Development of a Recombinant Antigen for Antibody-Based Diagnosis of Mycoplasma bovis Infection in Cattle

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Clinical and Diagnostic Laboratory Immunology, November 1999, p. 861-867, Vol. 6, No. 6
1071-412X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Development of a Recombinant Antigen for Antibody-Based Diagnosis of Mycoplasma bovis Infection in Cattle

Marion Brank,¹ Dominique Le Grand,² François Poumarat,³ Pierre Bezille,² Renate Rosengarten,¹ and Christine Citti¹^,^*

Institut für Bakteriologie, Mykologie und Hygiene, Veterinärmedizinische Universität Wien, 1210 Vienna, Austria,¹ and Ecole Nationale Vétérinaire de Lyon, Pathologie du Bétail, 69280 Marcy-l'Etoile,² and CNEVA-Lyon, Laboratoire de Pathologie Bovine, 69342 Lyon Cedex 07,³ France

Received 19 February 1999/Returned for modification 16 June 1999/Accepted 30 July 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Mycoplasma bovis induces various clinical manifestations in cattle, such as mastitis, arthritis, and pneumonia. We have evaluatedthe immunoreactivity of three variable surface proteins (Vsps)of M. bovis, namely VspA, VspB, and VspC, with sera collectedfrom herds with mycoplasmosis or from cattle experimentally infectedwith M. bovis. Western blot analysis revealed that the Vsps arethe predominant antigens recognized by the host humoral responseduring M. bovis infection. The immunoreactivity of VspA, VspB,and VspC with host antibodies was independent of the clinicalmanifestations, the geographical origin of the M. bovis isolates,the mode of infection, and the animal's history. Moreover, theresults showed that Vsp-specific host antibodies can be detectedabout 10 days after experimental infection and for up to severalmonths. The full-length or truncated versions of the VspA productwere overexpressed in Escherichia coli as fusion proteins (FP-VspA).Recombinant products showed strong immunoreactivity with the Vsp-specificmonoclonal antibodies 1A1 and 1E5, with the corresponding epitopeslocalized at the VspA N-terminal and C-terminal ends, respectively.Anti-M. bovis sera of cattle naturally or experimentally infectedalso strongly recognized the full-length FP-VspA. The seroreactivityof sera collected from cattle between 6 and 10 days after experimentalinfection was weaker with truncated versions of VspA lacking the1E5 epitope than with the full-length VspA or the truncated versionslacking the 1A1 epitope. Overall, the results indicate that theVsps, despite their inter- and intraclonal variability, may beapplied as target antigens in serodiagnostic assays for epidemiologicalstudies.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Mycoplasma bovis is considered one of the most pathogenic bovine mycoplasmas (18). While mycoplasmosis induced by this pathogenis spread worldwide, it occurs predominantly in Europe and NorthAmerica, resulting in significant economic losses in areas withintensive dairy and meat production (18, 30). In cattle, M.bovis is associated with diverse clinical manifestations, suchas mastitis in cows and arthritis and pneumonia in young animals,as well as genital disorders, abscess, conjunctivitis, otitis,and meningitis (11-13, 18, 28, 32). In most cases, fataloutcomes are due to coinfection with other bacterial pathogens,such as pasteurellas (8, 31). M. bovis may be asymptomaticallypresent as commensal organisms in the upper respiratory tractsof older animals, where the mycoplasmas form a constant sourceof infection for young animals that are more susceptible to developingclinical symptoms (17, 31). In the absence of an effectiveantibiotic therapy or vaccination, the only strategy currentlyavailable to control infection is the strict segregation of M.bovis-infected animals from healthy herds (18). Rapid detectionof animals that have been in contact with the pathogen is thereforea crucial step requiring sensitive and specific diagnostic approaches.The diagnosis of an M. bovis infection is currently based on theidentification of the organism in secretions, excretions, or tissueseither (i) by cultivation in broth medium followed by colony ordot blot immunostaining methods (6, 14, 19, 21, 26),(ii) by PCR (1, 4, 7, 10, 29), or (iii) by antigen-captureenzyme-linked immunosorbent assay (2, 9). These techniquesrely on the presence of organisms in the samples at a detectableconcentration that depends on the sensitivity of the test. Assaysthat assess the presence of anti-M. bovis circulating antibodiesoffer an improved alternative, because they can identify animalswhich have been infected within a large herd even in the absenceof sheddingorganisms.

In a preliminary study, serum antibodies from animals naturally infected with M. bovis originating from Northern Germany wereshown to predominantly recognize major epitopes carried by a familyof abundant, variable surface lipoproteins, designated as Vsps(25). So far, three Vsps, VspA, VspB, and VspC, have been characterizedin clonal variants derived from M. bovis type strain PG45. Detailedanalysis revealed that each Vsp undergoes high-frequency variationin expression and size, generating extensive surface diversificationin a given M. bovis strain or isolate (3). This phenomenonmay profoundly affect the outcome of serodiagnostic assays, becausetheir sensitivity may vary, depending on the choice of the targetantigen (26).

Development of sensitive and specific serologic tests for the rapid detection of infected animals is bound to the identificationof a specific antigen. In this study, we have evaluated the reactivityof M. bovis antigens, and more specifically of Vsp epitopes, withsera obtained from animals experimentally or naturally infectedwith M. bovis. We describe the expression of recombinant VspAproducts in Escherichia coli which contain immunodominant epitopesstrongly reacting specifically with sera from naturally infectedcattle as well as with sera collected 6 days after experimentalinfection with M. bovis.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Mycoplasmas, bacterial strains, and plasmids. M. bovis 1067 was originally isolated from an animal with mastitis in 1983 and propagated as a filter-cloned culture (22).This strain and a clonal variant derived from M. bovis type strainPG45, which expressed a 67-kDa version of VspA (see below) (3)designated VspA 67, were used for experimental infections. Clonalvariants used for Western blot analysis were selected from a collectionof isogenic variants previously generated from M. bovis type strainPG45 and expressing either 79-kDa VspC, 64-kDa VspA plus 46-kDaVspB, or 67-kDa VspA (3). E. coli DH10B (GIBCO BRL, Life Technologies,Inc., Grand Island, N.Y.) was used as a host for recombinant plasmidsderived from the cloning and expression vector pMAL-c2 (New EnglandBiolabs, Inc., Beverly, Mass.).

Serum samples collected from cattle experimentally infected with M. bovis. Sera collected from experimentally infected cattle were selected from four independent M. bovis infections (Table 1, experiments1 to 4), which were conducted between 1986 and 1998 by the CentreNational d'Etude Vétérinaires et Alimentaires (CNEVA) de Lyon,Lyon, France, and the Ecole Nationale Vétérinaire de Lyon, Lyon,France. Before sampling, animals were shown to be free of M. bovisrespiratory infection by bacteriological examination of individualbronchoalveolar lavages (BAL) and an indirect hemagglutinationtest (IHA) (5, 20). This was retrospectively confirmed byWestern blot analysis of M. bovis whole-cell antigens as describedbelow by using preimmune sera. Experiment 1 involved 24 youngcattle, experiments 2 and 3 involved 8 and 17 calves, respectively,and experiment 4 involved 21 pregnant dairy cows. Cattle weregiven experimental infections by endobronchial inoculation ofapproximately 50 ml of fresh culture containing 10⁹ to 10¹⁰ CFU of M. bovis strain 1067 per ml (experiments 1, 3, and 4)or of a clonal variant expressing a single VspA of 67 kDa (experiment2). In experiments 2 and 3, all animals were inoculated, whilein experiments 1 and 4, only one-third of the group was inoculatedto promote natural infection by contact with the remaining animals.After inoculation, animals of experiments 1, 2, and 3 were examinedfor 6 to 30 days before slaughtering, while animals of experiment4 were kept and routinely monitored for an additional 2 years.Routine surveillance consisted of (i) a regular clinical examination(daily for experiment 2), (ii) weekly bacterial testing of BALin the first month (daily for experiment 2), and (iii) blood samplingfor serology before inoculation and then twice a week (monthlyfor the longest experiment [experiment 4]). Regular respiratoryshedding of M. bovis was systematically shown in all infectedanimals, endobronchially or by contact, for at least few daysafter exposure. Clinical expression of M. bovis disease was mostlymild (as measured by transient fever, raised respiratory rate,and inappetance), except in experiment 4, in which abortion occurredin two cows with isolation of M. bovis in fetus liver. The extentof macroscopic lung lesions in animals of experiments 1, 2, and3 largely varied according to the stage of slaughtering, fromno lesion of the lung surface to 65% lesion. Animals inoculatedwith the clonal variant VspA 67 only showed a few microscopiclesions, mainly interstitial pneumonia with occasionally bronchopneumoniaareas.

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TABLE 1. Characteristics of bovine sera selected from four experimental M. bovis infections

Serum samples collected from cattle naturally infected with M. bovis. Sera from 26 animals were selected during natural outbreaks in four herds. These outbreaks were confirmed by reisolation ofM. bovis. They occurred in France (1-3) and in Switzerland (4)and were chosen to be representative of at least one major clinicalmanifestation of M. bovis infection (i.e., mastitis, pneumonia,or arthritis), as well as to represent different age groups (i.e.,calves, young cattle, and adults) (Table 2). Twenty additionalserum samples (Table 2, field sampling) were randomly collectedfrom 10 herds showing asymptomatic M. bovis infections. Theseherds $---$ six in France (1988 to 1990) and four in Switzerland (1997) $---$ containedseveral animals showing a strong reaction by IHA, suggesting aprevious or current asymptomatic infection with M. bovis. Amongthese 19 serum samples, 17 were IHA positive and 2 were IHA negative.

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TABLE 2. Characteristics of bovine sera selected from natural M. bovis outbreaks

MAbs and hyperimmune sera. The monoclonal antibodies (MAbs) 1E5 and 1A1 used in this study have been previously described by Rosengarten et al. (3)and LeGrand et al. (15), respectively. Briefly, MAb 1E5 of theimmunoglobulin M (IgM) isotype was raised against a M. bovis clonalvariant derived from the type strain PG45 and was shown to specificallyreact with a common epitope to VspA, VspB, and VspC. The MAb 1A1of the IgG1 isotype was obtained by a similar procedure and wasshown to react with VspA and VspC, but not with VspB (3, 15,25). Both MAbs were shown not to react with ruminant mycoplasmaspecies other than M. bovis. Rabbit hyperimmune sera were raisedagainst those mycoplasma species which are most frequently isolatedfrom cattle (M. bovigenitalium, M. bovirhinis, M. arginini, Acholeplasmalaidlawii, and Ureaplasma diversum) and against M. agalactiae,which is closely related to M. bovis, as previously described(21). The serum PAL, kindly provided by D. Bergonier (EcoleVétérinaire de Toulouse, France), was collected from a sheepnaturally infected with M. agalactiae and shown to strongly reactwith M. agalactiae surfacecomponents.

IHA and Western blot analysis. The IHA was performed as described elsewhere (5, 20) with the type strain PG45 as an antigen. The procedures for sodiumdodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)and Western blotting of mycoplasma proteins have previously beendescribed (25). For Western blot analysis, nitrocellulose membraneswere blocked for 50 min with Tris-buffered saline (TBS [0.01 MTris-HCl, 0.15 M NaCl, pH 7.2]) containing 10% (vol/vol) horseserum, washed once with TBS containing 0.05% (vol/vol) Tween 20(TBS T20) and once with TBS only, and then incubated for 2 h at33°C with the primary antibodies diluted in TBS supplemented with5% (vol/vol) horse serum (bovine sera diluted 1:75, MAb 1E5 diluted1:100, MAb 1A1 diluted 1:2,000; rabbit hyperimmune sera diluted1:1,000). After three washes with TBS T20 and one with TBS, theblots were incubated for 1 h at 33°C with the appropriate secondaryantibodies. The peroxidase-conjugated rabbit antibovine Igs (Dako,Glostrup, Denmark), sheep anti-bovine IgM and IgG (Bethyl Laboratories,Inc., Montgomery, Tex.), and goat anti-mouse IgM and IgG (AccurateChemical and Scientific Corporation, Westbury, N.Y.) were dilutedin phosphate-buffered saline as recommended by themanufacturer.

Expression of VspA in E. coli as a fusion protein. The fusion protein FP-VspA-I was generated by using the pMAL-c2 protein fusion system of New England Biolabs. Briefly, oligonucleotidesP-5 (5'-GCA GGA TCC TGT GGT GAG ACC AAA G-3') and P-3 (5'-TATTAA GCT TAA GAA CTT GTT GGT ATT TT-3') (boldface lettersindicate engineered restriction sites, and underlined lettersindicate the codon encoding the first amino acid of the VspA matureprotein), which span the exported, mature coding sequence of VspA(Fig. 1A), were used to produce by PCR a DNA fragment from thecloned VspA gene template (16). Engineered BamHI and HindIIIrestriction sites located in primers P-5 and P-3, respectively,were used to insert the PCR product in frame with the malE gene,which encodes the maltose binding protein (MBP), into the pMAL-c2plasmid by standard procedures. The fusion protein FP-VspA-I encodedby the resulting recombinant plasmid pFP-VspA-I was overexpressedin transformed E. coli DH10B cells (GIBCO BRL, Life Technologies,Inc., Grand Island, N.Y.) and was purified by affinity chromatographyby using maltose binding properties, as prescribed by the manufacturer(New England Biolabs, Inc.). Cleavage of the VspA product fromthe MBP by the protease factor Xa was achieved as instructed bythe manufacturer.

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FIG. 1. Schematic representation of the VspA fusion proteins and localization of immunodominant epitopes 1A1 and 1E5. (A) Localization of the primers on the vspA gene used to generate the recombinant proteins represented in panel C (numbers indicate nucleotide position). (B) Representation of the different domains that compose the VspA product (open boxes) and their localization (numbers represent amino acid position). (C) Representation of the domains that compose the FP-VspA-I to -V fusion proteins and their reactivity with MAbs 1E5 and 1A1 and animal sera A009 (experiment 2), 56 and 30 (from two animals of outbreak 4), and 6248 (from one animal of outbreak 2).

Three truncated versions of the FP-VspA fusion protein (Fig. 1C), namely FP-VspA-II, FP-VspA-III, and FP-VspA-V, were obtainedby the same procedure. For this purpose, primers complementaryto the junction of two distinct repeated units or to unrepeatedsequences located between two blocks of repeated elements weredesigned: R3-5 (5'-CCC AGG ATC CCC GCA TGA T-3'), R3-3(5'-CCT GAA GCT TGT TGT GAG TTA G-3'), and R1-3 (5'-GTTTTC CTC AAG CTT TTT AAT TTT C-3'). These primers were usedin combination with P-5 (5') or P-3 (3'), as shown in Fig. 1A.Boldface letters represent engineered BamHI (5'-end primer) andHindIII (3'-end primer) restriction sites for in-frame insertionof the PCR fragment into the pMAL-c2 vector downstream of themalE sequence. Finally, the FP-VspA-IV fusion protein was obtainedby subcloning the EcoRI DNA fragment of the plasmid pFP-VspA-I,which contained the 3' end of the pMAL-c2 polylinker and the first313 nucleotides of the vspA gene, into EcoRI-pMAL-c2. Expressionof the truncated fusion proteins was performed as described above.PCR fragments cloned into pMAL-c2 were sequenced by deoxy terminatorcycle sequencing with infrared labelled primers and the DNA sequencerLong Readir 4200 (LI-COR, Lincoln, The Netherlands) and shownto be identical to the previously published vspA gene (16).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Humoral response to M. bovis epitopes in experimentally infected cattle. To evaluate the host antibody reactivity to M. bovis antigens, and more specifically to Vsps, identical immunoblots representingwhole-cell extracts of selected clonal variants derived from M.bovis type strain PG45 were independently immunostained with theVsp-specific MAb 1E5 and with sera of experimentally infectedanimals (Table 1). Analyses were performed with three PG45 clonalvariants, each expressing distinct Vsp products easily identifiedby their size in Western blot analysis by using the MAb 1E5 (Fig.2A), namely 79-kDa VspC (lane 1), 64-kDa VspA plus 46-kDa VspB(lane 2), and 67-kDa VspA (lane 3). As summarized in Table 1,all sera collected from experimentally infected animals generatedimmunoprofiles identical to that obtained with MAb 1E5. This isillustrated in Fig. 2, which shows the Vsp-specific reaction obtainedwith the sera of animals A009 (Fig. 2C), M (Fig. 2E), and E095(Fig. 2F), while no reaction was observed between M. bovis whole-cellantigens and preimmune sera from the same animals (Fig. 2B andD [not shown for E095]). These results showed that bovine antibodiesto Vsp epitopes appeared specifically after infection with M.bovis. Moreover, bovine serum antibodies to M. bovis recognizedassorted sizes of Vsp products (Fig. 2C, E, and F; 64- and 67-kDaVspA in lanes 2 and 3, 79-kDa VspC in lane 1, and 46-kDa VspBin lane 2). As well, they reacted with Vsp products expressedby a different strain from the one used for inoculation, sinceserum antibodies from animals infected with M. bovis 1067 recognizedVsps of the PG45 strain. Interestingly, sera collected from animalsinoculated with a clonal variant derived from the type strainPG45 that expressed a single Vsp, 67-kDa VspA (experiment 2),also contained antibodies that reacted with VspC and VspB (seeserum A009, Fig. 2C). As shown in Fig. 2, circulating host antibodiesdirected toward Vsp epitopes were detected in sera as early as6 days after infection (Fig. 2C and E), but were also detected532 days postinoculation (Fig. 2F).

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FIG. 2. Selective recognition of defined Vsp products of M. bovis PG45 by serum antibodies from M. bovis-infected cattle. Identical Western blots representing the total proteins of three clonal variants (lanes 1 to 3) derived from M. bovis PG45 were respectively immunostained with MAb 1E5 (A), with sera collected from experimental infection (B to F), or with sera collected from natural outbreaks (G to K). The sera used in this experiment are described in Tables 1 and 2 and correspond to animal A009 before (B) and after (C) infection; animal M before (D) and after (E) infection; sera E095 (F), 30 (G), and 56 (H) from two animals of outbreak 4; serum 6241 (I) from outbreak 2; serum 47 (J) from outbreak 1; and serum 283/17 (K) from the field sampling. Lanes 1 through 3 represent clonal variants expressing 79-kDa VspC (lane 1), 64-kDa VspA plus 46-kDa VspB (lane 2), and 67-kDa VspA (lane 3).

Humoral response to M. bovis epitopes in naturally infected cattle. To further investigate whether the results obtained with sera from experimentally infected animals reflected the situationoccurring in the field, similar experiments were performed withsera collected from animals displaying diverse clinical manifestationsduring natural M. bovis outbreaks in geographically distant herds.As illustrated in Fig. 2G to K, immunoprofiles obtained with serarepresentative of outbreaks 1, 2, and 4 (Table 2) were identicalto that obtained with MAb 1E5 or with sera collected from animalsexperimentally infected with M. bovis (Fig. 2). In a few cases,immunoprofiles obtained with field sera were more complex thanthat presented in Fig. 2, because several mycoplasma componentsother than the Vsps were also weakly reacting with the host antibodies(data not shown). Sera obtained from asymptomatic animals thatwere strongly reacting with M. bovis in the IHA displayed a patternsimilar to that obtained in Fig. 2, because they only reactedwith Vsp epitopes (Table 2, field sampling). In some cases, weobserved that the reactivity of the sera with 46-kDa VspB wasweaker than that observed with 64-kDa VspA (Fig. 2H, lane 2, anddata not shown) indicating that recognition of VspB epitopes bythe immune system may vary from one animal to another, while allsera reacted strongly with the 67-kDa VspA product (Fig. 2G toK, lane 3). Finally, hyperimmune sera against other mycoplasmasfrequently isolated from cattle (M. bovigenitalium, M. bovirhinis,M. arginini, Acholeplasma laidlawii, and Urealyticum diversum)and against M. agalactiae, a mycoplasma that is phylogeneticallyclosely related to M. bovis and occasionally found in cattle (21),did not react with M. bovis antigens (except for a very weak reactionwith M. arginini and uncharacterized antigens of M. bovis whole-cellextract).

Reactivity of VspA overexpressed in E. coli with hyperimmune sera of cattle experimentally and naturally infected with M. bovis. To define whether the VspA product would be a suitable tool for serodiagnostic purposes, for instance, in epidemiologicalstudies, the VspA product of M. bovis PG45 was expressed in E.coli as a nondenatured recombinant product. This was achievedby inserting the DNA sequence encoding the mature VspA productfrom the +1 Cys to the C-terminal tip, into the pMAL-c2 vectorto create an in-frame fusion with the malE gene, which encodesthe MBP (Fig. 1). In SDS-PAGE, the resulting recombinant fusionprotein, designated FP-VspA-I, had an apparent molecular massof about 107 kDa (Fig. 3) which corresponds to the mature VspAsequence (67 kDa without the signal peptide) (16) fused to theC-terminal region of the MBP (36 kDa for the MBP). Western blotanalysis showed that the FP-VspA-I was antigenically comparableto the native VspA, because it reacted both with the Vsp-specificMAb 1A1 (Fig. 3A, lane 1) and MAb 1E5 (Fig. 3A, lane 2), whichbinds to VspA and VspC, but not to VspB. Moreover, serum antibodiesfrom cows naturally or experimentally infected with M. bovis alsoreacted with the recombinant fusion protein FP-VspA-I, as illustratedin Fig. 3A, lanes 3 and 4. In contrast, no reaction of these serawas obtained with the MBP fused with $beta$ -galactosidase (Fig. 3A,lanes 3 and 4). The immunoreactivity of FP-VspA-I was also testedwith (i) serum collected from sheep infected with M. agalactiaeand (ii) serum obtained from an animal which was shown to be freeof M. bovis. As shown in Fig. 3A, lanes 5 and 6, none of thesesera reacted with FP-VspA-I. Moreover, no reaction was obtainedwith hyperimmune serum raised against M. arginini (data not shown),which was shown to react weakly with uncharacterized antigensof M. bovis whole-cell extract. Immunoblot analysis of FP-VspA-Idigested with the factor Xa revealed that the cleaved 67-kDa VspAproduct reacted with (i) the MAbs 1E5 (Fig. 3B, lane 2) and 1A1(data not shown) and (ii) all positive bovine sera correspondingto outbreaks 1, 2, 3, and 4 shown in Table 1 (see Fig. 3B, lanes8 and 9 for two representative serum samples). By the same procedure,host antibodies to VspA were detected in IHA-negative serum ofanimal J005 (Table 1, experiment 1) collected at day 13 or 17following contact with the infected animal J004 (Fig. 3B, lanes10 and 11). Since M. bovis was first reisolated in BALs of animalJ005 at day 6, these results support our previous findings thatshowed the early appearance of circulating host antibodies toVsp epitopes in animals infected by endobronchial inoculation(Table 1, experiments 2 and 3). Serum samples collected fromanimal J005 after day 23 were all positive in IHA and reactedwith the VspA product. Similar results obtained with sera collectedfrom two other contact-infected animals (data not shown) indicatedthat host antibodies to M. bovis are detectable within 10 dayswith FP-VspA-I, however, not with the IHA.

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FIG. 3. Seroreactivity of the VspA immunogenic domains with Vsp-specific MAbs and animal sera. The FP-VspA-I product and the MBP- $beta$ -galactosidase (A) or FP-VspA-I product digested with the factor Xa (B) or the FP-VspA-I, FP-VspA-II, and FP-VspA-V fusion proteins (C) were separated by SDS-PAGE and transferred onto nitrocellulose membrane. Immunostaining of the Western blots was performed with MAb 1A1 (lane 1), MAb 1E5 (lane 2), serum A009 from experiment 2 (lane 3), serum 56 from outbreak 4 (lane 4), hyperimmune serum PAL from sheep infected with M. agalactiae (lane 5), serum from an M. bovis-free animal (lane 6), anti-MBP serum (lane 7), serum 30 from outbreak 4 (lane 8), serum 45 from outbreak 4 (lane 9), IHA-negative sera from animal J005 at days 13 (lane 10) and 17 (lane 11), and serum 6248 from outbreak 2 (lane 12).

Approximately 80% of the VspA amino sequence is composed by two distinct stretches of repeated sequences separated from eachother by 22 amino acids (Fig. 1B). The first block, localizedat the N-terminal portion, is composed of two distinct motifs,designated R_A1 and R_A2, while the second block, localized at theC-terminal portion, contains three repeated motifs, R_A3, R_A4.1,and R_A4.2 (16). In order to better define which portion of theVspA molecule is involved in stimulating the host humorale immuneresponse, four truncated versions of the FP-VspA-I, designatedFP-VspA-II, FP-VspA-III, FP-VspA-IV, and FP-VspA-V, were generatedby cloning independently selected vspA regions into the pMAL-c2vector, as described in Materials and Methods. Figure 1C illustratesthe different regions encoded by the genes coding for these truncatedproducts. Localization of the 1A1 and 1E5 epitopes was achievedby Western blot analysis. This showed that the first 106-amino-acidsequence contains the 1A1 epitope (Fig. 3C, lane 1), while theC-terminal region from amino acid 155 to amino acid 325 encodesthe 1E5 epitope (Fig. 3C, lane 2). The four truncated fusion proteinsreacted with sera 56 and 30, collected from outbreak 4, and withserum 6248, collected from outbreak 2. Interestingly, serum A009,collected 6 days after experimental infection with the VspA 67clonal variant (experiment 2), only reacted with fusion proteins(FP-VspA-I and -II) that contain the 1E5 epitope (Fig. 1C and3C, lane 3). Similarly, sera collected 9 days after infectionwith M. bovis 1067 (experiment 3, calves Y and V [Table 2]) onlyrecognized the FP-VspA-I and -II, while sera taken at day 21 fromthe same calves (experiment 3, calves Y and V) did react as wellwith FP-VspA-III (data notshown).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The results presented in this report show that the Vsps represent those components that predominantly elicit the bovine humoralimmune response in cattle after experimental or natural infectionwith M. bovis, independently of the clinical manifestations, thegeographic location and origin of the agent, the mode of infection,and the animal's history. In experimentally infected calves, circulatinghost antibodies directed toward Vsp epitopes appeared within anaverage of 10 days following inoculation with M. bovis, but alsoas early as 6 days, and were still detectable for several monthsafter infection. Results obtained with contact-infected animalsindicated that a similar situation is likely to occur in the field.Serum antibodies collected from cattle naturally infected withM. bovis of unknown Vsp phenotype and genotype were shown to recognizethe three Vsps expressed by the type strain PG45. Inoculationof animals with strain 1067 also resulted in the appearance ofantibodies that cross-reacted with the Vsps of strain PG45. Thisimplies that despite their clonal variability, the Vsps or atleast some members of the Vsp family are persistently expressedby M. bovis in the bovine host during infection and that immunodominantepitopes are highly conserved among strains and isolates. Thepresence of anti-VspB and anti-VspC antibodies in addition toanti-VspA antibodies during infection with a clonal variant expressingVspA (experiment 2) indicated that common epitopes shared by thethree Vsps (VspA, VspB, and VspC) are strongly immunogenic inthe host and/or that oscillation in Vsp expression occurs in vivo,generating subpopulations expressing VspB and VspC. In some cases,the reactivity of bovine serum antibodies was stronger with theVspA and VspC products than with VspB. This can be explained by(i) the absence of the 1A1 epitope on VspB which is shared byboth the VspA and the VspC proteins and (ii) the fact that thenumber of repeated elements which constitute 80% of the moleculeand are thought to contain the immunodominant epitopes is lowerin the 46-kDa VspB product than in the 64-kDa VspA and 79-kDaVspC molecules. On the other hand, previous data suggested thatthe VspA and the VspC proteins may be the products of two distinctallelic versions of the same vsp gene (16), explaining theirsimilar reactivity with the MAbs 1A1 and 1E5 and the animalsera.

In light of these findings and the proven nonreactivity of the Vsps to sera raised against closely related mycoplasmas commonlyisolated from cattle, the surface-exposed VspA product of M. boviswas overexpressed in E. coli as a recombinant protein. This productwas shown to be antigenically comparable to the native VspA, becauseit reacted with two MAbs directed to Vsps, 1A1 and 1E5, as wellas with all sera used in this study, collected from cattle experimentallyor naturally infected with M. bovis. Interestingly, recognitionof the VspA immunodominant domains by the host immune system wasslightly different, because truncated recombinant VspA productslacking the R_A4 repeated region, FP-VspA-III, FP-VspA-IV, andFP-VspA-V, failed to react with sera taken between 6 to 10 days,but were recognized by sera of the same animals collected at alater stage. As shown in this study, the R_A4 region contains thetarget epitope of MAb 1E5, which is an IgM isotype, while theN-terminal R_A1 repeated motif, encoded by the genes coding forall of the truncated VspA products, is recognized by MAb 1A1,which is an IgG isotype. This suggests that detection of the N-terminalregion of VspA, which contains the R_A1 motif, may require theseroconversion of IgM to IgG, due to either a low concentrationof IgM reacting with the 1A1 target epitope or due to a conformationalstructure that temporarily masks the target epitope. Nevertheless,these data indicate that the recombinant product containing theentire VspA sequence is suitable for the early and late detectionof animals infected with M. bovis.

The presence of vsp gene homologues in field isolates or strains other than the PG45 type strain was recently assessed in250 M. bovis field isolates collected in France, Germany, Italy,Spain, and Switzerland (23). All were shown to contain DNA sequenceshomologous to vsp genes and to express, to various degrees, epitopesthat reacted with either the 1A1 or the 1E5 MAb. Interestingly,the few isolates that did not react with MAb 1E5 failed to reactin Southern blot analysis with the oligonucleotide probe correspondingto the R_A4 motif. In contrast, all isolates contained multiplecopies of the sequence encoding the motif R_A1 and were reactingwith MAb 1A1 (23). This corresponds to the results obtainedin this study with the truncated recombinant Vsps revealing thelocation of the 1A1 and 1E5 epitopes within the R_A1 and R_A4 repeatedmotifs,respectively.

Even though the Vsp proteins were shown to participate in adhesion to the host cell (27), their exact role during the processof the disease remains to be elucidated. However, if the presenceof Vsp epitopes at the surface of the mycoplasma depends on theon and off status of the corresponding gene or genes, it alsodepends on the number of vsp genes that dictate the Vsp repertoirein a given strain. For the type strain PG45, which contains eightdistinct vsp genes (24) that may all be subjected to on andoff oscillation in expression, the likelihood that each cell expressesat least one Vsp is rather high. In fact, immunostaining of M.bovis PG45 colonies with MAbs 1E5 and 1A1 revealed that nearlyall colonies do express the target epitopes. It is likely thata similar situation occurs in M. bovis field isolates, and thisargument is supported by the results presented in this study thatshowed the presence of anti-Vsp antibodies in sera of animalsinfected with M. bovis of unknown Vspphenotypes.

Thus, based on the data obtained in this study, we propose the utilization of the VspA recombinant fusion protein FP-VspA-Ias an immunologic reagent for the rapid identification of cattleinfected with M. bovis.

	ACKNOWLEDGMENTS

We thank J. Nicolet (University of Bern, Bern, Switzerland), F. Marty (France), and Sanofi Santé Nutrition Animal for providingsera, K. Sachse for providing the clonal VspA gene, and K. Siebert-Gulleand M. Solsona for technicalassistance.

This study is part of the European COST action 826 "Ruminants' mycoplasmoses" and was supported by a grant by the French Ministryof Agriculture (E.N.V.L. Lyon-454-1997) to D.L.G. and a grantby the Austrian Ministry of Health and Consumer Protection (353.024/2-III/9/96)to R.R.

M. Brank and D. Le Grand contributed equally to thispaper.

	FOOTNOTES

^* Corresponding author. Mailing address: Institut für Bakteriologie, Mykologie und Hygiene, Veterinärmedizinische UniversitätWien, Veterinärplatz 1, 1210 Vienna, Austria. Phone: 43 1 250772101. Fax: 43 1 25077 2190. E-mail: Christine.Citti{at}vu-wien.ac.at.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Ayling, R. D., R. A. Nicholas, and K. E. Johansson. 1997. Application of the polymerase chain reaction for the routine identification of Mycoplasma bovis. Vet. Rec. 141:307-308[Free Full Text].

2. Ball, H. J., D. Finlay, and G. A. Reilly. 1994. Sandwich ELISA detection of Mycoplasma bovis in pneumonic calf lungs and nasal swabs. Vet. Rec. 135:531-532[Medline].

3. Behrens, A., M. Heller, H. Kirchhoff, D. Yogev, and R. Rosengarten. 1994. A family of phase- and size-variant membrane surface lipoprotein antigens (Vsps) of Mycoplasma bovis. Infect. Immun. 62:5075-5084[Abstract/Free Full Text].

4. Chavez Gonzalez, Y. R., C. R. Bascunana, G. Bölske, J. G. Mattson, C. Fernandez Molina, and K. E. Johansson. 1995. In vitro amplification of 16S rRNA genes from Mycoplasma bovis and Mycoplasma agalactiae. Vet. Microbiol. 47:183-190[Medline].

5. Cho, H. J., H. L. Ruhnke, and E. V. Langford. 1976. The indirect hemagglutination test for the detection of antibodies in cattle naturally infected with mycoplasmas. Can. J. Comp. Med. 40:20-29[Medline].

6. Gardella, R. S., R. A. Delguidice, and J. G. Tully. 1983. Immunofluorescence, p. 431-439. In S. Razin, and J. G. Tully (ed.), Methods in mycoplasmology, vol. I. Mycoplasma characterization. Academic Press, New York, N.Y

7. Ghadersohi, A., R. J. Coelen, and R. G. Hirst. 1997. Development of a specific DNA probe and PCR for the detection of Mycoplasma bovis. Vet. Microbiol. 56:87-98[Medline].

8. Gourlay, R. N., and S. B. Houghton. 1985. Experimental pneumonia in conventionally reared and gnotobiotic calves by dual infection with Mycoplasma bovis and Pasteurella haemolytica. Res. Vet. Sci. 38:377-382[Medline].

9. Heller, M., E. Berthold, H. Pfützner, R. Leirer, and K. Sachse. 1993. Antigen capture ELISA using a monoclonal antibody for the detection of Mycoplasma bovis in milk. Vet. Microbiol. 37:127-133[Medline].

10. Hotzel, H., K. Sachse, and H. Pfützner. 1996. Rapid detection of Mycoplasma bovis in milk samples and nasal swabs using the polymerase chain reaction. J. Appl. Bacteriol. 80:505-510[Medline].

11. Kinde, H., B. M. Daft, R. L. Walker, B. R. Charlton, and R. Petty. 1993. Mycoplasma bovis associated with decubital abscesses in Holstein calves. J. Vet. Diagn. Investig. 5:194-197[Abstract/Free Full Text].

12. Kirby, F. D., and R. A. Nicolas. 1996. Isolation of Mycoplasma bovis from bullocks' eyes. Vet. Rec. 138:552[Medline]. (Letter.)

13. Kirk, J. H., and L. H. Lauermann. 1994. Mycoplasma mastitis in dairy cows. The compendium. Compend. Edu. Prat. Vet. 16:541-551.

14. Kotani, H., and G. J. McGarrity. 1986. Identification of mycoplasma colonies by immunobinding. J. Clin. Microbiol. 23:783-785[Abstract/Free Full Text].

15. Le Grand, D., M. Solsona, R. Rosengarten, and F. Poumarat. 1996. Adaptive surface antigen variation in Mycoplasma bovis to the host immune response. FEMS Microbiol. Lett. 144:267-275[Medline].

16. Lysnyansky, I., R. Rosengarten, and D. Yogev. 1996. Phenotypic switching of variable surface lipoproteins in Mycoplasma bovis involves high-frequency chromosomal rearrangements. J. Bacteriol. 178:5395-5401[Abstract/Free Full Text].

17. Pfützner, H. 1990. Epizootiology of Mycoplasma bovis infection of cattle, p. 394-399. In G. Stanek, G. H. Cassell, J. H. Tully, and R. F. Whitcomb (ed.), Recent advances in mycoplasmology, Proceedings of the 7th Congress of the International Organization for Mycoplasmology, vol. 20. Gustav Fisher Verlag, Stuttgart, Germany

18. Pfützner, H., and K. Sachse. 1996. Mycoplasma bovis as an agent of mastitis, pneumonia, arthritis and genital disorders in cattle. Rev. Sci. Technol. 15:1477-1494[Medline].

19. Polak-Vogelzang, A. A., R. Hagenaars, and J. Nagel. 1978. Evaluation of an indirect immunoperoxidase test for identification of Acholeplasma and Mycoplasma. J. Gen. Microbiol. 106:241-249[Abstract/Free Full Text].

20. Poumarat, F., M. Perrin, P. Belli, and J. L. Martel. 1987. Recherche des anticorps anti-Mycoplasma bovis dans les serum des bovins a l'aide de la réaction d'hemagglutination passive: valeur et limites de la réaction. Rev. Med. Vet. 138:981-989.

21. Poumarat, F., M. Perrin, and D. Longchambon. 1991. Identification of ruminant mycoplasmas by dot immunobinding on membrane filtration (MF dot). Vet. Microbiol. 29:329-338[Medline].

22. Poumarat, F., M. Perrin, J. L. Martel, and J. P. Lacombe. 1985. Etude d'un foyer de mammites à Mycoplasma bovis. Rev. Med. Vet. 161:649-654.

23. Poumarat, F., D. Le Grand, M. Solsona, R. Rosengarten, and C. Citti. 1999. Vsp antigen and vsp-related sequences in field isolates of M. bovis. FEMS Microbiol. Lett. 173:103-110[Medline].

24. Razin, S., D. Yogev, and Y. Naot. 1998. Molecular biology and pathogenicity of mycoplasmas. Microbiol. Mol. Biol. Rev. 62:1094-1156[Abstract/Free Full Text].

25. Rosengarten, R., A. Behrens, A. Stetefeld, M. Heller, M. Ahrens, K. Sachse, D. Yogev, and H. Kirchhoff. 1994. Antigen heterogeneity among isolates of Mycoplasma bovis is generated by high-frequency variation of diverse membrane surface proteins. Infect. Immun. 62:5066-5074[Abstract/Free Full Text].

26. Rosengarten, R., and D. Yogev. 1996. Variant colony surface antigenic phenotypes within mycoplasma strain populations: implications for species identification and strain standardization. J. Clin. Microbiol. 34:149-158[Abstract].

27. Sachse, K., H. Pfützner, M. Heller, and I. Hänel. 1993. Inhibition of Mycoplasma bovis cytadherence by a monoclonal antibody and various carbohydrate substances. Vet. Microbiol. 36:307-316[Medline].

28. Stipkovits, L., M. Rady, and R. Glavits. 1993. Mycoplasmal arthritis and meningitis in calves. Acta Vet. Hung. 41:73-88[Medline].

29. Subramaniam, S., D. Bergonier, F. Poumarat, S. Capaul, Y. Schlatter, J. Nicolet, and J. Frey. 1998. Species identification of Mycoplasma bovis and Mycoplasma agalactiae based on the uvrC genes by PCR. Mol. Cell. Probes 12:161-169[Medline].

30. Ter Laak, E. A., G. H. Wentink, and G. M. Zimmer. 1992. Increased prevalence of Mycoplasma bovis in The Netherlands. Vet. Q. 15:100-104.

31. Trevor, R. 1997. Dairy calf pneumonia, the disease and its impacts. Vet. Clin. N. Am. Small Anim. Pract. 13:379-391.

32. Walz, P. H., T. P. Mullaney, J. A. Render, R. D. Walker, T. Mosser, and J. C. Baker. 1997. Otitis media in preweaned Holstein dairy calves in Michigan due to Mycoplasma bovis. J. Vet. Diagn. Investig. 9:250-254[Abstract/Free Full Text].

This article has been cited by other articles:

Glew, M. D., Papazisi, L., Poumarat, F., Bergonier, D., Rosengarten, R., Citti, C. (2000). Characterization of a Multigene Family Undergoing High-Frequency DNA Rearrangements and Coding for Abundant Variable Surface Proteins in Mycoplasma agalactiae. Infect. Immun. 68: 4539-4548 [Abstract] [Full Text]

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1.	Ayling, R. D., R. A. Nicholas, and K. E. Johansson. 1997. Application of the polymerase chain reaction for the routine identification of Mycoplasma bovis. Vet. Rec. 141:307-308[Free Full Text].
2.	Ball, H. J., D. Finlay, and G. A. Reilly. 1994. Sandwich ELISA detection of Mycoplasma bovis in pneumonic calf lungs and nasal swabs. Vet. Rec. 135:531-532[Medline].
3.	Behrens, A., M. Heller, H. Kirchhoff, D. Yogev, and R. Rosengarten. 1994. A family of phase- and size-variant membrane surface lipoprotein antigens (Vsps) of Mycoplasma bovis. Infect. Immun. 62:5075-5084[Abstract/Free Full Text].
4.	Chavez Gonzalez, Y. R., C. R. Bascunana, G. Bölske, J. G. Mattson, C. Fernandez Molina, and K. E. Johansson. 1995. In vitro amplification of 16S rRNA genes from Mycoplasma bovis and Mycoplasma agalactiae. Vet. Microbiol. 47:183-190[Medline].
5.	Cho, H. J., H. L. Ruhnke, and E. V. Langford. 1976. The indirect hemagglutination test for the detection of antibodies in cattle naturally infected with mycoplasmas. Can. J. Comp. Med. 40:20-29[Medline].
6.	Gardella, R. S., R. A. Delguidice, and J. G. Tully. 1983. Immunofluorescence, p. 431-439. In S. Razin, and J. G. Tully (ed.), Methods in mycoplasmology, vol. I. Mycoplasma characterization. Academic Press, New York, N.Y
7.	Ghadersohi, A., R. J. Coelen, and R. G. Hirst. 1997. Development of a specific DNA probe and PCR for the detection of Mycoplasma bovis. Vet. Microbiol. 56:87-98[Medline].
8.	Gourlay, R. N., and S. B. Houghton. 1985. Experimental pneumonia in conventionally reared and gnotobiotic calves by dual infection with Mycoplasma bovis and Pasteurella haemolytica. Res. Vet. Sci. 38:377-382[Medline].
9.	Heller, M., E. Berthold, H. Pfützner, R. Leirer, and K. Sachse. 1993. Antigen capture ELISA using a monoclonal antibody for the detection of Mycoplasma bovis in milk. Vet. Microbiol. 37:127-133[Medline].
10.	Hotzel, H., K. Sachse, and H. Pfützner. 1996. Rapid detection of Mycoplasma bovis in milk samples and nasal swabs using the polymerase chain reaction. J. Appl. Bacteriol. 80:505-510[Medline].
11.	Kinde, H., B. M. Daft, R. L. Walker, B. R. Charlton, and R. Petty. 1993. Mycoplasma bovis associated with decubital abscesses in Holstein calves. J. Vet. Diagn. Investig. 5:194-197[Abstract/Free Full Text].
12.	Kirby, F. D., and R. A. Nicolas. 1996. Isolation of Mycoplasma bovis from bullocks' eyes. Vet. Rec. 138:552[Medline]. (Letter.)
13.	Kirk, J. H., and L. H. Lauermann. 1994. Mycoplasma mastitis in dairy cows. The compendium. Compend. Edu. Prat. Vet. 16:541-551.
14.	Kotani, H., and G. J. McGarrity. 1986. Identification of mycoplasma colonies by immunobinding. J. Clin. Microbiol. 23:783-785[Abstract/Free Full Text].
15.	Le Grand, D., M. Solsona, R. Rosengarten, and F. Poumarat. 1996. Adaptive surface antigen variation in Mycoplasma bovis to the host immune response. FEMS Microbiol. Lett. 144:267-275[Medline].
16.	Lysnyansky, I., R. Rosengarten, and D. Yogev. 1996. Phenotypic switching of variable surface lipoproteins in Mycoplasma bovis involves high-frequency chromosomal rearrangements. J. Bacteriol. 178:5395-5401[Abstract/Free Full Text].
17.	Pfützner, H. 1990. Epizootiology of Mycoplasma bovis infection of cattle, p. 394-399. In G. Stanek, G. H. Cassell, J. H. Tully, and R. F. Whitcomb (ed.), Recent advances in mycoplasmology, Proceedings of the 7th Congress of the International Organization for Mycoplasmology, vol. 20. Gustav Fisher Verlag, Stuttgart, Germany
18.	Pfützner, H., and K. Sachse. 1996. Mycoplasma bovis as an agent of mastitis, pneumonia, arthritis and genital disorders in cattle. Rev. Sci. Technol. 15:1477-1494[Medline].
19.	Polak-Vogelzang, A. A., R. Hagenaars, and J. Nagel. 1978. Evaluation of an indirect immunoperoxidase test for identification of Acholeplasma and Mycoplasma. J. Gen. Microbiol. 106:241-249[Abstract/Free Full Text].
20.	Poumarat, F., M. Perrin, P. Belli, and J. L. Martel. 1987. Recherche des anticorps anti-Mycoplasma bovis dans les serum des bovins a l'aide de la réaction d'hemagglutination passive: valeur et limites de la réaction. Rev. Med. Vet. 138:981-989.
21.	Poumarat, F., M. Perrin, and D. Longchambon. 1991. Identification of ruminant mycoplasmas by dot immunobinding on membrane filtration (MF dot). Vet. Microbiol. 29:329-338[Medline].
22.	Poumarat, F., M. Perrin, J. L. Martel, and J. P. Lacombe. 1985. Etude d'un foyer de mammites à Mycoplasma bovis. Rev. Med. Vet. 161:649-654.
23.	Poumarat, F., D. Le Grand, M. Solsona, R. Rosengarten, and C. Citti. 1999. Vsp antigen and vsp-related sequences in field isolates of M. bovis. FEMS Microbiol. Lett. 173:103-110[Medline].
24.	Razin, S., D. Yogev, and Y. Naot. 1998. Molecular biology and pathogenicity of mycoplasmas. Microbiol. Mol. Biol. Rev. 62:1094-1156[Abstract/Free Full Text].
25.	Rosengarten, R., A. Behrens, A. Stetefeld, M. Heller, M. Ahrens, K. Sachse, D. Yogev, and H. Kirchhoff. 1994. Antigen heterogeneity among isolates of Mycoplasma bovis is generated by high-frequency variation of diverse membrane surface proteins. Infect. Immun. 62:5066-5074[Abstract/Free Full Text].
26.	Rosengarten, R., and D. Yogev. 1996. Variant colony surface antigenic phenotypes within mycoplasma strain populations: implications for species identification and strain standardization. J. Clin. Microbiol. 34:149-158[Abstract].
27.	Sachse, K., H. Pfützner, M. Heller, and I. Hänel. 1993. Inhibition of Mycoplasma bovis cytadherence by a monoclonal antibody and various carbohydrate substances. Vet. Microbiol. 36:307-316[Medline].
28.	Stipkovits, L., M. Rady, and R. Glavits. 1993. Mycoplasmal arthritis and meningitis in calves. Acta Vet. Hung. 41:73-88[Medline].
29.	Subramaniam, S., D. Bergonier, F. Poumarat, S. Capaul, Y. Schlatter, J. Nicolet, and J. Frey. 1998. Species identification of Mycoplasma bovis and Mycoplasma agalactiae based on the uvrC genes by PCR. Mol. Cell. Probes 12:161-169[Medline].
30.	Ter Laak, E. A., G. H. Wentink, and G. M. Zimmer. 1992. Increased prevalence of Mycoplasma bovis in The Netherlands. Vet. Q. 15:100-104.
31.	Trevor, R. 1997. Dairy calf pneumonia, the disease and its impacts. Vet. Clin. N. Am. Small Anim. Pract. 13:379-391.
32.	Walz, P. H., T. P. Mullaney, J. A. Render, R. D. Walker, T. Mosser, and J. C. Baker. 1997. Otitis media in preweaned Holstein dairy calves in Michigan due to Mycoplasma bovis. J. Vet. Diagn. Investig. 9:250-254[Abstract/Free Full Text].