Natural history of Ehrlichia ruminantium

Ehrlichia ruminantium is an obligately intracellular proteobacterium which causes a disease known as heartwater or cowdriosis in some wild, and all domestic, ruminants. The organism is transmitted by ticks of the genus Amblyomma, and it is of serious economic importance wherever the natural vectors occur, an area which includes all of sub-Saharan Africa, and several islands in the Caribbean. The disease was first recognized in South Africa in the 19th century, where its tick-borne nature was determined in 1900, but the organism itself was not demonstrated until 1925, when it was recognized to be a rickettsia, initially named Rickettsia ruminantium. It was thus the first species of what are now known as Ehrlichia to be discovered, and most of the early work to elucidate the nature of the organisms, and its reservoirs and vectors, was performed in South Africa. The next milestone was the development, in 1945, of an infection and treatment regimen to immunize livestock, and this is still the only commercially available "vaccine" against the disease. Then in 1985, after fruitless attempts over many years, the organism was propagated reliably in tissue culture, opening the way for the first application of the newly developed techniques of molecular genetics. From 1990 onwards the pace of heartwater research accelerated rapidly, with notable advances in phylogeny, diagnosis, epidemiology, immunology, and vaccine development. The complete genome sequence was published in 2005, and during the last two years a new understanding has arisen of the remarkable genetic variability of the organism and new experimental vaccines have been developed. Despite all this the goal of producing an effective vaccine against the disease in the field still remains frustratingly just beyond reach. This article summarises our current understanding of the nature of E. ruminantium, at a time when the prospects for the development of an effective vaccine against the organism seem better than at any time since its discovery 83 years ago.

Characterization of Taenia madoquae and Taenia regis from carnivores in Kenya using genetic markers in nuclear and mitochondrial DNA, and their relationships with other selected taeniids

In the present study, we have extended earlier taxonomic, biochemical and experimental investigations to characterize two species of Taenia from carnivores in Kenya by use of the sequences of a variable domain (D1) of nuclear ribosomal DNA and the cytochrome c oxidase subunit 1 and NADH dehydrogenase 1 genes of mitochondrial DNA. Emphasis was placed on the characterization of Taenia madoquae from the silver-backed jackal (Canis mesomelas) and Taenia regis from the lion (Panthera leo), given the previous absence of any DNA sequence data for them, and on assessing their genetic relationships with socioeconomically important taeniids. The study showed that T. regis was genetically most closely related to T. hydatigena, and T. madoquae to T. serialis, T. multiceps or T. saginata. The present findings provide a stimulus for future work on the systematic relationships and epidemiology of lesser-known taeniid cestodes in Africa and other continents, employing mitochondrial sequence data sets.

Extensive genetic recombination occurs in the field between different genotypes of Ehrlichia ruminantium

The intracellular bacterium Ehrlichia ruminantium is the causative agent of heartwater throughout sub-Saharan Africa, Madagascar, and some islands of the Caribbean. The disease is tick-borne and causes substantial livestock losses, threatening food security and productivity in both the commercial and small-scale farming sectors in endemic areas. Immunization by infection and treatment is currently practised in South Africa, and it is known that a variety of immunotypes of the organism occur in the field, and that cross-protection between them varies widely from total to minimal. Future vaccines may therefore need to incorporate components from different genotypes so it is essential to have information on the extent of genetic variation among isolates. To obtain this information we amplified and sequenced a panel of eight core function genes from 12 different cultured stocks originally isolated in different areas of Africa and the Caribbean. Phylogenetic trees inferred from the sequences yielded different branching orders for different genes, and the reason for this inconsistency appears to be that extensive recombination takes place between different genotypes in the field. It is possible that recombination occurs during the period when the organisms are extracellular within the tick, immediately after feeding and before intracellular infection is established, although detection of more than one genotype in DNA from single ticks is encountered infrequently. The results of the analysis show that the phylogenetic variation is greatest among the isolates of southern African origin, suggesting that this is the region where the parasite first evolved. It also appears likely that the Gardel genotype, isolated in the Caribbean, originally came from west central Africa, not from west Africa as had long been assumed.

Molecular sequence evidence for the reclassification of some Babesia species

Taxonomic characterization of organisms in the genera Theileria and Babesia was originally based on observations of morphology and certain general phenotypic characteristics, which enabled many parasites to be unequivocally assigned to a particular genus. However, application of molecular genetic techniques, such as the polymerase chain reaction (PCR) for gene amplification, and DNA sequencing, have revealed gross inconsistencies in the assignation of some parasite genetic variants, particularly those of the B. gibsoni and B. microti complexes, to the genus Babesia. These variants cannot be assigned, on the basis of sequence information and phylogenetic analysis, to either of the genera Theileria and Babesia. The gene for which most sequence information is available for phylogenetic analysis is the small subunit ribosomal RNA (srRNA) gene. This gene allows clear distinction of the genera Theileria and Babesia (sensu stricto) and reveals that many "Babesia" variants are phylogenetically distinct from both genera. This distinction is confirmed, for some of the variants, by beta-tubulin sequence data, suggesting that the organisms should be renamed and reclassified.

Protection against heartwater by DNA immunisation with four Ehrlichia ruminantium open reading frames

We have reported previously that a recombinant DNA vaccine consisting of four Ehrlichia ruminantium (Welgevonden) open reading frames (ORFs) known as the 1H12 cocktail provided protection against a virulent E. ruminantium (Welgevonden) needle challenge in sheep. In this study, we have investigated the vaccine effectiveness of two other cocktails of E. ruminantium (Welgevonden) ORFs, as well as single ORFs from the 1H12 cocktail, to protect sheep against a virulent needle challenge with the homologous strain. Each individual 1H12 ORF provided protection, but all the animals vaccinated with the other cocktails succumbed to the challenge.

Ehrlichia ruminantium variants which do not cause heartwater found in South Africa

In 1994 a batch of apparently healthy goats was selected for intended export to the USA from a heartwater-free and vector tick-free region of South Africa. The animals were tested serologically for heartwater, using either or both an IFA and an ELISA test, and 52% were found to be serologically positive. A PCR assay based on Ehrlichia ruminantium 16S gene sequences gave positive results for 54% of the animals, suggesting that apparently non-pathogenic E. ruminantium variants existed in this heartwater-free area. To identify and characterise the agents responsible for the positive serological and PCR results, ticks and animal blood samples were collected from two of the three farms involved in the original survey during two successive seasons of expected peak tick activity. Ticks were kept alive for a minimum of 3 weeks to allow digestion of any blood meal before being processed. Over the two seasons, 28% of the livestock and 15% of the ticks sampled were found to be carrying E. ruminantium. E. ruminantium 16S and pCS20 sequences were detected in all of the four tick species collected from the livestock (Rhipicephalus evertsi evertsi, Rhipicephalus evertsi mimeticus, Hyalomma truncatum, Hyalomma marginatum rufipes), suggesting that some of the species may act as vectors. Animals generally carried multiple E. ruminantium 16S genotypes, whereas ticks rarely carried more than one. Infection levels in both animals and ticks were too low to generate a marked response when a blood stabilate was sub-passaged in a clean sheep, preventing the subsequent establishment of any of the organisms in culture.

An attenuated Ehrlichia ruminantium (Welgevonden stock) vaccine protects small ruminants against virulent heartwater challenge

Heartwater is a tick-borne disease of ruminants caused by the intracellular rickettsia Ehrlichia ruminantium. The only commercially available immunization procedure involves infecting animals with cryopreserved sheep blood containing virulent E. ruminantium organisms, followed by treatment with tetracyclines when fever develops. The virulent Welgevonden stock of E. ruminantium was attenuated by continuous propagation of the organisms in a canine macrophage-monocyte cell line (DH82), followed by re-adaptation to grow in a bovine endothelial cell line (BA 886). The material used for the present experiments consisted of the attenuated stock between passages 43 and 64 after re-adaptation. When inoculated into sheep or goats the attenuated organisms did not produce disease, and the only symptom observed was a rise in body temperature in most, but not all, animals. All sheep injected with 2 ml of culture suspension were subsequently found to be fully protected against a lethal needle challenge with the virulent homologous stock or with one of four different heterologous stocks (Ball 3, Gardel, Mara 87/7, Blaauwkrans). Titrations of elementary body suspensions showed that 2ml of a 1:10,000 dilution of culture suspension injected into sheep or goats was still sufficient to trigger an immune response which resisted a lethal needle challenge with the virulent Welgevonden stock. Adult Amblyomma hebraeum ticks, fed as nymphs on sheep immunized with DH82-derived organisms of passage 111, were able to transmit the attenuated stock to a naive sheep, which was found to be protected against a subsequent lethal homologous needle challenge.

The genome of the heartwater agent Ehrlichia ruminantium contains multiple tandem repeats of actively variable copy number

Heartwater, a tick-borne disease of domestic and wild ruminants, is caused by the intracellular rickettsia Ehrlichia ruminantium (previously known as Cowdria ruminantium). It is a major constraint to livestock production throughout subSaharan Africa, and it threatens to invade the Americas, yet there is no immediate prospect of an effective vaccine. A shotgun genome sequencing project was undertaken in the expectation that access to the complete protein coding repertoire of the organism will facilitate the search for vaccine candidate genes. We report here the complete 1,516,355-bp sequence of the type strain, the stock derived from the South African Welgevonden isolate. Only 62% of the genome is predicted to be coding sequence, encoding 888 proteins and 41 stable RNA species. The most striking feature is the large number of tandemly repeated and duplicated sequences, some of continuously variable copy number, which contributes to the low proportion of coding sequence. These repeats have mediated numerous translocation and inversion events that have resulted in the duplication and truncation of some genes and have also given rise to new genes. There are 32 predicted pseudogenes, most of which are truncated fragments of genes associated with repeats. Rather then being the result of the reductive evolution seen in other intracellular bacteria, these pseudogenes appear to be the product of ongoing sequence duplication events.

Characterization of the pCS20 region of different Ehrlichia ruminantium isolates

Heartwater is a serious tick-borne disease of ruminants caused by the rickettsial organism Ehrlichia (Cowdria) ruminantium. A diagnostic test, targeting the pCS20 genomic region and using PCR amplification and probe hybridization, detects E. ruminantium infection in ticks and animals. However, only the pCS20 sequence of the Crystal Springs E. ruminantium isolate is available and the existence of sequence variation amongst different E. ruminantium isolates has not been determined. Primers were designed from the published pCS20 sequence to obtain sequences of the pCS20 region of various E. ruminantium isolates. These primers were unable to amplify the pCS20 region from genomic Welgevonden DNA and genome walking was used to characterize the pCS20 region. This technique showed that the published pCS20 sequence is from a chimeric clone. Sequences of the pCS20 region of 14 different E. ruminantium isolates were determined after amplification with newly designed primers. Sequencing data indicated that West African E. ruminantium isolates are highly conserved, whereas more variation occurs amongst the southern African isolates. These results facilitated the design of a short pCS20 probe and a large PCR target that improved the sensitivity of the E. ruminantium detection assay.

Characterization of a major outer membrane protein multigene family in Ehrlichia ruminantium

Ehrlichia ruminantium is a tick-transmitted rickettsial pathogen, which causes heartwater or cowdriosis in wild and domestic ruminants. A dominant antibody response of animals infected with E. ruminantium is directed against the outer membrane protein MAP1 (major antigenic protein 1). Part of the locus containing map1 has been characterized and consists of four map1 paralogs, designated map1-2, map1-1, map1 and map1+1, indicating that map1 is encoded by a multigene family. The purpose of this study was to determine the total number of map1 paralogs and their transcriptional activities. Using genome walking and data from an ongoing E. ruminantium genome sequencing project at the Onderstepoort Veterinary Institute, we found 16 paralogs of the map1 gene tandemly arranged in a 25 kb region of the E. ruminantium genome. The map1 multigene family is downstream of a hypothetical transcriptional regulator gene and upstream of the secA gene. Thirteen paralogs at the 5' end of the 25-kb locus were connected by short intergenic spaces (ranging from 0 to 42 bp) and the remaining three paralogs at the 3' end were connected by longer intergenic spaces (ranging from 375 to 1612 bp). All 16 map1 paralogs were transcriptionally active in E. ruminantium grown in endothelial cells and paralogs with short intergenic spaces were co-transcribed with their adjacent genes.

Development of improved vaccines for heartwater

Heartwater is a tick-borne disease of ruminants which causes major economic losses for domestic livestock owners throughout sub-Saharan Africa and the Caribbean. It is caused by the intracellular rickettsia Ehrlichia (formerly Cowdria) ruminantium and the only commercially available vaccination procedure is over 50 years old. It involves infecting animals with cryopreserved sheep blood containing virulent E. ruminantium organisms, followed by antibiotic treatment when fever develops. Experimental attenuated, inactivated, and nucleic acid vaccine procedures have been investigated over the last half-century, but none of them has yet been particularly successful. We have developed two new experimental vaccines, a live attenuated vaccine and a nucleic acid vaccine. The attenuated vaccine was developed by continuous passage of E. ruminantium organisms of the virulent Welgevonden isolate in a continuous canine macrophage-monocyte cell line. After more than 50 passages the cultures produced no disease when inoculated into mice or sheep, and the inoculated animals were 100% immune to a subsequent lethal homologous needle challenge. The nucleic acid vaccine is based on four E. ruminantium genes from a genetic locus involved in nutrient transport. A cocktail of all four genes, cloned in a DNA vaccine vector and used to immunize sheep, engendered 100% protection against a subsequent lethal needle challenge with the homologous isolate and with each of five different virulent heterologous isolates. Sheep immunized with this cocktail were also exposed to a field challenge in a heartwater-endemic area and few animals survived. This suggests that the local E. ruminantium genotypes were different from any which were administered by needle challenge, or that needle challenge is not a good model for tick challenge in the field.

Phylogenetic relationships among Ehrlichia ruminantium isolates

Ehrlichia ruminantium, the causative agent of heartwater, is a tick-borne pathogen infecting ruminants throughout sub-Saharan Africa and on some Caribbean islands. The most reliable test for E. ruminantium is PCR-based, but this gives positive results in some areas free of clinical heartwater and of the known Amblyomma spp. tick vectors. To investigate the molecular basis for this finding we have sequenced and carried out phylogenetic analysis of a range of genes from a number of E. ruminantium isolates. The genes include ribonuclease III and cytochrome c oxidase assembly protein genes (the pCS20 region), groESL, citrate synthase (gltA), and 16S ribosomal RNA. Relationships among major antigenic protein (map1) genes have been exhaustively investigated in a previous study that showed that the genes are variable in length, have non-synonymous mutations, and show no geographical specificity among isolates. The 16S sequences are highly conserved, except in the V1 loop region. The pCS20, groESL, and gltA genes show only single nucleotide polymorphisms (SNPs) dispersed throughout the sequenced regions. Phylogenetic analysis using pCS20 data differentiates the western African isolates into a single clade, which also includes a southern African isolate. All other southern African isolates and a Caribbean isolate fall into a further clade, which is subdivided into two groups. Sequence variation within this clade is greater than that within the western African clade, suggesting that E. ruminantium originated in southern Africa.

Preparation of Ehrlichia ruminantium challenge material for quantifiable and reproducible challenge in mice and sheep

The causative agent of heartwater, Ehrlichia ruminantium, is a tick-transmitted pathogen that infects bovine endothelial cells. Due to the obligate intracellular nature of this organism obtaining pure material in sufficient quantities for challenge studies is difficult. A murine model is frequently used to study potential vaccine candidates but giving reproducible challenges in this model for heartwater has always been problematic. We have therefore performed a series of experiments to optimize the parameters governing the reproducibility of challenge material. Two cryoprotectants were compared for the preparation of challenge material, buffered lactose peptone (BLP) and sucrose-potassium-glutamate (SPG). In addition two sources of virulent E. ruminantium were used, infected bovine endothelial cultures and infected mouse spleen homogenates. We also examined practical parameters affecting the reproducibility of challenge experiments: the time it takes to deliver the challenge material, the length of time a mouse remains immune to E. ruminantium challenge, and the effect of a given challenge dose. Finally, we performed a pilot study to determine whether mice could be used to titrate challenge material to be used for experiments in sheep. We found that: (a) E. ruminantium-infected mouse spleen homogenate provides more reproducible challenges than tissue culture material; (b) SPG is a better cryoprotectant than BLP; (c) challenge material should be used within 20min of thawing; (d) it is not essential to use syngeneic material for murine challenge experiments; (e) Balb/c mice are more sensitive to E. ruminantium challenge than C57BL/6J mice; (f) mice immunized by infection and treatment for use as positive immune controls should be challenged within 3 months of immunization; and (g) mice should be challenged with a dose not exceeding 10 LD(50)s.

Development of improved attenuated and nucleic acid vaccines for heartwater

Heartwater, an economically important tickborne disease of wild and domestic ruminants, is caused by the intracellular rickettsia Ehrlichia (formerly Cowdria) ruminantium. The only commercially available immunization procedure is more than 50 years old and uses an infection and treatment regimen using a preparation of virulent organisms in cryopreserved sheep blood. Much research has been conducted into the development of attenuated, inactivated, and nucleic acid vaccines over the last half-century, with relatively little success until recently. We describe here the development of two new experimental vaccines, a live attenuated vaccine and a nucleic acid vaccine. The attenuation of virulent E. ruminantium was achieved by growing the organisms in a continuous canine macrophage-monocyte cell line. After more than 125 passages the cultures produced no disease when inoculated into mice or sheep, and the animals were completely protected against a subsequent lethal homologous needle challenge. The nucleic acid vaccine consists of a cocktail of four E. ruminantium genes, from a genetic locus involved in nutrient transport, cloned in a DNA vaccine vector. Sheep immunized with this cocktail were completely protected against a subsequent lethal needle challenge, either with the homologous isolate or with any one of five different virulent heterologous isolates. Protection against a field challenge in a heartwater endemic area, however, was relatively poor. Genetic characterization of the E. ruminantium genotypes in the challenge area did not identify any having major differences from those used in the heterologous needle challenge experiments, so lack of cross-immunity between the vaccine genotype and those in the field was unlikely to be the main reason for the lack of protection. We believe that a needle challenge is far less severe than a tick challenge, and that the immunity engendered by the DNA vaccine alone was not sufficient to protect against the natural route of infection. Boosting with live organisms after DNA vaccination results in much higher levels of protection against tick challenge than DNA vaccination alone, suggesting that improved methods of boosting could lead to more effective immunization.

Major outer membrane proteins of Ehrlichia ruminantium encoded by a multigene family

Immune responses of infected animals and humans have been reported to be directed against variable outer membrane proteins of Ehrlichia species that are encoded by polymorphic multigene families. In Ehrlichia (= Cowdria) ruminantium, two immunodominant proteins have been identified, namely major antigenic protein 1 (MAP1) and open reading frame 2 (ORF2). The aim of the present study was to identify additional map1-like genes in the E. ruminantium genome. A 12 kb clone that hybridized with the map1 probe was amplified using long template PCR. The PCR product was partially digested, cloned, and sequenced. Four map1-like genes are located in tandem, namely map1-1 (orf2) and map1-2 upstream of map1 as well as map1+1 downstream of map1. A large ORF (2.4 kb) at the 3' end is homologous to secA genes of other organisms. The sequence data in this study support other findings that outer membrane proteins are located in tandem and are encoded by a polymorphic multigene family.

Sequencing of a 15-kb Ehrlichia ruminantium clone and evaluation of the cpg1 open reading frame for protection against heartwater

A 1.2 kb polymorphic fragment from the Gardel isolate of Ehrlichia (formerly Cowdria) ruminantium was used to isolate a 15kb clone from the E. ruminantium Welgevonden LambdaGEM-11 library. This clone, WL2EL1, was subcloned and sequenced. Eight open reading frames (ORFs) were identified. The ORF in WL2EL1 which contained the Welgevonden homologue of the 1.2 kb polymorphic fragment was designated Cowdria polymorphic gene 1 (cpg1). The cpg1 ORF was cloned into pCMViUB, a genetic vaccine vector. Mice and sheep were immunized with pCMViUB/cpg1 by intramuscular injection and gene gun inoculation. Although all of the immunized mice died, there was a trend for mice that received larger amounts of pCMViUB/cpg1 DNA to survive longer. Four out of five sheep immunized with the construct survived lethal challenge.

Sequence analysis of three Ehrlichia ruminantium LambdaGEM-11 clones

Three Lambda GEM11 clones were isolated from a large-insert Ehrlichia ruminantium Welgevonden library. The inserts were amplified, sequenced, and analyzed. A total of 39 827 bp was obtained, and 18 different open reading frames (ORFs) were identified. Long repeats (100-200 kbp) were found in all three sequences. These repeats may play a role in the induction of antigenic variation. Along with a 20-kbp sequence of a clone from the E. ruminantium cosmid library, these sequences are the first large sequences to be yielded by the E. ruminantium genome sequencing project.

Genetic immunization with Ehrlichia ruminantium GroEL and GroES homologues

Ehrlichia ruminantium GroEL and GroES genes were amplified from E. ruminantium Welgevonden genomic DNA and were cloned into genetic vaccine and Salmonella expression vectors. These constructs were used to inoculate Balb/c and C57BL/6J mice. Both GroEL and GroES induced low levels of protection in Balb/c and C57BL/6J mice immunized with the Salmonella expression vectors. None of the mice inoculated with the genetic vaccine survived. Immunological memory was also tested in these mice and a correlation between splenocyte proliferation and the survival rate was observed.

The Kümm isolate of Ehrlichia ruminantium: in vitro isolation, propagation and characterization

An effective culture system for Ehrlichia (Cowdria) ruminantium comb. nov. was first established in 1985 and many stocks were subsequently isolated and propagated in vitro. A notable exception, however, was the Kümm isolate that resisted all attempts at in vitro culture until the successful experiment described here. In one experiment white blood cells were harvested from heparinized blood derived from a sheep infected with the Kümm isolate. The cells were added to DH 82 cells and incubated at 37 degrees C. The high metabolic activity of the DH 82 cells necessitated that cell growth be retarded by the addition of cycloheximide. Colonies were first detected 19 days after culture initiation and, once the cultures were established, they could be passaged every 3 days. Bovine and sheep endothelial cells were readily infected with culture supernatant obtained from the infected DH 82 cells. In a further experiment another sheep was infected, using a higher dose of the same batch of Kümm stabilate, and we attempted to infect several different cell lines: these were DH 82 cells, bovine aorta (BA 886) cells, sheep brain endothelial (SBE 189) cells and sheep fibroblastoid cells (E2). Ten days after culture initiation only the E2 cells had become positive for E. ruminantium. Culture supernatant from the first cultured isolate (Kümm-1) was less virulent for mice than that of the second cultured isolate (Kümm-2) which killed all mice. Upon molecular characterization with E. ruminantium 16S probes we found that Kümm-1 hybridized with a Senegal 16S genotype probe, whereas Kümm-2 hybridized only with an Omatjenne 16S genotype probe. The original stabilate used to infect the sheep hybridized with both probes. These results clearly indicate that two different stocks had been isolated in culture.

Molecular diagnosis of theileriosis and heartwater in bovines in Africa

The advent of the polymerase chain reaction (PCR) coupled with the specificity of deoxyribocucleic acid (DNA)-DNA hybridization has led to the development of specific and sensitive molecular diagnostic tests to detect and characterize the organisms that cause theileriosis and heartwater. Theileriosis is a widespread disease of wild and domestic ruminants caused by apicomplexan parasites of the genus Theileria. Species-specific variations in small subunit ribosomal ribonucleic acid genes (SSUrRNA) have been used to develop probes that can distinguish between Theileria species such as T. parva, T. annulata, T. mutans, T. buffeli and T. taurotragi. Routine application of this test has led to the discovery of previously unknown species, such as Theileria sp. (buffalo) which is apparently apathogenic to both buffalo and cattle, and Theileria sp. (sable) which is pathogenic to sable and possibly also to roan antelope. In addition, characterization probes located in the internal transcribed spacer (ITS) can be used to distinguish between most isolates of the causative agents of East Coast fever (T. p. parva) and Corridor disease (T. p. lawrencei). Heartwater is an economically important disease of livestock and some wild ruminants, caused by the intracellular rickettsial parasite Ehrlichia (ex Cowdria) ruminantium. DNA probes used to detect and characterize E. ruminantium isolates include SSUrRNA (16S) probes, the pCS20 probe and map1 probes. A panel of eight 16S probes has been developed for the detection of E. ruminantium and related Ehrlichia species. There are probes for 5 different E. ruminantium genotypes, one which will detect all 5 of these genotypes, one to detect any Ehrlichia species other than E. ruminantium, and one for any Anaplasma species. The pCS20 probe is specific for E. ruminantium and is the most sensitive of the probes for E. ruminantium detection, but it is not able to distinguish among the different genotypes. The map1 gene has also been used for diagnosis, but the extensive polymorphism of this gene means that it is most useful for characterization of different genotypes of the parasite. Routine application of these tests has led to the discovery of new genotypes that are probably not E. ruminantium but are probably new species of Ehrlichia.

Low molecular weight proteins of Cowdria ruminantium (Welgevonden isolate) induce bovine CD4+-enriched T-cells to proliferate and produce interferon-gamma

An important objective in vaccination strategies is to activate lymphocytes with particular effector functions. Cellular immunity and the type I cytokine IFN-gamma have been implicated in protective immunity to heartwater. Furthermore, low molecular weight proteins of Cowdria ruminantium have been shown to induce peripheral blood mononuclear cells to proliferate. To determine which lymphocyte subset responds when stimulated with fractionated C. ruminantium proteins, specific short-term lymphocyte cultures were established from cattle immunized with the Welgevonden isolate. Four cattle were immunized, two by infection and treatment and two with inactivated organisms. Cell surface phenotypic analysis of the cultures indicated that CD4+ lymphocytes were enriched over time. This coincided with increased antigen-specific proliferation and IFN-gamma production. Proteins of molecular weights 13-18kDa induced the CD4+-enriched T-cell cultures, derived from each of the animals, to proliferate and produce IFN-gamma. Although the two groups of cattle were immunized differently, their lymphocytes responded similarly. These results extend previous findings by identifying the responder cells as being predominantly IFN-gamma producing CD4+ lymphocytes. This cytokine has been implicated in immunity to the parasite. The low molecular weight proteins that induced CD4+ lymphocytes to proliferate and produce IFN-gamma are therefore likely to be important in protection against heartwater and may have a role in vaccine development.

Novel Ehrlichia genotype detected in dogs in South Africa

DNA samples from dogs presenting with symptoms suggestive of canine ehrlichiosis, but with no morulae detected on blood smears, frequently failed to give a positive reaction with a North American Ehrlichia canis-specific PCR assay targeting the 16S rRNA gene. We suspected the presence of a pathogen genetically different from North American E. canis, and we performed experiments to test this hypothesis. DNA from one canine blood sample was subjected to PCR with primers designed to amplify Ehrlichia (Cowdria) ruminantium ruminantium 16S and map1 genes. Amplicon sequencing yielded 16S and map1 sequences which were more closely related to other E. ruminantium sequences than to those of any other Ehrlichia species. Fifty canine DNA samples were subjected to a PCR assay, previously found to be Cowdria-specific, which targets the pCS20 gene. Thirty-seven (74%) gave a positive signal, and 16 (32%) also gave visible amplicons after gel electrophoresis, suggesting that this E. ruminantium organism is common in the Pretoria-Johannesburg area. The organism has not been isolated in culture, so we cannot definitively state that it was responsible for the canine ehrlichiosis symptoms, although the occurrence of several similar cases suggests this to be so. Most importantly, we also do not yet know whether the organism is infective for, or causes heartwater in, ruminants.

Ehrlichia ruminantium major antigenic protein gene (map1) variants are not geographically constrained and show no evidence of having evolved under positive selection pressure

In a search for tools to distinguish antigenic variants of Ehrlichia ruminantium, we sequenced the major antigenic protein genes (map1 genes) of 21 different isolates and found that the sequence polymorphisms were too great to permit the design of probes which could be used as markers for immunogenicity. Phylogenetic comparison of the 21 deduced MAP1 sequences plus another 9 sequences which had been previously published did not reveal any geographic clustering among the isolates. Maximum likelihood analysis of codon and amino acid changes over the phylogeny provided no statistical evidence that the gene is under positive selection pressure, suggesting that it may not be important for the evasion of host immune responses.

Genome size and genetic map of Cowdria ruminantium

Cowdria ruminantium is the cause of a serious tick-borne disease of domestic ruminants, known as heartwater or cowdriosis. The organism belongs to the tribe Ehrlichieae:, which contains obligate intracellular pathogens, causing several important animal and human diseases. Although a few C. ruminantium genes have been cloned and sequenced, very little is known about the size, gross structure and organization of the genome. This paper presents a complete physical map and a preliminary genetic map for C. ruminantium. Chromosomal C. ruminantium DNA was examined by PFGE and Southern hybridization. PFGE analysis revealed that C. ruminantium has a circular chromosome approximately 1576 kb in size. A physical map was derived by combining the results of PFGE analysis of DNA fragments resulting from digestion of the whole genome with KSP:I, RSR:II and SMA:I and Southern hybridization analysis with a series of gene probes and isolated macrorestriction fragments. A genetic map for C. ruminantium with a mean resolution of 290 kb was established, the first for a member of the Ehrlichieae: A total of nine genes or cloned C. ruminantium DNA fragments were mapped to specific KSP:I, RSR:II and SMA:I fragments, including the major antigenic protein gene, map-1.

Antigenic, phenotypic and molecular characterization confirms Babesia odocoilei isolated from three cervids

Babesia isolates from an elk (Cervus elaphus canadensis) and a caribou (Rangifer tarandus caribou) with fatal infections were compared to Babesia odocoilei (Engeling isolate) from white-tailed deer (Odocoileus virginianus) by experimental infection, serologic, and small subunit ribosomal RNA (SSU rRNA) gene sequence analysis studies. Both the indirect fluorescent antibody test and immunoprecipitation assays demonstrated antigenic variation among the isolates. Experimental infection studies showed no clinical differences among the isolates. Nucleotide sequence analysis showed that the elk and caribou Babesia sp. isolates possessed SSU rRNA genes with identical sequences to that of B. odocoilei. A phylogenetic tree constructed from SSU rRNA gene sequences shows that B. odocoilei is most closely related to Babesia divergens, both of which branch together in the true babesia clade.

Macrorestriction fragment profiles reveal genetic variation of Cowdria ruminantium isolates

Macrorestriction profile analysis by pulsed-field gel electrophoresis (PFGE) was used to distinguish between seven isolates of Cowdria ruminantium from geographically different areas. Characteristic profiles were generated for each isolate by using the restriction endonucleases KspI, SalI, and SmaI with chromosomal sizes ranging between 1,546 and 1,692 kb. Statistical analysis of the macrorestriction profiles indicated that all the isolates were distinct from each other; these data contribute to a better understanding of the epidemiology of this pathogen and may be exploited for the identification of genotype-specific DNA probes.

Identification of Cowdria ruminantium antigens that stimulate proliferation of lymphocytes from cattle immunized by infection and treatment or with inactivated organisms

Cowdria ruminantium is an obligate intracellular pathogen that causes heartwater in ruminants. Several findings suggest that T cells play an important role in protection against the disease. In order to identify which proteins are involved in T-cell immunity, C. ruminantium proteins were fractionated by continuous-flow electrophoresis and tested for their ability to stimulate lymphocyte proliferation in vitro. C. ruminantium-infected endothelial cell lysates were fractionated at between 11 and 38 kDa and 50 and 168 kDa on 15 and 7% acrylamide gels, respectively. In an attempt to stimulate the natural infective process, peripheral blood mononuclear cells (PBMC) were obtained from two cattle rendered immune by infection and treatment and assayed in proliferation assays with fractionated proteins. In a parallel study, four cattle were immunized with inactivated C. ruminantium to determine whether their lymphocytes also responded to fractionated proteins. Proliferation assays after immunization by infection and treatment detected no C. ruminantium-specific proliferation in vitro after one vaccination. Proliferation was observed, however, between 1 and 4 weeks after challenge. This was followed by a period of no detectable response, after which the response reappeared. PBMC from animals immunized with inactivated organisms proliferated specifically in response to antigen soon after the first immunization. Only C. ruminantium proteins with low molecular masses of 11, 12, 14 to 17, and 19 to 23 kDa induced proliferative responses by lymphocytes from all six animals. These protein fractions may have potential as vaccine antigens.

A study of the systematics of Theileria spp. based upon small-subunit ribosomal RNA gene sequences

The systematics of benign and moderately pathogenic Theileria isolates from cattle and deer originating from different geographic regions was undertaken by small-subunit ribosomal RNA (SSU rRNA) gene nucleotide-sequence analysis. A maximum-likelihood phylogenetic tree constructed from these sequences resulted in two major divisions, each with a common ancestor. One major division branches into four relatively divergent groups, including (1) bovine Theileria sp. Type D (USA and Korea), (2) T. mutans Intona and Theileria sp. MSD (Africa), (3) T. cervi (USA), and (4) well-characterized pathogenic Theileria spp. (Africa). The other major division branches into two groups: (1) T. buffeli Warwick and T. buffeli Marula and (2) a second branch of closely related isolates with SSU rRNA gene Types B, B1, C, E, and H. Putative geographically associated diversity was noted only in the Korean bovine Theileria spp. with SSU rRNA gene types C and H and in African T. mutans Intona and Theileria sp. MSD. The current results show that the United States bovine Theileria isolates are not T. mutans because they have T. buffeli Marula (Type A) and/or Type D (species undesignated) SSU rRNA gene sequences. The taxonomic separation of T. buffeli Warwick from African T. mutans is confirmed in this study.

The occurrence of Theileria and Cowdria parasites in African buffalo (Syncerus caffer) and their associated Amblyomma hebraeum ticks

The polymerase chain reaction and oligonucleotide probing were used to detect Theileria and Cowdria species in DNA extracted from blood and ticks recovered from 24 African buffalo during a gamecapture operation in the Kruger National Park, South Africa. Species-specific probing indicated that all but one of the buffalo were carrying at least one Theileria species. Indirect fluorescent antibody (IFA) serology indicated that all animals had been exposed to Theileria parva infection but only 33% were positive for T. parva by probing. Twelve (50%) of the animals but only six of the 214 adult Amblyomma hebraeum ticks examined (2.8%) were probe-positive for Cowdria. Only one Cowdria 16S genotype was detected in the animals and ticks.

Cowdria ruminantium DNA is unstable in a SuperCos1 library

A Cowdria ruminantium genomic library was constructed in a cosmid vector to serve as a source of easily accessible and pure C. ruminantium DNA for molecular genetic studies. The cosmid library contained 846 clones which were arrayed into microtitre plates. Restriction enzyme digestion patterns indicated that these clones had an average insert size of 35 kb. Probing of the arrays did not detect any bovine clones and only one of the known C. ruminantium genes, pCS20, was detected. Due to the high AT content and the fact that C. ruminantium genes are active in the Escherichia coli host, the C. ruminantium clones were unstable in the SuperCos1 vector and most clones did not grow reproducibly. The library was contaminated with E. coli clones and these clones were maintained with greater fidelity than the C. ruminantium clones, resulting in a skewed representation over time. We have isolated seven C. ruminantium clones which we were able to serially culture reproducibly; two of these clones overlap. These clones constitute the first large regions of C. ruminantium DNA to be cloned and represent almost 10% of the C. ruminantium genome.

Theileria parva ribosomal internal transcribed spacer sequences exhibit extensive polymorphism and mosaic evolution: application to the characterization of parasites from cattle and buffalo

We sequenced the rRNA genes and internal transcribed spacers (ITS) of several Theileria parva isolates in an attempt to distinguish between the causative agents of East coast fever and Corridor disease. The small subunit (SSU) and large subunit (LSU) rRNA genes from a cloned T. p. lawrencei parasite were sequenced; the former was identical to that of T. p. parva Muguga, and there were minor heterogeneities in the latter. The 5.8S gene sequences of 11 T. parva isolates were identical, but major differences were found in the ITS. Six characterization oligonucleotides were designed to hybridize within the variable ITS1 region; 93.5% of T. p. parva isolates examined were detected by probe TPP1 and 81.8% of T. p. lawrencei isolates were detected by TPL2 and/or TPL3a. There was no absolute distinction between T. p. parva and T. p. lawrencei and the former hybridized with fewer of the probes than did the latter. It therefore seems that a relatively homogenous subpopulation of T. parva has been selected in cattle from a more diverse gene pool in buffalo. The ITSs of both T. p. parva and T. p. lawrencei contained different combinations of identifiable sequence segments, resulting in a mosaic of segments in any one isolate, suggesting that the two populations undergo genetic recombination and that their gene pools are not completely separate.

Evaluation of 16S, map1 and pCS20 probes for detection of Cowdria and Ehrlichia species

A panel of 16S ribosomal RNA gene probes has been developed for the study of the epidemiology of heartwater; five of these detect different cowdria genotypes, one detects five distinct genotypes; one detects any Group III Ehrlichia species other than Cowdria and one detects any Group II Ehrlichia species. These probes have been used on PCR-amplified rickettsial 16S rRNA genes from over 200 Amblyomma hebraeum ticks. Control ticks were laboratory-reared and either uninfected or fed on sheep experimentally infected with different cowdria isolates, field ticks were collected from animals in heartwater-endemic areas. All tick-derived DNA samples were also examined by PCR amplification and probing for two other cowdria genes (map1 and pCS20) which have previously been used for heartwater epidemiology. This paper describes the first direct comparison of all currently available DNA probes for heartwater-associated organisms.

Comparative evaluation of 16S, map1 and pCS20 probes for the detection of Cowdria and Ehrlichia species in ticks

We have developed a panel of 16S ribosomal RNA gene probes for heartwater epidemiology; five of these detect different Cowdria genotypes (Ball3, Senegal, Omatjenne, Crystal Springs, and Mara 87/7); one detects all five of these genotypes; one detects any Group III Ehrlichia species other than Cowdria; one detects any Group II Ehrlichia species. We have used these probes on PCR-amplified rickettsial 16S rRNA genes from over 200 Amblyomma ticks. Control ticks were laboratory-reared and either uninfected or fed on sheep experimentally infected with different Cowdria isolates, field ticks were harvested from animals in heartwater-endemic and heartwater-free areas. All the samples were also examined by PCR amplification and probing for two other Cowdria genes (map1 and pCS20) which have been used for heartwater epidemiology. This paper describes the first direct comparison of all the currently available DNA probes for heartwater-associated organisms.

Purification of Cowdria ruminantium organisms for use in genome analysis by pulsed-field gel electrophoresis

Cowdria ruminantium is an obligate intracellular rickettsial pathogen which is responsible for a tick-borne disease of domestic and wild ruminants called heartwater or cowdriosis. Although several genes have been cloned and partially sequenced, the genome size, gross structure, and organization of the C. ruminantium genome is unknown. Genome analysis of the organism has been hindered because it is difficult to obtain C. ruminantium DNA free from contaminating host cell DNA, and this probably accounts for the lack of genome size data for this organism. In this study we investigated several methods for purifying C. ruminantium from bovine cellular contaminants and organisms of a relatively high purity were obtained. These were used to prepare Cowdria DNA which was analyzed by pulsed-field gel electrophoresis (PFGE) and which revealed a genome approximately 1900 kbp in length plus an additional extra-chromosomal fragment migrating with an apparent size of 815 kbp. This is the first time that the genome size of C. ruminantium has been determined and the first demonstration of an extrachromosomal element.

A partially protective clone from Cowdria ruminantium identified by using a Salmonella vaccine delivery system

A strategy has been developed to screen the Cowdria genome, using a Salmonella vaccine delivery system, to identify genes that code for protection-stimulating proteins. We have cloned mini-libraries of Cowdria into this Salmonella system, used the recombinant bacteria to immunize outbred mice, and then challenged them after two weeks with a lethal dose of Cowdria. When one of these mini-libraries was tested in a group of 5 mice, one mouse lived much longer than the others. The experiment was repeated with each of the clones from the mini-library being tested individually in 10 mice, and one mouse survived the challenge. This clone has been tested repeatedly in larger groups of mice and is proven to protect 14% of outbred mice against a lethal Cowdria challenge.

Isolation of Theileria taurotragi and Theileria mutans from cattle in Botswana

Two Theileria species demonstrated in peripheral Giemsa-stained blood smears of sick cattle from various parts of Botswana were subsequently identified as Theileria mutans and T. taurotragi using DNA hybridization and the polymerase chain reaction. Initial screening for Theileria species was done using microscopy, the indirect fluorescent antibody technique and the micro Elisa test. The syndrome was characteristically that of high morbidity but low mortality and vague malaise. A low parasitaemia of pleomorphic intra-erythrocytic piroplasms and the absence of schizont stages in circulating lymphocytes and lymph node aspirates were evident. Dual infections were common and often complicated by intercurrent disease conditions.

Construction and initial analysis of a representative lambda ZAPII expression library of the intracellular rickettsia Cowdria ruminantium: cloning of map1 and three other Cowdria genes

The causative agent of heartwater, the rickettsia Cowdria ruminantium, is very poorly understood at the molecular level owing to a profound lack of suitable tools. We have developed an immunoaffinity chromatographic method to purify C. ruminantium from host cell components and the purified rickettsial cells have been used to prepare substantially pure Cowdria DNA. This DNA has been used to construct what we believe to be the first fully representative C. ruminantium expression library. A clone containing the complete Cowdria map1 gene has been isolated and sequenced. This gene has been expressed in E. coli cells from the native Cowdria promoter, suggesting that the mechanisms for gene transcription and translation are similar between these two organisms. Parts of three other Cowdria genes have also been isolated and sequenced.

Different organisms associated with heartwater as shown by analysis of 16S ribosomal RNA gene sequences

Cowdria ruminantium is a rickettsial parasite which causes heartwater, a economically important disease of domestic and wild ruminants in tropical and subtropical Africa and parts of the Caribbean. Because existing diagnostic methods are unreliable, we investigated the small-subunit ribosomal RNA (srRNA) gene from heartwater-infected material to characterise the organisms present and to develop specific oligonucleotide probes for polymerase chain reaction (PCR) based diagnosis. DNA was obtained from ticks and ruminants from heartwater-free and heartwater-endemic areas from Cowdria in tissue culture. PCR was carried out using primers designed to amplify only rickettsial srRNA genes, the target region being the highly variable V1 loop. Amplicons were cloned and sequenced; 51% were C. ruminantium sequences corresponding to four genotypes, two of which were identical to previously reported C. ruminantium sequences while the other two were new. The four different Cowdria genotypes can be correlated with different phenotypes. Tissue-culture samples yielded only Cowdria genotype sequences, but an extraordinary heterogeneity of 16S sequences was obtained from field samples. In addition to Cowdria genotypes we found sequences from previously unknown Ehrlichia spp., sequences showing homology to other Rickettsiales and a variety of Pseudomonadaceae. One Ehrlichia sequence was phylogenetically closely related to Ehrlichia platys (Group II Ehrlichia) and one to Ehrlichia canis (Group III Ehrlichia). This latter sequence was from an isolate (Germishuys) made from a naturally infected sheep which, from brain smear examination and pathology, appeared to be suffering from heartwater; nevertheless no Cowdria genotype sequences were found in this isolate. In addition no Cowdria sequences were obtained from uninfected ticks. Complete 16S rRNA gene sequences were determined for two C. ruminantium genotypes and for two previously uncharacterised heartwater-associated Ehrlichia spp. Sequenced difference within the V1 loop were sufficient for the derivation of four Cowdria genotype-specific oligonucleotide probes. Four further probes were designed; one for the detection of any Cowdria genotype, one for the detection of any Group II Ehrlichia sp., one for any Group III Ehrlichia sp. and one for all Pseudomonadaceae. All the probes were specific except that for the Cowdria (Ball 3) genotype. The high prevalence (96%) in field samples of pseudomonad-like 16S sequences was the result of environmental contamination. The probes were used to screen DNA from goats in an area free of both Amblyomma ticks and clinical heartwater. A substantial proportion (42%) gave positive reactions for the apparently apathogenic Cowdria (Omatjenne), indicating that this genotype is relatively common.

Development of the OPgun for bombardment of animal tissues

A simple and inexpensive particle-bombardment device, the OPgun, was constructed for the delivery of DNA into animal tissues. This device is based on the particle-inflow gun first described for plant-cell transfection. The delivery of tungsten particles into the epidermis of the mouse ear, without the use of vacuum and without causing damage to the tissue, was demonstrated. The system was also shown to be capable of inducing antibodies to a foreign gene in mice.

Evidence for two single copy units in Theileria parva ribosomal RNA genes

Bacteriophage clones containing ribosomal RNA genes of Theileria parva were isolated from genomic DNA libraries. Physical mapping studies revealed 2 ribosomal DNA units, which were distinguishable by restriction enzyme site polymorphisms in flanking sequences. The cloned ribosomal DNA units were mapped to 2 separate T. parva chromosomes. Analysis of sequences contained in lambda EMBL3 recombinants, together with Southern blot analysis of genomic DNA and data on the copy number of the rRNA genes, suggested that the rDNA units were not tandemly repeated. This organisation of ribosomal transcription units is similar to that described for other genera of apicomplexan protozoa, but 2 rDNA units, each containing single copies of the rRNA coding genes, would be the lowest copy number described for any eukaryote in which amplification of rRNA genes is not known to occur. EcoRI restriction fragment length polymorphisms, which were revealed using rRNA gene probes, separated T. parva stocks into 2 categories. Nucleotide sequence analysis of polymerase chain reaction-amplified internal transcribed spacer DNA revealed 2 different ITS sequences derived from rDNA transcription units within the genome of a cloned T. parva parasite. Polymorphism was also observed between ITS sequences amplified from the DNA of different T. parva stocks. A synthetic oligonucleotide derived from T. parva Uganda ribosomal ITS DNA sequences hybridised to DNA from the T. parva Uganda stock, but not to the DNA of the T. parva Muguga stock. This oligonucleotide is potentially useful as a marker for the T. parva Uganda stock.

Phylogeny and evolution of the piroplasms

Small subunit ribosomal RNA (srRNA) genes of three Theileria species, one Cytauxzoon and four Babesia species were amplified using the polymerase chain reaction (PCR), cloned and sequenced. Our sequences were aligned with srRNA sequences previously published for eight species of Apicomplexa, one ciliate and one dinoflagellate, the last two being included as free-living outgroup species. Phylogenetic relationships between the organisms were inferred by four independent methods of phylogenetic tree construction using the ciliate Oxytricha nova to root the trees. Our trees fail to show a consensus branching order. They do, however, clearly indicate that the theilerias form a monophyletic taxon derived from a paraphyletic group which includes the species B. equi, C. felis and B. rodhaini. The distance trees indicate that the babesias sensu stricto (B. canis, B. caballi, B. bigemina and B. bovis) form another monophyletic taxon which diverged before the theilerias separated from the above-mentioned paraphyletic group. The parsimony and maximum likelihood trees suggest that the babesias and theilerias are sister taxa, both of which were derived from the paraphyletic group.

Characterisation of a glutamine- and proline-rich protein (QP protein) from Theileria parva

We have isolated a clone from a Theileria parva infected lymphocyte cDNA library which has the potential to encode a protein of 480 amino acids. This protein is particularly rich in glutamine and proline and has some short repeated amino acid motifs based on the sequences QPXP and QPXQ. We have called it the 'QP protein'. Southern blotting suggests that the QP protein gene is present as a single copy in the T. parva Muguga genome. Northern blotting revealed that the gene is transcribed in both schizonts and piroplasms. We have expressed part of the QP protein as a fusion with glutathione S-transferase in Escherichia coli and used this product to raise an anti-QP protein serum. Western blots of T. parva lysates using this serum showed a major polypeptide of approximately 100 kDa and two further polypeptides of approximately 67 and 72 kDa. Indirect immunofluorescence assays using the anti-QP protein serum on infected cells showed that the protein is associated with the schizont. The pattern of staining in the indirect immunofluorescence assays and the structure of the protein suggest that it is a component of the schizont membrane.

Discrimination between six species of Theileria using oligonucleotide probes which detect small subunit ribosomal RNA sequences

The complete small subunit ribosomal RNA (srRNA) gene of Theileria parva was cloned and sequenced. Two primers were designed which permitted the specific amplification of part of the Theileria srRNA gene from Theileria-infected cell line samples which were predominantly (> 95%) bovine DNA. The sequence of the central (variable) region of the srRNA genes of T. annulata, T. taurotragi, T. mutants and two unidentified parasites referred to as Theileria sp. (buffalo) and Theileria sp. (Marula) were obtained. An alignment of the sequences was generated from which 6 oligonucleotide probes, corresponding to species-specific regions, were designed. These probes were demonstrated to provide unequivocal identification of each of the 6 species either by direct detection of parasite srRNA or by hybridization to amplified parasite srRNA genes. The probes were not able to distinguish buffalo-derived T. parva, the causal agent of Corridor disease, from cattle-derived T. parva, the causal agent of East Coast fever.

Detection of polymorphisms among Theileria parva stocks using repetitive, telomeric and ribosomal DNA probes and anti-schizont monoclonal antibodies

A total of 21 Theileria parva stocks from 6 countries were characterized using T. parva repetitive and ribosomal DNA probes, a Plasmodium berghei telomeric oligonucleotide and a panel of anti-schizont monoclonal antibodies (MAbs). Hybridization of the repetitive DNA probe to Southern blots of EcoRI-digested T. parva DNA revealed 20 different restriction fragment patterns among DNA samples isolated from infections initiated using 16 parasite stocks. The panel of anti-schizont MAbs defined 8 different profiles among schizont-infected lymphoblastoid cell-cultures infected with the same 16 T. parva stocks. Many stocks, which were differentiated by the repetitive DNA probe, could not be distinguished using the anti-schizont MAbs. A cloned T. parva small subunit ribosomal RNA (SSUrRNA) gene probe separated 17 T. parva stocks into 2 groups, exhibiting either 1 or 2 restriction fragments, when hybridized to EcoRI-digested T. parva DNA. When hybridized to PvuII-digested DNA from 8 T. parva stocks, the ribosomal probe identified 4 groups with similar restriction fragment patterns. A synthetic oligonucleotide derived from a P. berghei telomeric sequence hybridized to 7 or 8 size-polymorphic restriction fragments in the EcoRI-digested DNA of most T. parva stocks. The telomeric and ribosomal probes defined the same 4 groups among 8 T. parva stocks as assessed by similarities in restriction fragment patterns. Based on the comparison of repetitive DNA sequences from the T. parva Uganda and Muguga stocks, a synthetic oligonucleotide was developed which distinguished the DNA of the T. parva Uganda stock from that of 4 other T. parva stocks on a positive/negative basis.

Detection of a carrier state in Theileria parva-infected cattle by the polymerase chain reaction

Two sets of oligonucleotide primers, one derived from a repetitive sequence and the other from the gene encoding a 67 kDa sporozoite antigen of Theileria parva, were used to amplify parasite DNA from the blood of T. parva-infected carrier cattle using the polymerase chain reaction (PCR). PCR amplification products were obtained from 15 carrier cattle infected with one of 4 different T. parva stocks. Successful amplifications were performed using DNA from 2 cattle infected with T. p. parva Pemba Mnarani, 10 cattle infected with T. p. parva Marikebuni, 2 cattle infected with T. p. bovis Boleni and 1 animal infected with T. p. lawrencei 7014. No amplification products were obtained from any of 7 cattle which had been infected with the T. p. parva Muguga stock. A synthetic oligonucleotide, which hybridized specifically to T. p. parva Marikebuni DNA among 6 T. parva stocks tested, was designed using sequence data from within the region of the T. parva genome amplified by the repetitive sequence primers. The oligonucleotide was used to probe PCR products and to increase the sensitivity and specificity of carrier animal detection. Southern blot analysis using a T. parva repetitive sequence probe demonstrated the existence of restriction fragment length polymorphisms between parasites isolated from T. p. parva Marikebuni-infected carrier cattle. The use of the PCR and other methods of carrier animal detection are discussed.