Murine Cytomegalovirus m41 Open Reading Frame Encodes a Golgi-Localized Antiapoptotic Protein

Viruses have evolved various strategies to prevent prematureapoptosis of infected host cells. Some of the viral genes mediatingantiapoptotic functions have been identified by their homologyto cellular genes, but others are structurally unrelated togenes of known function. In this study, we used a random, unbiasedapproach to identify such genes in the murine cytomegalovirusgenome. From a library of random transposon insertion mutants,a mutant virus that caused premature cell death was isolated.The transposon was inserted within open reading frame m41. Anindependently constructed m41 deletion mutant showed the samephenotype, whereas deletion mutants lacking the adjacent genesm40 and M42 did not. Apoptosis occurred in different cell types,could be blocked by caspase inhibitors, and did not requirep53. Within the murine cytomegalovirus genome, m41, m40, andm39 form a small cluster of genes of unknown function. Theyare homologous to r41, r40, and r39 of rat cytomegalovirus,but lack sequence homology to UL41, UL40, and UL37 exon 1 (UL37x1)which are located at the corresponding positions of the humancytomegalovirus genome. Unlike UL37x1 of human cytomegalovirus,which encodes a mitochondrion-localized inhibitor of apoptosisthat is essential for virus replication, m41 encodes a proteinthat localizes to the Golgi apparatus. The murine cytomegalovirusm41 product is the first example of a Golgi-localized proteinthat prevents premature apoptosis and thus extends the lifespan of infected cells.

INTRODUCTION

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Introduction

The programmed cell death (apoptosis) of a virus-infected cellis a strategy of the host organism to prevent virus replicationand spread. Apoptosis can occur as a direct result of virusinfection or can be triggered by immune effector cells thatrecognize infected cells. As a counterstrategy, viruses havedeveloped mechanisms to inhibit apoptosis and extend the lifespan of the infected cell (31, 44).

Herpesviruses possess large double-stranded DNA genomes. Theyencode up to 200 genes, many of which modulate intrinsic functionsof the host cell (38). Cytomegaloviruses (CMVs), prototypesof the ß subgroup of the Herpesviridae, are the largestof the herpesviruses. With protracted replication cycles of ${approx}$ 24 h for murine cytomegalovirus (MCMV) and 48 to 72 h for humancytomegalovirus (HCMV), these viruses are particularly vulnerableto elimination by apoptosis. Therefore, it is not surprisingthat CMVs have acquired a number of genes that prevent prematureapoptosis of the infected host cell.

The immediate-early genes IE1 and IE2 of HCMV were the firstCMV genes for which an antiapoptotic function was demonstrated.The IE1 and IE2 proteins both inhibit the induction of apoptosisby tumor necrosis factor alpha or by an E1B 19-kDa protein-deficientadenovirus (50). More recent work demonstrated that inhibitionof apoptosis by IE1 and IE2 involves activation of the phosphatidylinositide3'-OH kinase pathway and the cellular kinase Akt (49).

Two additional HCMV genes expressed at immediate-early timesafter infection have been shown to inhibit apoptosis at differentlevels. The product of open reading frame (ORF) UL37 exon 1(pUL37x1) encodes a mitochondrion-localized protein. It formsa complex with the adenine nucleotide translocator and suppressesapoptosis by blocking permeabilization of the mitochondrialouter membrane (17). The UL37x1 protein also disrupts mitochondrialnetworks (28). It shows no significant amino acid homology toBcl-2 and does not bind BAX or the mitochondrial voltage-dependentanion channel VDAC, suggesting that pUL37x1 represents a separateclass of cell death inhibitors (16). The product of UL36 bindsto the prodomain of caspase 8 and prevents its activation (40).It lacks sequence similarity to viral or cellular FLICE-inhibitoryproteins and to other known antiapoptotic proteins.

The antiapoptotic function of these HCMV genes was studied incells expressing the isolated genes but not in the context ofviral infection. However, it has been shown that UL36 is dispensablefor virus growth in cell culture (32) and that this gene ismutated in the most commonly used laboratory strains, AD169and Towne (32), owing to a missense mutation or partial deletionthat renders the UL36 protein nonfunctional (40). In fact, theHCMV laboratory strains contain a number of known (9, 13, 30,40) and likely many more unknown mutations compared to freshclinical isolates. Unlike the clinical HCMV strains, which infectvarious cell types in human patients and in cell culture (35),the laboratory strains replicate almost exclusively in culturedhuman fibroblasts, precluding analysis of cell type-specificfunctions with virus mutants.

The laboratory strains of murine cytomegalovirus (MCMV) appearto be less degenerate than the HCMV laboratory strains, as MCMVlaboratory strains can replicate in various cell types in vitroand cause disease in experimentally infected mice. MCMV hasbeen used to study the genetic basis for endothelial cell tropism.A library of random transposon insertion mutants of the MCMVgenome was screened for mutants that had lost the ability toreplicate in endothelial cells in culture. A gene, M45, whichis required for virus growth and spread in endothelial cellsby preventing rapid onset of apoptosis in infected endothelialcells was identified (6). The mechanism of action of the M45protein has not yet been determined. M45 shows significant sequencehomology to the ICP10 protein of herpes simplex virus type 2,including the N-terminal protein kinase domain of ICP10. Twolaboratories have recently demonstrated that ICP10 can inhibitapoptosis and that the protein kinase domain is required forthis activity. However, the mechanism by which apoptosis issuppressed remains controversial (25, 33, 34).

In a different approach, systematic analysis of an entire viralgene family revealed that another MCMV gene had antiapoptoticactivity, which became apparent only in a specific cell type.Inactivation of gene M36, the genetic and functional homologof the HCMV gene UL36, led to a virus mutant with a severe growthdefect in macrophages but not in fibroblasts (29).

In the present study, we identified and analyzed a previouslyuncharacterized antiapoptotic gene of MCMV. We show that theproduct of ORF m41 is a Golgi-resident protein that is requiredto prevent premature apoptosis of infected cells and thus extendstheir life span.

MATERIALS AND METHODS

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Materials and Methods

Plasmids and retroviral vectors. ORFs m41 and UL37x1 were amplified by PCR with the primers listedin Table 1, introducing an influenza virus hemagglutinin (HA)epitope tag at the 5' or the 3' end of the coding sequence.PCR products were digested with BamHI and EcoRI or XhoI andEcoRI, respectively, and cloned into pcDNA3 (Invitrogen) togenerate pcDNA-m41HA, pcDNA-HAm41, and pcDNA-UL37x1HA. The integrityof the cloned m41 and UL37x1 sequences was verified by sequenceanalysis.

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TABLE 1. Oligonucleotide primers used in this study

Epitope-tagged genes were excised from pcDNA3 with the sameenzymes as above and cloned into pRetroEBNA (23) to obtain pRetro-m41HA,pRetro-HAm41, and pRetro-UL37x1HA. Amphotropic retroviral vectorswere generated by use of the Phoenix packaging cell line asdescribed previously (23).

Mutagenesis of CMV genomes. All mutant CMV genomes were generated in Escherichia coli basedon full-length bacterial artificial chromosome (BAC) clonesof the HCMV AD169 genome (22), the MCMV genome (pSM3fr) (47),and the MCMV-GFP genome. MCMV-GFP (kindly provided by M. Messerle)contains the enhanced green fluorescent protein (EGFP) genefrom pEGFP-C1 (Clontech) inserted into the MCMV ie2 locus. Theie2 gene has been shown to be dispensable for virus growth invitro and in vivo (8, 27).

A library of MCMV transposon insertion mutants has been publishedpreviously (6). The transposon insertion mutants were generatedby a single-step transposon mutagenesis protocol (5, 7) andtransferred to fibroblasts by bacterial invasion to obtain alibrary of mutant viruses (6). The transposon contains a kangene for selection in E. coli and the EGFP gene driven by anHCMV immediate-early promoter from pEGFP-C1. The location ofthe transposon insertion was determined by direct sequencingas described previously (7).

Gene deletion mutants were constructed by homologous recombinationin E. coli with linear, PCR-generated fragments. Briefly, azeocin resistance gene (zeo) was amplified by PCR from pEM7/Zeo(Invitrogen). The primers contained an additional 50 nucleotidesfor homologous recombination. See Table 1 for a complete listof the primers used in this study. Recombination of BACs withlinear DNA fragments was carried out in E. coli strain DY380as described previously in detail elsewhere (26). DY380 expressesthe recombination genes exo, bet, and gam of bacteriophage ${lambda}$ in a temperature-dependent fashion.

Tagging of viral genes was also performed by homologous recombinationwith linear fragments, essentially as described above. A kangene flanked by FRT sites was excised with EcoRI from plasmidpSLFRTKn (1) and inserted into pcDNA-m41HA. The resulting plasmid,pcDNA-m41HA-FK, served as the template for PCR amplificationof the influenza virus HA epitope sequence and the FRT-flankedkan gene. This cassette was inserted at the 3' end of the geneto be tagged. The kan gene was subsequently removed with FLPrecombinase expressed in E. coli strain DH10B from plasmid pCP20(11). For a detailed description of the gene tagging strategy,see the report by Uzzau et al. (45).

For molecular analysis, BACs were digested with different restrictionenzymes and separated on large 0.6% agarose gels. Southern blothybridizations were performed with a nonradioactive digoxigeninlabeling and detection kit (Roche). Mutations introduced wereverified by PCR or sequencing.

Cells and viruses. MCMV was grown and titered on NIH 3T3 cells by standard procedures.Virus titers were determined according to the median tissueculture infectious dose (TCID₅₀) method (37). NIH 3T3, M2-10B4,and SVEC4-10 cells were obtained from the American Type CultureCollection. The murine 10.1 cell line and life-extended humanforeskin fibroblasts (HFFs) have been described previously (4,19).

To reconstitute infectious virus from mutant MCMV genomes, BACDNA was transfected into NIH 3T3 cells with Superfect transfectionreagent (Qiagen) as described previously (7). For HCMV, BACDNA was transfected into HFFs by electroporation as previouslydescribed (2). AD169 ${Delta}$ UL37x1 virus was obtained by transfectionof BAC DNA into HFFs transduced with Retro-UL37x1HA and propagatedon the same cells.

Cell death assays. Cell viability was determined by a neutral red inclusion assayessentially as described previously (24). To analyze nuclearDNA fragmentation, cells were grown on coverslips, fixed with2% paraformaldehyde, and stained with a terminal deoxynucleotidyltransferase-mediateddUTP-biotin nick end labeling (TUNEL) assay kit (Roche) accordingto the manufacturer's recommendations. Nuclei were counterstainedwith 4',6'-diamidino-2-phenylindole (DAPI). For detection ofphosphatidylserine on the outer leaflet of the cell membraneas an early sign of apoptosis, cells on coverslips were incubatedwith labeled annexin V (Roche) and propidium iodide followingthe recommended protocol. The percentage of apoptotic cellswas determined by counting a total of at least 400 cells infour or more random visual fields. The caspase inhibitors Z-VAD-FMKand Boc-D-FMK (Calbiochem) were added to the cells 30 min priorto infection at a final concentration of 100 µM. All assayswere performed in duplicate or triplicate.

Immunofluorescence. Cells were grown on coverslips, fixed with 4% paraformaldehyde,and stained with primary and secondary antibodies accordingto standard procedures. HA-tagged proteins were detected witha monoclonal rat antibody, 3F10 (Roche). A mouse monoclonalantibody against protein disulfate isomerase (PDI) was purchasedfrom StressGen. An antibody recognizing the Golgi membrane proteinp115 (48) was kindly provided by M. G. Waters. Secondary antibodiesanti-rat immunoglobulin G-Alexa 488 and anti-mouse immunoglobulinG-Alexa 568 and the mitochondrion-specific dye Mitotracker RedCMXRos were obtained from Molecular Probes.

Immunoprecipitation and Western blotting. Metabolic labeling with [³⁵S]methionine and [³⁵S]cysteine andimmunoprecipitation experiments were performed essentially asdescribed previously elsewhere (1). The 3F10 anti-HA antibodyand protein G-Sepharose were used for precipitation. Proteinsamples were separated by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE). The gels were dried and exposedto Kodak X-Omat AR films. For Western blotting, proteins weretransferred to nitrocellulose membranes and probed with themonoclonal mouse anti-HA antibody 16B12 (Covance Research Products).Signals where detected by enhanced chemiluminescence.

RESULTS

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Results

MCMV mutant causes apoptosis of infected cells. In a previous study, a library of mutant MCMV genomes was establishedby random transposon mutagenesis of a full-length MCMV BAC.The uncharacterized library of mutant viral genomes was subsequentlyconverted into a library of mutant viruses by direct transferof the BACs from E. coli to fibroblasts (6). Each mutant viruscarries a transposon inserted at a random position within theMCMV genome. The transposon contains the EGFP gene driven byan HCMV immediate-early promoter. Therefore, cells infectedwith the virus mutants can be identified by their green fluorescence.In this library, we found a virus mutant, IIIB11, that causedan interesting phenotype in infected NIH 3T3 fibroblasts: membraneblebbing and release of vesicles reminiscent of apoptotic bodies(Fig. 1A). These phenomena were seen in only a few cells infectedwith the control virus, MCMV-GFP, which contains the EGFP geneinserted at an innocuous position. A similar phenotype was observedupon infection of SVEC4-10 endothelial cells (Fig. 1B) and M2-10B4bone marrow stromal cells (not shown), suggesting that the phenotypeis not cell type specific. Premature cell death was even moreapparent when cells were infected at a high multiplicity ofinfection. At 36 h after infection, the viability of cells infectedwith IIIB11 was markedly lower than that of cells infected withthe MCMV-GFP control virus (Fig. 1C). This effect was inhibitedwhen the infection was done in the presence of broad-spectrumcaspase inhibitors, although inhibition of cell death was notcomplete (Fig. 1C).

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FIG. 1. Apoptotic cell death induced by an MCMV transposon insertion mutant. (A) NIH 3T3 and (B) SVEC4-10 cells were infected at a multiplicity of infection of 0.01 TCID₅₀/cell with mutant IIIB11 and with the control virus, MCMV-GFP. The fluorescent images show virus plaques with morphological signs of apoptosis (membrane blebbing, disintegration of cells with formation of apoptotic bodies) in individual IIIB11-infected cells, most prominently seen around the center of the plaque. Bar, 20 µm. (C) The viability of NIH 3T3 cells infected with IIIB11 was markedly reduced compared to that of cells infected with MCMV-GFP (MG) 36 h after infection at a multiplicity of 10 TCID₅₀/cell. Cell death could be largely inhibited by treating cells with caspase inhibitor I or III (CI1 or CI3, i.e., Z-VAD-FMK or Boc-D-FMK, respectively) but not by addition of dimethyl sulfoxide (D), the solvent used for the caspase inhibitors.

Identification of ORF m41. The corresponding BAC clone was used to determine the transposoninsertion site in mutant IIIB11. The transposon was found tobe inserted at nucleotide position 54022 of the MCMV genome,within a short ORF of 414 nucleotides (Fig. 2). This ORF, m41,is located in a group of ORFs that are conserved between MCMVand rat CMV, but not between the rodent CMVs and HCMV (10, 30,36, 46) (Fig. 2). However, HCMV contains a gene encoding a mitochondrion-localizedinhibitor of apoptosis, UL37x1, at a similar position withinits genome (17).

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FIG. 2. Location of the transposon insertion in mutant IIIB11. The transposon insertion within ORF m41 of the MCMV genome results in a change of the EcoRI restriction pattern (white arrowheads) in IIIB11 BAC (lane 2) compared to the MCMV wild-type BAC (lane 1), because the transposon (Tn) contains EcoRI sites within its inverted repeats. The exact location of the transposon insertion was determined by sequencing. ORFs m39, m40, and m41 show no sequence homology to the HCMV ORFs at the corresponding positions but are homologous to r39 to r41, respectively, of rat CMV (RCMV). Genes conserved among the three CMVs are shown in gray. Lane MW, molecular size markers.

The phenotype observed in mutant IIIB11 could result from disruptionof ORF m41, an effect on the expression of one of the adjacentgenes m40 and M42, or from an additional adventitious mutationelsewhere in the viral genome. To discriminate among these possibilities,we constructed targeted deletion mutants MCMV ${Delta}$ m40, MCMV ${Delta}$ m41, MCMV ${Delta}$ M42,and MCMV ${Delta}$ M45 (Fig. 3). The ${Delta}$ M45 mutant was included as a positivecontrol virus, as viruses carrying mutations in this gene havepreviously been shown to induce apoptosis rapidly in infectedendothelial cells (6). The mutant MCMV genomes were constructedby homologous recombination in E. coli with the BAC technology.The individual ORFs were deleted and replaced with a zeocinresistance gene. For the ${Delta}$ M42 and ${Delta}$ M45 mutants, short sequencesat the 3' end of the ORFs were left intact to avoid deletionof potential promoter sequences of downstream genes. In thesetwo mutants, additional EcoRI restriction sites were introducedto facilitate detection of the mutations by restriction digestion.Figure 3 shows a schematic representation of the mutations andthe mutant genomes in an ethidium bromide-stained gel and ina Southern blot analysis.

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FIG. 3. Construction of MCMV deletion mutants. (A) ORFs m41, m40, M42, and M45 were deleted from the MCMV-GFP BAC (MG) and replaced with a zeo gene (black box). This resulted in loss or gain of an EcoRI restriction site (E) in mutants MCMV ${Delta}$ m40, ${Delta}$ M42, and ${Delta}$ M45 but not in ${Delta}$ m41. The calculated sizes of the EcoRI restriction fragments in the m40 to M45 region are given on the right. (B) Restriction patterns visualized by ethidium bromide staining. Bands with sizes different from that of the parental MCMV-GFP BAC are indicated by arrowheads. An SnaBI restriction site within m41 is lost in MCMV ${Delta}$ m41, resulting in fusion of two SnaBI fragments of 4.8 and 3.3 kb into a new fragment of 8.1 kb (arrowheads). (C) Southern blot of EcoRI-digested BACs, hybridized with a probe specific for the zeo gene sequence. Lane MW, molecular size markers.

The deletion mutants shown in Fig. 3 were derived from MCMV-GFPand can thus be visualized in the same way as IIIB11. Cellsinfected with MCMV ${Delta}$ m41 displayed the same phenotype as shownfor IIIB11 in Fig. 1, whereas cells infected with MCMV ${Delta}$ m40 orMCMV ${Delta}$ M42 did not (data not shown). To compare the importanceof m41 and M45 for inhibition of virus-induced apoptosis, weused different cell death assays. Annexin V detects phosphatidylserineon the outer leaflet of the cell membrane, an early sign ofapoptosis. At later stages of apoptosis and during nonapoptoticcell death, cell membrane integrity becomes compromised, allowingannexin V to enter the cell and bind to phosphatidylserine moleculesat the inner leaflet of the cell membrane. Costaining with propidiumiodide is used to control for this. The TUNEL assay, by contrast,detects nuclear DNA fragmentation, which occurs at late stagesof apoptosis. The neutral red inclusion assay measures cellviability and is a very reliable test to quantitate cell survivaland death. However, this assay cannot discriminate between apoptoticand nonapoptotic cell death.

SVEC4-10 endothelial cells were infected at a high multiplicityof infection with the deletion mutants. At 24 h after infection,an annexin V assay was used to detect early signs of apoptosisin infected cells (Fig. 4A). At a later time point, cell viabilitywas measured by neutral red inclusion (Fig. 4B). Both the m41and M45 mutants induced apoptotic cell death, but the effectof the ${Delta}$ M45 mutant appeared to be stronger than the effect ofthe m41 mutants. Similar results were obtained when nuclearDNA fragmentation as a late sign of apoptosis was measured witha TUNEL assay (not shown). Mutants ${Delta}$ m40 and ${Delta}$ M42 did not differsignificantly from the MCMV-GFP parental virus, demonstratingthat the phenotype of IIIB11 and MCMV ${Delta}$ m41 is caused by inactivationof m41 rather than an effect on neighboring genes. As determinedby the TUNEL assay, MCMV ${Delta}$ m41 and MCMV ${Delta}$ M45 also induced prematureapoptosis in 10.1 cells, a spontaneously immortalized, p53-deficientcell line unrelated to SVEC4-10 cells (Fig. 4C). This indicatedthat p53 is not required for viral induction of apoptosis.

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FIG. 4. MCMV deletion mutations cause apoptosis. SVEC4-10 endothelial cells were infected at a multiplicity of 5 TCID₅₀/cell with MCMV-GFP (MG) or deletion mutants. (A) Phosphatidylserine on the outer leaflet of the cell membrane was detected with annexin V at 24 h after infection. The percentage of cells staining positive with both annexin V and propidium iodide (indicating late-stage apoptosis or nonapoptotic cell death) is shown in black. (B) Cell viability was determined 32 h after infection by the neutral red inclusion assay. The viability of cells infected with the ${Delta}$ m41 or the ${Delta}$ M45 mutant was markedly reduced, whereas cells infected with MCMV ${Delta}$ m40 or MCMV ${Delta}$ M42 were as viable as cells infected with MCMV-GFP. (C) Cells of p53-deficient fibroblast cell line 10.1 also underwent apoptosis after infection with the ${Delta}$ m41 or the ${Delta}$ M45 mutant. Cells were stained on coverslips by the TUNEL assay and counterstained with DAPI. Fewer cells are seen in the photomicrographs of cells infected with the ${Delta}$ m41 or ${Delta}$ M45 mutant virus because dead and disintegrated cells detached from the coverslips.

Growth properties of mutant viruses. In a previous study we showed that inactivation of the M45 geneprecluded growth of MCMV in endothelial cells but allowed almostnormal growth in fibroblasts, bone marrow stromal cells, andhepatocytes (6). Multistep growth curves, in which cells wereinfected with the mutant viruses at a multiplicity of 0.1 TCID₅₀/cell,revealed that, in comparison to the wild-type virus, the m41mutant viruses grew to a slightly reduced level in fibroblastsbut were diminished by up to 50-fold in endothelial cells (Fig.5A and B), probably because SVEC4-10 endothelial cells are moreprone to apoptosis than NIH 3T3 fibroblasts (unpublished observation).Single-step growth curves in which NIH 3T3 cells were infectedat a multiplicity of 5 TCID₅₀/cell showed a more rapid declinein viral titers for the m41 and M45 deletion mutants 3 to 5days after infection (Fig. 5C). The decline in virus titer wasprobably caused by premature cell death, as seen in a time courseanalysis of cell viability (Fig. 5D). When SVEC4-10 cells wereused instead of NIH 3T3 cells, cell viability was even morecompromised (not shown), consistent with our previous observationthat SVEC4-10 cells are more sensitive to virus-induced apoptosis.However, the titer drop was delayed compared to the declinein cell viability. Virus release by dying cells and stabilityof previously released virus particles could account for thisdelay. Taken together, the results suggests that the antiapoptoticfunction of the m41 gene product became apparent predominantlyat late stages after infection and when cells were infectedat a high multiplicity of infection (see also Fig. 1 and 4).

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FIG. 5. Growth properties of MCMV mutants. (A) NIH 3T3 fibroblasts and (B) SVEC4-10 endothelial cells were infected at a multiplicity of 0.1 TCID₅₀/cell for multistep growth curves. Deletion and insertion mutagenesis of the m41 ORF (mutants MCMV ${Delta}$ m41 and IIIB11) had no obvious effect on virus growth in NIH 3T3 fibroblasts and resulted in only moderately reduced titers in SVEC4-10 endothelial cells. By contrast, the ${Delta}$ M45 mutant failed to grow on SVEC4-10 cells, consistent with previous results (6). (C) After infection at a multiplicity of 5 TCID₅₀/cell, the titers of the ${Delta}$ m41 and the ${Delta}$ M45 mutants declined faster than the titers of the control viruses. All titers represent mean values of two or three parallel experiments. Dotted line, detection limit. (D) A time course analysis showed a faster decline of cell viability for the m41 mutant viruses ( ${Delta}$ m41 and IIIB11) compared to MCMV-GFP. Values were determined in triplicate with standard deviations (error bars).

Subcellular localization of the m41 proteins. According to the published MCMV sequence (36), ORF m41 encodesa polypeptide of 138 amino acids. It contains a hydrophobicstretch close to the C terminus and is predicted to be a typeII transmembrane protein of 14.6 kDa.

To determine the subcellular distribution of the protein encodedby the m41 ORF, the m41 sequence was cloned by PCR and fusedto an HA epitope tag sequence at either the 5' or the 3' end.In addition, the HCMV UL37x1 gene was cloned and HA tagged atthe 3' end. Proteins HA-m41, m41-HA, and UL37x1-HA were expressedin NIH 3T3 cells by using retroviral expression vectors andvisualized by immunofluorescence with an antibody directed againstthe HA epitope. Figure 6 shows that the m41 protein colocalizedwith a marker for the Golgi apparatus but not with markers forthe endoplasmic reticulum or mitochondria. This localizationwas observed for both the N- and C-terminally tagged m41 proteins.By contrast, UL37x1-HA localized to the mitochondria (not shown),consistent with previous reports and its function as a mitochondrion-localizedinhibitor of apoptosis (12, 17).

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FIG. 6 and 7. Figure 6 (top panels) shows subcellular distribution of the m41 protein. ORF m41 was tagged with an HA epitope sequence at the 3' or the 5' end and expressed in NIH 3T3 cells with a retroviral vector (panels A and B, respectively). The m41 protein colocalized with a marker for the Golgi (p115) but not with markers for the endoplasmic reticulum (PDI) or mitochondria (Mitotracker). Colocalizations are shown in yellow in the merged pictures.

Similar protein distributions were seen when m41 and UL37x1were expressed in NIH 3T3 cells by transient transfection withpcDNA3 plasmid expression vectors. However, the extremely highexpression levels obtained with these vectors sometimes resultedin cell toxicity and partly aberrant subcellular distributionpatterns, which were interpreted as overexpression artifacts.Therefore, retroviral expression vectors were preferred forcolocalization studies.

To test the hypothesis that the m41 gene product requires interactionswith other viral proteins to acquire its proper structure orto be transported to a specific compartment, we analyzed itsintracellular localization during MCMV infection. As an m41-specificantibody was not available, we created a mutant MCMV BAC inwhich the m41 sequence was tagged in situ (Fig. 7A). For comparison,we also created recombinant HCMV AD169 BACs, in which the UL37x1gene was tagged or inactivated (Fig. 7B and C). As the UL36-38region contains spliced genes (41), we wanted to minimize thesequence alterations in this region. Therefore, only a shortsequence encoding amino acids 5 through 34 was deleted and replacedwith a prokaryotic kan gene for inactivation of UL37x1. Thisshort sequence has previously been shown to be essential forboth mitochondrial localization and antiapoptotic activity ofthe UL37x1 protein (20).

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FIG. 7 Figure 7 (bottom panels) shows construction of epitope-tagged CMV mutants. (A) An HA epitope tag sequence (hatched box) was fused to the 3' end of the MCMV m41 ORF by homologous recombination. A kan gene flanked by FRT sites (black ovals) was inserted for selection of recombinant BACs in E. coli. The kan gene was subsequently removed with FLP recombinase, leaving a single FRT site behind. (B) In an analogous fashion, an AD169-UL37x1 HA-tagged mutant was constructed. (C) In mutant AD169 ${Delta}$ UL37x1, a domain essential for UL37x1 protein function was deleted and replaced with a kan gene. EcoRI restriction sites are indicated by arrows. (D) EcoRI restriction patterns of the MCMV wild-type BAC (lane 1), MCMV-m41HA (lane 2), the AD169 wild-type BAC (lane 3), AD169 ${Delta}$ UL37x1 (lane 4), and AD169-UL37x1HA (lane 5). Changes in the restriction pattern are indicated by arrowheads. Lane MW, molecular size markers. (E) The m41 protein expressed in NIH 3T3 cells by a tagged MCMV mutant colocalizes with a marker for the Golgi apparatus (p115), whereas the HA-tagged pUL37x1 expressed in HFF cells by AD169-UL37x1HA colocalizes with a mitochondrial marker (Mitotracker). (F) NIH 3T3 cells were infected with wild-type MCMV (M) or MCMV-m41HA (clones T1 and T2) or transduced with Retro-m41HA (R). After metabolic labeling with [³⁵S]methionine and [³⁵S]cysteine, HA-tagged proteins were immunoprecipitated and separated by SDS-PAGE. Two m41 protein products were expressed by MCMV-m41HA but only one by Retro-m41HA. Similar results were obtained in Western blot experiments (not shown).

Recombinant viruses were obtained by transfecting the MCMV-m41HAand AD169-UL37x1HA BACs (Fig. 7D) into fibroblasts. In infectedcells, the tagged proteins were detected by Western blotting(not shown) and by immunofluorescence microscopy (Fig. 7E).Both proteins, UL37x1 and m41, exhibited the same localizationwithin CMV-infected cells as was observed for cells that receivedthe individual protein in the absence of CMV infection (Fig.6).

Transfection of human fibroblasts with the AD169- ${Delta}$ UL37x1 BACdid not yield recombinant virus. However, when fibroblasts transducedwith a retroviral vector expressing UL37x1 were used, AD169- ${Delta}$ UL37x1virus could be grown. The mutant virus grew slowly on complementingcells, with obvious signs of apoptosis in infected cells, suggestingthat the fibroblasts expressed UL37x1 at levels insufficientfor full complementation of the defect (not shown). Recombinantvirus generated on the complementing cells could not be propagatedin noncomplementing fibroblasts. Although the same results wereobtained with two separate AD169- ${Delta}$ UL37x1 BAC clones, a second-sitemutation that contributes to the observed phenotype cannot beentirely excluded. However, results recently presented by othersalso indicated that UL37x1 is essential for AD169 replicationin human fibroblasts (G. Hahn, S. T. Eichhorst, B. Korn, P.H. Krammer, and R. Greaves, presentation at the 26th InternationalHerpesvirus Workshop, abstr. 7.06, 2001). Our findings are inaccordance with these results.

ORF m41 encodes at least two distinct protein products. As we analyzed the protein products of the m41 ORF by immunoprecipitationand in Western blot experiments with the tagged MCMV-m41HA virus,we identified two distinct protein products with apparent molecularmasses of approximately 19 and 21 kDa (Fig. 7F). When the HA-taggedORF was expressed by a retroviral or a plasmid expression vector,only the smaller product of 19 kDa was detected (Fig. 7F). Moreover,the apparently larger product was also absent in cells transducedwith Retro-m41HA and superinfected with MCMV (not shown), rulingout the possibility that the larger product resulted from aposttranslational modification by MCMV proteins.

DISCUSSION

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Discussion

In this study, we provide genetic evidence that the m41 ORFis required to prevent premature apoptosis of MCMV-infectedcells. Apoptosis of cells infected with m41 mutant viruses wasshown by morphology and by apoptosis-specific cell death assays(annexin V, TUNEL, and caspase inhibitors). Systematic deletionmutagenesis of the region surrounding the m41 ORF confirmedthat the neighboring ORFs, m40 and M42, did not encode the function.This function of an m41 gene product could not be predictedby sequence analysis, as m41 shows no apparent homology withany protein of known function. This demonstrates that randomunbiased mutagenesis and screening procedures are valuable toolswith which to identify viral gene functions.

The m41 ORF encodes at least two distinct protein products.Only one of them could be detected by heterologous expressionof the m41 ORF with retroviral or plasmid vectors. The secondgene product, which accumulated to a similar level, was onlyseen when m41 expression was analyzed during virus infection.In the absence of a specific antibody, this was achieved bytagging the coding sequence within the viral genome. Such anin situ tagging procedure, which has previously been used totag bacterial and yeast genes (39, 45), should be very usefulfor herpesvirus genetics as well. Although we have not yet beenable to determine the origin of the second m41 gene product,preliminary results suggest that it derives from a spliced transcript(W. Brune, unpublished results). A more detailed analysis oftranscription in this region will be necessary to identify allspliced and unspliced genes. At present it is not known whetherthe antiapoptotic function is mediated by the smaller or thelarger m41 gene product or both.

Even though MCMV m41 and HCMV UL37x1 show no sequence homology,their similar positions within the two viral genomes suggesteda potential functional homology. Both proteins are involvedin inhibition of apoptosis induced by virus infection. However,the antiapoptotic effect of UL37x1 appears to be stronger, asUL37x1 has been shown to be essential for replication of theHCMV AD169 strain. By contrast, expression of m41 improves thevirus yield but is not essential for virus replication in cellculture. On the other hand, one has to take into considerationthat an AD169 strain with a mutant UL37x1 is in fact mutantfor two antiapoptotic genes, as UL36 has previously been shownto be mutant in this strain (40). It is possible that UL36 andUL37x1 have additive effects and that only one of the genesis required to allow survival of the infected cell and virusreplication. This question can only be resolved by use of anHCMV strain that contains a wild-type UL36 gene or by repairingthe UL36 mutation in AD169.

The different subcellular distributions of the UL37x1 and m41proteins suggest quite divergent mechanisms of action. The UL37x1protein localizes to mitochondria, where it fulfills a Bcl-2-likefunction even though it has no structural homology to Bcl-2(16, 17). By contrast, m41 encodes a protein product that localizesto the Golgi apparatus and is thus not likely to be a functionalhomolog of UL37x1.

How could a protein found in the secretory pathway interferewith induction of apoptosis? It is conceivable that m41 interactswith death receptors or their ligands to downmodulate theirpresentation on the cell surface. Such a function has been demonstratedfor the RID protein complex (also known as E3-10.4K/14.5K) ofadenovirus type 5 (14, 18, 42, 43). However, the RID complexdoes not accumulate in the Golgi as m41 does, but binds to deathreceptors on the cell surface and targets them to lysosomesfor degradation. To our knowledge, m41 represents the firstexample of a Golgi-resident inhibitor of apoptosis. Interestingly,an endoplasmic reticulum-resident protein, M-T4, that is requiredto prevent premature apoptosis of infected lymphocytes (3, 21)was recently identified in myxomavirus, a poxvirus with numerousantiapoptotic genes (15). Although the mechanisms by which them41 and M-T4 proteins interfere with apoptosis are still unknown,these examples highlight the use of multiple strategies by largeDNA viruses like the herpesviruses and poxviruses to ensuretheir survival in different host cells. Identifying the mechanismof m41 action will enhance our understanding of cellular defensesagainst virus infection.

ACKNOWLEDGMENTS

We thank J. Goodhouse for excellent help with confocal microscopyand S. Erhard for technical assistance.

This work was supported by the Deutsche Forschungsgemeinschaft(Emmy Noether Fellowships to W.B. and M.N. and SFB 479) andby grant CA85786 from the National Cancer Institute.

FOOTNOTES

* Corresponding author. Mailing address: Rudolf Virchow Zentrum für Experimentelle Biomedizin, Universität Würzburg, Versbacher Str. 9, D-97078 Würzburg, Germany. Phone: 49 931 20148903. Fax: 49 931 20148123. E-mail: wolfram.brune{at}virchow.uni-wuerzburg.de.

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