|Interleukin-1beta receptor expressed by modified vaccinia virus Ankara interferes with interleukin-1beta activity produced in various virus-infected antigen-presenting cells.|
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|PMID: 23356675 Owner: NLM Status: Publisher|
|ABSTRACT: BACKGROUND: Modified vaccinia virus Ankara (MVA) is a highly attenuated virus and a promising vaccine vector with potent immune stimulating properties. Deletion of the gene encoding the viral interleukin-1beta receptor (vIL-1betaR) in MVA (MVA[increment]IL-1betaR) was previously shown to enhance memory T cell function. Here, we investigated the influence of vIL-1betaR on blocking interleukin-1beta (IL-1beta) upon MVA infection in various antigen presenting cells of murine and human origin, and analyzed whether inflammasome function contributes to IL-1beta production in different cell types. FINDINGS: Extending previous studies, immunizing mice with low doses of MVA[increment]IL-1betaR still showed enhanced memory CD8+ T cell activation compared to MVA wild-type (MVAwt) immunization. In vitro, murine myeloid dendritic cells, and activated, but not naive primary macrophages were identified as potent producers of IL-1beta upon infection with MVA. Importantly, free IL-1beta was only detected in the absence of vIL-1betaR. Moreover, MVA[increment]IL-1betaR increased amounts of bioactive IL-1beta compared to MVAwt after infection of human THP-1 cells, as detected using a reporter system that only responds to active and free IL-1beta. The MVA-mediated induction of IL-1beta was confirmed to depend on inflammasome function in human and murine cells, however in murine cells this apparently involves caspase-1-independent pathways. CONCLUSIONS: MVA lacking IL-1beta blocking activity leads to increased concentrations of free IL-1beta upon infection of murine and human antigen presenting cells; this is likely responsible for enhanced memory T cell activation upon MVA[increment]IL-1betaR immunization of mice. Moreover, our results suggest that MVA-mediated IL-1beta induction is a multifactorial process.|
|Stefan Zimmerling; Zoe Waibler; Theresa Resch; Gerd Sutter; Astrid Schwantes|
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|Type: JOURNAL ARTICLE Date: 2013-1-28|
|Title: Virology journal Volume: 10 ISSN: 1743-422X ISO Abbreviation: Virol. J. Publication Date: 2013 Jan|
|Created Date: 2013-1-29 Completed Date: - Revised Date: -|
Medline Journal Info:
|Nlm Unique ID: 101231645 Medline TA: Virol J Country: -|
|Languages: ENG Pagination: 34 Citation Subset: -|
|APA/MLA Format Download EndNote Download BibTex|
Journal ID (nlm-ta): Virol J
Journal ID (iso-abbrev): Virol. J
Publisher: BioMed Central
Copyright ©2013 Zimmerling et al.; licensee BioMed Central Ltd.
Received Day: 2 Month: 9 Year: 2012
Accepted Day: 23 Month: 1 Year: 2013
collection publication date: Year: 2013
Electronic publication date: Day: 28 Month: 1 Year: 2013
Volume: 10First Page: 34 Last Page: 34
PubMed Id: 23356675
Publisher Id: 1743-422X-10-34
|Interleukin-1β receptor expressed by modified vaccinia virus Ankara interferes with interleukin-1β activity produced in various virus-infected antigen-presenting cells|
|Stefan Zimmerling1||Email: firstname.lastname@example.org|
|Zoe Waibler2||Email: Zoe.Waibler@pei.de|
|Theresa Resch2||Email: Theresa.Resch@pei.de|
|Gerd Sutter14||Email: email@example.com|
|Astrid Schwantes13||Email: Astrid.Schwantes@pei.de|
1Division of Virology, Paul-Ehrlich Institute, Langen, Germany
2Junior Research Group, Novel Vaccination Strategies and Early Immune Responses, Paul-Ehrlich Institute, Langen, Germany
3President´s Research Group 2, Paul-Ehrlich Institute, Langen, Germany
4Institute for Infectious Diseases and Zoonoses, LMU University of Munich, Munich, Germany
Modified vaccinia virus Ankara (MVA) is a highly attenuated vaccinia virus (VACV) generated by tissue culture passaging of VACV Ankara, a first generation smallpox vaccine . During this process many viral genes acquired mutations or were deleted, resulting in the loss of productive viral replication in most mammalian cell types [2,3]. This enabled recombinant MVA to be established as efficient and particularly safe VACV vector .
In contrast to conventional VACV, MVA is able to potently stimulate innate immunity [5-7] including induction of IL-1β . Paradoxically, the gene encoding the viral interleukin-1beta receptor homolog (vIL-1βR) has remained functional in MVA [3,7]. Viral IL-1βR is expressed late during the VACV life cycle as a secreted protein that binds specifically and with high affinity to mature IL-1β [7,9,10]. The protein has been shown to play a role in the pathogenesis of poxvirus-mediated disease , pointing to the importance of blocking the activity of the pro-inflammatory cytokine interleukin-1beta (IL-1β). Deleting the gene encoding vIL-1βR in MVA vaccines has resulted in enhanced memory CD8+ T cell responses against MVA or recombinant antigens upon immunization of mice [12-14].
Here, we show the ability of MVA to induce IL-1β in various antigen presenting cells, and indicate the possibility of a different requirement of caspase-1-containing inflammasomes for IL-1β induction. Particularly, we demonstrate that vIL-1βR substantially affects the availability and activity of free IL-1β.
To explore in more detail the potency of MVA-induced IL-1β on memory T cell activation in vivo, we immunized C57BL/6 mice with different low doses of wild-type MVA (MVAwt) or mutant MVA lacking vIL-1βR expression (MAVΔIL-1βR) . Viruses were administered intravenously to elicit a predominantly systemic T cell response that could be measured in secondary lymphatic organs. Ten weeks after primary vaccination, all mice received a booster immunization. Since our previous results in the BALB/c model indicated that priming is critical for differences in memory T cell activation , we used MVAwt for the second immunization to provide identical conditions for secondary T cell expansion in all mice.
In agreement with our previous findings , we consistently found higher numbers of IFN-γ-secreting activated memory CD8+ T cells specific for two different VACV-specific epitopes (Kb-restricted immunodominant B8R20-27; Db-restricted subdominant determinant K3L6-15) in mice immunized with MVAΔIL-1βR than in those immunized with MVAwt (Figure 1). These new data suggest that even low amounts of MVA induce IL-1β in vivo, and that in the absence of vIL-1βR this is sufficient to enhance memory T cell stimulation.
We previously hypothesized that MVAΔIL-1βR’s inability to neutralize IL-1β upon infection may lead to improved functionality of DCs, and thus better T cell memory responses . Myeloid dendritic cells (mDCs) are potent antigen presenting cells and important for T cell priming; we therefore investigated their ability to respond to MVA infection by producing IL-1β. We also compared their response to identically treated bone marrow-derived macrophages (BMDMs), which have already been shown to produce IL-1β upon MVA infection .
To investigate the blocking effect of vIL-1βR on IL-1β induction we compared MVAΔIL-1βR with MVAwt. IL-1β production was detected by ELISA where vIL-1βR interferes with one of the ELISA antibodies binding to IL-1β so only unbound IL-1β is detected. Upon infection of BMDM and mDC with MVAΔIL-1βR, IL-1β production was observed in both cell types, but interestingly, higher IL-1β levels were detected in mDCs. IL-1β was detected 4 hours after infection, and was still increasing up to 24 hours after infection (Figure 2A,D). However, the cytokine was not measurable at late time points upon infection with MVAwt or MVA-IL-1βRrev, a revertant virus with a re-inserted vIL-1βR gene , indicating that vIL-1βR has potent blocking activity (Figure 2A,D). Unlike our results, Delaloye et al. observed IL-1β production in BMDM even with MVAwt . However, they used LPS-primed cells, suggesting that activating antigen presenting cells in this manner enhances MVA-mediated IL-1β production. In contrast, our results show that free IL-1β can be produced from unstimulated cells, but only with MVA lacking IL-1β binding capacity.
MVA is thought to induce IL-1β via the inflammasome in murine and human macrophages . Here, we also wanted to investigate relevant pathways leading to IL-1β activation in murine mDCs. First, we studied the impact of interleukin-1 receptor I and Toll-like receptor signaling on IL-1β activation in mDCs and BMDMs, both generated from MyD88−/−Trif−/− knockout mice. Upon infecting both cell types with MVAΔIL-1βR, considerably less free IL-1β was detected than in wt cells (Figure 2B,E vs. 2A,D), suggesting one or both of these molecules are required for IL-1β induction.
To investigate the inflammasome contribution, we focused on caspase-1, a central molecule of several inflammasomes because it cleaves pro-IL-1β into its mature and secreted form . Interestingly, IL-1β was produced in BMDMs and mDCs in the absence of caspase-1. However, levels of free IL-1β were less in mDCs than in wt cells (Figure 2F vs. 2D), but not in BMDMs (Figure 2C vs. 2A). In the latter cell type, IL-1β activation was completely abrogated upon LPS stimulation, confirming the absence of caspase-1 activity (Figure 2C).
These results suggest an alternative caspase-1-independent mechanism of MVA-mediated IL-1β activation in murine antigen presenting cells. Some reports describe that other proteinases such as the neutrophil- and macrophage-derived serine protease proteinase-3, elastases, cathepsin-G and certain matrix metalloproteases also process pro-IL-1β into a secretable cytokine [17-19]. Thus, MVA or poxviruses in general are likely able to activate IL-1β by caspase-1-dependent and independent inflammasomes.
We subsequently analyzed IL-1β induction in primary macrophages isolated from the peritoneal cavity of mice. In contrast to the results found for BMDM in Figure 2, infection of these cells with MVAΔIL-1βR did not induce detectable levels of free IL-1β (Figure 3A, immunization: mock). However, when macrophages were isolated from mice immunized with MVAwt or MVA derivatives six days before, in vitro infection of these cells with MVAΔIL-1βR again resulted in IL-1β production, regardless of the immunizing virus used (Figure 3A, immunization: MVA variants).
Assuming that peritoneal immunization leads to activation of local macrophages, we investigated levels of activation markers on peritoneal macrophages after immunization with MVA viruses. Indeed expression levels of MHC class II and CD80 were elevated (Figure 3B). Interestingly, when we investigated IL-1β induction in vivo at an early time point after immunization, we detected no IL-1β in either lavages or supernatants of macrophages isolated 6 hours after MVAΔIL-1βR immunization (data not shown), indicating a certain resistance of primary macrophages to produce IL-1β upon MVA stimulation. This suggests that primary macrophages only respond to MVA in an activated state, at least in the C57BL/6 background.
To examine the biological activity of MVA-mediated IL-1β in the presence or absence of vIL-1βR in human cells, we infected monocytic THP-1 cells with MVAwt, MVAΔIL-1βR, or MVA-IL-1βRrev. The biological activity of induced IL-1β was determined by transferring cell culture supernatants onto HEK-293 reporter cells that specifically and quantitatively respond to exogenously applied free IL-1β . Supernatants from THP-1 cells infected with MVAΔIL-1βR stimulated the highest levels of reporter gene expression, demonstrating that more biologically active free IL-1β was available than in other infections or THP-1 mock controls (Figure 4, left block). These data demonstrate that vIL-1βR reduces the biological activity of IL-1β produced in response to MVA infection in human cells.
We also analyzed the inflammasome contribution in THP-1 cells where expression of the adaptor molecule apoptosis-associated speck-like protein (ASC), a component of many inflammasomes , was down-regulated by shRNA . Upon infection with the MVA derivates, even MVAΔIL-1βR was unable to stimulate IL-1β activity, as reflected by negligible reporter cell responses (Figure 4, right block). This confirms previous studies  demonstrating the impact of the inflammasome on MVA-mediated IL-1β induction in human cells.
MVA can induce IL-1β in different antigen presenting cells, including murine myeloid dendritic cells. Whereas in these cells MyD88 and Trif are clearly required for IL-1β production, caspase-1 only seems to be involved in some cases. Moreover, only when the viral IL-1β receptor is absent can MVA infection stimulate high levels of free IL-1β to accomplish the cytokine´s biological function. Thus, deleting the gene encoding the viral IL-1β receptor offers a viable strategy for increasing inflammatory responses in order to enhance MVA-based vaccine immunogenicity.
Female C57BL/6 mice (Charles River Laboratories, Sulzfeld, Germany), MyD88−/−TRIF−/− mice (C57BL/6 background) [5,22] and Caspase-1−/− mice  were bred and treated as previously described . Mouse experimental work was approved by the State Government of Hessen, Germany (authorization no. F107-103). All animals were handled in compliance with German Animal Welfare Regulations.
The following cells were cultivated as described in each reference: primary chicken embryo fibroblast (CEF) , HEK-Blue IL-1β reporter cells (Cayla-InvivoGen, Toulouse, France) , monocytic THP-1 (DSMZ, Braunschweig, Germany) and THP-1 shASC  (both cultivated according ); primary mouse cells , additionally supplemented with 1 mM sodium pyruvate, 1 mM HEPES, 0.1 mM 2-mercaptoethanol.
Bone marrow derived macrophages were generated as described . Myeloid dendritic cells were isolated and generated accordingly using GM-CSF for differentiation (100 ng/ml, Peprotech GmbH, Hamburg, Germany) and 8-day cultivation. Cells from the peritoneal cavity were isolated from sacrificed mice by flushing out cells through injection of 5–7 ml of PBS into the abdominal cavity.
Cells were infected with indicated viruses at a multiplicity of infection (MOI) of five, washed after one hour, and cultivated as described above. As positive controls, cells were treated with 1 μg/ml LPS (from Salmonella typhimurium, Sigma-Aldrich, Steinheim, Germany). Harvested supernatants were cleared from cells and debris by centrifugation at 1200 × g.
Cell-free supernatants were diluted with 1 volume PBS/10% FCS and subjected to IL-1β ELISA (BD Biosciences, Heidelberg) performed according to the manufacturer´s instructions.
PMA-stimulated THP-1 or THP-1 shASC cells were infected with the indicated viruses and supernatants transferred 16 hours after infection onto HEK-Blue™ IL-1β cells (Cayla-Invivogen, Toulouse, France). Treatment of HEK-Blue cells and colorimetric assay was performed according to the manufacturer´s instructions .
Spleen cells of sacrificed mice were stimulated with 1 μg/ml VACV-specific peptides B8R20-27 or K3L6-15 or as a control, β-galactosidase876 peptide (Thermo Electron Corp. Ulm, Germany)  for two hours, then another three hours after adding 1 μl of Golgi Plug (Becton Dickinson, Heidelberg, Germany). For intracellular cytokine stain, cells were treated with anti-CD16/CD32-Fc-block, followed by antibodies directed against CD8 and CD62L. Cells were fixed and permeabilized using Cytofix/Cytoperm according to the manufacturer´s instructions (BD Biosciences, Heidelberg, Germany) followed by staining for INF-γ. Each incubation step was performed for 20 min at 4°C. Cells were finally fixed with 2.5% formaldehyde and analyzed by FACS. Macrophages were blocked as described for spleen cells and then stained for activation markers CD80 or MHCII in FACS buffer (PBS/2% BSA/20 mM EDTA/0.03% sodium azide) followed by staining for F4/80, CD11b and CD11c. All steps were performed for 30 min interspersed by washing rounds with FACS buffer. Cells were fixed with 1% paraformaldehyde and analyzed by FACS.
Source of FACS staining antibodies: MHCII (PE), CD11b (PerCP-Cy5.5), CD11c (APC), CD8 (PacBlue), CD62L (APC), INF-γ (PE) and anti-CD16/CD32-Fc-block are from BD Biosciences (Heidelberg, Germany), CD80 (FITC) from eBioscience (Frankfurt/Main, Germany) and F4/80 (PacBlue) from AbD Serotech (Düsseldorf, Germany). Data acquired by FACS analysis on a LSRII using FACSDiVa software (BD Biosciences) were analyzed with FCS express (De Novo Software; Figure 3B) or FlowJo (Tree Star Inc.; Figure 1).
BMDM: Bone marrow-derived macrophages; IFN: Interferon; IL-1β: Interleukin-1beta; mDC: Myeloid dendritic cells; MOI: Multiplicity of infection; MVA: Modified vaccinia virus Ankara; MVAwt: MVA wild-type; MyD88: Myeloid differentiation primary response gene 88; PEC: Peritoneal exudate cells; SEAP: Secreted alkaline phosphatase; TLR: Toll-like receptor; VACV: Vaccinia virus; vIL-1βR: Viral interleukin-1beta receptor; wt: Wild-type.
GS is an inventor and has a patent application concerning the mutant virus MVAΔIL-1βR and its use in immunotherapy and vaccination, in particular in the prevention and therapy of cancer and infectious diseases. The other author(s) declare that they have no competing interests.
SZ, TR and AS performed experiments; SZ, AS, ZW, GS conceived and designed experiments, and analyzed and interpreted the results; AS drafted and SZ, TR, ZW and GS revised the manuscript. All authors read and approved the final manuscript.
We thank Dorothea Kreuz for breeding knockout mice. Additionally, we kindly acknowledge Prof. I. Steinmetz, University of Greifswald, Germany for providing Caspase-1 knockout mice, and D. Taxman with permission of Dr. J.P.Y. Ting, both UNC, USA for providing THP-1 shASC cells. We also thank Kay-Martin Hanschmann for statistical analysis, Yasemin Suezer and Matthias Hamdorf for technical help and fruitful discussions, Elea Conrad for help in performing peritoneal lavages, and Dagmar Fecht-Schwarz for reading the manuscript.
This work was supported by grants from the European Commission (FP6 MVACTOR LHSP-CT-2006-037536, FP6 BIOSAFE SSPE-CT-2006-022725). The funders played no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
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Keywords: Modified vaccinia virus Ankara, Interleukin-1β induction, Viral interleukin-1β receptor, Inflammasome, Caspase-1, Human cells, Macrophages, Dendritic cells.
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