An Anaplasma centrale DNA probe that differentiates between Anaplasma ovis and Anaplasma marginale DNA

Evidence confirming the phylogenetic position of Anaplasma centrale (ex Theiler 1911) Ristic and Kreier 1984

In 1911, Sir Arnold Theiler isolated and described a parasite that was very similar to Anaplasma marginale but which was more centrally located within the erythrocytes of the host cells, and was much less pathogenic than A. marginale. He named the parasite A. marginale variety centrale. The name Anaplasma centrale, referring to the same organism, was published in Validation List No. 15 in 1984, but the publication was based on an erroneous assumption that Theiler had indicated that it was a separate species. Many authors have subsequently accepted this organism as a separate species, but evidence to indicate that it is a distinct species has never been presented. The near full-length 16S rRNA gene sequence, and the deduced amino acid sequences for groEL and msp4 from several isolates of A. marginale and A. centrale from around South Africa were compared with those of the A. marginale type strain, St Maries, and the A. centrale Israel strain and other reference sequences. Phylogenetic analyses of these sequences demonstrated that A. centrale consistently forms a separate clade from A. marginale, supported by high bootstrap values (≥90 %), revealing that there is divergence between these two organisms. In addition, we discuss distinctive characteristics which have been published recently, such as differences in Msp1a/Msp1aS gene structure, as well as genome architecture that provide further evidence to suggest that A. centrale is, in fact, a separate species. Our results, therefore, provide evidence to support the existing nomenclature, and confirm that A. centrale (ex Theiler 1911) Ristic and Kreier 1984 is, indeed, a distinct species.

Phylogenetic analysis of the erythrocytic Anaplasma species based on 16S rDNA and GroEL (HSP60) sequences of A. marginale, A. centrale, and A. ovis and the specific detection of A. centrale vaccine strain

Phenotypic criteria for the identification of erythrocytic ruminant Anaplasma species has relied on subjective identification methods such as host pathogenicity (virulence for cattle or sheep) and/or the location of Anaplasma inclusion bodies within the host's red cells. Sequence comparisons of new and available GenBank Accessions were investigated to elucidate the relationships among these closely related Anaplasma species. Twenty-one 16S rDNA and GroEL (HSP60) sequences from 13 Anaplasma marginale (South Africa, Namibia, Zimbabwe, Israel, USA, Australia and Uruguay), three A. centrale (South Africa and Japan), two A. ovis (USA and South Africa), and two unknown Anaplasma species isolated from wild ruminants (South Africa), were compared. 16S rDNA maximum-likelihood and distance trees separated all A. marginale (and the two wild ruminant isolates) from the two South African A. centrale (including original vaccine strain, Theiler, 1911). The Japanese A. centrale (Aomori) demonstrated the lowest sequence identity to the remaining erythrocytic Anaplasma species. A. ovis inter-species relationships could not be resolved through the 16S rDNA analyses, whereas strong bootstrap branch support is demonstrated in the GroEL distance tree using A. ovis OVI strain. All erythrocytic Anaplasma species and isolates were confirmed to belong to the same cluster showing strong branch support to Anaplasma (Ehrlichia) phagocytophilum with Ehrlichia (Cowdria) ruminantium and Rickettsia rickettsii serving as appropriate out-groups. Based on groEL sequences, a specific PCR method was developed which amplified A. centrale vaccine (Theiler, 1911) specifically. This study confirms the suitability of 16S rDNA sequences to define genera and demonstrates the usefulness of GroEL sequences for defining species of erythrocytic Anaplasma.

Simultaneous detection of Anaplasma and Ehrlichia species in ruminants and detection of Ehrlichia ruminantium in Amblyomma variegatum ticks by reverse line blot hybridization

The detection of Anaplasma and Ehrlichia species is usually based on species-specific PCR assays, since no assay is yet available which can detect and identify these species simultaneously. To this end, we developed a reverse line blot (RLB) assay for simultaneous detection and identification of Anaplasma and Ehrlichia species in domestic ruminants and ticks. In a PCR the hypervariable V1 region of the 16S ribosomal RNA (rRNA) gene was amplified with a set of primers unique for members of the genera Anaplasma and Ehrlichia [Int. J. Syst. Evol. Microbiol. 51 (2001) 2145]. Amplified PCR products from blood of domestic ruminants or Amblyomma variegatum tick samples were hybridized onto a membrane to which eight species-specific oligonucleotide probes and one Ehrlichia and Anaplasma catch-all oligonucleotide probe were covalently linked. No DNA was amplified from uninfected blood, nor from other hemoparasites such as Theileria annulata, or Babesia bigemina. The species-specific probes did not cross-react with DNA amplified from other species. E. ruminantium, A. ovis and another Ehrlichia were identified by RLB in blood samples collected from small ruminants in Mozambique. Finally, A. variegatum ticks were tested after feeding on E. ruminantium infected sheep. E. ruminantium could be detected in adult ticks even if feeding of nymphs was carried out 3.5 years post-infection. In conclusion, the developed species-specific oligonucleotide probes used in an RLB assay can simultaneously detect and identify several Ehrlichia and Anaplasma species. However, as no quantitative data for the detection limit are available yet, only positive results are interpretable at this stage.

A msp1alpha polymerase chain reaction assay for specific detection and differentiation of Anaplasma marginale isolates

Anaplasma marginale is the causative agent of bovine anaplasmosis, a disease which can be protected by vaccination with the less pathogenic Anaplasma species, A. centrale. Currently, there is no polymerase chain reaction (PCR) assay available which differentiates between different species of Anaplasma or which can differentiate isolates of A. marginale within outbreaks and between different countries. A molecular test specific for A. marginale would be ideal for the identification of Anaplasma species in wild ruminants, as possible reservoirs of anaplasmosis, and to differentiate between A. marginale from A. centrale. A PCR assay was designed to amplify the major surface protein 1alpha gene of the rickettsial bovine pathogen, A. marginale both as an inter- and intra-specific test. The test did not amplify A. centrale or A. ovis, and discriminated A. marginale by amplifying repeat regions within the msp1alpha gene which vary in number between many isolates. The nested A. marginale amplicons varied in size from 630 to 1190bp representing one to eight internal repeats. All 22 Australian isolates tested amplified a 630bp product (one repeat) in contrast to all 19 non-Australian isolates tested. Eight sequences from Australian isolates from different geographical regions confirmed the conserved nature of the Australian A. marginale msp1alpha genes. The Australian 'repeat unit' MSP1a deduced amino acid sequence has been designated as Australian type 1. The msp1alpha PCR method developed here enabled the amplification and comparison of A. marginale isolates originating from North and South America, Africa, Israel and Australia. The method is sensitive and specific for A. marginale. Although additional msp1alpha products were amplified from at least two Australian isolates, the results suggest limited introduction of A. marginale into Australia.

Characterization of Anaplasma isolates from eland (Taurotragus oryx). Pathogenicity in cattle and sheep and DNA profiles analysis

Two eland Anaplasma isolates, AnapE1, from Kenya, and AnapE2, from South Africa were characterised. Their characterization was based on their pathogenicity to intact and splenectomized cattle and sheep and also their DNA profiles. Their DNA profiles were analysed and compared to Anaplasma marginale, A. ovis and A. centrale after endonuclease restrictions and probing with Anaplasma DNA probes, AC5-12 and AC-1. The results of the pathogenicity trials showed AnapE1 to be similar to A. ovis and AnapE2 an isolate of A. marginale. On DNA profiles, AnapE1 was close to A. ovis, with differences that occur even in same Anaplasma species isolates from different locations. On the other hand, AnapE2, resembled one of the A. marginale isolates known to occur in South Africa. The DNA profiles correlated well with the pathogenicity results. It is concluded that elands are carriers of both A. marginale and A. ovis parasites and are therefore important reservoirs that need attention in epidemiology of anaplasmosis.

Recent developments in the molecular biology of anaplasmosis

Recent applications of DNA analysis, cloning, sequencing and expression technology have resulted in significant advances in our understanding of the hemoparasite Anaplasma marginale. Analysis of 16S ribosomal RNA has confirmed a phylogenetic position close to Ehrlichia sp. and Cowdria ruminantium. Intact genomic DNA of A. marginale digested with SfiI separates into bands from 14 to 170 kbp on pulse-field gels, with a total genome size of 1200-1260 kbp and G + C content of 56 mol%. Major surface proteins (MSP1-MSP5) have been identified and DNA coding sequences are available for most of these. These data have revealed that MSPs may be quite polymorphic between different geographic isolates, may be encoded by multi-gene families, and have some similar features to other prokaryotes including signal peptidase cleavage sites and gene regulatory sequences. Homologies have been detected between MSPs and immunodominant proteins of Cowdria ruminantium. Several MSPs have been expressed to high level and purified from recombinant Escherichia coli. MSP 1, 2 and 4 have potential for the development of vaccines and MSP3 and 5 for improved diagnostic assays.

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

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

Antigen profiles of Anaplasma ovis and A. mesaeterum and cross infection trials with them and A. marginale

Antigen profiles of Anaplasma ovis and A. mesaeterum were analysed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting, and cross infection trials were performed by A. ovis challenge to A. mesaeterum- or A. marginale-inoculated goats and A. marginale challenge to an A. ovis-inoculated calf. Antigen analysis showed unique and common proteins of A. ovis and A. mesaeterum and identified a major 38 kDa protein to be a dominant immunogen bearing two epitopes common to Anaplasma species. An epitope specific to A. ovis and A. marginale, absent from A. mesaeterum, was recognised on the major protein of A. ovis. Pre-inoculation of goats with A. mesaeterum induced continuous antibody response with low parasitemia and partial protection against A. ovis challenge, as demonstrated by lower peak parasitemia and normal body temperature compared with values for goats inoculated with A. ovis alone. Pre-inoculation of goats with A. marginale and a calf with A. ovis induced weak or no antibody response without parasitemia, and was of no effect for preventing anaplasmosis by heterologous challenge. These results suggest that the development of parasitemia is essential for inducing continuous antibody by which cross protection would be possible.