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Clinical and Diagnostic Laboratory Immunology, January 2005, p. 114-121, Vol. 12, No. 1
1071-412X/05/$08.00+0     doi:10.1128/CDLI.12.1.114-121.2005
Copyright © 2005, American Society for Microbiology. All Rights Reserved.

Antigenic and Immunogenic Investigation of B-Cell Epitopes in the Nucleocapsid Protein of Peste des Petits Ruminants Virus

Foreign Animal Disease Division, National Veterinary Research and Quarantine Service, Anyang, Kyoung-gi,¹ College of Veterinary Medicine, Chungbuk National University, Heungduk-Ku, Cheongju, Chungbuk, Korea,² Department of Veterinary Diagnostic and Production Animal Medicine, College of Veterinary Medicine, Iowa State University, Ames, Iowa³

Received 11 July 2004/ Returned for modification 28 September 2004/ Accepted 22 October 2004

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

 
Attempts were made to identify and map epitopes on the nucleocapsid (N) protein of peste des petits ruminants virus (PPRV) (Nigeria75/1 strain) using seven monoclonal antibodies (MAbs) and deletion mutants. At least four antigenic domains (A-I, A-II, C-I, and C-II) were identified using the MAbs. Domains A-I (MAb 33-4) and A-II (MAbs 38-4, P-3H12, and P-13A9) were determined to be located on the amino-terminal half (amino acids [aa] 1 to 262), and domains C-I (P-14C6) and C-II (P-9H10 and P-11A6) were within the carboxy-terminal region (aa 448 to 521). Nonreciprocal competition between A-II MAbs and MAbs to C-I and C-II domains was observed, indicating that they may be exposed on the surface of the N protein and spatially overlap each other. Blocking or competitive enzyme-linked immunosorbent assay studies using PPRV serum antibodies revealed that epitopes on the domains A-II and C-II were immunodominant, whereas those on the domains A-I and C-I were not. The competition between MAb and rinderpest virus (RPV) serum antibodies raised against RPV strain LATC was found in two epitopes (P-3H12 and P-13A9) on the domain A-II, indicating that these epitopes may cause cross-reactivity between PPRV and RPV. Identification of immunodominant but PPRV-specific epitopes and domains will provide the foundation in designing an N-protein-based diagnostic immunoassay for PPRV.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

 
Peste des petits ruminants (PPR) is an acute and highly contagious viral disease causing high morbidity and mortality in small ruminants, such as goats and sheep. The disease has accounted for significant economic losses to the livestock industry in many countries of Africa, the Middle East, the Near East, and South Asia where rinderpest has been present (34). There is a growing threat for the emergence of PPR in countries free of the disease, especially ones neighboring areas where PPR is endemic. PPR is caused by an enveloped RNA virus known as PPR virus (PPRV), which belongs to the Morbillivirus genus in the family Paramyxoviridae (2, 32). Other members of the genus Morbillivirus include rinderpest virus (RPV), measles virus (MV), canine distemper virus (CDV), phocine distemper virus (PDV), and dolphin morbillivirus (DMV) (2, 13). PPRV is genetically grouped into four distinct lineages (I, II, III, and IV) on the basis of partial sequence analysis of the fusion (F) protein gene (2, 11, 34), despite the fact that only a single serotype has been reported. Although PPRV mainly infects small ruminants whereas RPV mainly causes disease in large ruminants, PPR overlaps to some degree with rinderpest with respect to regions where outbreaks of these diseases occur, type of animals infected (hosts), and clinical manifestation.

Structural proteins of morbilliviruses consist of nucleocapsid (N) protein, fusion (F) protein, hemagglutinin (H) protein, matrix (M) protein, and polymerase (L) protein (13, 20). Among the structural proteins, N protein is antigenically the most conservative among morbilliviruses and is highly immunogenic in spite of its internal location (8, 28, 39). The N protein is expressed to a very high level in morbillivirus-infected cells (13, 17, 39). Hence, N protein can be used for serologic screening for naturally infected or vaccinated animals, although it may not be important for humoral immune protection (8, 10, 23, 27, 28). N protein also can be a good antigen candidate for the development of differential tests for differentiating infected animals from ones vaccinated with F- and/or H-recombinant marker vaccines (8, 24, 25, 28). Such recombinant maker vaccines have been used on an experimental basis to address concerns about the thermal stability of attenuated live PPRV vaccination, which has been practiced in countries where PPR is endemic (3, 12, 15, 16).

Despite a growing interest in diagnostic applications of N protein for PPRV as described above, epitopes on PPRV N protein and their immunological function have not been identified.

Previous studies on the N protein of RPV (525 amino acids [aa]) in our laboratory revealed that immunodominant epitopes are present at the amino-terminal half (aa 1 to 149) (7) and the carboxy terminus (aa 479 to 486) (9). For MV, another morbillivirus, antigenic determinants were also identified at both amino- and carboxy-terminal regions (aa 122 to 150, aa 457 to 476, and aa 519 to 523) of N protein, although it is not known whether these epitopes are immunodominant or not (5). Taken together, it is logical to assume that there should be immunodominant epitopes in both ends of the N protein of PPRV.

In the following study, we attempted to topologically map epitopes on N protein of PPRV by using a series of gene deletion mutants and a panel of monoclonal antibodies (MAbs). In addition, relative immunogenicity of each of the identified epitopes was further analyzed in small ruminants. Such information may provide a better foundation for designing serological methods suitable for epidemiological surveillance, evaluation of immune response of vaccinated animals to PPRV, diagnosis of suspected animals in the early stage of infection, and differentiation from animals vaccinated with a marker vaccine.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

 
Virus. Nigeria 75/1 (Nig75/1) strain of PPRV (12), the seed virus for PPR vaccine production, was kindly supplied by G. Libeau (CIRAD-EMVT, Montpellier, France) and used for the study. The virus belongs to lineage I. The virus was propagated in Vero cells using a roller bottle culture system, concentrated, and semipurified as previously described (6). The amount of total protein in the purified viral antigen was determined using a GeneQuant II (Pharmacia Biotech), and then the antigen preparation (0.1 mg/ml) was stored at –70°C until it was used as an immunogen for MAb production or antigen in enzyme-linked immunosorbent assay (ELISA) to screen hybridomas.

Monoclonal antibodies. Production of MAb specific for PPRV was done as previously described (6). In brief, mice were injected via the footpad with viral antigens at a rate of 0.01 mg per mouse. Murine lymphocytes were collected from popliteal lymph node 10 to 14 days after the injection and were fused with murine myeloma SP2/O cells. PPRV antibody-secreting hybridomas were identified by an indirect ELISA (iELISA) using whole virus as described above and an immunofluorescence on PPRV-infected Vero cells. Hybridomas secreting MAb specific for PPRV N protein were then selected by testing against a recombinant PPRV N (rPPRV-N) protein in an indirect ELISA. Once N-protein-specific MAbs were produced, the isotype of each MAb was determined by a commercial isotyping ELISA kit (Boehringer, Manheim, Germany) according to the manufacturer's instructions. Two MAbs (33-4 and 38-4) raised against PPRV Nig75/3 strain were obtained from G. Libeau as reference (29). PPRV-neutralizing MAb P-13E5 directed against PPRV 75/1 produced in this study was used as a negative control for the N protein.

For use in competitive ELISA, MAbs were biotinylated with a biotin-labeling kit (Boehringer) after being purified through the ImmunoPure (A/G) immunoglobulin G (IgG) purification kit (Pierce, Rockford, Ill.) for the IgG antibody or a KappaLock Sepharose column (Zymed Labs, San Francisco, Calif.) for the IgM antibody according to the manufacturer's instructions. All MAbs were adjusted to 2 mg/ml by using a GeneQuant II before labeling.

Sera. Five PPRV-antibody-positive goat/sheep field sera, designated PPR 2-65, PPR 2-66, PPR 2-69, PPR 2-73, and PPR 2-81, from eastern Africa (PPR lineage III region) were kindly supplied by E. Couacy-Hymann (LANADA/LCPA, Bingerville, Ivory Coast). Two bovine anti-RPV sera (RP K9061 and RP K9062) were previously produced in our laboratory with the RPV LATC strain (8). All these sera had virus-neutralizing titers of >256 against homologous virus. Negative sera were obtained from 10 goats naive for both RPV and PPRV and were used as negative controls. Strong positive, weak positive, and negative controls included in an internationally available competitive ELISA kit for PPR serology were also used. In addition, a total of 22 sera periodically collected from three goats experimentally infected with PPRV (lineage I) were obtained from E. Couacy-Hymann.

Recombinant GST fusion proteins. A series of glutathione S-transferase (GST) fusion proteins containing either full-length N protein (aa 1 to 525) or partially overlapping fragments of N protein (aa 1 to 262, aa 1 to 447, and aa 405 to 521) of PPRV were expressed in E. coli BL21 cells using procedures previously described (6). Four primer sets, N-F1 (5'-GAGCTCATGGCGACTCTCCTCAAAAG-3') and N-R525 (5'-AACCATGGTCAGCTGAGGAGATCCTTGT-3'), N-F1 and N-R262 (5'-CGCCGGCGGAGTCCGGCTTCTACAATAT-3'), N-F1 and N-R447 (5'-CGCCGGCGCTTCGGACCCATTTGGGATC-3'), and N-F405 (5'-GAGCTCGAACGAACCGTTAGAGGGAC-3') and N-R521 (5'-CCATGGCTATTCTCTGTTCTCAAACCAGT-3') were used to amplify genes encoding aa 1 to 525, aa 1 to 262, aa 1 to 447, and aa 405 to 521, respectively (Fig. 1A), based on the published N amino acid sequence of PPRV strain Nig75/1 (GenBank accession number X74443). Restriction enzyme sites were incorporated at the 5' ends of each primer to facilitate cloning and are indicated by the underlined nucleotides. cDNA of each N gene construct was reverse transcription-PCR amplified, cloned into pGEM-T Easy vector (Promega, Madison, Wis.), and then subcloned into pGEX vector (Amersham Pharmacia, Piscataway, N.J.). Recombinant pGEX plasmids pGEX-N_1-525 (aa 1 to 525), pGEX-N_1-262 (aa 1 to 262), pGEX-N_1-447 (aa 1 to 447), and pGEX-N_405-521 (aa 405 to 521) were transformed into E. coli BL21 cells (Amersham Pharmacia). Expression of GST fusion proteins (i.e., GST-N_1-525, GST-N_1-262, GST-N_1-447, and GST-N_405-521) was induced by adding 0.5 mM isopropyl-ß-D-thiogalactopyranoside (IPTG) to transformed cells and incubating them at ambient temperature for 4 to 6 h. The induced cells were harvested, washed three times with cold 0.01 M phosphate-buffered saline (PBS) by centrifugation at 10,000 x g for 1 min, and resuspended in a one-fifth volume of cold GST buffer (10 mM Tris-1 mM EDTA [pH 8.0], 0.1 mM dithiothreitol [DTT], 1 mM phenylmethylsulfonyl fluoride [PMSF], 50 mM potassium glutamate, and 10% glycerol), and treated with lysozyme (final concentration, 0.2 mg/ml) and sodium sarkosyl (final concentration, 0.5%) for 10 min at ambient temperature. After a brief centrifugation (10,000 x g for 1 min), the supernatant was incubated with Triton X-100 (final concentration, 5%) for 30 min at ambient temperature to inactivate sarkosyl. Once extracted, the fusion proteins were then purified from Triton X-100-treated supernatants through a single-step glutathione Sepharose 4B affinity column (Amersham Pharmacia) according to procedures recommended by the manufacturer.

View larger version (28K): [in this window] [in a new window]   FIG. 1. Schematic diagram (A) of GST fusion protein constructs containing full-length or truncated nucleocapsid fragments of PPRV and Western immunoblot confirmation (B) of E. coli-expressed products using goat anti-PPRV serum.

Western immunoblot. Recombinant GST fusion N proteins with various deletions (e.g., GST-N_1-525, GST-N_1-262, GST-N_1-447, and GST-N_405-521), rPPRV-N, and rRPV-N were electrophoretically separated through NuPAGE Novex Bis-Tris Gels using an Xcell SureLock Mini-Cell (Invitrogen) according to the manufacturer's instructions. Separated polypeptides were transferred from the gels onto nitrocellulose membranes by using the Xcell II Blot Module (Invitrogen) according to manufacturer's instructions. Immunoblotting was then performed by standard techniques using MAbs (1:1,000 dilution) or sera (1:100 dilution). Specific antigen-antibody reactions on each membrane were visualized by applying anti-species IgG (H+L) conjugated with alkaline phosphatase (1:1,000 dilution) followed by 5-bromo-4-chloro-3-indolylphosphate/nitroblue tetrazolium substrate solution (Kirkegaard-Perry Laboratories Inc., Gaithersburg, Md.).

iELISA. ELISA plates (Maxisorp; Nunc, Roskilde, Denmark) were coated with 50 µl of optimally diluted native or recombinant N proteins for 1 h at 37°C. Plates were washed three times with 0.002 M PBS containing 0.05% Tween 20 (PBST) and then were incubated with 50 µl of serial dilutions of each MAb in a blocking buffer (0.01 M PBS, 3% skimmed milk, and 0.05% Tween 20) for 1 h at 37°C. MAb P-13E5 was used as a negative control. Plates were then washed three times with PBST. Antigen-antibody complexes were visualized by applying 50 µl of peroxidase-conjugated anti-mouse immunoglobulins (IgA+IgM+IgG) (Kirkegaard and Perry Laboratories, Inc.) diluted 1:1,500 in the blocking buffer and then O-phenylenediamine substrate (Sigma, St. Louis, Mo.). Colorimetric reactions were stopped with 1.25 M sulfuric acid solution, and the optical density (OD) of each well was measured at 492 nm. The net absorbance of each MAb was corrected by subtracting the OD for control MAb P-13E5 from that for recombinant fusion protein. MAbs with a net OD value of 0.2 were considered positive.

Blocking enzyme-linked immunosorbent assay (bELISA). To determine whether MAbs recognize the same or different epitopes, alternate rows of an ELISA plate coated with the purified whole-virus antigen in 0.01 M PBS at a predetermined optimal concentration was first incubated with a 1:100, 1:1,000, or 1:10,000 dilution of each unlabeled MAb (50 µl/well) in the blocking buffer for 45 min at 37°C. MAb P-13E5 was used as a negative control antibody. Without washing, 50 µl of each biotinylated MAb at 70 to 80% saturating concentration was added to paired wells (i.e., one with unlabeled MAb and the other without unlabeled MAb pretreatment) and incubated for an additional 1 h at 37°C. Plates were then washed three times with PBST, and binding of biotinylated MAbs was detected using 50 µl of peroxidase-labeled streptavidin diluted 1:1,500 in the blocking buffer. The rest of the procedure for the ELISA was identical to that of the iELISA described above. The optical densities (OD) were converted to percent inhibition (PI) values for each MAb pair by using the following formula: PI = [(100 – OD with MAb pretreatment) x 100]/(OD without MAb pretreatment). Two MAbs (i.e., unlabeled and labeled) were considered to share (overlap) an epitope when 50% or higher reduction occurred.

Another blocking ELISA (bELISA-II) was also performed to assess the relative immunogenicity of each of the epitopes identified on PPRV N protein as described above, with a few modifications. First, ELISA plates were coated with rPPRV-N instead of whole PPR viral antigens. Second, anti-PPRV field caprine or ovine sera were diluted 1:20 and 1:400 and applied first to wells coated with the antigen. Third, the plates were incubated with each unlabeled MAb at 70 to 80% saturating concentration. Fourth, peroxidase-labeled streptavidin was replaced with peroxidase-conjugated anti-mouse immunoglobulins (IgA+IgM+IgG) (Kirkegaard and Perry Laboratories, Inc.) diluted 1:2,000 in the blocking buffer in order to detect mouse antibody (i.e., MAbs). The net OD of each MAb was corrected by subtracting the OD of MAb P-13E5 from the OD of each MAb. Percent inhibition values (PI) by each serum were calculated by using the following formula: PI = [(100 – OD in the presence of test serum) x 100]/(Mean OD in the presence of negative sera). When 50% or higher inhibition was observed, the epitope recognized by the MAb of interest was considered to be blocked. The degree of immunogenicity of each MAb-reactive epitope was determined by comparing PI values of MAbs with 1:20 and 1:400 dilutions of PPR sera. When the binding of a MAb was blocked by 1:20 dilution of PPR-positive sera, the blocking of the MAb epitope (immunogenicity) was further tested by 1:400 dilution of the sera and was compared.

cELISA. A competitive enzyme-linked immunosorbent assay (cELISA) was performed for PPR serology according to the modified procedure of the commercial competitive ELISA kit for PPRV (28). Optimal running conditions of cELISA were predetermined by a checkerboard titration using PPR control sera, whole-virus antigen, and detecting MAb as previously described (36). For testing, alternate rows of ELISA plates coated with the antigen were incubated with an equal mixture of serum (final 1:20 dilution) and each MAb in the blocking buffer for 1 h at 37°C. Other alternate rows of ELISA plates were incubated only with each MAb. Plates were then washed three times with PBST, and binding of MAb was detected using peroxidase-labeled anti-mouse immunoglobulin and the substrate. The rest of the procedure for the ELISA was identical to that for the bELISAs described above. Percent inhibition by serum antibodies was calculated by using the following formula: PI = [1 – (OD of serum-MAb mixture/OD of MAb alone)] x 100. The sera with PI values of 50 were considered to be positive.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

 
Characterization of MAbs. A total of five MAbs specific for N protein of PPRV Nig75/1 were produced, designated P-3H12, P-9H10, P-11A6, P-13A9, and P-14C6. MAbs P-9H10, P-3H12, P-11A6, and P-13A9 were IgG class, whereas MAb P-14C6 was IgM class. Among IgG MAbs, P-9H10 was IgG1, P-3H12 was IgG2a, and P-11A6 and P-13A9 were IgG2b. The two MAbs from G. Libeau (33-4 and 38-4) were both IgG1. All of these MAbs had kappa light chains.

Recombinant pGEX plasmids (pGEX-N_1-525, pGEX-N_1-262, pGEX-N_1-447, and pGEX-N_405-521) expressed high levels of GST fusion proteins (GST-N_1-525, GST-N_1-262, GST-N_1-447, and GST-N_405-521) with expected sizes, which were recognized by antibodies to PPRV (Fig. 1B). GST-N_405-521 was successfully extracted from the soluble fractions, and the other GST fusion proteins were harvested from insoluble fractions (data not shown). Degradation into smaller polypeptides was observed in all GST fusion proteins, although the majority of the fusion proteins remained intact (Fig. 1).

The degree of reactivity of the MAbs to recombinant N proteins (GST-N_1-525 and rPPRV-N) in comparison to that of native N protein is illustrated in Fig. 2. Based on endpoint titer and OD values, the reactivity pattern of each MAb to the baculovirus-expressed recombinant N protein (rPPRV-N) was determined to be similar to that of the native N protein. On both proteins, the ELISA reactivity of MAbs 38-4 and P-11A6 for all N proteins was the highest, while MAbs P-14C6 and 33-4 showed the lowest ELISA reactivity. In contrast, a wide-ranging difference in the reactivity to E. coli-expressed GST-N_1-525 was found among some MAbs (i.e., 33-4, P-3H12, P-9H10, and P-13A9). MAbs P-3H12, P-9H10, and P-13A9 were barely bound to GST-N_1-525, whereas MAb 33-4 showed a relatively high degree of ELISA reactivity with GST-N protein.

View larger version (24K): [in this window] [in a new window]   FIG. 2. Reactivity of anti-PPRV nucleocapsid MAbs with native (A), baculovirus-expressed recombinant (B), or E. coli-expressed recombinant GST fusion nucleocapsid proteins (C) in an indirect ELISA.

View larger version (62K): [in this window] [in a new window]   FIG. 3. Mapping of MAb epitopes using GST fusion proteins containing partially overlapped fragments of PPRV nucleocapsid protein. GST-N1-525 (B), GST-N1-262 (C), GST-N1-447 (D), and GST-N405-521 (E) were separated electrophoretically and then transferred to nitrocellulose membranes. Baculovirus-expressed N protein rPPRV-N (A) was used as control. The binding of each MAb to GST fusion proteins on the membranes was detected using Western immunoblotting.

Spatial relationship of epitopes. Blocking of each MAb by homologous and heterologous MAbs is summarized in Table 1. As expected, complete blocking was observed between homologous MAbs. MAb 33-4 binding was blocked only by homologous antibody. The other MAbs showed one-way or two-way competition with two or more heterologous MAbs (except for MAb 33-4) as well as homologous MAb. Based on the competition between the two MAbs, epitopes were categorized into at least four antigenic domains: A-I (33-4), A-II (P-3H12, P-13A9, and 38-4), C-I (P-14C6), and C-II (P-9H10 and P-11A6). Within the A-II and C-II domains, the MAb defining the epitopes differed slightly. Of the domain A-II MAbs which recognize epitopes in the amino-terminal half, MAbs P-3H12 and P-13A9 competed nonreciprocally with three MAbs (P-14C6, P-9H10, and P-11A6) which recognize epitopes in the carboxy-terminal region, while MAb 38-4 did not. MAbs P-3H12 and P-13A9 had identical relations with each other and with the other MAbs, except for MAb 38-4. Domain C-II MAbs P-9H10 and P-11A6 competed nonreciprocally with each other.

View larger version (62K): [in this window] [in a new window]   FIG. 4. Immunogenicity of seven epitopes on the nucleocapsid of PPRV as determined by the degree of blocking of their binding to the baculovirus-expressed recombinant PPRV N protein by anti-PPRV caprine sera (PPR 2-65, PPR 2-66, PPR 2-69, PPR 2-73, and PPR 2-81), PPRV hyperimmune serum (RPV positive), or anti-PRV bovine sera (RP K9061 and K9062) at dilutions of 1:20 (A) and 1:400 (B). Each epitope is designated by the name of each detector MAb.

View larger version (24K): [in this window] [in a new window]   FIG. 5. Average humoral antibody response to four immunodominant epitopes (MAbs 38-4, P-3H12, P-13A9, and P-11A6) of PPRV N protein in three goats experimentally infected with PPRV of lineage I as measured by a competitive ELISA.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The location of MAb epitopes was predicted by using deletion mutants. Of seven epitopes identified in this study, four epitopes (recognized by 33-4, P-3H12, P13A9, and 38-4) were located in the amino-terminal half (aa 1 to 262), while the others (recognized by P-14C6, P-9H10, and P-11A6) were localized in the carboxy-terminal region (aa 448 to 521). The presence of epitopes in both ends of N protein has been previously reported for other morbilliviruses, including measles virus (5) and rinderpest virus (7, 9). Topologically, MAbs-reactive epitopes were located in both N-terminal and C-terminal regions. Two antigenic domains were identified in each region (A-I and A-II or C-I and C-II). MAb 33-4 (recognizing domain A-I) did not display any competition with the other MAbs, suggesting that the domain was topologically separated from the other domains. MAbs reactive to epitopes on other domains (i.e., A-II, C-I, and C-II) displayed competition nonreciprocally with each other. One-way competition (i.e., nonreciprocal competition) has been commonly observed among epitopes of other viruses because of their conformational structure (6, 22, 29, 33, 38, 42). However, it should be noted that epitopes (P-3H12 and P-13A9) on domain A-II were blocked by MAbs against epitopes (P-14C6, P-9H10, and P-11A6) in domains C-I and C-II but not vice versa. Such broad blocking effects allow us to draw some preliminary assumptions. First, the folding of PPRV N protein may bring distal epitopes at both ends close together and expose them on the surface of the N protein, as with Sendai virus (21). Second, domain A-II may be located close to but behind domains C-I and C-II so that MAb binding of domain C-I or C-II epitope sterically hinders binding of MAbs P-3H12 and P-13A9 to domain A-II. Third, the 38-4 epitope on domain A-II may be more topologically separated from domains C-I and C-II than P-3H12 and P-13A9 epitopes, because 38-4 reactivity was not affected by the binding of domain C-I and C-II antibodies.

From an immunogenicity point of view, epitopes in domain A-II (P-3H12, P-13A9, and 38-4) and domain C-II (P-9H10 and P-11A6) appeared to be immunodominant (see Fig. 4). Of them, P-3H12 and P-13A9 epitopes were more immunodominant. However, spatial overlap of epitopes should be taken into consideration for immunogenicity, because a higher PI value of MAb in bELISA-II could be achieved by not only direct competition but also indirect competition (i.e., steric hindrance). For example, P-3H12 epitope could be blocked by indirect competition with other antibodies against P-13A9, P-14C6, P-9H10, and P-11A6 epitopes in serum as well as direct competition by antibody to P-3H12 epitope in serum. Diagnostically, the use of antigen possessing an epitope with such broad blocking could improve the sensitivity of MAb-based blocking (or competitive) ELISA for PPR serology. This concept was supported in part by the results of cELISA on sera from goats experimentally infected with PPRV showing that antibodies against P-3H12, P-13A9, and 38-4 epitopes were detected earlier than those of P-11A6 epitope (Fig. 5).

Serological cross-reactivity has been observed among morbilliviruses because of common antigens present among the viruses (35, 38). Considering that the N protein is highly immunogenic and conserved among morbilliviruses (8, 14), it is apparent that the N protein would play an important role in such an antigenic cross-reactivity. In our earlier work (8), anti-RPV sera displayed strong reactivity with the PPRV N protein (rPPRV-N) as well as PPRV whole-virus antigen in an indirect ELISA. In this study, MAbs P-13A9 and 33-4 reacted with the N protein of strains PPRV Nig75/1 and RPV LATC (8, 29), suggesting that these two epitopes can serve as common antigens. While the P-13A9 epitope likely plays a major role in cross-reactivity due to its immunogenicity, the 33-4 epitope would not play an important role in cross-reactivity between the two viruses because it appeared to be the least immunogenic. However, it should be noted that P-3H12 antibody strongly blocked P-13A9 epitope, suggesting that P-3H12 MAb may be in competition with RPV antiserum (i.e., cross-reaction) in a blocking ELISA for PPR serology, although the MAb was not directly bound to the RPV. This was evident in bELISA-II, where MAb P-3H12 competed with RPV sera (1:20 dilution) while the others did not (see Fig. 4A). Such a competition was not, however, observed between MAb P-11A6 (domain C-II) and PRV antibody cross-reacting with P-13A9 epitope of PPRV, even though MAb P-11A6 could block P-13A9 epitope nonreciprocally. Two-way competition appears to be important for cross-reactivity due to steric hindrance.

In conclusion, our observations on the immunogenicity and spatial relationships of epitopes on the four domains of the PPRV N protein would be useful in designing sensitive and specific immunoassays based on the N protein. For example, MAb P-3H12 (recognizing the immunodominant domain A-II) would be applicable for the detection of antibodies in competitive ELISA for serosurveillance and the diagnosis of suspected animals under certain circumstances (i.e., poor sample quality and low laboratory capacity). This test would be useful in PPR- and RP-free countries for the screening of animals either naturally infected or vaccinated with attenuated PPRV vaccine. It could also be used to differentiate infected animals from those vaccinated with F- and/or H-recombinant marker vaccines in areas where the virus is endemic, although weak cross-reactivity with RPV antibody was found in the competition immunoassay in this study. PPR-specific MAb P-9H10 (recognizing domain C-II) would be suitable for the detection of PPRV-specific antibody and/or antigen, although domains C-I and C-II are less immunodominant than domain A-II. Nonetheless, the exact location of MAb epitopes remains to be further investigated by immunoassays (i.e., immunospot) using synthetic peptide fragments (18), phage display libraries (40), or site-directed mutagenesis with an infectious clone (1).

In addition, anti-N MAbs produced in this study may be applicable to further studies of structural biology and replication of PPRV nucleocapsid (4, 19, 21, 26, 30, 31).

	ACKNOWLEDGMENTS

 
We thank G. Libeau (CIRAD-EMVT) and E. Couacy-Hymann (LANADA/LCPA) for supplying us with diagnostic reagents and RPV and PPRV sera, respectively. Hoe-Wol Lee and Sang-Mi Kang are gratefully acknowledged for their excellent technical assistance.

This work was supported by funding from the National Veterinary Research and Quarantine Service, Korean Ministry of Agriculture and Fishery.

	FOOTNOTES

 
* Corresponding author. Mailing address: Foreign Animal Disease Division, National Veterinary Research and Quarantine Service, 480 Anyang-6 dong, Anyang, Kyoung-gi, 430-824, Korea. Phone: 82-31-467-1860. Fax: 82-31-449-5882. E-mail: choiks{at}nvrqs.go.kr.

	REFERENCES

Top Abstract Introduction Materials and Methods Results Discussion References

 

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