Serp2, an Inhibitor of the Interleukin-1beta -Converting Enzyme, Is Critical in the Pathobiology of Myxoma Virus

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Journal of Virology, October 1998, p. 7830-7839, Vol. 72, No. 10
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Serp2, an Inhibitor of the Interleukin-1 $beta$ -Converting Enzyme, Is Critical in the Pathobiology of Myxoma Virus

Frederique Messud-Petit,¹ Jacqueline Gelfi,¹ Maxence Delverdier,² Marie-France Amardeilh,² Robert Py,¹ Gerd Sutter,³ and Stephane Bertagnoli¹^,^*

Laboratoire Associe de Microbiologie Moleculaire¹ and Laboratoire d'Anatomie Pathologique,² Institut National de la Recherche Agronomique and Ecole Nationale Vétérinaire, Toulouse, France, and GSF-Institute of Molecular Virology, Oberscheissheim, Germany³

Received 9 March 1998/Accepted 2 July 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

Recently, myxoma virus was shown to encode an additional member of the serpin superfamily. The viral gene, called serp2, wascloned, and the Serp2 protein was shown to specifically bind tointerleukin-1 $beta$ (IL-1 $beta$ )-converting enzyme (ICE), thus inhibitingthe cleavage of pro-IL-1 $beta$ by the protease (F. Petit, S. Bertagnoli,J. Gelfi, F. Fassy, C. Boucraut-Baralon, and A. Milon, J. Virol.70:5860-5866, 1996). Here, we address the role of Serp2 in thedevelopment of myxomatosis, a lethal infectious disease of theEuropean rabbit. A Serp2 mutant myxoma virus was constructed bydisruption of the single-copy serp2 gene and insertion of theEscherichia coli gpt gene serving as the selectable marker. Arevertant virus was obtained by replacing the E. coli gpt geneby the intact serp2 open reading frame. The Serp2 mutant virus replicated with wild-type kinetics both in rabbitfibroblasts and a rabbit CD4⁺ T-cell line (RL5). Moderate reduction of cell surface levelsof major histocompatibility complex I was observed after infectionwith wild-type or Serp2 mutant myxoma virus, and both produced white pocks on the chorioallantoicmembrane of the chick embryo. After the infection of Europeanrabbits, the Serp2 mutant virus proved to be highly attenuated compared to wild-typemyxoma virus, as demonstrated by the clinical course of myxomatosisand the survival rates of infected animals. Pathohistologicalexaminations revealed that infection with wild-type myxoma virusresulted in a blockade of the inflammatory response at the vascularlevel. In contrast, rapid inflammatory reactions occurred uponinfection with the Serp2 mutant virus. Furthermore, lymphocytes in lymph nodes derivedfrom animals inoculated with Serp2 mutant virus were shown torapidly undergo apoptosis. We postulate that the virulence ofmyxoma virus in the European rabbit can be partially attributedto an impairment of host inflammatory processes and to the preventionof apoptosis in lymphocytes. The weakening of host defense isdirectly linked to serp2 gene function and is likely to involvethe inhibition of IL-1 $beta$ -converting-enzyme-dependent pathways.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Virus survival within immunocompetent hosts requires multiple defensive strategies to evade antiviral and inflammatory responses.Poxviruses, which are among the largest animal viruses, have developedspecific and efficient strategies, including interference withcytokines and growth factors, inhibition of the complement cascade,reduction of inflammation, and repression of cellular immune recognition,to effectively propagate within the infected host (3, 38,47, 57, 60).

The genome of poxviruses is a linear large, double-stranded DNA molecule, encoding all the enzymes required for replicationand transcription of its DNA, in addition to virulence factors.Whereas the essential genes are located in the central part ofthe genome, the genes responsible for virulence and host-range(usually not essential) mostly map near the termini (17, 65,66). Some viral proteins help circumvent the host immune response,usually by mimicking cytokines or cytokine receptors. Poxvirusesproduce homologues to tumor necrosis factor (TNF) receptor (27,56), interleukin-1 $beta$ (IL-1 $beta$ ) receptor (2, 59), gamma interferon(IFN- $gamma$ ) receptor (4, 5, 61, 69), and chemokine inhibitors(25, 55). Poxviruses are also able to block the productionof some important cytokines by inhibiting the enzymes requiredfor their processing. This is the case for the Orthopoxvirus genusmembers, for which SPI-2 protein (also known as CrmA) is an inhibitorof the IL-1 $beta$ -converting enzyme (ICE) (33, 48, 50, 58,64).

Previously, we described the cloning and characterization of Serp2, a new myxoma virus-encoded serpin protein closely relatedto CrmA (46). Myxoma virus (MV), a member of the genus Leporipoxvirus,is responsible for myxomatosis, a disease fatal to the Europeanrabbit (Oryctolagus cuniculus). After an incubation period ofa few days following infection, the primary site of intradermalinoculation evolves as a lesion characterized by tissue degenerationand necrosis. Viral dissemination leads to a generalization ofthe symptoms in the skin, head, and genital region, together withthe development of gram-negative infections of the nasal and conjunctivalmucosae (20, 37). The disease is characterized by generaldysfunction of cellular immunity and multiple interruptions ofthe host cytokine network, with death as the most common outcomedue to extreme weakness and secondary respiratory tract infections.

A number of MV proteins have been described to function as virulence factors, including M-T1 (25), M-T5 (39), M-T7 (40),M-T2 (69), SERP-1 (34, 67), M11L (45), and myxoma growthfactor (45); most of these are proteins that interfere directlywith effectors of the host immune system. The importance of Serp2to myxoma virus replication in vitro and in vivo has not beeninvestigated. We report here the characterization of Serp2 asanother critical virulence factor of MV. Disruption of the Serp2open reading frame resulted in an MV mutant that replicated normallyin vitro and in vivo but was highly attenuated upon infectionof European rabbits. Loss of MV virulence was correlated withmarked increase of inflammatory and apoptotic responses in animalsinoculated with Serp2 mutant virus. These in vivo findings are well explained by theresults from our previous in vitro experiments suggesting thatSerp2 can specifically inhibit ICE.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Cells and viruses. The MV strains T1 and Lausanne, the Serp2 mutant virus, the Shope fibroma virus (SFV), the vaccinia virus MVA, and the recombinantvaccinia virus MVA-HIV-nef were grown in the rabbit kidney cellline RK13 maintained in Dulbecco's minimum essential medium supplementedwith 10% fetal calf serum. The revertant MV-Serp2 rev was selectedin HGPRT HeLa cells (30). Rabbit CD4⁺ T lymphocytes, RL5 (29), were maintained in RPMI 1640 (GibcoBRL) supplemented with 10% fetal calf serum.

Construction of MV-Serp2 mutant and revertant viruses. The MV serp2 gene was cloned into the Bluescript phagemid expression vector as described previously (46). DNA of this plasmidwas used as template to PCR amplify the DNA fragments MV-serp2Land MV-serp2R. The following primers were used: 5'serp2-1 5'-XhoI-CAGCTC GAG CGT CGG CAG TCT TCG TTT CTC CCCG-3'; 5'serp2-2 5'-PstI-CAGCTG CAG GCC CTC GTT CCT CAC GTC CACG-3', 3'serp2-1 5'-ClaI-CAGATC GAT CCC GTA CGA GTA CGG GTA CTCC-3', and 3'serp2-2 5'-SacI-CAGGAG CTC CGC GTA CGG GGG ACT GTT TAA ACG CG-3'. Amplified MV-serp2Land MV-serp2R DNA was digested with XhoI/PstI and ClaI/SacI, respectively,and inserted into pRBgpt flanking an expression cassette containingthe Escherichia coli guanosine phosphoribosyltransferase (gpt)gene under the control of the vaccinia virus early-late promoter7.5K (18). The resulting plasmid, called pserp2:gpt, was usedfor transfection into MV-infected cells. MV-Serp2 mutant MV was isolated selecting for resistance against mycophenolicacid (19).

An MV-Serp2 rev revertant virus containing a wild-type Serp2 open reading frame was constructed by transfecting plasmid DNAcontaining the complete serp2 gene into MV-Serp2-infected RK13 cells and by using reverse gpt selection on HeLacells (28) to isolate revertants. PCR and Southern blot analysisof viral DNA was used to confirm the disruption of the Serp2 openreading frame by insertion of the p7.5 gpt expression cassette,the absence of detectable wild-type virus in preparations of MV-Serp2 mutant virus, and the restoration of the serp2 gene in MV-Serp2rev revertant virus. Immunoprecipitation of labeled proteins withanti-Serp2 antibodies was used to confirm the presence of a 34-kDaprotein in extracts of cells infected with the wild-type or theMV-Serp2 rev revertant viruses, as well as the absence of anyspecific protein in extracts from MV-Serp2 mutant virus-infected cells.

Single-step growth analysis in cell culture. RL5 cells (5 × 10⁵) were infected with MV strain T1 or MV-Serp2 at a multiplicity of infection of 5 for 2 h. Unadsorbed freevirus was removed, cells were washed with serum-free medium threetimes, growth medium was added, and cells were incubated at 37°C.Cultures were harvested at multiple time points postinoculation,and virus was released by freeze-thawing and brief sonication.Virus titers in these lysates were determined by standard plaquetitration on RK13 cells monolayers. Single-step growth experimentswere performed in triplicate.

Apoptosis assays. To determine whether Serp2 could inhibit TNF- $alpha$ -mediated apoptosis, 2 × 10⁴ HeLa cells in microtiter plates were infected with wild-typeor MV-Serp2 MV at a multiplicity of infection of 100, in RPMI containing10 µM BrdU (bromodeoxyuridine). At 15 h postinfection, the cellswere rinsed twice and fresh medium supplemented with serum wasadded. TNF- $alpha$ (10 ng/ml; Boehringer-Mannheim) and cycloheximide(40 µg/ml; Sigma) were added, and apoptosis was assessed 8 h laterby cellular DNA fragmentation enzyme-linked immunosorbent assay(ELISA) (Boehringer-Mannheim) according to the recommendationsof the manufacturer. The cells were harvested by the additionof lysis buffer, which leads to a release of fragmented DNA fromthe cytoplasm to the supernatant. After an incubation of 30 minat room temperature, followed by a centrifugation at 250 × g for10 min, the supernatants were transferred to an ELISA plate precoatedwith anti-DNA antibodies, and the amount of BrdU present in eachsample was determined by using anti-BrdU peroxidase conjugatesolution and its substrate with a spectrophotometer at 450 nm.Mock-infected cells, in the presence of TNF- $alpha$ and cycloheximide,were used as a positive control, and cells cultured for 8 h withcycloheximide in the absence of TNF- $alpha$ were used as a negativecontrol.

Antibody binding and flow cytometry analysis. RL5 cells (2 × 10⁶) were infected with MV strain T1, MV-Serp2, MV strain Lausanne, SFV, vaccinia virus MVA, or recombinantvaccinia virus MVA-HIV-nef at a multiplicity of infection of 5for 2 h. Unadsorbed virus was removed, and the cells were washedwith serum-free medium three times and then with medium supplementedwith serum; the cultures were then harvested at 24 h postinfection.Cells were rinsed twice in RPMI supplemented with 1% serum andresuspended in 100 µl RPMI or binding buffer (137 mM NaCl, 12mM NaHCO₃, 2.6 mM KCl, 2 mM MgCl₂, 5.6 mM glucose; pH 7.4) (11).CD4 monoclonal antibodies (Spring Valley Laboratories) were addedat a concentration of 25 µg/ml to the cells in RPMI, and classI major histocompatibility complex (MHC) monoclonal antibodies(Spring Valley Laboratories) were added at a concentration of25 µg/ml to the cells in binding buffer. After an incubation of20 min at 4°C, the cells were rinsed in RPMI before addition offluorescein isothiocyanate-conjugated goat anti-mouse antibody.The mixture was incubated for a further 20 min at 4°C. The cellswere then rinsed twice in RPMI and resuspended in phosphate-bufferedsaline for analysis on a fluorescence-activated cell sorter Caliburflow cytometer (Becton Dickinson). Data were acquired from 20,000cells and analyzed with CellQuest software. Experiments usingisotypic immunoglobulin G1 were used as nonspecific binding controls.Analysis with all antibodies and all viruses were performed intriplicate.

Infection of rabbits with MV-Serp2 mutant virus. Eight-week-old male New Zealand White rabbits (Oryctolagus cuniculus) were obtained from a local supplier and housed in biocontainmentfacilities under the guidelines of the European Community Councilon Animal Care. Injections were performed intradermally in theright ear with 5 × 10³ PFU of virus per animal. Rabbits which became moribund were sacrificedafter anesthetization with T61 (Distrivet) administered intravenously.For histological studies, six rabbits each were inoculated withMV T1 strain or MV-Serp2 as described above. At 4, 8, and 11 days postinoculation, twoanimals from each group were sacrificed. Two mock-infected rabbitswere sacrificed and used as controls.

Histological examination. All animals were subjected to a complete postmortem examination. Tissue material from the injection site (ear; primary site)and ocular conjunctiva, parotid lymph node, spleen, lungs, andtestis were taken and stored in 10% neutral formalin for furtheranalysis. After fixation, tissues were processed routinely intoparaffin blocks, sectioned at 4 µm, and stained with hematoxylinand eosin for microscopic examination. Histologic lesions wereassessed and graded as follows: +, minimal; ++, light; +++, moderate;++++, marked; and +++++, severe. The TUNEL method was used toassess apoptosis of lymphocytes in parotid lymph nodes and spleen.For this reaction, two thymuses of young mice treated with corticoidswere used as positive controls. Conventional histologic sections,pretreated with 20 µg of proteinase K per ml (Boehringer-Mannheim)for 15 min at 37°C, were incubated with digoxigenin-labeled dUTPand terminal deoxytransferase (ONCOR), according to the recommendationsof the manufacturer. The samples were stained using anti- digoxigeninperoxidase-conjugated antibodies. The localized peroxidase thencatalytically generated a signal from a chromogenic substrate(3,3'-diaminobenzidine with nickel). The following form of grading,based on the number of apoptotic bodies for each microscopic fieldat a ×400 magnification, was used: +, minimal apoptosis, 25 to50 apoptotic bodies; ++, light apoptosis, 50 to 75 apoptotic bodies;+++, moderate apoptosis, 75 to 100 apoptotic bodies; ++++, markedapoptosis, 75 to 100 apoptotic bodies; and +++++, severe apoptosis,125 to 150 apoptotic bodies.

Immunostaining of histologic sections. Viral antigens in paraffin-embedded sections of ear (primary site) and parotid lymph node were reactivated by using 0.1% trypsinin phosphate-buffered saline (pH 7.6) for 30 min at 37°C. Afterneutralization of endogenous peroxidase and before incubationwith the specific primary antibody (rabbit hyperimmune serum anti-MV),the samples were incubated in goat preimmune serum. This stepwas performed in order to minimize the background generated bythe secondary antibody (biotinylated goat anti-rabbit immunoglobulinG) provided by Dako (kit K492). Horseradish peroxidase-streptavidincomplex was added and revealed by DAB (3,3'-diaminobenzidine tetrahydrochloride),which formed a brown precipitate. Nuclei were counterstained withMayer's hematoxylin.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Construction and characterization of MV-Serp2 mutant and revertant. The Serp2 open reading frame is present as a single-copy gene in the MV genome (46) located within the EcoRI-F restrictionfragment. To construct MV mutant virus, we disrupted the Serp2open reading frame by targeting insertion of the Ecogpt markergene under the control of the vaccinia virus p7.5 promoter byhomologous recombination precisely to a site within the Serp2coding sequence, resulting in a 30-bp deletion in the coding sequence.Using a standard dominant selection method (12, 19, 68),we isolated an MV-Serp2 mutant virus able to replicate in the presence of mycophenolicacid. As a control we constructed a revertant virus derived fromMV-Serp2 in which the complete Serp2 open reading frame was restored andwhich was referred to as MV-Serp2 rev.

To ensure correct disruption of the serp2 gene and its authentic restoration in MV-Serp2 rev, viral DNA was analyzed by PCRwith the specific primers 5'serp2-1 and 3'serp2-2. Agarose gelelectrophoresis of DNA amplified from wild-type- and MV-Serp2rev-specific template DNA revealed fragments corresponding insize (1,130 bp) to the expected molecular weight of the completeSerp2 coding sequence (data not shown). In contrast, a DNA fragmentof 2,850 bp could be amplified from MV-Serp2 DNA, which indicated the presence of additional genomic sequencedue to the integration of the gpt expression cassette. Furthermore,this analysis confirmed the genetic purity of MV-Serp2 mutant virus as shown by the failure to amplify a detectableDNA band corresponding in size to the wild-type Serp2 coding sequence.Additionally, Southern blot analysis of viral DNA revealed characteristicrestriction patterns for the wild-type, MV-Serp2, and MV-Serp2 rev genomes (data not shown). Since only 30 bpof the serp2 open reading frame were missing, we wanted to makesure that the protein could not be produced, even as a truncatedform. Immunoprecipitation with a specific anti-Serp2 antiserum(46) revealed a polypeptide of 34 kDa, corresponding to Serp2,in extracts from RK13 cells infected by either the wild-type orthe MV-Serp2 rev virus, but no specific band could be visualizedon extracts from cells infected with the MV-Serp2 mutant (data not shown).

Comparison of pocks formed on the chorioallantoic membrane. The chorioallantoic membrane (CAM) of chick embryos has been widely used to study the acute inflammatory response to poxvirusinfection. In that system the wild-type cowpox virus produceshemorrhages, whereas a mutant lacking the crmA gene produces whitepocks characterized by an influx of inflammatory cells (22,48). To compare the lesions produced on CAM, 9-day-old embryonatedeggs were infected with 10⁵ PFU of wild-type MV or MV-Serp2 mutant. After 5 days of incubation at 33°C, an examination ofthe CAM revealed small white pocks (ca. 1 mm in diameter) whichwere present on CAM infected with either virus. No hemorrhagewas detected. Furthermore, the pocks formed by both viruses didnot differ in number or other morphology.

MV-Serp2 mutant efficiently replicates in rabbit kidney cell and CD4⁺ T-cell lines. No defects in the ability of MV-Serp2 to replicate in cultured rabbit RK13 fibroblasts in vitro were noted in a single-stepgrowth curve analysis. Similar results were also found in a culturedrabbit RL5 CD4⁺ T-cell line (data not shown).

MV-Serp2 mutant fails to induce apoptosis upon cell culture infection. Since we have demonstrated previously that Serp2 exhibits ICE inhibiting activity and that the ICE family, recently namedthe caspases, plays a central role in the execution of apoptosis,we were interested in investigating apoptotic cell death afterinfection with MV-Serp2 mutant virus.

Since MV-Serp2 could replicate with wild-type kinetics in RL5, these cells were not expected to be a good model for investigatingan antiapoptotic role for Serp2. Indeed, when using DNA fragmentationELISA, we found no apoptosis in RL5 cells, infected with eitherwild-type or MV-Serp2 MV.

MV-Serp2 mutant virus inhibits TNF- $alpha$ -mediated apoptosis. In a similar way we also studied HeLa cells, which are susceptible to TNF- $alpha$ -mediated apoptosis. We measured the cellular DNAfragmentation (ELISA test) after infection with wild-type MV orMV-Serp2 and after treatment with TNF- $alpha$ and cycloheximide. Mock-infectedcells, in the absence of TNF- $alpha$ , showed no sign of apoptosis. Incubationwith TNF- $alpha$ and cycloheximide induced apoptosis, as measured 8h after treatment. There was no significative apoptosis in cellsinfected with wild-type MV. The results were the same with cellsinfected with MV-Serp2, indicating that Serp2 is not necessary for the inhibition ofTNF-induced apoptosis in HeLa cells (data not shown).

Effect of Serp2 on the level of cell surface antigens. Since it has been shown that there is a decrease of the class I MHC surface expression at 24 h after infection with MV strainLausanne (11), we investigated whether disruption of the Serp2open reading frame could influence the expression of these antigensat the cell surface. Having checked that mock-infected RL5 cellsshowed strongly positive surface staining with monoclonal antibodyagainst the class I MHC, we saw no striking difference in thedownregulation of MHC I on the surface of RL5 cells infected withwild-type MV strain T1 or with MV-Serp2 mutant virus (data not shown). These results suggest that Serp2is not implicated in the downregulation of MHC I antigens on thesurface of T-lymphocyte cells.

It has also been published that upon infection with MV, the level of CD4 surface antigens was markedly reduced (8). Ina similar way, we also investigated the influence of serp2 disruptionon the described phenotype. Mock-infected RL5 cells showed a strongpositive surface staining with anti-CD4 antibodies. After infectionwith wild-type MV strain T1 or Lausanne, there was a slight decreasein surface CD4 levels; the same observation could be made afterinfection of RL5 cells with MV-Serp2 mutant. Infection of RL5 cells with vaccinia virus expressingHIV-nef led to a severe downregulation of CD4 molecules and servedas a positive control (data not shown). These results suggestthat Serp2 has no impact on the downregulation of CD4 antigenson the surface of RL5 cells.

MV-Serp2 is an important virulence factor in the European rabbit. European rabbits infected with wild-type MV (strain T1 or Lausanne) rapidly develop a routinely 100% fatal disease known asmyxomatosis. As well as being able to activate CPP32, an importantcell death protease, ICE is known to liberate bioactive IL-1 $beta$ ,a proinflammatory lymphokine that can alert neighboring cellsof the immune system. This signaling may allow inflammatory cellsto activate and accumulate at a site where cell suicide is beingused as an antiviral defense (70). Therefore, the putative anti-ICEactivity of Serp2 tempted us to determine the effects of a serp2disruption on MV virulence in vivo. Three groups of animals wereinfected with wild-type MV (n = 4), MV-Serp2 mutant virus (n = 10), or MV-Serp2 rev (n = 4). We observed amarked reduction in virulence in rabbits infected with MV-Serp2 compared to rabbits infected with wild-type MV or MV-Serp2 rev,respectively (Table 1). On day 4 postinfection, the inoculationsite was a diffuse inflammation in rabbits infected with MV-Serp2, larger and less circumscribed than in rabbits infected withwild-type MV or MV-Serp2 rev, in which a red and soft nodule,known as the primary myxoma, was present. At day 7 postinfection,when rabbits inoculated with either wild-type MV or MV-Serp2 revdemonstrated classical symptoms of myxomatosis and were prostrated,rabbits infected with MV-Serp2 had no skin lesions, such as secondary myxomas, on the head,body, or legs. They behaved normally and presented only a mildconjunctivitis. The ears were thickened and red. By day 11 postinfection,all eight rabbits infected with wild-type MV or MV-Serp2 rev hadto be sacrificed, whereas in MV-Serp2-infected rabbits, clinical signs of gram-negative infectionsin the conjunctiva and respiratory tract had developed, althoughthe usual state of health remained unchanged (Fig. 1). The respiratorysymptoms worsened between days 10 and 15, but no classical myxomaswere observed. Seven of ten animals infected with MV-Serp2 mutant virus completely recovered within 30 days. Only threerabbits had to be sacrificed because of respiratory infection(on days 14, 15, and 25), which yields an overall survival rateof 70% in animals infected with MV-Serp2 virus. In contrast, a 100% mortality was found in both groupsof control rabbits.

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TABLE 1. Pathogenicity of MV-Serp2 in European rabbits

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FIG. 1. Clinical course of rabbits at 10 days postinoculation. Rabbits infected with the wild-type MV (A and B) show secondary skin lesions turning necrotic on the head, the back, and the legs and edema of the testicles (A) and show primary and secondary myxomas on the ears, leading to abnormal posture, and on the nose and around the eyes, and blepharoconjunctivitis (B). Rabbits infected with the MV-Serp2 mutant (C and D) show no secondary skin lesions and little edema of the genital region (C); they also show marked diffuse inflammation of the ears and blepharoconjunctivitis (D).

Histologic analysis of lesions from wild-type virus and MV-Serp2-infected rabbits. In view of the significant difference in virulence of the MV-Serp2 mutant and the wild-type MV, we performed a more detailed histologicexamination of tissue material taken from both primary (ear) andsecondary (ocular conjunctiva and parotid lymph node) infectionsites at various times during the course of infection. Other samplesites (spleen, lungs, and testis) were realized to detect possiblehistologic lesions linked to a systemic spread of the virus. Inall animals, no lesion was observed in these tissues, whateverthe time after infection. The results of the complete analysisare summarized in Table 2.

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TABLE 2. Histologic observations of lesions from rabbits infected with the wild-type MV or the MV-Serp2 mutant

At day 4 postinoculation, the injection site of animals infected with wild-type MV demonstrated a light perivascular dermatitiswith focal edema and scattered heterophils. At the site of injectionof the MV-Serp2 mutant, the inflammatory response was qualitatively the samebut was less intense. A superficial perivascular conjunctivitiswas present in each case, though slightly more pronounced forthe wild-type virus. It should be noted that one rabbit inoculatedwith MV-Serp2 mutant showed a light lymphodepletion, while small lymphonoduleswere present in the lamina propria of the ocular conjunctiva inall other rabbits.

In the parotid lymph nodes, lesions induced by the two types of viruses differed significantly. A marked lymphadenitis withhistiocytosis and infiltration by heterophils was seen after infectionwith the wild-type MV, whereas the lesions caused by MV-Serp2 mutant virus were characterized by extensive focal depletionsof lymphocytes. The latter finding could well be the consequenceof vigorous cell death triggered by the viral infection even ifthis process cannot be determined on conventional histologic sections.

At day 8 postinoculation, the differences in the resulting pathologic pattern became even more evident. In primary sites,the lesions associated with the wild-type virus were a markedperivascular dermatitis with diffuse edema, focal interstitialhemorrhages, accumulation of heterophils, and a well-developedmyxoma (i.e., activated fibroblasts and interstitial mucinosis).In contrast, the lesions associated with the MV-Serp2 mutant presented two striking differences: they were much lessintense, and the sequential inflammatory cellular reactions progressedmore rapidly, as attested to by the presence of infiltrates ofmononuclear cells (histiocytes and lymphocytes). These observationsare also valid for the conjunctival lesions. The parotid lymphnodes of rabbits inoculated with the wild-type MV showed a markedlymphadenitis with secondary myxomas. The parotid lymph nodesof rabbits inoculated with MV-Serp2 mutant exhibited a severe lymphodepletion and no secondary myxomawas observed.

At day 11, the same major differences were noted, and some features must be pointed out: (i) a severe infiltration by heterophilspersisted at the primary sites of infection with the wild-typevirus, whereas for the MV-Serp2 mutant, mononuclear cells were predominant (Fig. 2); (ii) well-developedsecondary myxomas were seen only in secondary sites of rabbitsinoculated with wild-type MV; and (iii) a severe lymphodepletionwas present only in the parotid lymph node of MV-Serp2 mutant-inoculated rabbits.

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FIG. 2. Hematoxylin and eosin-stained skin samples from rabbits at 11 days postinoculation with wild-type MV (A and C) or with MV-Serp2 mutant (B and D). Magnification: ×40 (A and B); ×200 (C and D). The panels show perivascular dermatitis with diffuse edema, thrombosis and perivascular accumulation of heterophils (A); perivascular dermatitis with a less-severe edema and interstitial infiltrates of mononuclear cells (B); severe perivascular and interstitial accumulation of heterophils (C); and interstitial infiltrates of mononuclear cells (C).

From these observations we can conclude that the inflammatory reaction is far less hemorrhagic and more rapidly progressivein lesions induced by the MV-Serp2 mutant. This virus leads to a progressive, severe lymphodepletionin the parotid lymph node. No secondary myxoma was seen in thesecondary sites.

Histologic assessment of lymphoid apoptosis. The TUNEL method was used to assess apoptosis of lymphocytes in the parotid lymph node and spleen of 12 inoculated rabbitsand 2 control animals. The main results for the parotid lymphnode are summarized in Table 3. The two controls showed minimalapoptosis (25 to 50 apoptotic bodies for each microscopic fieldat a ×400 magnification), mainly located in the germinal centers.For rabbits inoculated with wild-type MV, apoptosis of lymphocyteswas at the same level and showed the same localization as controls,whatever the day of the experiment (Fig. 3A). The foci of apoptoticheterophils were seen; they could be easily distinguished fromapoptotic lymphocytes by cytologic criteria.

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TABLE 3. Histologic assessment by the TUNEL method of lymphoid apoptosis in the parotid lymph nodes of rabbits infected with wild-type MV or MV-Serp2 mutant

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FIG. 3. Parotid lymph node (TUNEL method). The panels show samples at 8 days postinoculation with the wild-type MV, with minimal lymphocytic apoptosis (A), and infection with the MV-Serp2 mutant at 4 days postinoculation, with focal extensive lymphocytic apoptosis in cortical areas (arrows) (B); at 4 days postinoculation, with focal extensive lymphocytic apoptosis at a higher magnification (C); and at 11 days postinoculation, with remnants of apoptotic foci in a lymphodepleted parenchyma (arrow) (D). Magnification: ×100 (A); ×40 (B); ×100 (C); ×40 (D).

The parotid lymph nodes of rabbits inoculated with the MV-Serp2 mutant underwent apoptosis, with major differences from the controls:at day 4 postinoculation, a focal extensive apoptosis was initiatedin an area of the lymph node (Fig. 3B and C). The grade of thetwo rabbits was different (light versus severe). Foci of apoptoticheterophils were also seen. At day 8 postinoculation, the parotidlymph node of both rabbits showed a severe focal extensive apoptosis.At day 11, large areas of the parotid lymph node contained onlyremnants of apoptotic bodies for each animal (Fig. 3D). Tracesof localized extensive foci persisted. In intact remaining lymphoidtissue, a light increase in the number of apoptotic lymphocyteswas noticed.

From these results we conclude that lymphodepletion in the lymph node draining the primary site is imputable to apoptosisof lymphocytes. Apoptosis of lymphocytes in the spleen was thesame in rabbits injected either with the wild-type MV or withthe MV-Serp2 mutant and was identical to the controls.

Virus load in tissues. In order to make sure that the striking phenotypic differences between the wild-type and the MV-Serp2 mutant could not be attributed to an impairment of the lattervirus to replicate in vivo, we quantified the level of viral replicationat the inoculation site and the parotid lymph node. Standard immunohistochemicalstudies were carried out, and the levels of virus replicationin tissues stained with anti-MV antibodies were quantified bycounting the number of infected cells per square millimeter.

At days 4, 8, and 11 postinoculation, there was the same level of virus replication at the injection site of either the wild-typeor the MV-Serp2 mutant (not shown); comparable results were obtained in the parotidlymph node (Fig. 4). Eight days after infection with the wild-typeMV, the cells in the lymph node (mostly fibroblasts and histiocytes,which are characteristic of the secondary myxomas) were positivelystained with the anti-MV antibodies (Fig. 4A). With the MV-Serp2 mutant, the cell populations were different (mostly mononuclearcells, which from morphologic criteria could be defined as lymphocytes),but the viral load, according to our semiquantitative measure,was on the same order of magnitude (Fig. 4B). From these resultswe conclude that the MV-Serp2 mutant is able to replicate in vivo at a level comparable tothat of the wild-type MV.

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FIG. 4. Parotid lymph node (immunohistochemistry) from rabbits at 8 days postinoculation (×400). Infected cells are visualized with DAB (arrow). (A) Infection with the wild-type MV. The cells present in the lymph node are mostly histiocytes and activated fibroblasts (large nucleus, double arrows). These and other cells are infected. (B) Infection with the MV-Serp2 mutant. Most cells are infected, and mononuclear cells are predominant.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

In this study we report data to elucidate the functions of the MV Serp2 protein, which is 35% identical to the cowpox virusCrmA protein. CrmA has been characterized as viral inhibitor ofICE (caspase 1), which can prevent the onset of both inflammationand apoptosis by reducing the levels of the active proinflammatorylymphokines IL-1 $beta$ and IL-18 and by preferentially inhibiting theproximal components of the ICE/CED-3 protease cascade in the celldeath process (33, 48, 50, 58, 64). CrmA also has ahigh affinity for caspase 8 or FLICE (72) and Granzyme B (49).More importantly, Serp2 was also previously shown to bind to humanICE and prevent it from processing the pro-IL-1 $beta$ into its bioactiveform (46). Therefore, Serp2 was another candidate poxvirus-encodedfactor to counteract host defenses and to potentially contributeto the pathology associated with MV infection.

To assess the role of Serp2 in the pathogenesis of myxomatosis, we successfully engineered a fully replication-competent MVmutant deleted in the Serp2 open reading frame. Revealing a wild-type-likephenotype when grown in vitro, the mutant virus was found to behighly attenuated upon in vivo infection in rabbits. The clinicalcourse of infection with MV-Serp2 mutant was characterized by the development of mild and more-diffuseprimary myxoma lesions at the site of inoculation, the absenceor benignity of rare secondary lesions and, most impressively,by the high rate of complete recovery seen in the infected animals.

Detailed histologic examination led to three major findings. First, the inflammatory response upon inoculation with wild-typeMV seemed to be arrested at the vascular level (with heterophilspredominant even at a late time), whereas with the MV-Serp2 mutantthe inflammation proceeded to the cellular phase (with lymphocytesand histiocytes infiltrating the lesion). In this latter casethe overall reaction was less intense and less hemorrhagic thanwhen Serp2 was present. The inhibition of IL-1 $beta$ processing bySerp2 is in accordance with these observations. IL-1 is a potentproinflammatory cytokine that can affect the function of manyphysiologic systems (for a review, see reference 15). Amongthe pleiotropic effects of IL-1 $beta$ , including thrombosis and inflammation,is an increased expression of the immunoglobulin superfamily moleculesICAM-1 and VCAM-1, which bind to integrins on lymphocytes andmonocytes (14, 24). By blocking IL-1 $beta$ processing, Serp2 woulddiminish the ability of these cells to migrate into the inflamedtissue. Moreover, ICE is involved in the processing of pro-IL-18into its active form (23, 26). IL-18, also known as IFN- $gamma$ -inducingfactor, stimulates the production of IFN- $gamma$ by lymphocytes (42,44). As for IL-1 $beta$ , the effects of IFN- $gamma$ are numerous, includingthe chemoattraction of macrophages (10, 43, 71). This phenomenonwas also occurs after infection with a mutant lacking a secretedhomolog of the IFN- $gamma$ receptor; Mossman et al. (40) reportedthat infection with the IFN- $gamma$ receptor-deficient MV resulted inan inversion of the heterophil/mononuclear cell ratio at the secondarysites. Our histologic findings, although not definitely provingwhich cytokine defect is involved, are consistent with the hypothesisthat the presence of Serp2 leads to a reduced amount of both IL-1 $beta$ and IFN- $gamma$ at the infection sites.

Our second important histologic observation was that lymphocytes, in the absence of Serp2, undergo apoptosis which can bequantified in the parotid lymph nodes. According to the spatialdistribution of the apoptotic foci in the lymph nodes, it is reasonableto assume that apoptosis occurred in the lymph node itself, aswell as in lymphocytes drained from the inoculation site. ICEhas been widely recognized as an important mediator of the apoptoticprocess (reviewed in references 7 and 41). The impairingof ICE by Serp2 would be in accordance with an inhibition of theapoptotic process by the wild-type virus, but not by the MV-Serp2 mutant virus. However, in our in vitro experiments, the defectin Serp2 production did not lead to apoptosis of RL5 T-helperlymphocytes. This cell line has been widely used to study otherMV genes. MV lacking the TNF receptor homologue (53), the M11L-gene(35), and the host-range superfamily member M-T5 (39) haveall been shown to induce apoptosis in this cell line. The reasonwhy all these mutants display the same phenotype in RL5 cellsis not clear. M-T5 might counteract the shutoff of protein synthesisafter MV infection (39), but M-T2 does probably not block apoptosisvia its TNF binding domain (53). M11L is a transmembrane proteininvolved in the repression of inflammation, but its target isunknown (43). On the other hand, the cell-type dependence ofapoptosis inhibition by viral products has been widely reported(6, 13, 21, 51). In that context, it is clear that RL5cells are not the best model for checking Serp2 inhibition ofICE-mediated apoptosis.

There are several reports that either cowpox CrmA (62) or its homologue vaccinia virus SPI-2 protein (16, 32) can inhibitFas-mediated apoptosis. However, in our experiments Serp2 wasnot required for the inhibition of TNF-induced apoptosis in HeLacells. Several hypotheses underlie our findings. The first possibilityis that, although reported to be unable to bind to human TNF- $alpha$ (52), the MV TNF receptor homologue was responsible for thisinhibition; another possibility is that there exists an as-yet-unidentifiedantiapoptotic factor encoded by MV, whose role would be to preventTNF-induced apoptosis. It has recently been shown that the MC159protein of Molluscum contagiosum, another member of the poxvirusfamily, could inhibit Fas- and TNFR1-induced apoptosis throughits death effector domain (9). It is thus possible that MVencodes one or more proteins that would prevent ICE activationin cell culture.

Since it has been reported that MV could downregulate the expression of CD4 (8) and MHC I molecules (11) on the surfaceof infected cells, we checked whether Serp2 could account forthis phenotype. In fact, we could see no difference in the relativedecrease of either CD4 or MHC I antigens of RL5 cells infectedwith the wild-type or the MV-Serp2 mutant. The effect of MV on the expression of these surface moleculeswas light in both cases compared to the more drastic effect observedupon the vaccinia virus-mediated expression of the human immunodeficiencyvirus type 1 nef gene (1, 54). It was particularly relevantto check for a possible implication of Serp2 in MHC I downregulation,since this would have interfered with the apoptosis process. Anydecrease in MHC I expression at the surface of infected cellswould result in the inability of the cytotoxic T lymphocytes tobind to these cells and to recognize them as targets. Since Serp2is not interfering with MHC I expression, the marked differencein the lymphocyte apoptosis observed in vivo cannot be attributedto a modification of the immune effectors on the membrane of theinfected cells. More likely, the difference is due to an antiapoptoticeffect of Serp2.

The last histologic finding was that in the secondary sites (ocular conjunctiva and lymph nodes) there were no so-called secondarymyxomas upon infection with the MV-Serp2 mutant, contrasting with the wild-type MV. The molecular mechanismby which MV induces the formation of myxomas is unclear, but itshould not be attributed only to the presence of the virus inthe tissue. Indeed, we were able to show that the MV-Serp2 mutant can replicate as efficiently as the wild-type virus atthe inoculation site and in the parotid lymph node. The comparablelevel of viral loads between both viruses indicates that the clinicaland histologic differences observed cannot be attributed simplyto a more poorly growing mutant virus. We were able to show thatthe lymphocytes in the lymph node of rabbits infected with theMV-Serp2 mutant are indeed infected.

Our conclusions from these observations are that in the MV, Serp2 is able to block both the processing of the inflammatoryreaction at an early stage and apoptosis of the lymphocytes. Itseems relevant to associate these phenomena with the inhibitionof caspase 1 and/or another aspartic acid-specific protease.

It was previously reported that inactivation of the crmA gene of cowpox virus or its equivalent SPI-2 gene of rabbitpox virusresulted in an attenuation of the clinical course, as measuredby the body weight of mice after intranasal infection (63).However, the cowpox and rabbitpox viruses differed in the inflammatoryresponse. An acute inflammatory response was described as associatedwith disruption of the SPI-2 gene in the rabbitpox virus, whereasdisruption of the open reading frame on the cowpox virus seeminglyresulted in a decreased influx of inflammatory cells. Using thesame murine intranasal model, other authors have reported thatinactivation of the SPI-2 gene of the vaccinia virus had no effecton virus virulence (31). These contradictory results concerningthree members of the Orthopoxvirus genus may be attributed toeither true differences in the viruses or to mutations acquiredelsewhere in the genomes, since neither cowpox nor rabbitpox revertantviruses were produced (63). However, in each case the mice hadbeen inoculated intranasally. Here, we have been using the intradermalroute, which seems more relevant since rabbits get contaminatedthrough fleas or mosquito bites (20). It is also unlikely thatmutations acquired elsewhere in the genome are responsible forour results since restoration of the wild-type phenotype was observedwith the revertant virus. So we can state that what we describehere truly reflects the role of Serp2 during the course of a naturalinfection.

The actual targets of Serp2 in vivo have not been found yet. Indeed, in previous experiments we were able to visualize a complexbetween Serp2 and human ICE, and the processing of pro-IL-1 $beta$ byICE was inhibited by Serp2 produced in a baculovirus expressionsystem (46). It is also reported, however, that CrmA can forma complex with ICE (caspase 1) (50), Cpp32 (caspase 3), FLICE(caspase 8), and Mch2 (caspase 6) (72); CrmA also has some inhibitoryeffect upon these four proteases (33, 72). However, kineticsanalysis indicates that caspase 1 and caspase 8, but not caspase3 and caspase 6, are direct targets of CrmA in vivo (72).

It has recently been demonstrated that, although the products of SPI-2 and crmA were thought to be equivalent, these two serpinsactually have distinct effects on the caspases (36). Both proteinscan block ICE activity in vitro (36). However, SPI-2 is unableto prevent apoptosis in pig kidney cells, whereas CrmA is a potentinhibitor. These results suggest that SPI-2 and CrmA have differenttargets in vivo.

It is likely that, like CrmA, Serp2 has more than one target. Our in vivo data support the hypothesis that ICE is one of them.Unlike CrmA and SPI-2, which are only expressed early during infection,Serp2 is expressed both at early and late times (46). It isnot surprising that its extra target(s) might be different fromthose of CrmA or SPI-2.

There is currently a better knowledge of the viral genetic functions important for the pathogenesis of the leporipoxvirusgenus, and several factors have been characterized to date. Theseinclude the MV TNF receptor (68); the IFN- $gamma$ receptor homolog(69); M-T5, which is a member of the host range superfamily(39); M11L and myxoma growth factor (MGF) (45); SERP-1, whichis a serpin-like protein that interferes with inflammation (34,67); and M-T1, a 35-kDa protein recently described as a chemokine-bindingprotein (25). Serp2 appears as a critical component of the immuneevasion strategy elicited by MV. Further dissection of the multipleconsequences of the inhibition of ICE and/or other caspases bySerp2 will be informative regarding the relative importance ofinflammation and apoptosis for eliminating the virus.

	ACKNOWLEDGMENTS

We are grateful to G. McFadden and G. L. Smith for kindly providing us with RL5 cells and HGPRT HeLa cells, respectively. We also thank V. Lourec for monitoringthe rabbits.

This work was supported by a grant from Institut National de la Recherche Agronomique.

	FOOTNOTES

^* Corresponding author. Mailing address: Laboratoire Associe de Microbiologie Moleculaire, INRA-ENVT, Ecole Nationale Vétérinaire,23 Chemin des Capelles, F-31076 Toulouse cedex 3, France. Phone:(33) 561-19-38-78. Fax: (33) 561-19-39-74. E-mail: s.bertagnoli{at}envt.fr.

REFERENCES

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Abstract
Introduction
Materials & Methods
Results
Discussion
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Serp2, an Inhibitor of the Interleukin-1-Converting Enzyme, Is Critical in the Pathobiology of Myxoma Virus

Serp2, an Inhibitor of the Interleukin-1 $beta$ -Converting Enzyme, Is Critical in the Pathobiology of Myxoma Virus