Vaccinia virus lacking the Bcl-2-like protein N1 induces a stronger natural killer cell response to infection

doi:10.1099/vir.0.2008/004119-0

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Vaccinia virus lacking the Bcl-2-like protein N1 induces a stronger natural killer cell response to infection

Nathalie Jacobs, Nathan W. Bartlett, Richard H. Clark and Geoffrey L. Smith

Department of Virology, Faculty of Medicine, Imperial College London, St Mary's Campus, Norfolk Place, London W2 1PG, UK

Correspondence
Geoffrey L. Smith
glsmith{at}imperial.ac.uk

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The vaccinia virus (VACV) N1 protein is an intracellular virulencefactor that has a Bcl-2-like structure and inhibits both apoptosisand signalling from the interleukin 1 receptor, leading to nuclearfactor kappa B activation. Here, we investigated the immuneresponse to intranasal infection with a virus lacking the N1Lgene (v ${Delta}$ N1L) compared with control viruses expressing N1L. Datapresented show that deletion of N1L did not affect the proportionof CD4⁺ and CD8⁺ T cells infiltrating the lungs or the cytotoxicT-cell activity of these cells. However, v ${Delta}$ N1L induced an increasedlocal natural killer cell activity between days 4 and 6 post-infection.In addition, in the absence of N1 the host inflammatory infiltratewas characterized by a reduced proportion of lymphocytes bearingthe early activation marker CD69. Notably, there was a goodcorrelation between the level of CD69 expression and weightloss. The implications of these findings are discussed.

${dagger}$ Present address: Department of Pathology, Faculty of Medicine,University of Liège, 4000 Liège, Belgium.

${ddagger}$ Present address: Department of Respiratory Medicine, Facultyof Medicine, Imperial College London, St Mary's Campus, NorfolkPlace, London W2 1PG, UK.

$§$ Present address: Warwick Medical School, University of Warwick,Coventry CV4 7AL, UK.

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Vaccinia virus (VACV) is a member of the genus Orthopoxvirus(OPV) of the Poxviridae (Moss, 2007; Smith, 2007). Like otherOPVs, VACV has a double-stranded DNA genome of approximately190 kb and encodes about 200 genes. Genes located in theleft and right terminal regions of the genome are variable betweenOPVs and affect virulence, host range and immunomodulation.Gene N1L is located near the left end of the VACV strain WesternReserve (WR) genome and encodes a 14 kDa intracellularhomodimer (Bartlett et al., 2002). Bioinformatic analysis showedthat the N1L gene is conserved in many OPVs (Bartlett et al.,2002), despite being located in the terminal (variable) regionof the genome. An exception to this conservation is the highlyattenuated VACV strain modified virus Ankara (MVA) that encodesa truncated N1 protein (Antoine et al., 1998). Overexpressionof N1 in uninfected cells was reported to inhibit nuclear factorkappa B (NF- ${kappa}$ B) and interferon response factor 3 (IRF3) activationby binding to the inhibitor of kappa kinase (IKK) complex andTANK-binding kinase 1 (TBK1), respectively (DiPerna et al.,2004). However, the crystal structure of N1 showed that thisprotein is a member of the Bcl-2 family of anti-apoptotic proteins(Aoyagi et al., 2007; Cooray et al., 2007) and it was demonstratedthat N1 inhibited staurosporine-induced apoptosis in transfectedand infected cells (Cooray et al., 2007). N1 inhibits interleukin(IL)-1-induced NF- ${kappa}$ B activation in transfected cells (DiPernaet al., 2004; Graham et al., 2008) but this effect was not evidentin infected cells (Cooray et al., 2007), presumably due to thepresence of other VACV NF- ${kappa}$ B signalling inhibitors. More recently,an additional study showed that N1 did not co-purify or co-precipitatewith the IKK complex, unlike another VACV protein, B14 (Chenet al., 2008).

VACV strains engineered to lack the N1L gene are attenuatedin mice (Kotwal et al., 1989; Bartlett et al., 2002; Billingset al., 2004). In an intradermal model of infection (Tscharke& Smith, 1999; Jacobs et al., 2006) the deletion mutant,v ${Delta}$ N1L, induced smaller lesion sizes than wild-type (WT) and revertant(Rev) controls and less infectious virus was recovered fromthe infected tissue (Bartlett et al., 2002). Similarly, v ${Delta}$ N1Lwas attenuated in the intracranial (Kotwal et al., 1989) andintranasal model of infection (Bartlett et al., 2002). However,the cellular immune response to infection with VACV lackingN1L has not been reported.

Here, we have investigated the effect of N1 on the host responseafter intranasal infection of female BALB/c mice (6–8weeks old) with 10⁴ p.f.u. of WT VACV, a deletion mutant lackingN1L (v ${Delta}$ N1L) and a Rev virus (vN1-Rev) in which the N1L gene wasreinserted into the N1L gene locus of v ${Delta}$ N1L (Bartlett et al.,2002). After infection, groups of mice (n=6) were monitoreddaily for signs of illness and weights and, as noted previously(Bartlett et al., 2002), animals infected with v ${Delta}$ N1L lost lessweight than controls (data not shown). In addition, at differentdays post-infection (p.i.), the animals were sacrificed andthe broncho alveolar lavage (BAL) fluids were prepared, andlungs, brain and spleen were removed. Cells present in the lungswere prepared as described previously (Clark et al., 2006) andanalysed after staining with appropriate combinations of fluoresceinisothiocyanate (FITC)-, phycoerythrin (PE)-, allophycocyanine(APC)- or tricolour-labelled anti-CD3 (Caltag), anti-CD8 (BDPharmingen), anti-CD4 (Caltag), anti-CD45 (pan leukocyte marker;BD Pharmingen) anti-CD25 (IL-2R ${alpha}$ ; BD Pharmingen), anti-CD69 (BDPharmingen) or anti-pan NK (DX5; BD Pharmingen) antibodies.The presence of cell-surface markers was determined on a FACScanflow cytometer with CellQuest software (BD Biosciences) anda lymphocyte gate was used to select at least 20 000 events.There was no difference in the proportion of CD4⁺ or CD8⁺ Tcells in the lungs at 3, 6 and 9 days p.i. with v ${Delta}$ N1L, comparedto WT and Rev controls (data not shown). In addition, we measuredthe cytolytic activity of these cells by chromium release assayson VACV-infected P815 (VACV WR at 10 p.f.u. per cell for 2 hat 37 °C) as described in Clark et al. (2006) and foundno difference between the groups at days 6 and 7 p.i. (datanot shown). However, in three independent experiments therewas an increased proportion of natural killer (NK) cells (CD3^–DX5⁺) in the lung (Fig. 1a), and a similar increase wasseen in BAL fluid (Fig. 1b). These differences were seenconsistently but with these sample sizes were not statisticallysignificant. However, when the cytolytic activity of these cellswas measured using Yac-1 target cells (Hussell & Openshaw,1998), it was found that NK cells derived from infection withv ${Delta}$ N1L had significantly greater activity on day 4 p.i. comparedwith WT and Rev (P<0.05 comparing v ${Delta}$ N1L with WT and Rev, Student'st-test) (Fig. 1c). This increased NK activity was observedonly locally (lungs) and not in the spleen (data not shown).

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Fig. 1. NK cells after intranasal infection with WT, v ${Delta}$ N1L and Rev. (a) The percentages of NK cells (% of CD3^–DX5⁺ in lymphocyte gate) in the lung. Data shown are means±SEM of four experiments. (b) Percentages of NK cells (% of CD3^–DX5⁺ in lymphocyte gate) in BAL of one experiment with pooled data from four mice. (c) Chromium release assay of cells isolated from infected lung against NK-sensitive Yac cells. Data shown are means±SEM of two experiments (E : T=effector : target ratio; the test is measured in triplicate).

Infection by v ${Delta}$ N1L induced an increased NK activity at earlytime points (day 4 p.i.) and therefore we measured if this affectedthe virus titres in the lungs at different times p.i. By 3 daysp.i., the titres of all three viruses had increased to >10⁶p.f.u. per lung and were indistinguishable from each other,showing that the N1 protein was not needed for efficient virusreplication in vivo. However, consistent with the enhanced cytolyticactivity of NK cells, by day 7 p.i. the titre of v ${Delta}$ N1L in thelung had started to fall, whereas the titres of control viruseswere higher than on day 3. At this time point the differencebetween v ${Delta}$ N1L and both control viruses was significant (P<0.05).This difference between v ${Delta}$ N1L and controls was increased furtherby day 10 and at this time the titres of all viruses were startingto fall (Fig. 2

). Data shown are the mean values from twoindependent experiments that gave the same result. This observationshows that although v ${Delta}$ N1L can replicate to high titres in mousetissue, it is cleared more rapidly by the host immune response,consistent with its attenuated phenotype. The increased NK cellactivity following infection with v ${Delta}$ N1L may partly explain thereduced virus titres seen at 7 days p.i. However, giventhe multiple roles of N1 in inhibiting both apoptosis and activationof NF- ${kappa}$ B via the IL-1R–TRAF6 pathway, it is probable thatother factors may also be involved.

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Fig. 2. The N1L protein contributes to virulence in an intranasal infection model. Groups of five female BALB/c mice (6–8 weeks of age) were infected intranasally with 10⁴ p.f.u. of the indicated virus. On days 3, 7 and 10 lungs were harvested and assayed for infectious virus by plaque assay. The data are expressed as means±SEM. The data were analysed by log-transforming followed by one-way ANOVA. Bonferroni's post-test with 95 % confidence levels (Prism 4 GraphPad) was used to pin-point significant differences. *, P<0.05; **, P<0.01 for v ${Delta}$ N1L compared with WT and Rev.

Next, we measured the activation status of the lymphocytes thatinfiltrated the lung. To do this the percentage of lymphocytesexpressing the early activation marker CD69 was measured byFACS (anti-CD69-PE; BD Biosciences). At days 4 and 6 p.i. withWT and Rev virus, $~$ 20 % of lung lymphocytes expressed CD69 andthis percentage decreased as the mice recovered from infection(day 11 p.i.) (Fig. 3a

). However, on days 4 and 6 p.i.with v ${Delta}$ N1L there was a significantly smaller proportion of lymphocytes(both NK and T cells) that was CD69⁺ compared with the proportionfollowing infection with WT and Rev viruses (Fig. 3a

).This suggests that N1 somehow contributes to immune activation,and, conversely, in the absence of N1 there was a reduced immuneactivation. In the intranasal model of infection used here,the degree of weight loss correlates with the severity of pneumonia,which is promoted by excessive inflammation. Consequently, diminishingthe inflammatory response can reduce illness. This was exemplifiedby the observation that expression of a secreted CC chemokine-bindingprotein from VACV strain WR decreased virus virulence in thismodel. This virus induced less weight loss, decreased virustitres and a reduced recruitment of inflammatory cells intothe lungs (Reading et al., 2003

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Fig. 3. CD69 expression on lung cells after intranasal infection with WT, v ${Delta}$ N1L and Rev. (a) CD69 expression in lung (lymphocytes gate). Data are means±SEM of two independent experiments. *, P<0.05; **, P<0.01. (b) Correlation between per cent weight loss and per cent of CD69-positive cells in the lungs at day 6 p.i. P<0.0001.

When the degree of weight loss was compared with CD69 expressionit was found that there was a direct relationship: animals thatlost more weight (infected by WT and Rev viruses) had a greaterpercentage of CD69⁺ cells, while those infected by v ${Delta}$ N1L showedlower weight loss and had a smaller percentage of CD69⁺ cells(Fig. 3b

, P<0.0001). Although previous in vitro datasuggest that CD69 exerts a pro-inflammatory function, recentin vivo results indicate that CD69 might act as a regulatorymolecule, modulating the inflammatory response (Sancho et al.,2005

). A link between NK activity and CD69 expression was suggestedby the observation that, compared with WT mice, CD69^–/–mice showed an enhanced NK-mediated anti-tumour response thatled to greater protection and rejection of major histocompatibilitycomplex class I low tumour cells (Esplugues et al., 2003

). Moreover,antibody against murine CD69, which downregulated CD69 expression,induced NK cytotoxic activity (Esplugues et al., 2005

). A relationshipbetween CD69 and Bcl-2 has also been reported. In asthma, eosinophilsin BAL expressed CD69 and antibody against human CD69 inducedBcl-2-dependent apoptosis (Foerster et al., 2002

An interesting parallel to the results reported here with theVACV N1 protein is the reduction in CD69 activation on B cells,which correlated with a decrease in splenomegaly, followinginfection with murine herpes virus 68 engineered to lack a viralBcl-2 protein (vBcl-2) (de Lima et al., 2005). Like N1, vBcl-2is a Bcl-2 family protein that inhibits apoptosis (Wang et al.,1999; Bellows et al., 2000; Ku et al., 2008). Moreover, it wassuggested that B cells expressing higher levels of CD69 playeda role in viral latency and this role was not directly linkedto viral infection of these cells since only a minority of CD69⁺B cells were infected (Krug et al., 2007). Another viral anti-apoptoticBcl-2 protein, M11L from myxoma virus (Kvansakul et al., 2007)also plays a role in inflammation (Opgenorth et al., 1992).While there are parallels between N1, M11 and vBcl-2 in thatall these viral proteins are anti-apoptotic, a notable differenceis that N1 also inhibits activation of NF- ${kappa}$ B, resulting fromIL-1R signalling. In accord with this, infection of macrophagesin vitro with VACV lacking gene N1L induced the production ofpro-inflammatory cytokines, such as alpha and beta interferon,but also immunosuppressive cytokine such as IL-10 (Zhang etal., 2005), suggesting that N1 regulates the inflammatory responsein favour of the virus. Moreover, it was described in a tumourmodel that inhibition of NF- ${kappa}$ B in tumour cells induced an upregulationof CD69 on NK co-cultivated with these cells (Jewett et al.,2006).

In conclusion, we demonstrate that deletion of the N1L genefrom VACV strain WR causes reduced weight loss and virus titresin the lungs of mice infected intranasally. In this model, lossof N1 promotes a stronger NK cell response to infection butthere are fewer CD69⁺ cells. Therefore, N1 can modulate boththe NK response and lymphocyte activation. It remains to bedetermined whether these effects are due to the ability of N1to inhibit apoptosis or signalling pathways, leading to NF- ${kappa}$ Bactivation.

ACKNOWLEDGEMENTS

This work was supported by grants from the Wellcome Trust, EuropeanCommission (EC QLRT-2001-01867) and Medical Research Council.G. L. S. is a Wellcome Trust Principal Research Fellow.

REFERENCES

TOP
ABSTRACT
MAIN TEXT
REFERENCES

Antoine, G., Scheiflinger, F., Dorner, F. & Falkner, F. G. (1998). The complete genomic sequence of the modified vaccinia Ankara strain: comparison with other orthopoxviruses. Virology 244, 365–396.[CrossRef][Medline]

Aoyagi, M., Zhai, D., Jin, C., Aleshin, A. E., Stec, B., Reed, J. C. & Liddington, R. C. (2007). Vaccinia virus N1L protein resembles a B cell lymphoma-2 (Bcl-2) family protein. Protein Sci 16, 118–124.[CrossRef][Medline]

Bartlett, N., Symons, J. A., Tscharke, D. C. & Smith, G. L. (2002). The vaccinia virus N1L protein is an intracellular homodimer that promotes virulence. J Gen Virol 83, 1965–1976.[Abstract/Free Full Text]

Bellows, D. S., Chau, B. N., Lee, P., Lazebnik, Y., Burns, W. H. & Hardwick, J. M. (2000). Antiapoptotic herpesvirus Bcl-2 homologs escape caspase-mediated conversion to proapoptotic proteins. J Virol 74, 5024–5031.[Abstract/Free Full Text]

Billings, B., Smith, S. A., Zhang, Z., Lahiri, D. K. & Kotwal, G. J. (2004). Lack of N1L gene expression results in a significant decrease of vaccinia virus replication in mouse brain. Ann N Y Acad Sci 1030, 297–302.[CrossRef][Medline]

Chen, R. A., Ryzhakov, G., Cooray, S., Randow, F. & Smith, G. L. (2008). Inhibition of I ${kappa}$ B kinase by vaccinia virus virulence factor B14. PLoS Pathog 4, e22[CrossRef][Medline]

Clark, R. H., Kenyon, J. C., Bartlett, N. W., Tscharke, D. C. & Smith, G. L. (2006). Deletion of gene A41L enhances vaccinia virus immunogenicity and vaccine efficacy. J Gen Virol 87, 29–38.[Abstract/Free Full Text]

Cooray, S., Bahar, M. W., Abrescia, N. G., McVey, C. E., Bartlett, N. W., Chen, R. A., Stuart, D. I., Grimes, J. M. & Smith, G. L. (2007). Functional and structural studies of the vaccinia virus virulence factor N1 reveal a Bcl-2-like anti-apoptotic protein. J Gen Virol 88, 1656–1666.[Abstract/Free Full Text]

de Lima, B. D., May, J. S., Marques, S., Simas, J. P. & Stevenson, P. G. (2005). Murine gammaherpesvirus 68 bcl-2 homologue contributes to latency establishment in vivo. J Gen Virol 86, 31–40.[Abstract/Free Full Text]

DiPerna, G., Stack, J., Bowie, A. G., Boyd, A., Kotwal, G., Zhang, Z., Arvikar, S., Latz, E., Fitzgerald, K. A. & Marshall, W. L. (2004). Poxvirus protein N1L targets the I- ${kappa}$ B kinase complex, inhibits signaling to NF- ${kappa}$ B by the tumor necrosis factor superfamily of receptors, and inhibits NF- ${kappa}$ B and IRF3 signaling by toll-like receptors. J Biol Chem 279, 36570–36578.[Abstract/Free Full Text]

Esplugues, E., Sancho, D., Vega-Ramos, J., Martinez, C., Syrbe, U., Hamann, A., Engel, P., Sanchez-Madrid, F. & Lauzurica, P. (2003). Enhanced antitumor immunity in mice deficient in CD69. J Exp Med 197, 1093–1106.[Abstract/Free Full Text]

Esplugues, E., Vega-Ramos, J., Cartoixa, D., Vazquez, B. N., Salaet, I., Engel, P. & Lauzurica, P. (2005). Induction of tumor NK-cell immunity by anti-CD69 antibody therapy. Blood 105, 4399–4406.[Abstract/Free Full Text]

Foerster, M., Haefner, D. & Kroegel, C. (2002). Bcl-2-mediated regulation of CD69-induced apoptosis of human eosinophils: identification and characterization of a novel receptor-induced mechanism and relationship to CD95-transduced signalling. Scand J Immunol 56, 417–428.[CrossRef][Medline]

Graham, S. C., Bahar, M. W., Cooray, S., Chen, R. A.-J., Whalen, D. W., Abrescia, N. G. A., Alderton, D., Owens, R. J., Stuart, D. I., Smith, G. L. & Grimes, J. M. (2008). Vaccinia virus proteins A52 and B14 share a Bcl-2-like fold but have evolved to inhibit NF- ${kappa}$ B rather than apoptosis. PLoS Pathog 4, e1000128[CrossRef][Medline]

Hussell, T. & Openshaw, P. J. (1998). Intracellular IFN- ${gamma}$ expression in natural killer cells precedes lung CD8⁺ T cell recruitment during respiratory syncytial virus infection. J Gen Virol 79, 2593–2601.[Abstract]

Jacobs, N., Chen, R. A., Gubser, C., Najarro, P. & Smith, G. L. (2006). Intradermal immune response after infection with vaccinia virus. J Gen Virol 87, 1157–1161.[Abstract/Free Full Text]

Jewett, A., Cacalano, N. A., Teruel, A., Romero, M., Rashedi, M., Wang, M. & Nakamura, H. (2006). Inhibition of nuclear factor kappa B (NF ${kappa}$ B) activity in oral tumor cells prevents depletion of NK cells and increases their functional activation. Cancer Immunol Immunother 55, 1052–1063.[CrossRef][Medline]

Kotwal, G. J., Hugin, A. W. & Moss, B. (1989). Mapping and insertional mutagenesis of a vaccinia virus gene encoding a 13,800-Da secreted protein. Virology 171, 579–587.[CrossRef][Medline]

Krug, L. T., Moser, J. M., Dickerson, S. M. & Speck, S. H. (2007). Inhibition of NF- ${kappa}$ B activation in vivo impairs establishment of gammaherpesvirus latency. PLoS Pathog 3, e11[CrossRef][Medline]

Ku, B., Woo, J. S., Liang, C., Lee, K. H., Hong, H. S., E., X., Kim, K. S., Jung, J. U. & Oh, B. H. (2008). Structural and biochemical bases for the inhibition of autophagy and apoptosis by viral Bcl-2 of murine gamma-herpesvirus 68. PLoS Pathog 4, e25[CrossRef][Medline]

Kvansakul, M., van Delft, M. F., Lee, E. F., Gulbis, J. M., Fairlie, W. D., Huang, D. C. & Colman, P. M. (2007). A structural viral mimic of prosurvival Bcl-2: a pivotal role for sequestering proapoptotic Bax and Bak. Mol Cell 25, 933–942.[CrossRef][Medline]

Moss, B. (2007). Poxviridae: the viruses and their replication. In Fields Virology, 5th edn, pp. 2905–2946. Edited by D. M. Knipe. Philadelphia: Lippincott Williams & Wilkins.

Opgenorth, A., Graham, K., Nation, N., Strayer, D. & McFadden, G. (1992). Deletion analysis of two tandemly arranged virulence genes in myxoma virus, M11L and myxoma growth factor. J Virol 66, 4720–4731.[Abstract/Free Full Text]

Reading, P. C., Symons, J. A. & Smith, G. L. (2003). A soluble chemokine-binding protein from vaccinia virus reduces virus virulence and the inflammatory response to infection. J Immunol 170, 1435–1442.[Abstract/Free Full Text]

Sancho, D., Gomez, M. & Sanchez-Madrid, F. (2005). CD69 is an immunoregulatory molecule induced following activation. Trends Immunol 26, 136–140.[CrossRef][Medline]

Smith, G. L. (2007). Genus Orthopoxvirus: Vaccinia virus. In Poxviruses, pp. 1–45. Edited by A. A. Mercer, A. Schmidt & O. Weber. Berlin: Birkhauser-Verlag.

Tscharke, D. C. & Smith, G. L. (1999). A model for vaccinia virus pathogenesis and immunity based on intradermal injection of mouse ear pinnae. J Gen Virol 80, 2751–2755.[Abstract/Free Full Text]

Wang, G. H., Garvey, T. L. & Cohen, J. I. (1999). The murine gammaherpesvirus-68 M11 protein inhibits Fas- and TNF-induced apoptosis. J Gen Virol 80, 2737–2740.[Abstract/Free Full Text]

Zhang, Z., Abrahams, M. R., Hunt, L. A., Suttles, J., Marshall, W., Lahiri, D. K. & Kotwal, G. J. (2005). The vaccinia virus N1L protein influences cytokine secretion in vitro after infection. Ann N Y Acad Sci 1056, 69–86.[CrossRef][Medline]

Received 10 May 2008; accepted 1 July 2008.

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