Theileria: intracellular protozoan parasites of wild and domestic ruminants transmitted by ixodid ticks

Theileria are economically important, intra-cellular protozoa, transmitted by ixodid ticks, which infect wild and domestic ruminants. In the mammalian host, parasites infect leukocytes and erythrocytes. In the arthropod vector they develop in gut epithelial cells and salivary glands. All four intra-cellular stages of Theileria survive free in the cytoplasm. The schizont stages of certain Theileria species induce a unique, cancer-like, phenotype in infected host leukocytes. Theileria undergoes an obligate sexual cycle, involving fusion of gametes in the tick gut, to produce a transiently diploid zygote. The existence of sexual recombination in T. parva has been confirmed in the laboratory, and is presumed to contribute to the extensive polymorphism observed in field isolates. Key parameters in T. parva population dynamics are the relative importance of asymptomatic carrier cattle and animals undergoing severe disease, in transmission of the parasite to ticks, and the extent of transmission by nymphs as compared to adult ticks. Tick populations differ in vector competence for specific T. parva stocks. Recombinant forms of T. parva and T. annulata sporozoite surface antigens induce protection against parasite challenge in cattle. In future, vaccines might be improved by inclusion of tick peptides in multivalent vaccines.

Vaccines against Theileria parva

Bovine theileriosis caused by Theileria parva continues to be a major economic problem in many parts of Eastern, Southern, and Central Africa. Due to the unsustainable nature of the present control method--using toxic acaricides to kill ticks--alternative control methods are being sought. Live vaccines are being used in many countries in the region. These vaccines are based on the infective sporozoite stage of the parasite. Sporozoites are inoculated in cattle with simultaneous administration of a long-acting formulation of oxytetracycline. These vaccines are poorly adopted in the region, mainly because of problems associated with the use of live parasites. An experimental recombinant vaccine based on a sporozoite surface antigen (p67) has been developed. Immunization with this antigen induces neutralizing antibodies and, under laboratory conditions, this technique protects approximately 70% of the immunized cattle to a defined needle challenge. The efficacy of the vaccine is currently being evaluated under field challenge in Kenya. Since a vaccine based on a single antigen may not be sustainable under field conditions, a search for schizont antigens that induce protective cell-mediated immune responses continues. It is expected that the ultimate vaccine against theileriosis will incorporate a mixture of several antigens derived from both sporozoite and schizont stages, contributing to robust immunity.

Molecular and immunological characterisation of Theileria parva stocks which are components of the 'Muguga cocktail' used for vaccination against East Coast fever in cattle

The 'Muguga cocktail' which is composed of three Theileria parva stocks Muguga, Kiambu 5 and Serengeti-transformed has been used extensively for live vaccination against East Coast fever in cattle in eastern, central and southern Africa. Herein we describe the molecular characterisation of the T. parva vaccine stocks using three techniques, an indirect fluorescent antibody test with a panel of anti-schizont monoclonal antibodies (MAb), Southern blotting with four T. parva repetitive DNA probes and polymerase chain reaction (PCR)-based assays detecting polymorphism within four single copy loci encoding antigen genes. The Muguga and Serengeti-transformed stocks exhibited no obvious differences in their reactivity with the panel of MAbs, whereas Kiambu 5 differed with several MAbs. Kiambu 5 DNA was very distinct from the Muguga and Serengeti-transformed isolates in the hybridisation pattern with all four nucleic acid probes, whereas Muguga and Serengeti-transformed isolates exhibited minor differences and could not be discriminated with one of the probes. PCR amplification in combination with restriction fragment length polymorphism analysis indicated that Kiambu 5 was also markedly divergent from the Muguga and Serengeti-transformed stocks within two of the four antigen coding genes. The T. parva Serengeti-transformed stock did not contain a 130 base pair insert within the p67 sporozoite antigen gene, which has been observed previously in most T. parva parasites isolated from buffalo, and could not be discriminated from T. parva Muguga at any of the four single copy loci. Collectively the data indicate that two of the cocktail components T. parva Serengeti-transformed and Muguga are genetically closely related, while the third component Kiambu 5 is quite distinct. Based on the findings, there may be a need to include only one of the T. parva Muguga and Serengeti-transformed components in the immunising cocktail. The study demonstrates the value of molecular characterisation data for monitoring of live vaccines.

Polymorphic open reading frames encoding secretory proteins are located less than 3 kilobases from Theileria parva telomeres

Polymorphic, multicopy gene families are frequently located in subtelomeric regions of the genomes of parasitic protozoa. Theileria parva telomere-associated (TA) DNA from two chromosomes contained long open reading frames (ORFs) 54% identical at the N-termini, whose 3' ends were 2670 and 2680 bp from the telomeric repeats. Probes derived from these ORFs revealed related sequences close to additional telomeres. The 3' end of an unrelated ORF was approximately 2720 bp from a third telomere. These are among the closest ORFs to telomeres in any organism. Reverse transcription PCR detected transcripts originating within the telomeric multicopy gene family. Additional ORFs, with complex sequence similarities, were located centromeric to the telomere-adjacent ORFs. Transcripts from the schizont stage of T. parva, containing domains with significant amino acid similarity to a 3529 codon ORF located 6900 bp upstream of the telomeric repeats, were mapped to a subtelomeric locus at a fourth telomere. Five telomeric ORFs contained predicted N-terminal signal peptides and one of these signal peptides was functional in a heterologous system. Hybridisation data suggested extensive strain polymorphism between ORFs. Two of the telomere-adjacent ORFs were absent from the genome of a cloned T. parva parasite which can, nonetheless, be passaged through ticks and cattle. T. parva is unusual, among organisms so far studied, in the high density of potential coding sequences located directly adjacent to telomeres and the apparent absence of extensive tracts of repeated sequences within the TA DNA.

Cloning, sequence and mRNA expression of bovine interleukin-16

A lambda gt11 cDNA library was constructed using mRNA isolated from Theileria parva-infected bovine lymphocytes. Sequencing of random clones of this library resulted in the identification of a cDNA encoding bovine interleukin-16 (IL-16). The cDNA has an open reading frame of 1134 bp, and a 3' untranslated region of 275 nucleotides with a polyadenylation signal 16 bases upstream from the poly (A) tail. The protein predicted by the cDNA sequence contains 378 amino acids and the level of amino acid homology with the corresponding part of human precursor IL-16 is 79 %. No information is available about the tissue distribution of IL-16 in cattle, therefore we investigated the expression of IL-16 mRNA in bovine lymphoid tissues by reverse-transcription polymerase chain reaction assays. To investigate the potential of IL-16 as an immunoregulatory molecule we also analysed IL-16 mRNA expression in CD4+ and CD8+T-cell clones derived from T. parva-immunised cattle.

Breast cancer in a 6-year-old child

A 6-year-old girl presented for a second opinion with a 1-year history of an enlarging soft tissue mass just lateral to the right areola. She had been seen by a pediatric surgeon elsewhere who reassured the parents that the lesion was benign. Ultrasound scan showed a 1.5- x 1.5-cm cystic structure adjacent to the right breast bud. Excisional biopsy results showed secretory ductal adenocarcinoma. Modified radical mastectomy with axillary node dissection was performed. All 11 nodes were negative for metastatic disease. She is now disease free 3 years after diagnosis. Estrogen-progesterone receptors were negative, as was screening for BCR 1 and 2. This is the first report of cytogenetics showing an abnormal cell line with a reciprocal translocation between 12p and 15q. Although breast cancer is extremely rare in children, a history of a painless, enlarging, firm breast mass should raise concern about possible neoplastic disease. Cystic appearance on ultrasound scan caused by the pseudocapsule around the tumor may be a marker for secretory carcinoma. Histological evaluation of all suspicious masses should be obtained. Because of the risk of local recurrence and axillary metastases, the authors recommend modified radical mastectomy with axillary node dissection for children with secretory carcinoma of the breast.

Theileria parva genomics reveals an atypical apicomplexan genome

The discipline of genomics is setting new paradigms in research approaches to resolving problems in human and animal health. We propose to determine the genome sequence of Theileria parva, a pathogen of cattle, using the random shotgun approach pioneered at The Institute for Genomic Research (TIGR). A number of features of the T. parva genome make it particularly suitable for this approach. The G+C content of genomic DNA is about 31%, non-coding repetitive DNA constitutes less than 1% of total DNA and a framework for the 10-12 Mbp genome is available in the form of a physical map for all four chromosomes. Minisatellite sequences are the only dispersed repetitive sequences identified so far, but they are limited in distribution to 13 of 33 SfiI fragments. Telomere and sub-telomeric non-coding sequences occupy less than 10 kbp at each chromosomal end and there are only two units encoding cytoplasmic rRNAs. Three sets of distinct multicopy sequences encoding ORFs have been identified but it is not known if these are associated with expression of parasite antigenic diversity. Protein coding genes exhibit a bias in codon usage and introns when present are unusually short. Like other apicomplexan organisms, T. parva contains two extrachromosomal DNAs, a mitochondrial DNA and a plastid DNA molecule. By annotating the genome sequence, in combination with the use of microarray technology and comparative genomics, we expect to gain significant insights into unique aspects of the biology of T. parva. We believe that the data will underpin future research to aid in the identification of targets of protective CD8+ cell mediated immune responses, and parasite molecules involved in inducing reversible host leukocyte transformation and tumour-like behaviour of transformed parasitised cells.

Molecular epidemiology of Theileria parva in the field

Molecular tools based on seminested RFLP-PCR techniques to characterize field parasites in bloodspots dried on filter paper permitted investigation of the extent and the dynamics of diversity of Theileria parva populations in the field. Parallel molecular studies explored the long-term genome stability of various isolates by probing Southern blots of EcoRI digested total genomic DNA with four different reference nucleic acid probes. Three polymorphic single copy loci encoding for antigen genes were developed for seminested PCR detection in order to apply them for a multilocus approach in population genetic studies. Seven alleles were identified for the polymorphic immunodominant molecule (PIM) locus by using restriction enzymes, and 4 alleles each for the p150 and p104 loci. A simple DNA extraction method gave good results in amplifying these loci from carrier animals using samples of blood dried on filter papers. Results from probing Southern blots of cultures taken at sequential timepoints indicate relative genome stability in T. parva in comparison to other parasitic protozoa such as Plasmodium. Comparatively homogeneous profiles in sympatric isolates from Zambia were identified using all four probes and PCR amplified products which contrasted with the variety found amongst Kenyan stocks. Preliminary characterization of T. parva field samples from the Southern Province of Zambia strongly suggest clonal expansion of one of the components of a non-Zambian trivalent vaccine used on a limited scale in the Province from 1985 until 1992.

Evaluation of recombinant sporozoite antigen SPAG-1 as a vaccine candidate against Theileria annulata by the use of different delivery systems

The major sporozoite surface antigen of Theileria annulata (SPAG-1) is a candidate for inclusion in a subunit vaccine. In this paper we summarize the results of 4 vaccination experiments using recombinant SPAG-1 expressed in different systems and presented in different adjuvants. The antigen has been presented as either a C terminal 108 amino acid peptide (called SR1) expressed as both beta-galactosidase and hepatitis B core antigen fusions or as a full-length form expressed as a GST fusion with an N terminal His6 tag. We used different adjuvants, namely Freund's, saponin, ISCOMs and a proprietary adjuvant supplied by SmithKline Beecham, which we call SKBA. The data point to the conclusion that SPAG-1 can elicit partial protection and is therefore suitable for inclusion in an eventual multicomponent subunit vaccine.

Linear peptide specificity of bovine antibody responses to p67 of Theileria parva and sequence diversity of sporozoite-neutralizing epitopes: implications for a vaccine

A stage-specific surface antigen of Theileria parva, p67, is the basis for the development of an anti-sporozoite vaccine for the control of East Coast fever (ECF) in cattle. By Pepscan analysis with a series of overlapping synthetic p67 peptides, the antigen was shown to contain five distinct linear peptide sequences recognized by sporozoite-neutralizing murine monoclonal antibodies. Three epitopes were located between amino acid positions 105 to 229 and two were located between positions 617 to 639 on p67. Bovine antibodies to a synthetic peptide containing one of these epitopes neutralized sporozoites, validating this approach for defining immune responses that are likely to contribute to immunity. Comparison of the peptide specificity of antibodies from cattle inoculated with recombinant p67 that were immune or susceptible to ECF did not reveal statistically significant differences between the two groups. In general, antipeptide antibody levels in the susceptible animals were lower than in the immune group and neither group developed high responses to all sporozoite-neutralizing epitopes. The bovine antibody response to recombinant p67 was restricted to the N- and C-terminal regions of p67, and there was no activity against the central portion between positions 313 and 583. So far, p67 sequence polymorphisms have been identified only in buffalo-derived T. parva parasites, but the consequence of these for vaccine development remains to be defined. The data indicate that optimizations of the current vaccination protocol against ECF should include boosting of relevant antibody responses to neutralizing epitopes on p67.

Immunohistochemical detection of parasite antigens in Theileria parva-infected bovine lymphocytes

Theileria parva is the causal agent of East Coast fever (ECF), a fatal disease of cattle characterized by pyrexia, transient lymphadenopathy and panleukopenia. We have evaluated monoclonal antibodies (mAb) against three distinct antigens (p67, PIM and p32) of the parasite as immunohistological reagents for monitoring the kinetics of infection in cattle. Bovine lymphocytes were stained with the mAb at various intervals after infection in vitro and in vivo. The p67 sporozoite surface antigen was detected in only a small percentage of both, in vitro and in vivo infected cells. In contrast, expression of the polymorphic immunodominant molecule (PIM) of the parasite proved a useful indicator of infection and staining was correlated with the results of Giemsa analysis. PIM was detected from day 3 in in vitro-infected cells, but was not detected until day 5 in vivo after challenge with a 70% lethal dose of stabilized sporozoite. The p32 antigen was expressed only late in infection in vivo and its expression was associated with the development of merozoites. Less than 20% of in vitro-infected cells expressed p32. The immunohistochemical staining with anti-PIM mAb was found to be a useful tool for analysis of T. parva infection kinetics in cattle.

Organisation and informational content of the Theileria parva genome

When compared with other Apicomplexan organisms, Theileria parva has an exceptionally small, 10-12 Mbp, genome. There are only 4 chromosomes, each in the Mbp range, and a complete physical map, based on SfiI linking data, is available for each one. A number of genes and cDNAs have been mapped to specific SfiI fragments. Telomeres consist of the simple repeat sequence typical of chromosomal ends but sub-telomeric homologies do not extend beyond 5 kbp. The only dispersed repetitive sequences identified to date are minisatellites, but these are found on a subset of SfiI fragments. There are clusters of distinct multicopy sequences which contain ORFs. However, the majority of parasite protein coding genes are present in a single copy. They have a compact structure, exhibit a bias in codon usage and non-translated regions are small. Introns, if present, are unusually short. Overall, the genome contains remarkably little repetitive, non-coding DNA. The parasite mitochondrial DNA is linear in structure, has a limited protein coding capacity and fragmented rRNA genes and its telomeres contain inverted repeat sequences.

Linkage of two distinct AT-rich minisatellites at multiple loci in the genome of Theileria parva

Minisatellite tandem repeat elements are well known components of vertebrate genomes, but have not yet been extensively characterized in lower eukaryotes. We describe two unusual, AT-rich minisatellites of the protozoan parasite Theileria parva whose sequences are unrelated to the G/C-rich i minisatellite superfamily' of vertebrate and plant genomes. The T. parva tandem repeats, one with a conserved sequence T2-5ACACA (6-17 copies), and the other with a 6-bp core sequence of either ACTATA or TATACT associated with additional variable sequences in repeats of 10-17bp (3-7 copies), were closely linked at more than 20 sites in the T. parva genome, separated by 390, 510 and 660bp at three loci analysed in detail. Such linkage is without precedent in minisatellites so far analysed in other organisms. The minisatellite loci were widely dispersed on 13 out of 33 genomic SfiI fragments, on all four T. parva chromosomes and did not exhibit a telomeric bias in their distribution. Analysis of flanking sequences revealed no obvious conserved sequences between the five loci, or other multicopy repeat sequences outside the minisatellite regions. The T2-5 ACACA minisatellite was highly effective as a multilocus fingerprinting probe for discrimination of T. parva isolates. Analysis of two individual minisatellite loci revealed variation between the genomic DNAs of two T. parva isolates in the copy number of the constituent repeats within the array, similar to that typical of vertebrate minisatellites. 1998 Elsevier Science B.V.

Different vaccine strategies used to protect against Theileria annulata

SPAG-1, a sporozoite surface antigen of T. annulata, has previously been shown to elicit partial protection when used, as an hepatitis B core antigen fusion, to immunize cattle. The objective of this study was to try and improve the protective capacity of this antigen by enlisting different vaccine strategies. Cattle were immunized with SPAG-1, as a fusion protein with a His6 tag, either incorporated into ISCOMs, with or without the merozoite antigens TAMS 1-1 and 1-2, or with RWL as adjuvant three times at monthly intervals. Another group of cattle were immunized with p67, the T. parva sporozoite antigen, in RWL to assess whether any cross-protection could be induced. The animals were then challenged with an estimated LD50 of T. annulata sporozoites, and their ability to resist the infection was investigated. Serum responses and T-cell proliferative responses were analyzed throughout the trial. Post-challenge analyses included lymph node biopsies and blood smears to check for the presence of parasites, routine hematological parameters, and observation for clinical manifestations of the disease. The results of this trial will be discussed.

Inflicted esophageal perforation

Esophageal perforation in children is uncommon. A 2 1/2-year-old girl presented with multiple soft tissue injuries of various chronological ages. Initial lateral cervical spine films showed the presence of a prevertebral air collection with soft tissue swelling. Enhanced computerized tomography confirmed the presence of proximal esophageal rupture and a retropharyngeal abscess. External drainage of the abscess and intravenous antibiotics led to resolution of the perforation in 13 days. Discrepancies in the history and the constellation of injuries pointed to an inflicted etiology (through child abuse). Since 1984, 21 case studies have described inflicted esophageal perforation. Common mechanisms of injury include foreign body ingestion and blunt or penetrating external trauma. Early diagnosis of these injuries reduces both acute and long-term morbidity and mortality. Pediatric surgeons must be aware of inflicted injury as an etiology of esophageal and hypopharyngeal perforation.

An enzyme-linked immunosorbent assay for detection of Theileria parva antibodies in cattle using a recombinant polymorphic immunodominant molecule

Field and experimental bovine infection sera were used in immunoblots of sporozoite and schizont lysates of Theileria parva to identify candidate diagnostic antigens. Four parasite antigens of Mr 67,000 (p67), 85,000 (the polymorphic immunodominant molecule, PIM), 104,000 (p104), and 150,000 (p150) were selected for a more detailed analysis. The p67 and p104 antigens were present only in the sporozoite lysates, whereas PIM and p150 were found in both sporozoite and schizont lysates. The four antigens were expressed as recombinant fusion proteins and were compared with each other in an enzyme-linked immunosorbent assay (ELISA) and in the whole-schizont-based indirect fluorescent antibody test (IFAT) in terms of their ability to detect antibodies in sera of experimentally infected cattle. The PIM-based ELISA provided a higher degree of sensitivity and specificity than did the ELISA using the other three recombinant antigens or the IFAT. Further evaluation of the PIM-ELISA using experimental sera derived from cattle infected with different hemoparasites and field sera from endemic and nonendemic T. parva areas showed that the assay had a sensitivity of > 99% and a specificity of between 94% and 98%.

Concerted evolution at a multicopy locus in the protozoan parasite Theileria parva: extreme divergence of potential protein-coding sequences

Concerted evolution of multicopy gene families in vertebrates is recognized as an important force in the generation of biological novelty but has not been documented for the multicopy genes of protozoa. A multicopy locus, Tpr, which consists of tandemly arrayed open reading frames (ORFs) containing several repeated elements has been described for Theileria parva. Herein we show that probes derived from the 5'/N-terminal ends of ORFs in the genomic DNAs of T. parva Uganda (1,108 codons) and Boleni (699 codons) hybridized with multicopy sequences in homologous DNA but did not detect similar sequences in the DNA of 14 heterologous T. parva stocks and clones. The probe sequences were, however, protein coding according to predictive algorithms and codon usage. The 3'/C-terminal ends of the Uganda and Boleni ORFs exhibited 75% similarity and identity, respectively, to the previously identified Tpr1 and Tpr2 repetitive elements of T. parva Muguga. Tpr1-homologous sequences were detected in two additional species of Theileria. Eight different Tpr1-homologous transcripts were present in piroplasm mRNA from a single T. parva Muguga-infected animal. The Tpr1 and Tpr2 amino acid sequences contained six predicted membrane-associated segments. The ratio of synonymous to nonsynonymous substitutions indicates that Tpr1 evolves like protein-encoding DNA. The previously determined nucleotide sequence of the gene encoding the p67 antigen is completely identical in T. parva Muguga, Boleni, and Uganda, including the third base in codons. The data suggest that concerted evolution can lead to the radical divergence of coding sequences and that this can be a mechanism for the generation of novel genes.

Conservation of the sporozoite p67 vaccine antigen in cattle-derived Theileria parva stocks with different cross-immunity profiles

Immunity to Theileria parva infection in cattle is often parasite stock specific. The antigenic diversity which is expressed at the schizont stage of the parasite together with a wild reservoir of the organism in buffalo has complicated the development of effective disease control by immunization. We have previously shown that about 70% of cattle inoculated with recombinant forms of p67, a sporozoite stage-specific surface antigen from the cattle-derived Muguga stock of the parasite, are immune to a homologous challenge. Thus, immune responses to p67 can play a role in immunity. The genes encoding this protein in five other parasite stocks have been sequenced. Here, we report that the p67 molecule encoded by four cattle-derived parasite stocks (Boleni, Uganda, Mariakani, and Marikebuni) that fall into different cross-immunity groups is identical in sequence to Muguga p67. The protein encoded by a buffalo-derived parasite exhibits 95% sequence identity with Muguga p67, the major difference being the presence of a 43-residue peptide insert. As predicted by these data, cattle inoculated with recombinant p67 can resist a heterologous cattle-derived parasite challenge. Seven of 12 cattle receiving a homologous Muguga challenge and 6 of 11 cattle receiving a heterologous Marikebuni challenge were immune to East Coast fever. These results extend earlier data suggesting that p67 is a conserved molecule and confirm its potential as a broad-spectrum vaccine antigen for the control of T. parva infection.

Characterization of an insect cell-derived Theileria parva sporozoite vaccine antigen and immunogenicity in cattle

Previous data showed that six out of a group of nine cattle inoculated with NS1-p67, a recombinant form of a 67-kDa Theileria parva sporozoite surface protein, were immune to East Coast fever. This bacterially expressed antigen encoded all 709 amino acid residues of p67 fused to the C-terminal end of 87 residues derived from NS1, a structural protein of influenza virus, and a linker DNA sequence. NS1-p67 lacked reactivity with TpM 12, a monoclonal antibody to native p67, and had an estimated molecular mass of 110 kDa, as opposed to the calculated mass of 85,000 Da. We have used the baculovirus expression system in an attempt to express this parasite protein in a native form and thereby increase the protective capacity of the antigen. However, Spodoptera frugiperda SF21AE cells infected with recombinant virus expressed p67 as a 100-kDa molecule. The host cells exhibited a limited capacity to glycosylate this molecule to a 110-kDa form, and p67 was not exported to the surface membrane. TpM 12 did not bind to these recombinant forms but, at time points late during viral infection, reacted with a molecule of about 70 kDa. Since the bulk of insect cell-derived p67 was not expressed in an appropriate form, we tested the immunogenicity of these partially processed recombinant p67 forms in cattle. Two groups of three cattle were inoculated with antigen formulated either with saponin or Freund's adjuvant. As seen previously with NS1-p67, all animals developed high levels of anti-p67 antibodies that neutralized sporozoite infectivity in vitro, but antigen-specific T-cell proliferative responses were not detected in peripheral blood. Given the caveat of the small number of cattle analyzed, insect cell-derived p67 does not appear to be superior to NS1-p67 as an immunogen, and the latter remains the molecule of choice for the development of vaccines against East Coast fever.

Theileria: improved species discrimination using oligonucleotides derived from large subunit ribosomal RNA sequences

Partial nucleotide sequences of large subunit ribosomal RNA (LSU rRNA) coding genes of Theileria parva and T. taurotragi were determined. Alignment of the T. parva and T. taurotragi sequences revealed species-specific regions within the LSU rRNA genes. A major species-variable region, located between the first and second conserved secondary structure domains of LSU rRNA, was identified. The sequence of the major species-variable region was determined for T. annulata, T. buffeli, and an unclassified Theileria species isolated from buffalo. Species-specific oligonucleotides complementary to LSU rRNA sequences were designed for five species of Theileria. The oligonucleotide probes discriminated between Theileria species when hybridized to amplified parasite LSU rRNA genes or directly to parasite rRNA. Three species-specific oligonucleotides derived from nonoverlapping sequences were developed for each of T. parva and T. taurotragi. A simplified procedure was developed in which T. parva- and T. taurotragi-specific oligonucleotides were used to discriminate the two species under nonstringent hybridization and washing conditions. Use of the nonstringent conditions also increased the sensitivity of target detection. Comparison of Theileria species-specific oligonucleotides derived from large subunit and small subunit rRNA genes demonstrated that, for closely related species, probes derived from LSU rRNA sequences had improved specificity.

DNA measurements and ploidy determination of developmental stages in the life cycles of Theileria annulata and T. parva

The relative DNA levels of different developmental stages of Theileria annulata and T. parva in the cow and the tick were measured by the cytophotometric DNA technique using the fluorochrome Hoechst 33258 as a staining dye. The results revealed that sporozoites, merozoites, gamonts, and gametes were haploid, whereas multinucleated intralymphocytic schizonts were polyploid. No difference was observed between T. parva and T. annulata in these stages. For both Theileria species, the DNA measurements revealed that fusion of gametes occurred in the gut of the final host, thus providing evidence of sexual reproduction. However, differences were observed between the two parasites in the tick. Whereas T. parva zygotes underwent a two-step meiotic division, a comparable reduction division could not be unequivocally detected in T. annulata. Differences could also be detected in the further development of kinetes, indicating that Theileria species are not characterized by only one life cycle, which is specific for this genus.

Theileria parva: detection of genomic polymorphisms by polymerase chain reaction amplification of DNA using arbitrary primers

Genomic DNA fingerprints were generated from Theileria parva piroplasm DNA by polymerase chain reaction amplification using arbitrary decamers as primers. Four of 12 primers tested generated amplified fragments which were polymorphic between different T. parva stocks or clones. Hybridization of radiolabeled total amplification products to Southern blots of T. parva piroplasm and uninfected bovine DNA confirmed that none of the amplified fragments were derived from any contaminating bovine DNA which may have been present in small quantities. Polymorphic DNA fragments were reproducibly amplified from independent DNA preparations made from cloned parasites. Individual amplified DNA fragments were gel purified and shown to hybridize to size-polymorphic EcoRI fragments in T. parva genomic DNA. Hybridization of individual amplified fragments to total fingerprints, generated using the same arbitrary primer, demonstrated that a single primer detected at least three independent genomic polymorphisms in T. parva DNA.

A recombinant sporozoite surface antigen of Theileria parva induces protection in cattle

At present immunization against Theileria parva is by infection with live sporozoites and simultaneous treatment with a long-acting oxytetracycline. This method has major limitations in that live organisms are used and the immunity engendered is parasite stock specific. In an attempt to develop an alternative immunization procedure, the gene encoding p67, a major surface antigen of sporozoites, has been expressed by using the plasmid expression vector pMG1. The gene, which has been characterized previously, encodes 709 amino acid residues, contains a single intron of 29 base pairs, and is only transcribed during sporogony. The recombinant p67 sequences were fused to the first 85 amino acid residues derived from a nonstructural gene (NS1) of influenza virus A. Immunization with a partially purified recombinant antigen emulsified in 3% saponin induced sporozoite neutralizing antibodies in cattle and provided protection in six of nine animals on homologous challenge with T. parva sporozoites. This recombinant antigen is therefore a candidate for development of a vaccine against T. parva.

New methods for the diagnosis of Babesia bigemina infection

Accurate diagnosis of Babesia bigemina infection, an economically important tick-transmitted protozoan parasite of cattle, is essential in the management of disease control and in epidemiological studies. The currently used methods of diagnosis are blood smear examination and serological tests which include agglutination and immunofluorescence tests. These tests have been used in the fild but because they lack sensitivity and specificity, newer and improved methods of diagnosis are being developed. The quantitative buffy coat (QBC) method, using microhaematocrit tubes and acridine orange staining allows rapid and quicker diagnosis of B. bigemina and other blood parasites compared to light microscopic examination of stained smears. Parasite specific monoclonal antibodies have been used in antigen/antibody capture enzymelinked immunosorbent assays with greater sensitivity and specificity than previously described serological tests. Similarly, DNA probes, derived from a repetitive sequence of the B. bigemina genome, offer a method of detecting very small numbers of parasites which are undetectable by conventional microscopy. An extrachromosomal DNA element, present in all the tick-borne protozoan parasites so far tested, provides an accurate means of differentiating mixed parasite populations in infected animals. These improved methods will greatly facilitate epidemiological studies.