Characterization of the gene encoding a 60-kilodalton Babesia bovis merozoite protein with conserved and surface exposed epitopes

DNA and a CpG oligonucleotide derived from Babesia bovis are mitogenic for bovine B cells

DNAs from bacteria and variety of nonvertebrate organisms, including nematodes, mollusks, yeasts, and insects, cause polyclonal activation of murine B lymphocytes. Similar studies have not been reported for bovine B cells, and to date no studies have reported mitogenic properties of protozoal DNA for any species. However, we and others have observed that protozoal parasite antigens can induce the proliferation of lymphocytes from nonexposed donors. Extending these studies, we now show that the mitogenic property of protozoal antigen preparations is in part attributable to parasite DNA and that Babesia bovis DNA is directly mitogenic for bovine B cells. DNase treatment of B. bovis extracts abrogated B. bovis-induced proliferation of peripheral blood mononuclear cells from nonexposed cattle. Like DNAs from other organisms that were mitogenic for murine B cells, B. bovis DNA is largely nonmethylated and induced a dose-dependent proliferation of bovine B cells, which was reduced upon methylation. Furthermore, B. bovis and E. coli DNAs enhanced immunoglobulin secretion by cultured B cells, inducing moderate increases in immunoglobulin G1 and stronger increases in immunoglobulin G2. Because certain nonmethylated CpG motifs present in bacterial DNA are known to stimulate proliferation of murine and human B cells, an 11-kb fragment of B. bovis DNA was analyzed for CG dinucleotide content and for the presence of known immunostimulatory sequences (ISS) centered on a CG motif. The frequency of CG dinucleotides was approximately one-half of the expected frequency, and several CpG hexameric sequences with known activity for murine B cells were identified. An oligodeoxynucleotide containing one of these ISS (AACGTT), which is present within the rhoptry-associated protein-1 (rap-1) open reading frame, was shown to stimulate B-cell proliferation. These ISS may be involved in host immune modulation during protozoal infection and may be useful as vaccine adjuvants.

Sequence and functional analysis of the intergenic regions separating babesial rhoptry-associated protein-1 (rap-1) genes

The rhoptry-associated protein 1 (RAP-1) expressed by all babesial parasites is encoded by tandemly arranged genes separated by discrete intergenic (IG) regions. We hypothesize that these IG regions regulate rap-1 gene expression. In Babesia bovis two identical rap-1 gene copies are separated by a 1.0-kb noncoding region which is also exactly conserved 5' to the rap-1 gene 1. In contrast, the complex B. bigemina rap-1 locus contains at least 5 polymorphic rap-1a genes separated by uncharacterized 3.38-kb regions. A genomic clone encoding the 3' sequence of rap-1 gene copy 1, the 1 kb IG region, and the 5' sequence of gene copy 2 was obtained by PCR amplification of DNA from the Mo7 biological clone of B. bovis and sequenced. This was follow by amplification and sequence analysis of the 3.38-kb region separating two B. bigemina rap-1a genes, revealing the presence of two different IG regions denominated IG-1 (0.7 kb) and IG-2 (1.3 kb), flanking a newly identified rap-1b orf. Sequence analysis and comparison among babesial rap-1 IG regions from B. bovis, B. bigemina, B. canis, and B. ovis revealed conservation of at least three putative regulatory boxes consistently positioned 5' of the start of the rap-1 orfs. To determine whether rap-1 IG regions contained a functional promoter, the entire 1-kb IG region from B. bovis was cloned into pCAT, a promoterless plasmid containing the cat gene. The IG region in the 5' --> 3' orientation strongly promoted transcription in vitro by homologous B. bovis RNA polymerases. The presence of conserved regions 5' to each rap-1 gene copy and among other babesial rap-1 IG regions and the in vitro promoter function in the 5' --> 3' orientation support a role for the IG region in rap-1 gene regulation.

Bovine babesiosis and anaplasmosis follow-up on cattle relocated in an endemic area for hemoparasitic diseases

A multiplex PCR/DNA probe assay was used to monitor Babesia bovis, B. bigemina and Anaplasma marginale infection in cattle introduced to a Boophilus microplus-infested area in Veracruz, Mexico. Eight intact, 18-month-old, cross-bred beef cattle (four naive, Group A; four Babesia species--premunized, Group B) were immediately exposed to ticks after arrival and were clinically monitored from day 6 to day 98 post-exposure (PE) to ticks. Blood sample analysis for DNA detection by the MPCR/DNA probe assay showed that Group A animals were infected with B. bovis from day 11 up to day 22 PE, requiring treatment on days 17-20. Group B animals were detected positive to B. bovis on days 17-20, did not require treatment and remained persistently infected from days 70 to 84 PE. Treatment of Group A animals delayed the infection with B. bigemina. These animals became positive to the parasite on days 63-77 PE. In contrast, Group B animals (untreated) showed B. bigemina infection on days 21-26 and 63-84 PE. One animal was positive for A. marginale infection on days 63-66 PE, the rest of the animals became so on days 80-98 PE. All infected animals required treatment with oxytetracycline. Monitoring the triple hemoparasite infection with the MPCR/DNA probe assay provided important epidemiological information. Thus, precautionary measures can be established when cattle are moved to a babesiosis/anaplasmosis risk area.

Conformational dependence of Anaplasma marginale major surface protein 5 surface-exposed B-cell epitopes

The Anaplasma marginale outer membrane is composed of immunogenic major surface proteins (MSPs) linked both covalently and noncovalently in multimeric complexes (M. C. Vidotto, T. C. McGuire, T. F. McElwain, G. H. Palmer, and D. P. Knowles, Infect. Immun. 62:2940-2946). Consequently, effective induction of antibody against surface-exposed MSP epitopes has been postulated to require maintenance of MSP secondary through quatenary structures. Using MSP5 as a model and the approach of epitope mapping with recombinant expressed full-length and truncated proteins, we demonstrated that the immunodominant surface epitope bound by monoclonal antibody (MAb) ANAF16C1 required disparate amino- and carboxy-terminal regions of MSP5, indicating the conformational dependence of this epitope. The required amino-terminal MSP5 region included the cysteines involved in intramolecular disulfide bonding. The dependence of the immunodominant epitope on disulfide bonding was confirmed by loss of MAb ANAF16C1 binding to MSP5 following disulfide bond reduction and covalent modification of the reduced sulfhydryl groups. The recognition of the MSP5 immunodominant epitope by antibody induced by protective immunization with A. marginale outer membranes was also conformationally dependent, as shown by the loss of epitope binding following serum adsorption with native but not reduced and denatured A. marginale. Importantly, the antibody response to all immunodominant MSP5 surface epitopes was restricted to conformationally dependent epitopes, since the binding of polyclonal anti-MSP5 antibody to the A. marginale surface could be blocked by adsorption with native but not denatured and reduced MSP5. These results confirm the importance of the secondary and tertiary structures of MSP epitopes as immune system targets and support the testing of immunogens which maintain the required conformation.

Structure, sequence, and transcriptional analysis of the Babesia bovis rap-1 multigene locus

The complexity of multigene families encoding rhoptry proteins and the generation of new variants in these families are constraints to development of vaccines incorporating rhoptry proteins. For example, the Babesia bigemina rhoptry associated protein (rap)-1 locus is composed of tandemly arranged genes including four polymorphic rap-1a genes and two classes of divergent genes, rap-1b and rap-1c. B. bigemina rap-1 polymorphism reflects recombination and gene conversion and results in multiple RAP-1 proteins with unique B- and T-cell epitopes. Is this complex locus structure and recombination a required feature of the rap-1 gene family among Babesia species? We addressed this question by analysis of the rap-1 locus in B. bovis. Sequence analysis of an 11 kb genomic clone representing the B. burn rap-1 locus revealed only two identical and continuous rap-1a gene copies, rap 1a-1 and rap-1a-2, located in a similar head to tail orientation. Using the conserved ig gene as a marker for the 3' boundary of the rap-1 locus, we conclude that divergent rap-1b and rap-1c genes, present in B. bigemina, are not similarly cis-linked to the B. bovis rap-1 locus. Analysis of the rap-1a genes 1 and 2 from each of multiple B. bovis strains from North and South America demonstrated RAP-1 size conservation with very limited amino acid sequence variation. The results suggest that the simple two gene arrangement in the B. bovis rap-1 gene family was generated by gene duplication and, in contrast to the B. bigemina rap-1 locus, both genes evolved together using homogenization mechanisms with point mutation as the single mechanism for gene variation. Three discontinuous non-rap-1 genes are closely cis-linked to the B. bovis rap-1 locus and the presence of multiple introns in these genes may limit rap-1 gene variation due to unequal crossing over. The different mechanisms likely involved in the evolution of the rap-1 family in B. bigemina versus B. bovis are reflected in the marked structural and antigenic polymorphism in the B. bigemina RAP-1 molecules as compared with the essentially monomorphic RAP-1 in B. bovis.

Helper T-cell epitopes encoded by the Babesia bigemina rap-1 gene family in the constant and variant domains are conserved among parasite strains

Among important candidates for babesial vaccines are apical complex proteins, including rhoptry-associated protein 1 (RAP-1) from Babesia bovis and B. bigemina, which have been shown to induce partial immunity. Four variant B. bigemina rap-1 transcripts identified in a clone of the Mexico strain have highly conserved sequence in the central region but vary in sequence at the amino and carboxy termini (NT and CT) of the predicted proteins, resulting in different combinations of NT and CT domains in the individual gene products. Cattle were immunized with native protein consisting of the RAP-alpha1 variant, which contains NT-1 and CT-1 domains, and T-cell responses were characterized. We previously reported the identification of two T helper (Th) cell epitopes in B. bigemina RAP-1alpha1 protein (I. Hötzel, W. C. Brown, T. F. McElwain, S. D. Rodriguez, and G. H. Palmer, Mol. Biochem. Parasitol. 81:89-99, 1996). One epitope mapped to the constant domain of RAP-1 (amino acids [aa] 144 to 187), and one mapped to the CT-1 variable domain (aa 386 to 480). Th1-like clones responding to these epitopes proliferated differentially to different strains of B. bigemina, raising the possibilities that the T-cell epitopes may vary antigenically and that CT-1 may be differentially expressed with respect to the other RAP-1 CT domains in the different strains. In this report, we definitively map the T-cell epitope identified in the constant domain of RAP-1 to aa 159 to 187 (FVVSLLKKNVVRDPESNDVENFASQYFYM) and show that the predicted amino acid sequence is completely conserved among seven strains. The T-cell epitope in the CT-1 domain was mapped to aa 436 to 465 (VNSEKVDADDAGNAETQQLPDAENEVRADD), which is also completely conserved among eight strains of B. bigemina. We further show that the RAP-1alpha1-immunized cattle were protected against homologous B. bigemina challenge, thus suggesting an association between protective immunity and the helper T-cell response against the two epitopes. The immunogenic and highly conserved nature of these T-cell epitopes and their ability to stimulate functionally relevant Th cells that express gamma interferon support their inclusion in a vaccine.

Dimorphic sequences of rap-1 genes encode B and CD4+ T helper lymphocyte epitopes in the Babesia bigemina rhoptry associated protein-1

The rhoptry-associated protein-1 (RAP-1) of Babesia bigemina induces protective immune responses in cattle and contains neutralization-sensitive B cell epitopes. RAP-1 variants containing blocks of sequence dimorphism in the amino and carboxy terminal ends are encoded by four nonallelic genes in B. bigemina. Epitopes recognized by RAP-1 specific monoclonal antibodies (MAbs) and bovine CD4+ T cell clones were mapped to determine whether these epitopes are localized in the amino and carboxy terminal dimorphic regions. Four B cell epitopes, including a neutralization-sensitive epitope, required both the amino terminal variant type 1 (NT-1) and non-dimorphic sequences for conformation. Intrachain disulfide bonds were required for at least one of these epitopes, since reduction and alkylation of cysteine residues abolished MAb binding. A fifth B cell epitope was mapped to the carboxy terminal variant type 1 (CT-1). As expected, the neutralizing MAb and two other MAbs requiring NT-1 for epitope binding recognized only the two RAP-1 variants with the NT-1 sequence, while the MAb binding an epitope in CT-1 did not bind RAP-1 variants with CT-2. In contrast, the fourth MAb requiring NT-1 for binding recognized all rap-1 gene products, indicating that dimorphic residues are not part of the epitope recognized by this MAb. Bovine CD4+ T cell clones characterized previously as responding in a strain dependent fashion recognized at least one epitope in CT-1, and did not cross-react with CT-2. A second group of bovine CD4+ T cell clones that responded to multiple parasite strains recognized an epitope in a non-dimorphic region of RAP-1. These data indicate that dimorphic regions of RAP-1 encode unique B and T helper lymphocyte epitopes and may be required for enhanced protective immune responses in cattle.

Babesia bovis rhoptry-associated protein 1 is immunodominant for T helper cells of immune cattle and contains T-cell epitopes conserved among geographically distant B. bovis strains

The ability of rhoptry-associated protein 1 (RAP-1) of Babesia bovis and Babesia bigemina to confer partial protective immunity in cattle has stimulated interest in characterizing both B-cell and T-cell epitopes of these proteins. It was previously shown that B. bovis RAP-1 associates with the merozoite surface as well as rhoptries and expresses B-cell epitopes conserved among otherwise antigenically different B. bovis strains. An amino-terminal 307-amino-acid domain of the molecule that is highly conserved in the B. bigemina RAP-1 homolog did not contain cross-reactive B-cell epitopes. The studies reported here demonstrate that B. bovis RAP-1 is strongly immunogenic for T helper (Th) cells from B. bovis-immune cattle and that like B-cell epitopes, Th-cell epitopes are conserved in different B. bovis strains but not in B. bigemina RAP-1. Lymphocytes from cattle immune to challenge with the Mexico strain of B. bovis proliferated against recombinant B. bovis RAP-1 protein derived from the Mexico strain. T-cell lines established by stimulating lymphocytes with recombinant RAP-1 protein responded against B. bovis, but not B. bigemina, merozoites. T-cell lines established by repeated stimulation of lymphocytes with B. bovis membrane antigen proliferated strongly against RAP-1, demonstrating the immunodominant nature of this protein. RAP-1-specific CD4+ T cell clones recognized Mexico, Texas, Australia, and Israel strains of B. bovis but neither B. bigemina merozoites nor recombinant B. bigemina RAP- 1. Analysis of cytokine mRNA in RAP-1-specific Th cell clones revealed strong expression of gamma interferon but little or no expression of interleukin-2 (IL-2), IL-4, or IL-10. Gamma interferon production was confirmed by enzyme-linked imunosorbent assay. These results indicate the potential to use selected B. bovis RAP-1 peptides as immunogens to prime for strong, anamnestic, strain-cross-reactive type 1 immune responses upon exposure to B. bovis.

Comparative sensitivity of two tests for the diagnosis of multiple hemoparasite infection of cattle

The purpose of this study was to evaluate the efficacy of light microscopy (LM) examination of blood smears and a multiplex polymerase chain reaction (MPCR) assay, in terms of their ability to detect cattle experimentally infected with Babesia bovis, Babesia bigemina, and Anaplasma marginale. Blood samples were collected from 32 intact, 1-2 year old, Holstein bulls, previous to and after simultaneous inoculation of culture-derived or field isolates of B. bovis- and B. bigemina-infected erythrocytes. To establish the triple hemoparasite infection, 16 of the bulls were also inoculated with a calf-derived isolate of A. marginale. The results showed that both tests had 100% specificity. In contrast, the sensitivities of the MPCR assay against the LM test were 93.5% and 70.9%; 96.7% and 100%; and 93.8% and 93.8% for B. bovis, B. bigemina, and A. marginale infection, respectively. The advantages and disadvantages of the MPCR assay to differentially diagnose cattle with multiple hemoparasite infection are discussed.

Sequences upstream and downstream from the glutamine-dependent carbamoyl phosphate synthetase-encoding gene from the protozoan Babesia bovis

In the protozoan parasite, Babesia bovis, the glutamine-dependent carbamoyl phosphate synthetase-encoding gene (CPSII) contains contiguous amidotransferase- and synthetase-encoding sequences. Unlike the organisation in most eukaryotes, the gene is not fused with other genes encoding enzymes of pyrimidine biosynthesis de novo. The nucleotide sequences immediately upstream and downstream from the gene contain motifs which may be involved in regulating its expression.

CD4+ T-helper lymphocyte responses against Babesia bigemina rhoptry-associated protein I

A multigene family of 58- to 60-kDa proteins, which are designated rhoptry-associated protein 1 (RAP-1) and which come from the parasites Babesia bigemina and Babesia bovis, is a target for vaccine development. The presence of multiple gene copies and conserved sequences and epitopes of RAP-1 implies that these proteins are functionally important for the survival of these parasites. Furthermore, it was previously shown that B. bigemina RAP-1 induced partial protection against challenge infection. However, the lack of correlation between protective immunity to B. bigemina infection and antibody titers against a merozoite surface-exposed, neutralization-sensitive epitope of B. bigemina RAP-1 indicated the potential importance of RAP-1-specific T helper (Th) cells in the observed protection. To begin to understand the mechanism of RAP-1-induced protective immunity, RAP-1-specific T-cell responses were characterized in cattle. Vigorous and sustained proliferative responses of peripheral blood mononuclear cells from native RAP-1-immunized cattle were observed. The anamnestic response in immunized cattle was specific for B. bigemina RAP-1 and predominantly comprised CD4+ T cells, which upon cloning expressed type 1 cytokine mRNA profiles and high levels of gamma interferon protein. The T cells responded to both native and recombinant forms of RAP-1, indicating the potential to use recombinant protein or epitopes derived therefrom as a vaccine that could evoke specific recall responses after exposure to natural infection. The differential responses of peripheral blood mononuclear cells and seven Th-cell clones derived from RAP-1-immunized cattle to different Central American strains of B. bigemina indicated the presence of at least one conserved and one variable Th-cell epitope. The lack of response to B. bovis RAP-1 indicated that a strictly conserved 14-amino-acid peptide shared by the two babesial species was not immunogenic for Th cells in these experiments. However, the Th-cell epitope conserved among strains of B. bigemina may be a useful component of a RAP-1 subunit vaccine.

Conservation of merozoite membrane and apical complex B cell epitopes among Babesia bigemina and Babesia bovis strains isolated in Brazil

Babesia merozoite polypeptides bear surface exposed and neutralization-sensitive B cell epitopes and have been shown to induce partial protection against experimental challenge. Variation in these epitopes has been examined in a limited number of strains. In this study, utilizing strains of Babesia bovis and Babesia begemina from Matto Grosso do Sul in Brazil, we examined the conservation of epitopes bound by monoclonal antibodies developed against Mexico strains of B. bovis and B. bigemina. Apical complex B-cell epitopes, previously shown to be species-specific but common among otherwise antigenically distinct strains, were also conserved between clones of the Mexico strains and the Matto Grosso do Sul strains of each Babesia species. Mexico strain polypeptides bearing these epitopes were recognized by sera from cattle infected with the Matto Grosso do Sul strains. Two distinct epitopes on the B. bovis neutralization-sensitive merozoite surface antigen-1 (MSA-1) were also conserved between the Mexico Mo7 clone and the Matto Grosso do Sul strain, in contrast to previous studies which demonstrated variability among strains. Sera from cattle with B. bovis infections naturally acquired in Matto Grosso do Sul bound Mexico Mo7 MSA-1, demonstrating that conserved MSA-1 epitopes were recognized by the bovine immune system. Similarly, merozoite surface epitopes on the B. bigemina 45 kDa and 55 kDa glycoproteins were conserved on the Matto Grosso do Sul strain of B. bigemina.

Identification of Babesia bovis merozoite antigens separated by continuous-flow electrophoresis that stimulate proliferation of helper T-cell clones derived from B. bovis-immune cattle

To characterize Babesia bovis merozoite antigens that stimulate anamnestic T helper (Th)-cell responses from B. bovis-immune cattle, B. bovis-specific Th-cell lines and clones, previously assigned to different antigenic groups (W. C. Brown, S. Zhao, A. C. Rice-Ficht, K. S. Logan, and V. M. Woods, Infect. Immun. 60:4364-4372, 1992), were tested in proliferation assays against fractionated merozoite antigens. The antigenic groups were determined by the patterns of response of Th clones to different parasite isolates and soluble or membrane forms of merozoite antigen. Soluble antigen fractionated by anion-exchange chromatography or gel filtration by using fast-performance liquid chromatography resolved two or three antigenic peaks, respectively. To enable fractionation of membrane-associated proteins and to resolve more precisely the proteins present in homogenized merozoites, a novel technique of continuous-flow electrophoresis was employed. Merozoite membranes or whole merozoites were homogenized and solubilized in sodium dodecyl sulfate-sample buffer, electrophoresed under reducing conditions on 15% or 10% acrylamide gels, eluted, and collected as fractions. Individual fractions were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and tested for the ability to stimulate Babesia-specific CD4+ T-cell lines and clones. CD4+ Th-cell lines from two cattle displayed differential patterns of reactivity and detected numerous peaks of antigenic activity, ranging from < 14 to 76 kDa. Th-cell clones previously categorized into different antigenic groups detected antigenic peaks unique for clones representative of a given group. Antigens of 29, 51 to 52, and 85 to 95 kDa (group I), 40 kDa (group III), 20 kDa (group IV), 58 to 60 kDa (group VI), and 38, 45, and 83 kDa (group VII) were identified in the stimulatory fractions. Immunization of rabbits with selected fractions produced a panel of antisera that reacted specifically on Western blots (immunoblots) with merozoite antigens of similar sizes, leading to the tentative identification of candidate antigens of B. bovis merozoites with molecular masses of 20, 40, 44, 51 to 52 or 95, and 58 to 60 kDa that stimulate proliferation of Th clones representative of five different antigenic groups. These antisera may be useful for isolating recombinant proteins that are immunogenic for Th cells of immune cattle and therefore potentially useful for vaccine development.

Targeting ticks for control of selected hemoparasitic diseases of cattle

Development in and transmission of hemoparasites by tick vectors are phenomena closely synchronized with the tick feeding cycle. In all known life cycles, initial infection of tick tissues occurs in midgut epithelial cells and transmission is effected as ticks feed after parasites have developed and multiplied in salivary glands. Many factors reviewed affect development and transmission of hemoparasites by ticks including age of ticks, artificial temperature, climate and/or season, tick stage or sex, hemoparasite variation, concurrent infection of ticks with other pathogens, host cell susceptibility, transovarial transmission, effect of hemoparasites on tick biology, and the effect of infecting parasitemia level in cattle on infection rates in ticks. Four hemoparasites of cattle, Anaplasma marginale, Cowdria ruminantium, Theileria parva, and Babesia spp., are all dependent on ticks for biological transmission. Babesia is transmitted transovarially whereas the other three are transmitted transstadially. Mechanical transfer of infective blood via fomites and mouthparts of biting arthropods is also a major means of transmission for Anaplasma marginale but not of the others. Potential control methods for hemoparasites that target parasites as they are developing in their respective tick hosts include tick control, vaccines (against ticks and parasites), and drugs (against ticks and parasites). Successful application of control strategies will be dependent upon thorough understanding of parasite developmental cycles, biology of the tick vectors and the immune response of cattle to ticks and to hemoparasites. The most effective control measures will be those that are targeted against both ticks and the hemoparasites they vector.

Nucleic acid probes as a diagnostic method for tick-borne hemoparasites of veterinary importance

An increased number of articles on the use of nucleic acid-based hybridization techniques for diagnostic purposes have been recently published. This article reviews nucleic acid-based hybridization as an assay to detect hemoparasite infections of economic relevance in veterinary medicine. By using recombinant DNA techniques, selected clones containing inserts of Anaplasma, Babesia, Cowdria or Theileria genomic DNA sequences have been obtained, and they are now available to be utilized as specific, highly sensitive DNA or RNA probes to detect the presence of the hemoparasite DNA in an infected animal. Either in an isotopic or non-isotopic detection system, probes have allowed scientists to test for--originally in samples collected from experimentally infected animals and later in samples collected in the field--the presence of hemoparasites during the prepatent, patent, convalescent, and chronic periods of the infection in the host. Nucleic acid probes have given researchers the opportunity to carry out genomic analysis of parasite DNA to differentiate hemoparasite species and to identify genetically distinct populations among and within isolates, strains and clonal populations. Prevalence of parasite infection in the tick vector can now be accomplished more specifically with the nucleic acid probes. Lately, with the advent of the polymerase chain reaction technique, small numbers of hemoparasites can be positively identified in the vertebrate host and tick vector. These techniques can be used to assess the veterinary epidemiological situation in a particular geographical region for the planning of control measures.

Immunization of cattle with recombinant Babesia bovis merozoite surface antigen-1

Cattle immunized with a recombinant merozoite surface antigen-1 molecule (MSA-1) produced high-titered antibody that reacted with the surface of the parasite and neutralized merozoite infectivity in vitro. However, recombinant MSA-1 immunization did not confer protection against challenge with virulent Babesia bovis. These results indicate that antibody-mediated neutralization of merozoite infectivity in vitro, at least for MSA-1-specific antibody, does not reflect in vivo protective immunity to babesiosis.

A large multigene family expressed during the erythrocytic schizogony of Plasmodium falciparum

We report the identification of a large multigene family of Plasmodium falciparum using a clone isolated with a polyclonal antiserum raised to a Babesia divergens merozoite protein. The recombinant antigen reacted with human sera collected from individuals exposed to malaria. The deduced protein sequence contains a motif homologous to the consensus sequence of merozoite rhoptry proteins encoded by multigene families in several Babesia species. Antibodies raised to the recombinant protein reacted with a 60-kDa merozoite protein both on B. divergens and on P. falciparum immunoblots. The insert hybridized to a large number of fragments on P. falciparum Southern blots and to most chromosomes of the parasite. Specifically, approx. 3-kb RNAs were detected in 4-16-nucleus schizonts. Ten distinct cDNAs were isolated that differed in the size, position and number of restriction sites in the region homologous to the original genomic clone. With about 140 copies per haploid genome, this is the first large multigene family described in malaria parasites. The existence of a multigene family encoding proteins present in the invasive stage of malaria parasites suggests an important role in invasion and denotes a significant potential for generating diversity.

Monoclonal antibodies to the equine CD2 T lymphocyte marker, to a pan-granulocyte/monocyte marker and to a unique pan-B lymphocyte marker

Murine monoclonal antibodies, HB88A, B29A and DH59B separately identify the CD2 T lymphocyte molecule, a unique pan-B lymphocyte surface marker and a pan-granulocyte/monocyte surface molecule, respectively, in the horse. Specificity was shown by two-color immunofluorescent flow cytometry and immunofluorescent microscopy. MAb HB88A reacted with a 52 kDa pan-T lymphocyte molecule present on 75% +/- 7 of peripheral blood lymphocytes (PBL) (n = 15 horses). It also reacted with lymphocytes restricted to T lymphocyte dependent areas of lymph node and spleen. Specificity of mAb HB88A to CD2 was demonstrated by its reactivity to COS7 cells which expressed a transfected 1.5 kb equine lymphocyte c-DNA clone having 77.5% overall sequence homology with human CD2 c-DNA. MAb B29A reacted with a pan-B lymphocyte specific cell surface complex, 143, 72, 50, 40, 27 and 14.5 kDa, present on 19% +/- 7 of PBL (n = 15 horses). This complex has not been described in the horse or other species. MAb DH59B reacted with a 96 kDa pan-granulocyte/monocyte specific surface protein and identified macrophages and Kupffer cells in equine tissue sections. Together these mAbs can be used to identify and quantitate the major constituents of equine leukocytes.

Interstrain conservation of babesial RAP-1 surface-exposed B-cell epitopes despite rap-1 genomic polymorphism

Members of the babesial rhoptry-associated protein 1 (RAP-1) family express surface-exposed B-cell epitopes and are candidate antigens for vaccine development. The relationship between rap-1 genomic polymorphism and surface-exposed B-cell epitope expression was analyzed by comparison of biological clones of Mexico strain Babesia bigemina and Babesia bovis with strains isolated in Argentina. Despite genomic polymorphism between strains, including sequences located within the open reading frame, defined RAP-1 B-cell surface epitopes and RAP-1 molecular size were conserved in both B. bovis and B. bigemina.

Polyclonal antibody characterization of Babesia caballi antigens

In a previous study diagnostic B. caballi antigens with apparent molecular mass of 50 and 48 kDa were identified. Another antigen of 141 kDa was recognized by most but not all B. caballi sera tested. Here a further characterization of the three antigens is reported. Rabbits were vaccinated with gel-purified antigens and monospecific antibodies were obtained for the 141 and 48 kDa antigens. Antibodies raised against the 50 kDa antigen cross-reacted with the 48 kDa antigen, suggesting that these two antigens bear unique as well as common epitopes. After two-dimensional electrophoresis the 50 and 48 kDa antigens were present as horizontal bands over a pH range from approximately 5.0-7.0 with focused spots at a pH of 5.5 and 5.9, respectively. The 141 kDa antigen was not present after two-dimensional electrophoresis. None of the three antigens could be identified as a glycoprotein. Judging from the immunofluorescence antibody test staining pattern obtained with the rabbit sera the 141 kDa antigen is present on the surface of infected erythrocytes. The 50 and 48 kDa antigens are located in the parasite itself and probably not on the surface of infected erythrocytes. The punctate staining pattern observed with the 48 kDa antiserum suggests that this antigen might be located in or associated with the apical complex of the parasite.

Multiplex polymerase chain reaction based assay for the detection of Babesia bigemina, Babesia bovis and Anaplasma marginale DNA in bovine blood

A highly sensitive polymerase chain reaction (PCR) based method was developed to detect, in the same blood sample, DNA of hemoparasites frequently found together infecting cattle in tropical and subtropical areas. Bovine blood containing equal parasitemias of Babesia bigemina, B. bovis and Anaplasma marginale infected erythrocytes was mixed to standardize the test. Twenty microliters of 10-fold dilutions from the pooled blood sample were resuspended in PCR mixture buffer containing each of the species-specific sets of primers. Group I primers (BiIA/IB, BoF/R and Am9/10) which specifically bind B. bigemina, B. bovis and A. marginale DNA were used to amplify a fragment of DNA from genomic parasite DNA. Group II nested primers (BiIAN/IBN, BoFN/RN and Am11/12) were used to prepare, via incorporation of digoxigenin-11-dUTP by PCR, nonradioactive probes specific for internal sequences present in DNA amplified with Group I primers. Agarose gel electrophoresis and Southern blot hybridization studies showed that by using Group I primers, DNA fragments of 278 bp, 350 bp and 200 bp were specifically amplified in samples containing B. bigemina, B. bovis and A. marginale DNA, respectively. The analytical sensitivity of the multiple PCR test, as evaluated by nucleic acid hybridization with the nonradioactive probe, was 0.00001%, 0.00001% and 0.0001% infected erythrocytes for B. bigemina, B. bovis and A. marginale, respectively. Blood collected from cattle previously inoculated with B. bovis (4 years), A. marginale (2 years) and B. bigemina (1 year) was demonstrated to be latently infected by using the Multiplex PCR test.

Immunogenic B-cell epitopes of Babesia bovis rhoptry-associated protein 1 are distinct from sequences conserved between species

Babesia bovis merozoite apical membrane polypeptide Bv60 was found to be rhoptry associated by immuno-electron microscopy and was redesignated rhoptry-associated protein 1 (RAP-1). The N-terminal 300 amino acids of RAP-1 have a high level of sequence similarity to the same N-terminal region of p58, its homolog from Babesia bigemina. However, the interspecies conserved sequences did not include RAP-1 surface-exposed B-cell epitopes as defined by monoclonal antibodies. Furthermore, neither heterologous B. bigemina immune nor monospecific anti-p58 bovine serum binds to whole RAP-1, indicating that the major B-cell epitopes recognized by these sera are also not encoded by the conserved sequences. Truncated RAP-1, expressed by a subclone encoding the N-terminal 235 amino acids, is weakly bound by antibodies in heterologous sera. A peptide representing the longest conserved amino acid sequence (amino acids 121 to 134) in this region is also weakly bound by antibodies in immune bovine sera, and rabbit antibodies induced by and strongly reactive with the peptide alone fail to bind native or denatured RAP-1. Thus, although the conserved region may contain one or more poorly immunogenic B-cell epitopes, these epitopes are inaccessible to antibody in whole RAP-1. The results indicate that the major immunogenic B-cell epitopes of RAP-1, including surface-accessible epitopes bound by monoclonal antibodies, are distinct from the conserved sequences representing putative functional domains.

Cloning and characterisation of cDNA clones encoding two Babesia bovis proteins with homologous amino- and carboxy-terminal domains

A dextran sulphate protein (DSP) fraction derived from Babesia bovis has previously been shown to induce a protective immune response in cattle. A B. bovis cDNA library was screened with both the complete anti-DSP serum and a subfraction of the anti-DSP serum affinity purified on a native B. bovis protein of approx. 80 kDa. cDNA clones encoding two different B. bovis proteins were identified. The product of one gene, Bv80, has a single divergent copy of a sequence of 149 amino acids (approx. 30% amino acid identity) in both the amino- and carboxy-terminal domains. These domains are separated by an array of short variant repeat sequences rich in proline and glutamic acid. The product of the other gene, BvVAl (homologous to the previously described 225-kDa B. bovis protein)[19], is predicted to have a single divergent copy of a sequence of 170-171 amino acids (approx. 35% amino acid identity) in both the amino- and carboxy-terminal domains. These domains are also separated by an array of repeats. The 73-amino acid repeat unit of this array is composed of a number of variant derivatives of shorter repeat units. Detailed analysis of genomic clones flanking two alleles of the gene encoding BvVAl/225 kDa identified further members of a multi-gene family. This region of the genome of B. bovis has been subject to a large number of amplification processes.

Molecular variation and diversity in candidate vaccine antigens from Babesia

Recombinant vaccines are being developed against a number of species of protozoan parasites in the genus Babesia. Protozoan parasites are notorious for their diversity of strains and their ability to express families of equivalent, but antigenically distinct, surface proteins. In order to reduce the likelihood of evasion of the immune response induced by a recombinant vaccine, ideal components should be essential proteins encoded by single copy genes. The proteins should also have a limited ability to tolerate polymorphism in amino acid sequence, especially in critical epitopes. While little is known about the function of the candidate protective antigens, there is now considerable information concerning the variation of a number of candidate vaccine antigens from several species of Babesia. Four of the well studied antigens are all members of multi-gene families. The members of the VMSA gene family of Babesia bovis are also highly polymorphic in sequence. The members of the Bv60/p58 family of rhoptry protein homologues exhibit more limited polymorphism within a single species of Babesia. However, comparison of the sequences of the equivalent proteins and the organisation of the corresponding genes from B. bovis, Babesia bigemina, Babesia canis and Babesia ovis suggests that members of this family have the potential to acquire and to tolerate substantial polymorphism in amino acid sequence. The choice of protein, and particular region of the protein, suitable for incorporation in a recombinant vaccine may require extensive analysis of the genetic systems encoding the candidate antigens.

Analysis of dinucleotide frequency and codon usage in the phylum Apicomplexa

Dinucleotide frequency (DiF) and codon usage (cu) were analysed in gene sequences from four parasitic protozoa, Babesia bovis, Theileria parva, Toxoplasma gondii and Eimeria tenella, of the phylum Apicomplexa. In keeping with the 'genome hypothesis', cu was found to be non-random and species specific in these organisms, although cu among members of the same subclass was found to be very similar. Several low-usage (lu) codons were identified, and the usage of lu codons appears to be related to the taxonomic position of the organisms under study. A comparison of the observed/expected DiF ratios obtained from gene coding regions revealed a low frequency of the TA and CG dinucleotides in all organisms studied. A comparison of these DiF ratios with those found in rRNA-encoding genes and in introns, showed that in the parasites, B. bovis and Th. parva (representing the piroplasms), the low frequency of dinucleotides appeared to be the result of coding pressure alone. In T. gondii and E. tenella (representing the coccidia), however, coding pressure could not completely explain differences in DiF.

Characterisation of a family of multi-copy genes encoding rhoptry protein homologues in Babesia bovis, Babesia ovis and Babesia canis

A monoclonal antibody that had been raised against a protease-containing fraction of Babesia bovis, and shown to bind to a protein located in the rhoptries, was used to screen a B. bovis cDNA expression library. The sequence of the protein encoded by a positive clone was almost identical to the equivalent region of a previously described B. bovis 60-kDa rhoptry protein (Bv60). A tandem repeat of the gene encoding Bv60 was identified in all Australian isolates of B. bovis examined. Genes encoding homologous of Bv60 were cloned from Babesia ovis and Babesia canis. In B. ovis, 5 closely linked genes were identified. Four of these genes appeared to encode very similar proteins (Bo60.1-4). The protein (Bo60.5) encoded by the fifth B. ovis gene had 72% amino acid identity to Bo60.1-4 in the amino-terminal 306 amino acids, but no significant similarities in the carboxy-terminal region. In B. canis one gene (Bc60.2) was sequenced and a second closely linked gene was identified. A further member of the family, p58, has also been described previously from Babesia bigemina. Tandemly repeated genes subject to extensive gene conversion appear to be a feature of this family of babesial rhoptry protein homologous. No proteins significantly related to any members of the gene family were identified in a search of translated DNA and protein sequence databases. Thus the function of this family of proteins remains a matter for speculation.

Neutralization-sensitive merozoite surface antigens of Babesia bovis encoded by members of a polymorphic gene family

Monospecific antibodies against native and recombinant versions of the major merozoite surface antigen (MSA-1) of Babesia bovis neutralize the infectivity of merozoites from Texas and Mexico strains in vitro. Sequence analysis shows that MSA-1 and a related, co-expressed 44 kDa merozoite surface protein (MSA-2) are encoded by members of a multigene family previously designated BabR. BabR genes, originally described in Australia strains of B. bovis, are notable because their marked polymorphism is apparently mediated by chromosomal rearrangements, but protein products of BabR genes have not previously been identified. The 3' terminal 173 nucleotides of the MSA-1 gene, including 60 nucleotides of untranslated sequence, are highly similar to the 3' terminal sequences of BabR 0.8 (84% identity) and MSA-2 (94% identity). Alignment of the predicted protein sequences demonstrates significant overall homology between MSA-1 and MSA-2, and between both proteins and the amino terminal BabR sequence. MSA-1 nucleic acid probes also hybridize weakly to genomic DNA from the Australia 'L' strain, even though this strain does not express merozoite surface epitopes cross-reactive with MSA-1 or MSA-2. Hybridization of these same probes to genomic DNA from the cloned Mexico strain reveals a pattern of bands compatible with two copies each of MSA-1 and MSA-2. Proteins encoded by this B. bovis gene family have been designated variable merozoite surface antigens (VMSA). The extent and mechanism of VMSA polymorphism among strains will be important when evaluating the role these surface proteins have in the host-parasite interaction, including immunity to blood stages.

Surface epitope localization and gene structure of a Babesia bovis 44-kilodalton variable merozoite surface antigen

Variation of Babesia bovis merozoite surface antigens occurs among geographic strains of the parasite. In this and a concurrent report, we investigate this variation at the gene and protein level. Using a monoclonal antibody (mAb 23/70.174), B. bovis gene sequences were identified that encoded a surface epitope of a 44-kDa merozoite surface antigen (MSA-2). This epitope is variably expressed among geographic isolates of B. bovis. Here, we describe the MSA-2 protein gene sequence, localize this surface epitope to a repeated amino acid sequence, and investigate the genomic organization of the gene in B. bovis strains from Mexico and Australia. The predicted protein sequence had hydrophobic regions at its amino and carboxy termini consistent with a signal peptide and a membrane anchor via glycosylphosphatidyl inositol, respectively. The surface epitope recognized by mAb 23/70.174 was localized within a 24-amino acid sequence which is repeated twice in tandem. Six different EcoRI bands hybridized to the MSA-2 gene sequence with varying intensities in genomic Southern blots of the homologous strain. Two of these appear to be alleles of the MSA-2 gene. Whereas 5' and 3' sequences of the MSA-2 gene sequence were detected in an Australia strain of B. bovis, internal gene sequences encoding the surface epitope were not. The 3' sequences of the MSA-2 gene also had significant sequence similarity with the MSA-1 gene of the Mexico strain B. bovis and a gene from the previously described BabR locus. These data indicate that the MSA-2 protein gene belongs to the BabR locus which encodes variable merozoite surface antigens.

Analysis of the composition of samples of Babesia bovis and the influence of different environmental conditions on genetically distinct subpopulations

A recombinant DNA probe specific for a tandemly repeated sequence located within the BoVA1 gene of Babesia bovis was used to analyse 10 independent samples of B. bovis. Twelve different alleles of the BoVA1 gene and flanking regions were identified in the 18 different subpopulations analysed. Most samples of B. bovis originally derived from single animals contained more than one genetically distinct subpopulation. However, only one population of parasites was identified in samples of the Ka line used in Australia from 1979 until 1990 as the live attenuated vaccine strain. In contrast, the replacement attenuated vaccine line, Ta, contained two genetically distinct subpopulations of parasites. Changes in the ratios of subpopulations of parasites were identified during attenuation and under different culture conditions. Batch-to-batch variation in the composition of doses of the live attenuated vaccine may lead to differences in efficacy and in severity of the infection associated with vaccination.

Cloning and expression in Escherichia coli of cDNAs encoding a 31-kilodalton surface antigen of Sarcocystis muris

Using polyadenylated RNA isolated from Sarcocystis muris cyst merozoites, we have constructed a cDNA library in the expression vector lambda ZAP. Immunoscreening with monoclonal and polyclonal antibodies directed against a 31-kDa surface antigen of S. muris [1] yielded a number of clones with insert sizes ranging between 1.1 kb and 1.3 kb. An additional clone with an insert length of 1.55 kb was isolated by screening with a labeled DNA probe derived from one of the cDNA clones. The cDNA sequence was found to contain an open reading frame specifying a polypeptide of 280 amino acids with a predicted size of 29.7 kDa. The deduced amino acid sequence is rich in serine and threonine (22%) and harbors a hypothetical N-terminal signal peptide sequence as well as a C-terminal glycosyl phosphatidylinositol anchor attachment site. The predicted amino acid sequence has been confirmed by peptide sequencing and an analysis of the overall amino acid composition of the 31-kDa protein. A recombinant protein was obtained which was recognized by the polyclonal antibodies directed against the 31-kDa antigen. Antiserum raised against the purified fusion protein specifically reacted with a 31-kDa protein from S. muris cystozoites. Southern blot analysis indicated that the corresponding gene exists as a single copy within the S. muris genome.

Screening of a Babesia bigemina cDNA library with monoclonal antibodies directed to surface antigens

A Babesia bigemina cDNA library prepared in lambda ZAP bacteriophage vector was immunoscreened to detect clones expressing surface-exposed epitopes of B. bigemina. A nonradioactive indirect plaque-lift immunoassay was used to detect the positive clones. The primary antibody consisted of a pooled sample of six monoclonal antibodies (mAb) specific for B. bigemina that recognizes various parasite surface antigens of different molecular mass. Screening of approximately 300,000 plaque-forming units from the lambda ZAP cDNA expression library resulted in the identification of five positive clones. The five recombinant clones were immunoscreened individually with each of the six mAb. All five independently obtained clones consisted of lambda ZAP recombinants expressing B. bigemina components recognized by mAb C2F3G3 and B1B3C4. Restriction enzyme digests of rescued recombinant phagemids showed that only four clones contained B. bigemina cDNA. One clone (lambda ZAP Bbi1) contained an insert of approximately 0.6 kBp whereas the other three clones (lambda ZAP Bbi2, lambda ZAP Bbi3, and lambda ZAP Bbi5) carried a cDNA insert of approximately 1.7 kBp. Immunoblotting of protein extracts from recombinants lambda ZAP Bbi2, lambda ZAP Bbi3, and lambda ZAP Bbi5 with mAb C2F3G3 and B1B3C4 demonstrated the expression of a recombinant B. bigemina polypeptide of 55 kDa in E. coli.

Detection of Babesia bovis carrier cattle by using polymerase chain reaction amplification of parasite DNA

Carrier cattle infected with Babesia bovis are difficult to detect because of the low numbers of parasites that occur in peripheral blood. However, diagnosis of low-level infections with the parasite is important for evaluating the efficacies of vaccines and in transmission and epidemiological studies. We used the polymerase chain reaction (PCR) to amplify a portion of the apocytochrome b gene from the parasite and tested the ability of this method to detect carrier cattle. The target sequence is associated with a 7.4-kb DNA element in undigested B. bovis genomic DNA (as shown previously), and the amplified product was detected by Southern and dot blot hybridization. The assay was specific for B. bovis, since no amplification was detected with Babesia bigemina, Trypanosoma brucei, Anaplasma marginale, or leukocyte DNA. The target sequence was amplified in DNA from B. bovis Mexico, Texas, and Australia S and L strains, demonstrating the applicability of the method to strains from different geographic regions. The sensitivity of the method ranged from 1 to 10 infected erythrocytes extracted from 0.5 ml of blood. This sensitivity was about 1,000 times greater than that from the use of unamplified parasite DNA. By the PCR method, six B. bovis carrier cattle were detected 86% of the time (range, 66 to 100%) when they were tested 11 times, while with microscopic examination of thick blood smears, the same carrier cattle were detected only 36% of the time (range, 17 to 66%). The method provides a useful diagnostic tool for detecting B. bovis carrier cattle, and the sensitivity is significantly improved over that of current methods. The results also suggest that characteristics of the apocytchrome b gene may make this a valuable target DNA for PCR-based detection of other hemoparasites.

A Babesia bovis 225-kilodalton protein located on the cytoplasmic side of the erythrocyte membrane has sequence similarity with a region of glycogen phosphorylase

A Babesia bovis gene sequence is described which encodes a geographically conserved epitope (recognized by monoclonal antibody (mAb) 23.8.34) of a 225-kDa protein located on the surface of merozoites and associated with the infected erythrocyte membrane. The gene sequence, derived from both genomic and cDNA copies, is 2044 bp long and has one long open reading frame encoding about one third of the 225-kDa protein. The open reading frame is expressed in an approximately 6,400 nucleotide RNA transcript. A 73-amino acid sequence occurs as 4 complete and 1 partial tandem repeats at the carboxy terminus of the partial protein sequence. The epitope recognized by mAb 23.8.34 was localized to the repeat region. Based on epitope localization with mAb 23.8.34, the repeat was exposed on the surface of merozoites and located near the cytoplasmic face of the erythrocyte membrane. The amino terminus of the protein was non-repetitive and had 21% identity (60% similarity) to glycogen phosphorylase over a region of 151 amino acids. In addition, the corresponding 5' DNA sequence hybridized to as many as 8 restriction fragments on Southern blots of genomic DNA. In contrast, the DNA sequence of the repeat hybridized to a single fragment. Both the repeat and multiple non-repeat DNA sequences were detected in a different geographic strain of B. bovis. These results indicate that the 5' end of the 225-kDa protein gene is related to a larger gene family, independent of the 3' end of the gene encoding the repeat.

Induction of proliferative responses of T cells from Babesia bovis-immune cattle with a recombinant 77-kilodalton merozoite protein (Bb-1)

A major portion of a Babesia bovis-specific gene encoding a 77-kDa merozoite protein (Bb-1) produced during natural infection in cattle and in microaerophilous culture was subcloned into the pGEX1N expression vector. Recombinant Bb-1 protein fused to glutathione S-transferase (Bb-1-GST) was used to examine cellular immune responses in B. bovis-immune cattle. Sera from rabbits immunized with Bb-1-GST reacted with fusion protein and with the native antigen present in crude B. bovis but not with B. bigemina merozoites. Bb-1-GST but not GST induced strong proliferation of T lymphocytes from these immune cattle, and Bb-1-reactive T-cell lines which consisted of a mixed population of either CD4+ and CD8+ cells or CD4+, CD8+, and "null" (gamma delta T) cells were established by in vitro stimulation of peripheral blood mononuclear cells with the recombinant fusion protein. Three CD4+ CD8- and three CD4- CD8+ Bb-1-specific T-cell clones were identified after limiting-dilution cloning of the cell lines. The studies described here demonstrate that the 77-kDa protein of B. bovis contains T-cell epitopes capable of eliciting proliferation of two types of T cells in immune cattle, an important consideration for the design of a recombinant subunit vaccine.

Antisense oligonucleotide inhibition of bovine leukemia virus tax expression in a cell-free system

Tax, the trans-activating protein of bovine leukemia virus, stimulates the long terminal repeat to promote viral transcription and also activates cellular genes that may be involved in tumorigenesis. To study Tax regulation, we identified antisense oligodeoxynucleotides that inhibit tax translation in rabbit reticulocyte lysate. Two antisense oligonucleotides directed toward the 5' end of tax RNA inhibited translation by 59% and 45%, when compared to the effect of a random sequence oligonucleotide. This inhibitory effect was independent of RNase H. In contrast, antisense directed at the middle of the tax RNA inhibited by only 12%, but, in the presence of RNase H, inhibited 38%. An antisense oligonucleotide directed at the 3' portion of tax RNA was not inhibitory and, in fact, stimulated translation. Identification of these inhibitory antisense sequences may allow elucidation of the biological role of Tax in BLV-persistent lymphocytosis and tumorigenesis.

Diversity and selection in Babesia bovis and their impact on vaccine use

In the past few years the prospect of a recombinant vaccine effective against the cattle hoemoparosite Babesia bovis has almost become a reality. However, in Australia, vaccination with live parasites has been practised since before the turn of the century and it has recently been proposed that selection of parasites resistant to immunity induced by the B. bovis line Ka (since 1979 the only component of the live attenuated vaccine) may have occurred. Brian Dalrymple examines the evidence for and against this proposal and discusses examples of strain diversity and variation and their effect on the long-term viability of defined attenuated and recombinant vaccines.

Strain variation of Babesia bovis merozoite surface-exposed epitopes

Babesia bovis merozoites are exposed to antibodies during the extraerythrocytic phase, and surface polypeptides bearing exposed epitopes are possible immunogens. Monoclonal antibodies reactive with the merozoite surface bind either immunodominant epitopes expressed diffusely on the merozoite surface or, alternatively, epitopes expressed in a polar pattern. Epitopes expressed diffusely on the immunodominant 42- and 44-kDa merozoite polypeptides were not conserved among strains from geographically diverse regions. In contrast, epitopes expressed in a polar pattern on the merozoite surface were conserved among nine strains and clones. Identification of variables and conserved epitopes provides a basis for defining antigenic variation and cross-protective immunity.

Cell-mediated immune responses to Babesia bovis merozoite antigens in cattle following infection with tick-derived or cultured parasites

Peripheral blood mononuclear cells from cattle experimentally infected with Babesia bovis were examined for parasite-specific cell-mediated immune responses. Unfractionated merozoites and soluble and membrane fractions derived from merozoites were all antigenic for immune cattle, although the membrane fraction was the most stimulatory. Cattle responded to different antigenic fractions in a differential manner, and only that animal immunized with autologous cultured parasites responded to parasitized erythrocyte culture supernatants. Plastic-adherent cells (presumably monocytes/macrophages) were required for a proliferative response to babesial antigens but not to the T-cell mitogen concanavalin A, suggesting that babesial proteins are not simply mitogenic for T cells. Lymphocyte responses directed against a different hemoparasite from Mexico, Babesia bigemina, indicate that this parasite shares cross-reactive T-cell epitopes with B. bovis. These studies define a system whereby T lymphocytes from babesia-immune cattle can be used in proliferation assays to identify babesial merozoite antigens which are immunogenic for T cells. Because identification of helper T-cell epitopes is important for the design of a babesial subunit vaccine which will evoke anamnestic responses, the studies described here provide a basis for such experiments.