievirus B4 (CVB4) and nuclear morphology, phosphatidylserine (PS) externalization, and the effects of Actinomycin D or cycloheximide (CHX) were examined. CVB4 induced neuronal cell death within 24 h while PS externalization was apparent in cell bodies 16 h after CVB4 infection. Actinomycin D or CHX significantly reduced CVB4 induced-neuronal cell death in a dose-dependent manner. Pretreatment with CHX or actinomycin D also inhibited nuclear condensation, which occurred after CVB4 infection. However, the changes were relatively unresponsive to zVAD-fmk. These results suggest that CVB4 induces CHX- and actinomycin D-sensitive, but zVAD-fmk-insensitive neuronal apoptosis.

Analysis of the production efficiency and titration of various recombinant adeno-associated viruses.

Recombinant adeno-associated virus type 2 (rAAV2) viral vector, a non-pathogenic human parvovirus, has recently emerged as a gene transfer vehicle for cancer gene therapy. To utilize rAAV2 properly and safely while carrying out preclinical and clinical studies, it is crucial to exactly titer the virus. We therefore compared biological infectious rAAV2 titers with physical titers of rAAV2 vectors encoding various transgenes with different sized viral genomes. Biological rAAV2 infectivity was assayed by measuring the number of virus particles able to transduce Hela cells using several detection methods, including X-gal staining and immunocytostaining. Physical titers of rAAV2 were determined using a commercially available rAAV2 particle-specific enzyme-linked immunosorbent assay. We found that total rAAV2 particle production was consistent within the limited size variations of the rAAV2 genome, regardless of the difference in transgenes. In contrast, the infectious titer of rAAV2 differed greatly, even for the same viruses, due to variation in the sensitivity of the relevant assays. Thus, the results suggest that both infectious virus titer and total virus particle should be precisely measured for rAAV2 vector utilized in each study.

Detection of enterovirus, cytomegalovirus, and Chlamydia pneumoniae in atheromas.

To investigate the presence of infectious agents in human atherosclerotic arterial tissues. Atherosclerotic plaques were removed from 128 patients undergoing carotid endarterectomy or other bypass procedures for occlusive disease, and from twenty normal arterial wall samples, obtained from transplant donors with no history of diabetes, hypertension, smoking, or hyperlipidemia. Using the polymerase chain reaction (PCR) or reverse transcription-PCR, these samples were analyzed for the presence of Chlamydia pneumoniae, cytomegalovirus, enterovirus, adenovirus, herpes simplex viruses types 1 and 2, and Epstein-Barr virus. The amplicons were then sequenced, and phylogenetic analyses were performed. Enteroviral RNA was found in 22 of 128 atherosclerotic vascular lesions (17.2%), and C. pneumoniae and cytomegalovirus were each found in 2 samples (1.6%). In contrast, adenovirus, herpes simplex viruses, and Epstein-Barr virus were not identified in any of the atherosclerotic samples. Enterovirus was detected in 6/24 (25.0%) aortas, 7/33 (21.2%) carotid arteries, 6/40 (15.0%) femoral arteries, and 3/31 (9.7%) radial arteries of patients with chronic renal failure. There were no infectious agents detected in any of the control specimens. Using phylogenetic analysis, the enterovirus isolates were clustered into 3 groups, arranged as echovirus 9 and coxsackieviruses B1 and B3. Enteroviral RNA was detected in 17.2% of atherosclerotic plaques, but was not observed in any of the control specimens. This suggests a connection between enteroviral infection and atherosclerosis. These findings differ from those of other studies, which found more frequent incidence of C. pneumoniae and cytomegalovirus infection in atherosclerotic plaques.

Antiviral protection against enterovirus 71 mediated by autophagy induction following FLICE-inhibitory protein inactivation.

Even with the recent awareness of enterovirus 71 (EV71) as a major public health issue, there are no preventive or therapeutic agents that are effective against EV71 infection. Although FLICE-like inhibitory protein (FLIP) has been identified as a factor that modulates virus pathogenesis, there are no reports regarding its effects on EV71 infection. The aim of the present study was to identify whether FLIP influences EV71 pathogenesis and to understand the underlying mechanisms. Virus replication was markedly reduced in MRC5 cells preincubated with anti-FLIP peptides, and infected cells were rescued from the cytopathic effects of the virus. The anti-FLIP peptides induced autophagy by disrupting intrinsic FLIP functions. The antiviral activity of these peptides was reduced when autophagy was inhibited by treatment with siRNA targeted to beclin-1. Thus, the present study provides evidence that anti-FLIP peptides induce autophagy by inactivating cFLIP, and that this is associated with antiviral effects against EV71.

An antiviral small-interfering RNA simultaneously effective against the most prevalent enteroviruses causing acute hemorrhagic conjunctivitis.

PURPOSE: Acute hemorrhagic conjunctivitis (AHC), a highly contagious eye disease, is caused primarily by either enterovirus 70 (EV70) or coxsackievirus A24 (CVA24) infection. Yet methods to prevent or cure AHC are not available. Recent evidence has shown that small-interfering RNAs (siRNAs), mediators of posttranscriptional gene knockdown, can act as effective antiviral agents. Thus, the authors attempted to develop a novel siRNA-based anti-AHC agent effective against both EV70 and CVA24. METHODS: Concurrent screening of the entire viral genome sequences of EV70 and CVA24 using the CAPSID program identified five different siRNA candidates complementary to genome regions of both viruses. The antiviral potentials of these siRNAs were assessed by treating MRC5 and primary human conjunctival cells with the siRNAs and following this with viral challenge. RESULTS: Among the five siRNAs, AHCe-3D-3 siRNA showed excellent cytoprotective effects and dramatic decreases in virus replication and virus protein synthesis. This siRNA, targeting the virus polymerase 3D gene, also induced similar antiviral effects in primary human conjunctival cells. CONCLUSIONS: These findings strongly suggest that the AHCe-3D-3 siRNA, homologous to two different AHC-associated enteroviruses, can provide equivalent antiviral activities against both AHC-causing enteroviruses. Such an siRNA may be developed as a clinically valuable AHC control agent.

High frequency of gross deletions in 5' LTR/gag and nef genes in patients infected with CRF02_AG of HIV type 1 who survived for over 20 years: an association with Korean red ginseng.

Abstract We have shown that Korean red ginseng (KRG) intake is associated with gross deletions in the 5' LTR/gag (gDeltaLTR/gag) and nef genes (gDeltanef) of patients infected with subtype B of HIV-1. Here, we investigated these effects in three long-term survivors (LTSs) of subtype CRF02_AG of HIV-1. The three LTSs were diagnosed with HIV in 1987, 1988, and 1989, and have been treated with KRG for 7-15 years. Thirty-two samples of peripheral blood mononuclear cells were obtained from the subjects and used to amplify the 5' LTR/gag and nef genes via nested PCR. We obtained 88 amplicons in 5' LTR/gag and 128 amplicons in nef. The frequency of gDeltaLTR/gag was significantly higher (37.5%) in three LTSs than in control patients (8.6%, p < 0.01). Eight amplicons (9.5%) contained premature stop codon(s) in the gDeltaLTR/gag in three LTSs. Fourteen of the 128 nef amplicons (10.9%) contained the gDeltanef, which was present in only two (7.7%) of the 26 amplicons from control subjects. Interestingly, gDeltanef was detected 7 years after the reinitiation of KRG intake in an LTS and, coincidently, CD4 T cell counts and CD4/CD8 ratios rapidly increased. These data indicate that long-term intake of KRG has the therapeutic potential to induce gross deletions in HIV-1.

Primary neurons become less susceptible to coxsackievirus B5 following maturation: the correlation with the decreased level of CAR expression on cell surface.

Coxsackievirus B (CVB) is one of the major pathogens of aseptic meningitis and meningioencephalitis, particularly in newborn infants. To analyze the influence of neural maturation on susceptibility to CVB infection, we prepared immature and mature neurons from 16-day-old BALB/c embryonic cortex. In contrast to immature neurons, mature neurons were less susceptible to CVB5 infection, as indicated by the decrease of cytopathic features. In mature neurons, progeny virus production was significantly hindered, and virus capsid protein VP1 synthesis and virus genome amplification were concomitantly reduced. In addition, the expression of coxsackievirus and adenovirus receptor (CAR), the major receptor of CVB5, was down-regulated in mature neurons. The antibody treatment specific to CAR significantly attenuated CVB5 susceptibility of immature neurons. These findings demonstrate that mature neurons become less susceptible to CVB by the decrease of CAR level. Thus, the data strongly support the idea that the level of virus receptor in neurons is one of the crucial determinants in the age-dependency of CVB virulence in central nervous system.

Universal and mutation-resistant anti-enteroviral activity: potency of small interfering RNA complementary to the conserved cis-acting replication element within the enterovirus coding region.

The promising potential of RNA interference-based antiviral therapies has been well established. However, the antiviral efficacy is largely limited by genomic diversity and genetic instability of various viruses, including human enterovirus B (HEB). In this work, the first evidence supporting the anti-HEB activity of the small interfering RNA (siRNA) targeting the highly conserved cis-acting replication element (CRE) within virus coding region 2C is presented. HeLa cells pre-treated with siRNA complementary to the conserved sequence of the loop region of CRE(2C) were effectively rescued from the cytopathic effects of HEBs. Downregulation of virus replication and attenuation of cytotoxicity were consistently observed in various reference strains and clinical isolates. Cells treated with this siRNA were resistant to the emergence of viable escape mutants and showed sustained antiviral ability. Collectively, the data suggest that the siRNA based on the disordered structure within the highly conserved cis-acting coding region has potential as a universal, persistent anti-HEB agent. The same strategy can be successfully applied to the development of siRNA with consistent antiviral effects in other virus groups possessing similar RNA elements.