Respiratory Syncytial Virus Fusion Protein Mediates Inhibition of Mitogen-Induced T-Cell Proliferation by Contact

Human respiratory syncytial virus (HRSV) and bovine respiratorysyncytial virus (BRSV) are major pathogens in infants and calves,respectively. Experimental BRSV infection of calves and lambsis associated with lymphopenia and a reduction in responsivenessof peripheral blood lymphocytes (PBLs) to mitogens ex vivo.In this report, we show that in vitro mitogen-induced proliferationof PBLs is inhibited after contact with RSV-infected and UV-inactivatedcells or with cells expressing RSV envelope proteins on thecell surface. The protein responsible was identified as theRSV fusion protein (F), as cells infected with a recombinantRSV expressing F as the single envelope protein or cells transfectedwith a plasmid encoding F were able to induce this effect. Thus,direct contact with RSV F is necessary and sufficient to inhibitproliferation of PBLs. Interestingly, F derived from HRSV wasmore efficient in inhibiting human PBL proliferation, whileF from BRSV was more efficient in inhibiting bovine PBLs. Sincevarious T-cell activation markers were upregulated after presentercell contact, T lymphocytes are viable and may still be activatedby mitogen. However, a significant fraction of PBLs were delayedor defective in G₀/G₁ to S-phase transit.

INTRODUCTION

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Introduction

Human respiratory syncytial virus (HRSV) and bovine respiratorysyncytial virus (BRSV) are major causes of severe lower respiratorytract disease in humans and animals, respectively (5). HRSVis the prototype of the Pneumovirus genus of the Pneumoviridaefamily. Its 15-kb negative-stranded genome RNA is containedin a ribonucleoprotein (RNP) complex comprising 10 genes arrangedin the order 3'-NS1-NS2-N-P-M-SH-G-F-M2-L-5'. At least fiveof the 11 encoded virus proteins are associated with the RNP:the nucleoprotein (N), the phosphoprotein (P), the RNA polymerase(L), and two regulatory proteins, M2-1 and M2-2. The two nonstructuralproteins, NS1 and NS2, cooperatively mediate resistance of thevirus to interferon (IFN)-induced cellular antiviral responses(35). The virus envelope contains an internal matrix protein(M) as well as three transmembrane glycoproteins, a small hydrophobicprotein (SH), whose function is still unclear, the presumedattachment protein (G), and the fusion protein (F). G and Fproteins represent the major targets for neutralizing antibodies,and F interacts with so far unidentified cellular receptorsduring virus entry (16, 45). BRSV is closely related to HRSV,and the clinical symptoms, immune response, and pathology causedby BRSV and HRSV are highly similar, making BRSV infection ofcalves a relevant animal model for the human disease.

Several observations indicate that RSV may actively interferewith early immune responses and prevent hosts from mountinga protective immunity. Multiple reinfections, even with membersof the same virus subgroup, are a typical feature of HRSV andBRSV. Although the severity of disease decreases with repeatedinfection, adults remain susceptible (5). Moreover, mitogen-inducedproliferation of peripheral blood lymphocytes (PBLs) isolatedfrom experimentally BRSV-infected lambs was found to be reduced(19, 40, 41, 48), and lymphopenia (42, 48) as well as an increasedsusceptibility to opportunistic infections were observed (39,46, 48). Most likely, RSV interferes with early immune mechanisms.Low gamma interferon (IFN- ${gamma}$ ) and high interleukin-4 (IL-4) concentrationsin the blood of HRSV-infected patients indicate an exaggeratedT helper cell (THC) type 2 response (2, 31, 43). A delayed THCtype 1 response seems also to be an important factor in measlesvirus (MeV)-mediated immune suppression and appears to be triggeredby deteriorated cytokine secretion by infected macrophages andlymphocytes (14).

Inhibition of lymphocyte proliferation by RSV was previouslyattributed solely to effects caused by virus replication inlymphocytes and to cytokines secreted from infected cells. Infectionof macrophages and lymphocytes with BRSV and HRSV has been demonstratedboth in vitro and in vivo (6, 20, 22, 27, 38). In vitro, RSVinfection of peripheral blood mononuclear cells (PBMCs) wasreported to result in suppression or delay of proliferationof PBMCs after stimulation with phytohemagglutinin (PHA) orwith Epstein-Barr virus antigen. Production of cytokines suchas IFN- ${alpha}$ and IL-1 inhibitor was considered responsible for theobserved inhibition of PBMC proliferation (18, 30, 32).

Here, we present experimental evidence for another mechanismof RSV immune cell suppression, direct contact inhibition ofPBL proliferation, which is independent of soluble factors orof virus infection of cells. Using a previously described cocultivationassay (33, 34, 36), we could show that contact with cells presentingRSV antigen (presenter cells [PCs]) causes a strong inhibitionof the proliferation of mitogen-stimulated PBLs (responder cells[RCs]). Neither viability nor activation of PCs was affected;rather, activated PBLs were accumulated in the G₀/G₁-phase.The responsible RSV contact antigen was identified as the RSVfusion protein F. Expression of F alone was able to cause contactinhibition of RCs. Interestingly, although HRSV and BRSV F proteinswere able to arrest both human and bovine RCs, a much strongereffect was observed with cells of the appropriate host.

MATERIALS AND METHODS

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Materials and Methods

Cell culture and proliferation assays. Human or bovine PBMCs serving as RCs were isolated from buffycoats of healthy adult donors or from heparinized blood froma cow and a calf by using Ficoll (Lymphoflot; Biotech, Dreieich,Germany) gradient centrifugation at 1,500 rpm in a Heraeus Varifuge.PBLs were separated from monocytes by plastic adherence andwere incubated in RPMI (Gibco) with 10% fetal calf serum (FCS)at 37°C and 5% CO₂. HL60 and Vero RCs were maintained inRPMI with 10% FCS and Dulbecco’s modified Eagle’smedium (DMEM) (Gibco) with 5% FCS, respectively.

PCs were generated by transfecting baby hamster kidney (BHK)-derivedBSR-T7/5 cells expressing phage T7 RNA polymerase (4) as describedbelow or by virus infection of different cell lines. Infectionsof HL60 cells, a human macrophage-derived cell line, was doneat a multiplicity of infection (MOI) of 0.1, except for recombinantviruses lacking the G gene (see below), for which an MOI of1 was used. Vero PCs were generated by infection with HRSV (strainLong) at an MOI of 1.

Surface expression of viral antigen was determined by fluorescence-activatedcell sorting (FACS). Only populations of greater than 80% RSVprotein-positive cells were used for inhibition experiments(Fig. 1C) and the total cell count (100%) was used for calculationof the PC/RC ratio. Control presenter cells (CPCs) were generatedby transfecting BSR-T7/5 cells with a vector plasmid or by mockinfection of Vero or HL60 cells. PC or CPC proliferation andvirus replication in PCs were inactivated by 10 min of UV (254nm) irradiation.

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FIG. 1. Cells presenting HRSV antigens inhibit proliferation of PHA-stimulated human PBLs. (A) HRSV-infected, inactivated Vero cells (PC; open squares) or mock-infected CPCs (solid circles) were cocultivated with human PBLs (RCs) in the ratios indicated. Proliferation of RCs was determined by [³H]dT incorporation. (B) Inhibition of proliferation compared to mock-infected control PCs and expressed as a percent. Values in A and B represent the result of four experiments using PBLs from four different donors. Error bars indicate standard deviation. (C) Surface expression of HRSV F protein in PCs and mock-infected control cells.

Inactivated PCs or CPCs were seeded in a volume of 100 µlper well into 96-cluster plates in concentrations as indicated.In the same volume, 5 x 10⁵ human or bovine PBLs were addedwhich had been stimulated with PHA (2.5 µg/ml) immediatelybefore. After 72 h of incubation at 37°C and 5% CO₂, cellswere labeled for 24 h with [³H]dT (0.5 mCi/ml [185 Gbq/mmol];Amersham). [³H]dT incorporation was determined after washingand harvesting (Tomtec) in a ß-plate reader (Wallac).All assays were performed at least in duplicate. No significantdifferences were noted between individual human or bovine donorsof RCs.

Assays in which inhibition of spontaneous proliferation of celllines of different origin was analyzed were done by using thesecell lines (see Results and Discussion) as RCs and by cocultivationof 5 x 10⁴ cells with inactivated HRSV-infected PCs in ratiosof 1:1 to 1:250 in the same volume and buffer as described forPBLs. Incorporation of [³H]dT was determined after 72 h of cocultivation.For physical separation of PCs from RCs, cell culture membraneinlays with a pore size of 0.2 µm were used, and 5 x 10⁴HRSV-infected and UV-irradiated HL60 PCs or CPCs were seededwith 2.5 µg of PHA per ml in the membrane inlays, whichwere then inserted into culture wells containing 5 x 10⁵ allogeneicPBLs serving as RCs.

HRSV strain Long and recombinant BRSVs derived from strain ATue-51908(4) as well as BRSV gene deletion mutants were grown on Verocells. For preparation of virus stocks, 70 to 80% confluentVero cell layers were infected at a multiplicity of 0.1 in DMEMin the absence of FCS. The inoculum was removed after 1 h, andcells were incubated in DMEM supplemented with 2.5% FCS at 37°Cand in a 5% CO₂ atmosphere. Virus was released by freezing andthawing the cell monolayer upon development of extensive cytopathiceffect. Infectious virus titers were determined on Vero cellsby endpoint dilution and counting of infected cell foci stainedfor indirect immunofluorescence with RSV F-specific monoclonalantibody F56, kindly provided by J. A. Melero, Madrid, or RSV-F(Serotec).

Immunohistochemistry and cell cycle analysis. For cell surface staining of viral envelope proteins or lymphocytesurface markers, cells were fixed for 5 min with 3% paraformaldehydeat room temperature. After washing with FACS buffer (PBS containing0.4% FCS and 0.02% NaN₃), staining for 30 min on ice was performedwith mouse monoclonal antibodies specific for RSV F (F56) orG (021-1G; provided by J. A. Melero) or specific for CD25, CD122,CD40L (Pharmingen), and CD45R0 (Immunotech). For negative controls,isotype-specific antibodies provided by the suppliers were used.After washing, cells were incubated for 30 min with fluoresceinisothiocyanate (FITC)-labeled anti-mouse immunoglobulin (Ig)antibody (Dianova), followed by washing and FACS.

For cell activation studies and cell cycle analysis, 10⁶ humanPBLs were stimulated with 2.5 µg of PHA/ml and cocultivatedwith HRSV-infected HL60 PCs or with mock-treated CPCs in a ratioof 5:1 for 48 h followed by immunostaining or DNA staining.For DNA staining, cells were fixed for 5 min with 3% paraformaldehyde,washed, and permeabilized with 0.1% Triton for 2 min. Afterwashing, cells were resuspended in 100 µl of RNase solution(100 µg of RNase A per ml in 1% trisodium citrate) andincubated at 37°C for 30 min. After washing, cells wereresuspended in 0.5 ml of propidium iodide (50 µg/ml in1% trisodium citrate) and incubated for 15 min in the dark priorto FACS analysis.

Cloning of HRSV glycoprotein expression plasmids. HRSV (strain Long) F and G cDNAs were generated by reverse transcription(RT)-PCR (Titan; Roche) from infected HeLa cells with primersolFLs (5'-GGGCCATGGAGTTGCCAATCCTCAAAGC-3'), and olGLsSGHS/A(5'-GGGAAGCTTACATGTCCAAAAACAAGGACCAACGC-3'), containing an NcoIor AflIII recognition site (underlined) located at the translationinitiation codons for insertion of the amplified DNA immediatelydownstream of the encephalomyocarditis virus internal ribosomeentry site (IRES) of the T7 promoter-controlled expression plasmidpTIT (4). The reverse primers olFLr (5'-AGGAATTCTCGAGTTTTTATATAACTATAAACTAGGAATCC-3')and olGLrRSGEI (5'-GGGGAATTCAATAACTACTGGCGTGTTGTG-3') each containedan EcoRI site (underlined) downstream of the stop codon whichwere used for cloning in pTIT, giving rise to pTIT-Fh and pTIT-Gh,respectively.

PCs expressing either RSV G or RSV F were generated by transfecting10⁶ BSR-T7/5 cells expressing phage T7 RNA polymerase (4) with5 µg of the respective pTIT plasmids. PCs coexpressingG and F were generated by cotransfecting BSR-T7/5 cells with3 µg each of pTIT-Fh and pTIT-Gh.

Construction of recombinant viruses. The BRSV full-length cDNA clone pBRSV (4) was cleaved with PflMI,resulting in removal of a 2.8-kbp fragment containing the SH,G, and most of the F gene but retaining the SH transcriptionalstart signal. Digestion with NheI resulted in further removalof a 1.3-kbp fragment spanning the reminder of the F gene andthe M2 gene. The 0.9-kbp SspI-NheI part of this fragment containingthe M2 gene part was reintroduced into the plasmid togetherwith a short DNA generated by annealing of two synthetic oligomers,olMBRSJF (5'-CTCGAGGTCGACTATAGTTATTTAAAAAGATATGACGCGT-3') andolMBRSAJF (5'-ACGCGTCATATCTTTTTAAATAACTATAGTCGACCTCGSGCTG-3'),containing a transcription stop signal and a unique SalI recognitionsite (underlined). This gave rise to a BRSV cDNA lacking theSH, G, and F open reading frames (pBRSV ${Delta}$ O). pBRSV ${Delta}$ O was digestedwith SalI, the recognition site for which is located betweenthe extra transcription start and stop signals and was treatedwith Klenow polymerase to fill in the 5' overhang. BRSV F cDNA(1.9 kbp) containing the complete F open reading frame was excisedfrom pTIT-Fb with NcoI and BamHI, also treated with Klenow,and ligated into pBRSV ${Delta}$ O, resulting in pBRSV ${Delta}$ SH-G/Fb.

For generation of a chimeric virus containing the F gene fromHRSV instead of BRSV, pBRSV ${Delta}$ O was cleaved with XhoI followedby Klenow fill-in and digestion with SalI. A fragment of 1.7kbp containing the HRSV F ORF was removed from pTIT-Fh (seeabove) with NcoI/Klenow and XhoI and ligated into the cleavedpBRSV ${Delta}$ O, giving rise to pBRSV ${Delta}$ SH-G/Fh.

For generation of a chimeric virus containing both G and F fromHRSV (pBRSV ${Delta}$ SH/GhFh), the F gene was isolated from pTIT-Fh andthe G gene was generated by RT-PCR from HRSV strain Long-infectedHeLa cells as described above by using primers GHRSVSalI (5'-GGGGGTCGACATGTCCAAAAACAGG-3')and FGHRSVNcoI (5'-GGGGGATTGGCAACTCCATGGTTA-3'). The resultingproduct was cleaved by SalI and NcoI. pBRSV ${Delta}$ O was cleaved bySalI and ligated with the G PCR product and the F fragment frompTIT-hF. All viruses were recovered from cDNA as described previously(35).

RESULTS

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Results

HRSV inhibits mitogen-induced lymphocyte proliferation. To determine whether contact-mediated mechanisms may contributeto RSV-mediated inhibition of lymphocyte proliferation, we cocultivatedcells presenting RSV antigens on their surface (PCs) with mitogen-stimulatedhuman PBLs serving as RCs. First, Vero cells infected with HRSVstrain Long were used as PCs. Cultures were UV irradiated toabolish virus replication, release of infectious virus, andproliferation of PCs. Noninfected control cells (CPCs) weretreated in the same way. RCs were generated from freshly isolatedhuman PBLs from different donors and were stimulated with 2.5µg of PHA per ml immediately before coincubation. PCsor CPCs were mixed with RCs at ratios in the range of 1:1 to1:250, and the mixed cells were coincubated for 72 h. Proliferationof RCs was monitored by [³H]dT incorporation for a further 24h.

Compared to CPCs, cocultivation with PCs resulted in a dose-dependentinhibition of RC proliferation (Fig. 1A). Inhibition was almostcomplete when equal numbers of PCs and RCs were mixed. A 50%reduction of RC proliferation was observed at a ratio of 1:50,and even at 1:250 a distinct 20% inhibition of lymphocyte proliferationwas determined (Fig. 1B). Not only mitogen-stimulated proliferationof primary lymphocytes but also spontaneous proliferation ofthe human T-cell line Jurkat, the human B-cell line BJAB, andthe macrophage-derived cell line HL60 was reduced in a comparabledegree by cocultivation with HRSV-infected PCs (not shown).

HRSV-mediated inhibition of RC proliferation depends on direct contact. To exclude the possibility that infectious virus contributedto the observed inhibition of RC proliferation, we determinedwhether infectious virus was released from the UV-irradiatedPCs. Confluent Vero cell layers in six-well plates were incubatedfor 2 h with HRSV-infected and UV-irradiated HL60 PCs or withinfected but nonirradiated cells. After washing, the monolayerswere incubated for 3 days and analyzed for HRSV-specific immunofluorescence.Whereas nonirradiated cells caused extensive infection, UV-irradiatedPCs did not result in detectable infection (Fig. 2A). Thus,infectious virus particles released from PCs could not be responsiblefor the observed inhibition of RC proliferation.

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FIG. 2. Direct contact with PCs is responsible for inhibition of RC proliferation. (A) UV-irradiated PCs do not produce infectious virus. Vero cell layers were exposed to UV-irradiated HL60 PCs (+UV) or to nonirradiated controls (-UV) and infection was visualized by immunostaining with an RSV F antibody. (B) Soluble factors produced by PCs or PC-contacted PBLs do not inhibit RC proliferation. A mixture of PBLs and PCs (column 2) or CPCs (column 3) was separated from RCs by membranes allowing passage of soluble factors. Aliquots of the PCs efficiently inhibited proliferation of RCs in standard contact assays (column 1). Error bars indicate standard deviation.

To further exclude a contribution of soluble factors releasedby HRSV-infected PCs, HL60 PCs were physically separated fromRCs by membranes allowing passage of soluble factors such asPHA. The inhibitory effect on RC proliferation was completelyabolished by the separation of RCs from PCs (not shown). Anotherexperiment was performed to exclude that active autocrine factorsare secreted by RCs upon contact with PCs. A mixture of HL60PCs and PBLs was separated by a membrane from PBLs serving asRCs (Fig. 2B). In contrast to the controls where PCs and RCswere directly mixed (Fig. 2B, column 1), no inhibition was observedwhen direct contact between the PC-PBL or CPC-PBL mixtures withRCs was prevented by the membranes (Fig. 2B, columns 2 and 3,respectively). Thus, direct contact of PCs and RCs is requiredand necessary for the observed suppression of RC proliferation,and soluble factors do not contribute in the present in vitrosystem.

HRSV F protein contact inhibits proliferation of lymphocytes. The above results suggested the involvement of viral structureson the surface of PCs in delivering an inhibitory signal toRCs by contact. To identify the proteins responsible, individualHRSV envelope proteins were expressed in PCs. BSR-T7/5 cellsexpressing T7 RNA polymerase (11) were transfected, either aloneor in combination with plasmids containing the HRSV F or G openreading frames (ORFs) under the control of a T7 RNA polymerasepromoter (pTIT-Fh and pTIT-Gh, respectively). Three days posttransfection,the majority of cells expressed considerable levels of the proteins,as determined by FACS (Fig. 3). After UV irradiation, cellswere used as PCs and were mixed at ratios of 1:5 to 1:100 withPHA-stimulated PBL RCs.

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FIG. 3. Cells expressing RSV F from cDNA inhibit proliferation of RCs. Surface expression of HRSV F, HRSV G, or both proteins on BSR-T7/5 cells after transfection of plasmids. Expression levels were determined by FACS using F- or G-specific monoclonal antibodies. The dotted line represents cells transfected with the vector plasmid.

Cocultivation of RCs with PCs expressing only HRSV F proteinresulted in a significant and dose-dependent inhibition of RCproliferation, with more than 50% inhibition at a 1:5 PC/RCratio (Table 1). To the contrary, PCs presenting HRSV G proteindid not lead to detectable inhibition at any concentration.Most interestingly, however, expression of F protein in combinationwith G was found to clearly augment the inhibitory capacityof F (Table 1). At a PC/RC ratio of 1:5, an approximately 90%inhibition was observed, which is comparable to that causedby virus-infected cells. Also at higher dilutions, cells coexpressingF and G led to increased inhibition. Notably, the level of Fsurface expression in cells coexpressing F and G was not higherthan in cells expressing F alone (Fig. 3), suggesting that Gmay influence or stabilize the structure of F required for signalinginhibition. Yet these experiments demonstrated that contactwith F protein alone at the surface of PCs is sufficient toinhibit PBL proliferation. Neither virus infection nor cellularstructures induced by virus infection of PCs are required forthe inhibitory effect on PBL proliferation.

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TABLE 1. RSV F inhibits proliferation of RCs

Differential inhibition of bovine and human lymphocytes by HRSV and BRSV F proteins. RSVs have a narrow host tropism in vivo, with HRSV infectinghumans and BRSV infecting cattle. Thus, it was of interest toassess whether PCs displaying proteins from human or bovineRSV are able to also suppress proliferation of lymphocytes ofthe heterologous host. Here, we used HL60 suspension cells asPCs, because these are equally well infected by HRSV and BRSV.Upon comparable envelope protein expression on the cell surfaceas determined by FACS analysis (data not shown), cells wereUV irradiated and used in proliferation assays with PHA-stimulatedPBLs isolated from either human or bovine blood.

Proliferation of both human and bovine RCs was affected by contactwith all of the infected PCs compared to controls with CPCs.However, HRSV was clearly superior to BRSV in inhibiting proliferationof human PBLs. In the contrary, BRSV caused a more pronouncedinhibition of bovine PBLs at all dilutions (Fig. 4A and B).In both cases, a PC/RC ratio of 1:16 resulted in an approximately80% reduction in proliferation of RCs from the adequate host,whereas an approximately 40% reduction was reached with PBLsfrom the inadequate host. This suggested that HRSV and BRSVF proteins are adapted to signaling growth arrest to PBLs ofthe appropriate host.

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FIG. 4. Inhibition of lymphocyte proliferation is more pronounced with PBLs of the specific host. Bovine RCs (solid squares) or human RCs (open squares) were coincubated with HL60 PCs infected with HRSV (A), BRSV (B), or recombinant BRSV-derived viruses possessing either HRSV F (C) or BRSV F (D) as the only viral surface protein, or with a virus having both F and G from HRSV (E). Mock-infected CPCs were used for calculating percent inhibition. Results are from three independent experiments using PBLs from four individual donors and two individual animals.

To verify that only the sequence of HRSV or BRSV F protein isresponsible for the differential inhibition of RCs from differentorigin and that other virus factors do not contribute, recombinantRSVs were generated by using recently established reverse geneticsprotocols (4, 35) and used for preparation of PCs. First, aBRSV was constructed lacking the SH and G genes while retainingthe F gene (rBRSV ${Delta}$ SH-G/Fb). In addition, a corresponding viruscarrying the F gene from HRSV in place of the BRSV F gene (rBRSV ${Delta}$ SH-G/Fh) was recovered from cDNA. Both viruses carrying eitherthe BRSV or HRSV F as the single envelope protein grew onlyslightly more slowely than wild-type BRSV in Vero or HL60 cellcultures, confirming again that SH and G are not required forRSV propagation in cell culture (16, 17, 45).

HL60 PCs infected with rBRSV ${Delta}$ SH-G/Fb carrying the BRSV F geneinduced a much greater inhibition of bovine PBL RCs than thecounterpart virus with the HRSV F protein (approximately 80and 40%, respectively) at high PC/RC ratios (Fig. 4D and C).In contrast, rBRSV ${Delta}$ SH-G/Fh induced a greater inhibition in humanPBLs than in bovine PBLs (80 and 30%, respectively; Fig. 4C and D).As the two viruses differ only in the F protein, theobserved specificity in suppressing mitogenic proliferationof RCs from different hosts is determined solely by the sequenceof the F protein.

Notably, and supporting the previous results with cDNA-expressedsurface proteins, the recombinant viruses lacking both the Gand SH genes were somewhat less effective in signaling proliferationinhibition than wild-type HRSV or wild-type BRSV (compare Fig.4A and C or B and D). To determine whether the above observedsupportive effect of G also applies to virus-infected cells,an additional recombinant was generated by introducing the HRSVG gene into rBRSV ${Delta}$ SH-G/Fh, resulting in rBRSV ${Delta}$ SH/GhFh. As shownin Fig. 4E, PCs infected with this virus were virtually equalin RC proliferation inhibition to PCs infected with wild-typeHRSV, with values of greater than 90% for inhibition of humanPBLs and greater than 70% for inhibition of bovine PBLs. Theseresults also suggest that the third envelope protein of RSV,SH, is not involved in signaling PBL arrest.

RSV F contact blocks the cell cycle but not mitogen-mediated activation of PBLs. To examine in more detail the nature of PBL proliferation inhibition,cellular activation markers of nonstimulated or PHA-stimulatedhuman PBLs were monitored. Irrespective of whether PHA-stimulatedPBLs were cocultured with PCs or with CPCs, surface expressionof CD40-L, CD25 (IL-2 ${alpha}$ -chain), and CD122 (IL-2 ß-chain)was greatly increased, and a slight increase was also observedfor CD45Ro (Fig. 5). In parallel experiments, aliquots of thePCs used were shown to inhibit RC proliferation in a range of65 to 82% (not shown). Thus, proliferation inhibition does notinterfere with activation of RCs by PHA but rather appears toaffect the cell cycle.

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FIG. 5. PBL activation by mitogen is not affected after contact with PCs. Expression of surface activation markers is induced by PHA in the presence of HRSV-infected HL60 PCs (column 2) or mock-infected HL60 PCs (column 3). Nonactivated PBLs from the same donor are shown in column 1. Error bars indicate standard deviation of four experiments performed with PBLs from four individual donors.

The DNA content of PBLs was therefore determined by FACS usingpropidium iodide staining. In nonstimulated PBL cultures, almostall cells were resting in the G₀/G₁ phase as indicated by asingle DNA content (Fig. 6, dotted line). After PHA stimulationfor 48 h, 31% of PBLs contained a doubled DNA content (Fig.6, continuous line), indicative of actively proliferating cells.However, after contact with PCs, which in parallel experimentsgave a 75% proliferation inhibition, significantly fewer cells(12%) with double DNA content were observed (Fig. 6, bold line).This indicates that proliferation inhibition is due to a defectof contacted PBLs in reaching the S phase.

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FIG. 6. Mitogen-stimulated PBLs accumulate in G₀/G₁ phase after PC contact. The DNA content of PBLs was determined by propidium iodide (PI) staining. Nonstimulated PBLs represented by the dotted line have a single DNA content. Compared to control PC-contacted cultures (continuous line), PC-contacted cultures (bold line) contain a lower number of proliferating cells with doubled DNA content (12 versus 31%).

DISCUSSION

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Discussion

Distortion and suppression of host immune cell responses afterHRSV and BRSV infection is a well-recognized feature that mayhave an important role in RSV pathogenesis (12, 13, 15, 31,40, 43, 48) and is also observed in different in vitro systems(1, 28, 29). However, the mechanisms involved have not beensatisfactorily dissected. In this in vitro study, we could showthat RSV F protein is able to mediate inhibition of mitogen-inducedproliferation of T cells by contact with the target cell. Activevirus replication in presenter cells is not necessary, as UV-irradiatedPCs not able to produce virus were effective. Moreover, cellsexpressing RSV F protein from transfected cDNA could substitutefor virus-infected presenter cells.

Previous reports on inhibition of RSV immune cells were basedon the analysis of mixed populations of infected and noninfectedlymphocytes and macrophages and therefore have not been ableto distinguish the effects caused by virus, virus proteins,or cellular factors released by either virus-infected or noninfectedcells. Here, we have used an in vitro system which has previouslyproven successful for investigation of MeV immune suppressionmechanisms (36). Production of infectious virus in PCs is abolishedby UV irradiation, and only noninfected PBLs were used as RCs.A contribution of soluble factors produced by RSV-infected PCsor by PC-contacted RCs could also be excluded, as physical separationof PCs and RCs by large-pored membranes allowing passage ofsoluble factors such as PHA completely abolished the inhibitoryeffect. In particular, a contribution of IFN- ${alpha}$ , which has beendescribed as a potent RSV-induced inhibitor of leukocyte proliferation(30), was excluded by using Vero PCs, which lack IFN- ${alpha}$ genes(8) and also do not produce active IFN-ß (35).

In the present assays, we thus exclusively monitored effectscaused by direct contact of PCs and RCs. The situation is thushighly reminiscent of the findings with MeV, where direct contactinhibition by viral surface proteins (36) has been shown toarrest leukocytes in vitro (9, 37). Moreover, in the case ofMeV, this mechanism contributes considerably to the pronouncedsystemic immune suppression following measles infection in ananimal model (24–26). Typically, such a systemic immunesuppression is not observed after RSV infection, although areduction of responsiveness of peripheral leukocytes has beendescribed in animals experimentally infected with BRSV (40,42).

In vitro, however, the effects of contact inhibition by RSVand MeV are highly comparable and seem to be due to similarlyeffective mechanisms. A ratio of 1 PC presenting RSV proteinscocultivated with 50 RCs resulted in an approximately 50% inhibitionof PHA-stimulated lymphocyte proliferation. Significant effectswere observed at ratios of up to 1:250. This is somewhat lowerthan with MeV, where ratios of up to 1:1,000 were shown to beeffective in vitro (36). Also similar to MeV (9, 37), contactwith RSV PCs did not inhibit the PHA mitogen-mediated activationof RCs, as shown by successful upregulation of important activationmarkers and unimpaired viability of cells, arguing against apoptosisof RCs upon PC contact.

As can be concluded from the analysis of DNA content, proliferationinhibition is due rather to a defect or delay in the transitfrom G₀/G₁ to S-phase. In the absence of PCs, activation ofPBLs by PHA lead to an enhanced DNA content in approximatelyone third of PBLs after 2 days, indicating that these have reachedS phase. Contact with PCs, however, reduced the percentage ofcells reaching S phase at least 2.5-fold. It was reported thatunresponsiveness of lymphocytes can also result from infectionwith RSV; however, this appears to be correlated with a lossof cell surface activation markers, including IL-2 receptorchains (32).

Expression from cDNA of individual RSV surface proteins as wellas analysis of genetically engineered RSV lacking surface proteingenes clearly identified the RSV F protein as the factor responsiblefor contact inhibition. This is in striking contrast to thesituation with MeV, where a functional complex of F and H isrequired and the single proteins F and H do not have any effect.RSV F expressed in the absence of other virus proteins was ableto inhibit PHA-stimulated lymphocyte proliferation, whereasexpression of comparable amounts of cell surface G protein didnot lead to inhibition. Moreover, F alone was responsible forthe observed species-specific response pattern in human andbovine PBLs, as shown by transfection experiments as well asby chimeric BRSVs in which BRSV and HRSV F genes were exchanged.

Most remarkable, however, although F alone was sufficient forinhibition, coexpression of F along with G markedly enhancedthe capacity of F in signaling unresponsiveness. This was againreflected by the behavior of recombinant viruses. RSVs containingeither HRSV F or BRSV F as the sole virus surface protein wereable to cause inhibition of human and bovine PBLs, yet lessefficiently than wild-type virus containing all three virussurface proteins, F, G, and SH. Upon reintroduction of the HRSVG gene into the BRSV-derived construct carrying HRSV F, theinhibiting capacity of wild-type HRSV was fully restored (Fig.4). These results suggest that RSV G has distinct auxiliaryfunctions in signaling inhibition, while SH protein appearsnot to contribute.

The role of RSV G in the virus life cycle is much less clearthan that of the corresponding type II glycoproteins of otherparamyxoviruses, such as MeV hemagglutinin (H). As previouslyindicated by the analysis of RSV mutants in which the SH andG genes were incomplete or missing (16, 17, 45) and as describedhere, RSV SH and G are nonessential virus proteins, at leastin vitro. This again is in striking contrast to the situationwith MeV, where a functional H protein, or rather a functionalF/H complex, is an absolute requirement not only for attachmentto the cellular MeV receptors CD46 and SLAM and entry into targetcells (7, 23, 44), but also for contact-mediated suppressionof T cells in vitro and in vivo (24, 36).

Another requirement for MeV contact inhibition is proteolyticcleavage of the fusion protein, whereas membrane fusion is notnecessary (47). From these data it appears that only the fusion-competentMeV F/H complex may acquire a structure effective in signalinginhibition. However, it has not been clarified which part ofthe protein makes the contact to cell surface signaling receptors.This is also true for other members of the Morbillivirus genusrecently identified to cause inhibition of T-cell proliferation,such as mumps virus and canine distemper virus (34), rinderpestvirus, and peste des petits ruminants virus (J. Heaney, T. Barrett,and S. L. Cosby, Abstr. 11th International Conference on NegativeStrand Viruses, abstr. 225, 2000).

RSV G, however, is not required for signaling and is thus probablynot involved in direct contact with responsive molecules onthe cell surface of PCs. Nevertheless, it considerably supportsF-mediated contact inhibition. As the level of F surface expressionwas not altered in the presence of G, a more efficient transportof F to the cell surface is excluded. It is rather suggestedthat G may facilitate access to the cell surface by bindingto, e.g., heparin-like surface structures (3, 10, 21) or isable to directly or indirectly chaperone surface F into a conformationthat allows more efficient interaction with the target ligandson RCs.

The identity of cell surface molecules signaling nonresponsivenessto contacted lymphocytes is not known, nor is it known whichmediate membrane fusion and RSV entry into cells. Our experimentsshowed a differential ability of RSV F proteins from differentorigins in inhibiting PBLs from different host species. Thisis also in contrast to MeV-induced contact suppression, whichaffects PBLs from different species equally (36). Proliferationinhibition of human PBLs was more pronounced when HRSV F proteinwas used as an effector, whereas PBLs of bovine origin weremore sensitive to BRSV F protein. Apparently, this correlateswith the permissivity of cells for virus infection, as humanand bovine PBLs are only poorly permissive for the heterologousvirus, BRSV and HRSV, respectively (unpublished data).

In addition to mitogen-induced proliferation of primary PBLs,spontaneous proliferation of the human T-cell-derived Jurkatline and the B-cell-derived BJAB line could be inhibited moreefficiently by HRSV F than by BRSV F (not shown), which alsocorrelates with permissivity of the cells to HRSV and BRSV.However, in all combinations proliferation inhibition was significant.Even proliferation of murine PBLs, which in vitro are nonpermissivefor HRSV or BRSV, was slightly reduced after contact with HRSV-or BRSV-infected PCs (data not shown).

This apparent correlation of infectibility and the degree ofcontact inhibition on first sight prompts the speculation ofa common receptor for entry and for signaling unresponsiveness.The degree of the inhibitory signal in RCs after PC contactcould reflect the affinity of the different RSV F proteins tothis putative receptor. However, only cells of hematopoieticorigin are susceptible to proliferation inhibition by RSV. Alarge variety of cells, such as Hep2, Vero, and BSR, can bereadily infected by RSV, while their spontaneous proliferationis not inhibited when they are used as RCs in standard cocultivationexperiments with HRSV-infected PCs.

Future experiments should help to clarify whether differentreceptors are used for entry into hematopoietic or nonhematopoieticcell types. In the case of common receptors, these might beable to signal downstream unresponsiveness only in hematopoieticcells. In the case of MeV-mediated contact inhibition, virusreceptors for entry, CD46 and SLAM, are most probably not involvedin mediating contact inhibition. This suggests that other leukocyte-specificmolecules are responsible for responding to contact. Furtherexperiments towards identification of responder cell structuresshould be facilitated by the fact that RSV F alone is effectiveand might reveal whether common mechanisms are involved in morbillivirusand pneumovirus-mediated T-cell suppression or whether individualstrategies have been evolved by these diverse viruses.

ACKNOWLEDGMENTS

This work was supported by the European Commission (5th FrameworkProgramme, QLK2-CT-1999-00443).

We thank J. A. Melero, Madrid, for providing RSV monoclonalantibodies F6 and G7 and Stefan Finke for valuable commentson the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Max von Pettenkofer Institute and Gene Center, Feodor-Lynen-Str. 25, D-81377 Munich, Germany. Phone: 49 89 2180 6851. Fax: 49 89 2180 6899. E-mail: conzelma{at}lmb.uni-muenchen.de.

Present address: Federal Research Center for Virus Diseasesof Animals, D-72076 Tübingen, Germany.

REFERENCES

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