Involvement of PKR and RNase L in translational control and induction of apoptosis after Hepatitis C polyprotein expression from a vaccinia virus recombinant

Removal of the C6 Vaccinia Virus Interferon-β Inhibitor in the Hepatitis C Vaccine Candidate MVA-HCV Elicited in Mice High Immunogenicity in Spite of Reduced Host Gene Expression

Hepatitis C virus (HCV) represents a major global health problem for which a vaccine is not available. Modified vaccinia virus Ankara (MVA)-HCV is a unique HCV vaccine candidate based in the modified vaccinia virus Ankara (MVA) vector expressing the nearly full-length genome of HCV genotype 1a that elicits CD8⁺ T-cell responses in mice. With the aim to improve the immune response of MVA-HCV and because of the importance of interferon (IFN) in HCV infection, we deleted in MVA-HCV the vaccinia virus (VACV) C6L gene, encoding an inhibitor of IFN-β that prevents activation of the interferon regulatory factors 3 and 7 (IRF3 and IRF7). The resulting vaccine candidate (MVA-HCV ΔC6L) expresses all HCV antigens and deletion of C6L had no effect on viral growth in permissive chicken cells. In human monocyte-derived dendritic cells, infection with MVA-HCV ΔC6L triggered severe down-regulation of IFN-β, IFN-β-induced genes, and cytokines in a manner similar to MVA-HCV, as defined by real-time polymerase chain reaction (PCR) and microarray analysis. In infected mice, both vectors had a similar profile of recruited immune cells and induced comparable levels of adaptive and memory HCV-specific CD8⁺ T-cells, mainly against p7 + NS2 and NS3 HCV proteins, with a T cell effector memory (TEM) phenotype. Furthermore, antibodies against E2 were also induced. Overall, our findings showed that while these vectors had a profound inhibitory effect on gene expression of the host, they strongly elicited CD8⁺ T cell and humoral responses against HCV antigens and to the virus vector. These observations add support to the consideration of these vectors as potential vaccine candidates against HCV.

High, broad, polyfunctional, and durable T cell immune responses induced in mice by a novel hepatitis C virus (HCV) vaccine candidate (MVA-HCV) based on modified vaccinia virus Ankara expressing the nearly full-length HCV genome

A major goal in the control of hepatitis C infection is the development of a vaccine. Here, we have developed a novel HCV vaccine candidate based on the highly attenuated poxvirus vector MVA (referred to as MVA-HCV) expressing the nearly full-length (7.9-kbp) HCV sequence, with the aim to target almost all of the T and B cell determinants described for HCV. In infected cells, MVA-HCV produces a polyprotein that is subsequently processed into the structural and nonstructural HCV proteins, triggering the cytoplasmic accumulation of dense membrane aggregates. In both C57BL/6 and transgenic HLA-A2-vaccinated mice, MVA-HCV induced high, broad, polyfunctional, and long-lasting HCV-specific T cell immune responses. The vaccine-induced T cell response was mainly mediated by CD8 T cells; however, although lower in magnitude, the CD4(+) T cells were highly polyfunctional. In homologous protocol (MVA-HCV/MVA-HCV) the main CD8(+) T cell target was p7+NS2, whereas in heterologous combination (DNA-HCV/MVA-HCV) the main target was NS3. Antigenic responses were also detected against other HCV proteins (Core, E1-E2, and NS4), but the magnitude of the responses was dependent on the protocol used. The majority of the HCV-induced CD8(+) T cells were triple or quadruple cytokine producers. The MVA-HCV vaccine induced memory CD8(+) T cell responses with an effector memory phenotype. Overall, our data showed that MVA-HCV induced broad, highly polyfunctional, and durable T cell responses of a magnitude and quality that might be associated with protective immunity and open the path for future considerations of MVA-HCV as a prophylactic and/or therapeutic vaccine candidate against HCV.

Antigen presentation assays to investigate uncharacterized immunoregulatory genes

Antigen presentation to T lymphocytes is the seminal triggering event of the specific immune response, and poxviruses encode immunomodulatory genes that disrupt this process. Discovery of viral proteins that interfere with steps in the antigen presentation process requires a robust, easily manipulated antigen-presenting and T lymphocyte response system. Use of fresh primary antigen-presenting cells (APC) is preferable because cell lines that can present antigen in vitro are often not representative of APC in vivo and are typically weak stimulators. To study immunomodulatory poxvirus genes, we have used infected primary rat macrophages to present a model antigen, the myelin basic protein peptide, to a cognate CD4+ RsL11 T cell clone. Using this system, viruses can be assessed for difference in immunomodulation, and viral gene functions may also be assayed by comparing effects of wild type virus and mutant viruses (e.g., a deletion in the putative immunomodulatory gene). While antigen presentation can be thought of as a single event, it can also be considered as a larger process comprising multiple steps including: antigen acquisition, antigen processing, peptide loading onto MHC molecules, transport to the surface, MHC binding to T cell receptor, interaction of costimulatory molecules, cell signaling, cytokine synthesis by both cells, and proliferation of antigen specific T lymphocytes. This system allows for the initial determination of whether there is a phenotype and then also allows the stepwise deconstruction of the system to analyze this process at several points to focus in on the mechanism of immunomodulation. We have used this model system to elucidate the function of a highly conserved but previously uncharacterized poxvirus gene that we showed was important for virulence in rodents. The experimental system developed should be broadly applicable to analyzing viral effects on immunity.

Early activation of interferon-stimulated genes in human liver allografts: relationship with acute rejection and histological outcome

BACKGROUND

Innate immunity mechanisms have been shown to play a paramount role in organ transplantation. Our aim was to investigate the hypothesis that activation of the interferon system may affect clinically relevant outcomes, such as acute rejection and/or early fibrosis progression, after liver transplantation.

METHODS

We studied 71 consecutive recipients (57 males; 25 with hepatitis C) who underwent two per protocol graft biopsies: the first, within 60 days after the transplant operation (median 24) and the second, after 1 year. The mRNA expression for five interferon-stimulated genes (Mx1, OAS2, PKR, IRF7A, IFI16) was measured on the first biopsy specimens. The main outcome measures were acute rejection during the first post-transplant year and fibrosis progression at the second biopsy.

RESULTS

On multivariate analysis, the independent predictors of gene expression were hepatitis C (Mx1, OAS2, PKR and IFI16), donor age (IFI16) and recipient gender (IRF7A) (P < .05 for all). During the first post-transplant year, 19/71 patients (27%) had acute cellular rejection. At multivariate analysis, acute cellular rejection was independently predicted by high IRF7A mRNA expression. At the end of follow-up, 25 patients had some degree of fibrosis (F2 or higher in seven cases). On multivariate analysis, hepatitis C etiology, recipient age, and OAS2 overexpression were independent predictors of early fibrosis progression.

CONCLUSIONS

In the early postoperative period of liver transplantation, interferon-stimulated gene activation is dependent on hepatitis C recurrence (the main factor responsible for early fibrosis progression) and donor age, and is related to the risk of acute cellular rejection.

Virus infection rapidly activates the P58(IPK) pathway, delaying peak kinase activation to enhance viral replication

Previously we showed that the cellular protein P58(IPK) contributes to viral protein synthesis by decreasing the activity of the anti-viral protein, PKR. Here, we constructed a mathematical model to examine the P58(IPK) pathway and investigated temporal behavior of this biological system. We find that influenza virus infection results in the rapid activation of P58(IPK) which delays and reduces maximal PKR and eIF2α phosphorylation, leading to increased viral protein levels. We confirmed that the model could accurately predict viral and host protein levels at extended time points by testing it against experimental data. Sensitivity analysis of relative reaction rates describing P58(IPK) activity and the downstream proteins through which it functions helped identify processes that may be the most beneficial targets to thwart virus replication. Together, our study demonstrates how computational modeling can guide experimental design to further understand a specific metabolic signaling pathway during viral infection in a mammalian system.

Subcellular forms and biochemical events triggered in human cells by HCV polyprotein expression from a viral vector

To identify the subcellular forms and biochemical events induced in human cells after HCV polyprotein expression, we have used a robust cell culture system based on vaccinia virus (VACV) that efficiently expresses in infected cells the structural and nonstructural proteins of HCV from genotype 1b (VT7-HCV7.9). As determined by confocal microscopy, HCV proteins expressed from VT7-HCV7.9 localize largely in a globular-like distribution pattern in the cytoplasm, with some proteins co-localizing with the endoplasmic reticulum (ER) and mitochondria. As examined by electron microscopy, HCV proteins induced formation of large electron-dense cytoplasmic structures derived from the ER and containing HCV proteins. In the course of HCV protein production, there is disruption of the Golgi apparatus, loss of spatial organization of the ER, appearance of some "virus-like" structures and swelling of mitochondria. Biochemical analysis demonstrate that HCV proteins bring about the activation of initiator and effector caspases followed by severe apoptosis and mitochondria dysfunction, hallmarks of HCV cell injury. Microarray analysis revealed that HCV polyprotein expression modulated transcription of genes associated with lipid metabolism, oxidative stress, apoptosis, and cellular proliferation. Our findings demonstrate the uniqueness of the VT7-HCV7.9 system to characterize morphological and biochemical events related to HCV pathogenesis.

Immunogenicity of human mesenchymal stem cells in HLA-class I-restricted T-cell responses against viral or tumor-associated antigens

Human mesenchymal stem cells (MSC) are immunosuppressive and poorly immunogenic but may act as antigen-presenting cells (APC) for CD4(+) T-cell responses; here we have investigated their ability to serve as APC for in vitro CD8(+) T-cell responses. MSC pulsed with peptides from viral antigens evoked interferon (IFN)-gamma and Granzyme B secretion in specific cytotoxic T lymphocytes (CTL) and were lysed, although with low efficiency. MSC transfected with tumor mRNA or infected with a viral vector carrying the Hepatitis C virus NS3Ag gene induced cytokine release but were not killed by specific CTL, even following pretreatment with IFN-gamma. To investigate the mechanisms involved in MSC resistance to CTL-mediated lysis, we analyzed expression of human leukocyte antigen (HLA) class I-related antigen-processing machinery (APM) components and of immunosuppressive HLA-G molecules in MSC. The LMP7, LMP10, and ERp57 components were not expressed and the MB-1 and zeta molecules were downregulated in MSC either unmanipulated or pretreated with IFN-gamma. Surface HLA-G was constitutively expressed on MSC but was not involved in their protection from CTL-mediated lysis. MSC supernatants containing soluble HLA-G (sHLA-G) inhibited CTL-mediated lysis, whereas those lacking sHLA-G did not. The role of sHLA-G in such inhibition was unambiguously demonstrated by partial restoration of lysis following sHLA-G depletion from MSC supernatants. In conclusion, human MSC can process and present HLA class I-restricted viral or tumor antigens to specific CTL with a limited efficiency, likely because of some defects in APM components. However, they are protected from CTL-mediated lysis through a mechanism that is partly sHLA-G-dependent.

Impact of protein kinase PKR in cell biology: from antiviral to antiproliferative action

The double-stranded RNA-dependent protein kinase PKR is a critical mediator of the antiproliferative and antiviral effects exerted by interferons. Not only is PKR an effector molecule on the cellular response to double-stranded RNA, but it also integrates signals in response to Toll-like receptor activation, growth factors, and diverse cellular stresses. In this review, we provide a detailed picture on how signaling downstream of PKR unfolds and what are the ultimate consequences for the cell fate. PKR activation affects both transcription and translation. PKR phosphorylation of the alpha subunit of eukaryotic initiation factor 2 results in a blockade on translation initiation. However, PKR cannot avoid the translation of some cellular and viral mRNAs bearing special features in their 5' untranslated regions. In addition, PKR affects diverse transcriptional factors such as interferon regulatory factor 1, STATs, p53, activating transcription factor 3, and NF-kappaB. In particular, how PKR triggers a cascade of events involving IKK phosphorylation of IkappaB and NF-kappaB nuclear translocation has been intensively studied. At the cellular and organism levels PKR exerts antiproliferative effects, and it is a key antiviral agent. A point of convergence in both effects is that PKR activation results in apoptosis induction. The extent and strength of the antiviral action of PKR are clearly understood by the findings that unrelated viral proteins of animal viruses have evolved to inhibit PKR action by using diverse strategies. The case for the pathological consequences of the antiproliferative action of PKR is less understood, but therapeutic strategies aimed at targeting PKR are beginning to offer promising results.

PKR and RNase L contribute to protection against lethal West Nile Virus infection by controlling early viral spread in the periphery and replication in neurons

West Nile virus (WNV) is a neurotropic, mosquito-borne flavivirus that can cause lethal meningoencephalitis. Type I interferon (IFN) plays a critical role in controlling WNV replication, spread, and tropism. In this study, we begin to examine the effector mechanisms by which type I IFN inhibits WNV infection. Mice lacking both the interferon-induced, double-stranded-RNA-activated protein kinase (PKR) and the endoribonuclease of the 2',5'-oligoadenylate synthetase-RNase L system (PKR(-/-) x RL(-/-)) were highly susceptible to subcutaneous WNV infection, with a 90% mortality rate compared to the 30% mortality rate observed in congenic wild-type mice. PKR(-/-) x RL(-/-) mice had increased viral loads in their draining lymph nodes, sera, and spleens, which led to early viral entry into the central nervous system (CNS) and higher viral burden in neuronal tissues. Although mice lacking RNase L showed a higher CNS viral burden and an increased mortality, they were less susceptible than the PKR(-/-) x RL(-/-) mice; thus, we also infer an antiviral role for PKR in the control of WNV infection. Notably, a deficiency in both PKR and RNase L resulted in a decreased ability of type I IFN to inhibit WNV in primary macrophages and cortical neurons. In contrast, the peripheral neurons of the superior cervical ganglia of PKR(-/-) x RL(-/-) mice showed no deficiency in the IFN-mediated inhibition of WNV. Our data suggest that PKR and RNase L contribute to IFN-mediated protection in a cell-restricted manner and control WNV infection in peripheral tissues and some neuronal subtypes.