Identification and characterization of a Babesia bigemina thrombospondin-related superfamily member, TRAP-1: a novel antigen containing neutralizing epitopes involved in merozoite invasion.

BACKGROUND: Thrombospondin-related anonymous protein (TRAP) has been described as a potential vaccine candidate for several diseases caused by apicomplexan parasites. However, this protein and members of this family have not yet been characterized in Babesia bigemina, one of the most prevalent species causing bovine babesiosis. METHODS: The 3186-bp Babesia bigemina TRAP-1 (BbiTRAP-1) gene was identified by a bioinformatics search using the B. bovis TRAP-1 sequence. Members of the TRAP and TRAP-related protein families (TRP) were identified in Babesia and Theileria through a search of the TSP-1 adhesive domain, which is the hallmark motif in both proteins. Structural modeling and phylogenetic analysis were performed with the identified TRAP proteins. A truncated recombinant BbiTRAP-1 that migrates at approximately 107 kDa and specific antisera were produced and used in Western blot analysis and indirect fluorescent antibody tests (IFAT). B-cell epitopes with neutralizing activity in BbiTRAP-1 were defined by enzyme-linked immunosorbent assays (ELISA) and invasion assays. RESULTS: Three members of the TRAP family of proteins were identified in B. bigemina (BbiTRAP-1 to -3). All are type 1 transmembrane proteins containing the von Willebrand factor A (vWFA), thrombospondin type 1 (TSP-1), and cytoplasmic C-terminus domains, as well as transmembrane regions. The BbiTRAP-1 predicted structure also contains a metal ion-dependent adhesion site for interaction with the host cell. The TRP family in Babesia and Theileria species contains the canonical TSP-1 domain but lacks the vWFA domain and together with TRAP define a novel gene superfamily. A variable number of tandem repeat units are present in BbiTRAP-1 and could be used for strain genotyping. Western blot and IFAT analysis confirmed the expression of BbiTRAP-1 by blood-stage parasites. Partial recognition by a panel of sera from B. bigemina-infected cattle in ELISAs using truncated BbiTRAP-1 suggests that this protein is not an immunodominant antigen. Additionally, bovine anti-recombinant BbiTRAP-1 antibodies were found to be capable of neutralizing merozoite invasion in vitro. CONCLUSIONS: We have identified the TRAP and TRP gene families in several Babesia and Theileria species and characterized BbiTRAP-1 as a novel antigen of B. bigemina. The functional relevance and presence of neutralization-sensitive B-cell epitopes suggest that BbiTRAP-1 could be included in tests for future vaccine candidates against B. bigemina.

Alsinol, an arylamino alcohol derivative active against Plasmodium, Babesia, Trypanosoma, and Leishmania: past and new outcomes.

Malaria, babesiosis, trypanosomosis, and leishmaniasis are some of the most life-threatening parasites, but the range of drugs to treat them is limited. An effective, safe, and low-cost drug with a large activity spectrum is urgently needed. For this purpose, an aryl amino alcohol derivative called Alsinol was resynthesized, screened in silico, and tested against Plasmodium, Babesia, Trypanosoma, and Leishmania. In silico Alsinol follows the Lipinski and Ghose rules. In vitro it had schizontocidal activity against Plasmodium falciparum and was able to inhibit gametocytogenesis; it was particularly active against late gametocytes. In malaria-infected mice, it showed a dose-dependent activity similar to chloroquine. It demonstrated a similar level of activity to reference compounds against Babesia divergens, and against promastigotes, and amastigotes stages of Leishmania in vitro. It inhibited the in vitro growth of two African animal strains of Trypanosoma but was ineffective in vivo in our experimental conditions. It showed moderate toxicity in J774A1 and Vero cell models. The study demonstrated that Alsinol has a large spectrum of activity and is potentially affordable to produce. Nevertheless, challenges remain in the process of scaling up synthesis, creating a suitable clinical formulation, and determining the safety margin in preclinical models.

Hap2, a novel gene in Babesia bigemina is expressed in tick stages, and specific antibodies block zygote formation.

BACKGROUND: Bovine babesiosis is a tick-borne disease caused by the protozoan parasites of the genus Babesia. In their host vector, Babesia spp. undergo sexual reproduction. Therefore, the development of sexual stages and the subsequent formation of the zygote are essential for the parasite to invade the intestinal cells of the vector tick and continue its life-cycle. HAP2/GCS1 is a protein identified in plants, protozoan parasites and other organisms that has an important role during membrane fusion in fertilization processes. The identification and characterization of HAP-2 protein in Babesia would be very significant to understand the biology of the parasite and to develop a transmission-blocking vaccine in the future. RESULTS: To isolate and sequence the hap2 gene DNA from an infected bovine with Babesia bigemina was purified. The hap2 gene was amplified, cloned and sequenced. The sequences of hap2 from four geographically different strains showed high conservation at the amino acid level, including the typical structure with a signal peptide and the HAP2/GSC domain. Antisera anti-HAP2 against the conserved extracellular region of the HAP2 amino acid sequence were obtained from rabbits. The expression of hap2 in the host and vector tissues was analyzed by using semi-quantitative RT-PCR, and the protein was examined by western blot and immunofluorescence. Based on the RT-PCR and WB results, HAP2 is expressed in both, sexual stages induced in vitro, and in infected ticks as well. We did not detect any expression in asexual erythrocytic stages of B. bigemina, relevantly anti-HAP2 specific antibodies were able to block zygotes formation in vitro. CONCLUSION: Babesia bigemina HAP2 is expressed only in tick-infecting stages, and specific antibodies block zygote formation. Further studies regarding the function of HAP2 during tick infection may provide new insights into the molecular mechanisms of sexual reproduction of the parasite.

Cultivo de Esporocinetos de Babesia bigemina em Hemócitos e Células Embrionárias de Rhipicephalus (Boophilus) microplus

Os hemoparasitos pertencentes ao gênero Babesia são intensamente estudados devido sua importância na economia da pecuária mundial. Culturas de hemócitos e células embrionárias de carrapatos constituem excelentes substratos para o isolamento e cultivo de hemoparasitos patogênicos, incluindo Babesia spp. Esta metodologia contribui para estudos da biologia, fisiopatologia, bem como controle da espécie. O presente estudo teve como objetivos cultivar in vitro, esporocinetos de Babesia bigemina em hemócitos e em células embrionárias de Rhipicephalus (Boophilus) microplus. Após desinfecção superficial de fêmeas ingurtitadas, a hemolinfa foi coletada e transferida para frascos de cultura com 25 cm2 e tubo de 10cm² e incubados a 28 °C. Para iniciar o cultivo primário embrionário, fêmeas ingurgitadas de R. (B) microlpus foram incubadas à 28°C e após 13 dias de postura, os ovos foram desinfectados superficialmente, macerados, filtrados e transferidos para meio de cultivo L15 suplementado e em temperatura de 28ºC. Observações foram realizadas diariamente em microscópio de contraste de fase invertido. Realizou-se Citospin e gota espessa das amostras, que foram coradas com Giemsa e observadas em microscopia de luz. Foram realizadas PCR para B. bigemina e Babesia bovis, utilizando dois pares de iniciadores para identificar o gene 18SrRNA para ambas espécies e também foi realizado a morfometria dos esporocinetos para confirmação da espécie. Esporocinetos de B. bigemina criopreservados a partir da cultura de hemócitos, foram descongelados, reativados em hemócitos livres de infecção e em células de linhagem CTVM/BME2. Observou-se o desenvolvimento dos esporocinetos de B. bigemina a partir do primeiro dia do cultivo, após reativação nas células. Os protozoários apresentaram boa motilidade e capacidade de aderência na membrana celular pela extremidade apical. No citoplasma dos hemócitos observou-se formas redondas, móveis e com núcleo vísivel de esporocinetos de B. bigemina. Nas amostras coradas do 3° e 17° dia do cultivo de esporocinetos de B. bigemina em hemócitos foram observadas formas íntegras piriformes de esporocinetos imaturos e maduros, com núcleo corado de vermelho escuro, as vezes, centralizado ou próximo da extremidade apical. Nas amostras do 17° dia de cultivo foram observados muitas formas pequenas redondas e ovais, compatíveis com esporocinetos imaturos. Pela técnica PCR foi possível a amplificação do DNA para o gene 18SrRNA de B. bigemina, assim como pelo estudo comparativo das mensurações dos esporocinetos. Os hemócitos e células embrionárias de R. (B.) microplus constituíram-se em substratos eficientes para cultivo in vitro de esporocinetos de B. bigemina. Foi possível a criopreservação de esporocinetos de B. bigemina em nitrogênio líquido e a sua reativação em cultura de hemócitos de R. (B.) microplus e em células da linhagem BME2

Babesia bigemina: in vitro multiplication of sporokinetes in Ixodes scapularis (IDE8) cells.

This paper describes the in vitro multiplication process of Babesia bigemina sporokinetes in a cell line (IDE8) from Ixodes scapularis ticks. The inoculum was obtained from hemolymph of engorged females of Rhipicephalus (Boophilus) microplus ticks naturally infected with B. bigemina. These ticks had been fed on calves living in a tick endemic farm in Brazil. Microscopic morphological details are shown to describe the development of the parasite in the tick cells; the identity of the parasite was confirmed by a duplex PCR method.

[Morphologic characterization and biological aspects of evolutive forms of Babesia bigemina (Smith and Kilborne, 1893) (Protozoa: Babesiidae) in Boophilus microplus (Canestrini, 1887)]. / Caracterizçã morfológica e aspectos biológicos das formas evolutivas de Babesia bigemina (Smith; Kilborne, 1893) (Protozoa: Babesiidae) em Boophilus microplus (Canestrini, 1887).

The development of Babesia bigemina in Boophilus microplus were studied in experimental conditions, using crossed-breed bovine from free-area of these parasites. Stages of the hemoparasites were observed in the tick vector, starting from the infected red-blood cells observed in the gut of engorged females, from the first 24 hours after detachment to the emergence of sporokinets in the larvas. In the period from 24 to 48 hours after detachment of the engorged females (DEF), the presence of some infected red-blood cells was verified, beside the occurrence of ray bodies and of vermiculars forms, known as oocynets. Since 72 hours after the DEF, the of okinets presence was observed in the cytoplasm of the epithelium cells besides of great sporokinets number in development. At same period, the presence of sporokinets of B. bigemina in the hemolymph samples was observed inside the hemocytes. After the fourth day of incubation beside the presence of the sporokinets was also verified in the Malpighi's tubes and ovaries. As well as in the ticks eggs from the sporokinets were also observed ticks eggs from the fourty day after the natural detachment of the engorged females of the host.

Ticks and tick-borne disease in Guatemalan cattle and horses.

Blood samples and ticks were collected from 48 cattle and 74 horses from seven sites in the Peten region of Guatemala. Data on body condition, mucous membrane capillary refill time and tick infestation levels were recorded for each animal in the study. Horses had significantly higher levels of tick infestation than cattle, as well as poorer body condition scores. Seroprevalence of Babesia spp. was 95.8% for B. bovis in cattle, 89.6% for B. bigemina in cattle, and 92.7% for B. equi in horses. Seroprevalence of Anaplasma marginale in cattle was 87.5%, similar to reports in animals from other regions of Central America. This is the first time that A. phagocytophilum has been reported in animals from this region, with overall PCR-prevalence of 27.6% in cattle and horses, and seroprevalence of 28.4% (52% in cattle and 13% in horses). An agent was identified with serological cross-reactivity and close genetic relatedness to Ehrlichia ruminantium, but further testing confirmed that the agent in Guatemalan cows was not the agent of heartwater. Ticks were identified to species with the predominant species identified on cattle as Boophilus microplus and Amblyomma cajennense, while Anocentor nitens and A. cajennense were most commonly found on horses. Prevalence of infection, tick infestation levels, host factors and environmental data were analyzed for association; A. nitens was significantly associated with A. phagocytophilum prevalence by village.

Molecular fluorescent approach to assessing intraerythrocytic hemoprotozoan Babesia canis infection in dogs.

The development of recent flow cytometry-based protocols for the diagnosis of canine babesiosis, Babesia gibsoni in particular, has encouraged us to investigate its applicability to detect B. canis-infected erythrocytes as well as optimize the hydroethidine-flow cytometry methodology (HE-FC), using peripheral blood samples from naturally and experimentally infected dogs. Our data demonstrated that HE at 25 microg/ml provided the most outstanding fluorescence profile, able to discriminate between infected and uninfected dogs with no alterations in cell properties such as forward scatter and unspecific fluorescence. The results were expressed as the percentage of positive fluorescent erythrocytes (PPFE) for each individual sample, with 1.53% of PPFE as the cut-off determined between infected and uninfected animals. B. canis-infected erythrocytes during both acute and chronic experimental infection were identified through HE-FC, validating its use for diagnosis purposes in endemic areas for canine babesiosis. In a clinical trial, 22.8% out of 162 dogs showed to be positive to Babesia infection through this approach. Such prevalence was similar to that estimated for altered hematological profiles (HT) < or = 30% (29%), but highly distinct from the prevalence provided by direct blood smear (BS) examination (1.8%) or immunofluorescent assay (IFA) (60.5%). Furthermore, our findings indicate that positive PPFE data was associated with HT < or = 30%, emphasizing that, in clinical practice, the haematocrit should be used as a screening test followed by HE-FC, suitable to confirm hypotheses of canine babesiosis.

Babesia equi field isolates cultured from horse blood using a microcentrifuge method.

Babesia equi, a causative agent of equine piroplasmosis, was isolated from horses in the Chaco Province of Argentina, a known piroplasmosis endemic region. Fifteen B. equi field isolates were acquired by culture from 23 actively working horses from 2 ranches. The horses appeared healthy with no clinical signs or histories indicative of equine piroplasmosis. All 23 horses had B. equi-specific antibody activity by the indirect fluorescent antibody test and 18 were also complement fixation test positive for B. equi. Equine erythrocytes were prepared for parasite culture using a microcentrifuge tube method. This method greatly reduces the time involved in cell handling and parasite exposure to ambient conditions. By this method, B. equi cultures can be initiated from very small quantities of blood.

Sporogony and experimental transmission of Babesia equi by Boophilus microplus.

The development of Babesia equi in salivary glands of adult female Boophilus microplus was observed under a light microscope using semithin sections stained with toluidine blue. Engorged nymphs were obtained from splenectomized foals experimentally infected with B. equi. As adults, they were then fed on rabbits for 5 days and the salivary glands of manually collected individuals were removed at intervals of 24 h. Sporozoites were found in type III granular acini cells between the 2nd and 5th days following feeding on the rabbits. Sporoblasts and sporozoites were observed in the same or adjacent acini cells in all the glands examined. The formation of the sporozoites occurred following the multiple division of the sporoblasts through a process of radial budding from the periphery of bodies resulting from multiple fission. Sporozoites were detected in smears of adult males stained with Giemsa, between the 2nd and 5th days following feeding by the ticks. Adults of B. microplus, fed during the nymphal phase on foals with patent parasitemia, transmitted sporozoites of B. equi to a splenectomized foal. The role of B. microplus in the transmission and epidemiology of B. equi is discussed.

In vitro cultivation of an African strain of Babesia bigemina, its characterisation and infectivity in cattle.

An African (Kenyan) strain of Babesia bigemina, Muguga (B(2-1)), was inoculated into a calf from a stabilate and blood from the calf was used to establish the parasite in vitro. The strain has been cultured continuously for 20 months, initially in bovine erythrocytes with 60% adult bovine serum, later, with 50%. Cultures were incubated at 37 degrees C in RPMI 1640 medium with a gas mixture of 1% O2, 5% CO2, 94% N2. Adaptation in vitro was demonstrated when serum from a calf which had recovered from infection with B(2-1) bound to proteins of Mr 46 kDa, 49 kDa, 52 kDa, 61 kDa and 72 kDa on Western blots of B(2-1) antigens from cattle blood but did not recognise the 49 kDa or 52 kDa antigens from in-vitro-derived parasites. These proteins were considered specific for B(2-1), as they were not recognised by the same serum on profiles of a Mexican isolate of B. bigemina or an African isolate of B. bovis (Kwanyange). After 9 months of in vitro culture, a stabilate of the cultured parasite was injected into two splenectomised calves and one intact calf. The calves experienced a drop in packed cell volume and low parasitaemias but recovered spontaneously. Two of these animals, one splenectomised and one intact, were challenged with virulent B(2-1) and experienced only mild babesiosis, in contrast to a previously uninfected calf also challenged with B(2-1), which had to be euthanised after 5 days with severe babesiosis.

Ultrastructure of sporogony in Babesia equi in salivary glands of adult female Boophilus microplus ticks.

The development of Babesia equi was studied in the salivary glands of adult female ticks, Boophilus microplus, using a transmission electron microscope (TEM). Engorged nymphs were obtained from splenectomized foals experimentally infected with B. equi and fed in the adult phase for 5 days on rabbits. Sporogony in B. equi involves the development of sporoblasts and sporozoites, which form from finger-like projections on the surface and through radial budding. Mature sporozoites (2.0 x 1.1 microns), typically pyriform, showed a polar ring, rhoptries, micronemes, nuclei, and mitochondria, and a high concentration of free ribosomes were observed from the 2nd day of the ticks, feeding on the rabbits. In general, sporogony of B. equi in the salivary glands of B. microplus showed similarities to the development of this parasite in species of Hyalomma, although with some significant differences in the sporozoite's dimensions. The results of this study indicate that B. equi is capable of multiplying in the salivary glands of adult female B. microplus, forming sporozoites with specialized organelles characteristic of the invasive form, and suggest that B. microplus can act as a natural vector of B. equi in endemic areas where there is no other probable source of infection or where it is the only tick species present on horses.