Skip to main content

Serological and molecular diagnostic surveys combined with examining hematological profiles suggests increased levels of infection and hematological response of cattle to babesiosis infections compared to native buffaloes in Egypt

Abstract

Background

Babesiosis threatens the development of the cattle and buffaloes industries in Egypt and improved control is needed. The main objectives of this study are surveying the presence of bovine babesiosis in distinct selected bovine and buffalo populations in Egypt using novel molecular and previously validated serological methods, while also comparing the occurrence of hematological alterations among Babesia infected cattle and buffalos.

Methods

A total of 253 and 81 blood samples from apparently healthy cattle and buffaloes, respectively, were randomly collected from diverse locations in Egypt. All samples were tested for Babesia bovis and B. bigemina infection using blood film examination, competitive ELISA (cELISA) and PCR. Novel semi-nested and nested PCR assays for the detection of B. bovis and B. bigemina respectively, were developed and used to analyze DNA extracted from bovine and buffalo samples. Hematological profiles were studied using a hematological analyzer.

Results

Blood films examination revealed 13.8 % and 7.4 % Babesia infection rates in cattle and buffaloes, respectively. However, in cattle, the cELISA detected 32.8 %, 21.3 % and 10.7 % infection rates with B. bigemina, B. bovis and mixed infection, respectively. In addition, cELISA identified 22.2 %, 22.2 % and 6.2 % infection rates with B. bigemina, B. bovis and mixed infection, respectively in buffaloes. The semi-nested PCR assay showed that 15 % of the tested samples were positive for B. bovis in cattle, but just 3 % in buffaloes. Infections with B. bigemina were also found in cattle (32.4 %), but not in buffaloes upon nested PCR analysis. Sequencing analysis confirmed the identity of the PCR amplicons and showed that Egyptian genotypes of B. bigemina and B. bovis highly resemble sequences previously deposited in GenBank. Hemograms performed on the sampled animals revealed macrocytic hypochromic anemia associated with reduced platelet counts in infected cattle with babesiosis. In addition, marked increases in total leukocyte and granulocytic counts and decreases in lymphocytic counts were found in infected cattle. In contrast, no such hematological anomalies were found in presumably Babesia-infected buffaloes.

Conclusions

Frequent occurrence of babesiosis among apparently healthy bovines in Egypt, suggests the need for appropriately designed prevalence studies in this country. Infected bovine, but not buffalo, populations often present hematological disorders compatible with intravascular hemolysis and thrombocytopenia.

Background

Babesiosis is caused by intraerythrocytic protozoan parasites of the genus Babesia that infect a wide range of domestic and wild animals and occasionally humans [1, 2]. Bovine babesiosis is the most significant tick-borne disease of cattle worldwide threatening approximately 1.3 billion animals in vast areas of Asia, Africa, Australia, Central and South America, and Southern Europe [3]. The disease has the potential to cause large economic and sanitary disruptions compromising the livestock industry all over the world [4].

In Egypt, bovine babesiosis is caused mainly by Babesia bovis and Babesia bigemina. B. bovis parasites are known to be transmitted in this country by Rhipicephalus microplus whereas B. bigemina is known to be transmitted by both R. microplus and Rhipicephalus annulatus [5, 6]. Because of its significant economic impact on meat and milk production and on livestock management, it is currently considered as the most important endemic parasitic disease affecting cattle in Egypt [5]. Both B. bigemina and B. bovis are capable of causing acute disease resulting in life-threatening hemolytic anemia as well as other severe clinical manifestations [7, 8]. Often, especially in bovines younger than a year old, acute disease resolves into persistent disease and the animals become carriers of the parasites, thus ensuring transmission by competent ticks in zoonotic areas. In addition to hemolytic anemia, bovine babesiosis is known to cause other blood disorders including thrombocytopenia [9]. However, there is a paucity of information on the overall impact that these hematological disorders may have in the development of cattle and buffalo industries in Egypt. Assessing hematological disorders can contribute to our better understanding of the pathogenic mechanisms of the disease, but these data can also become a predictor for recovery and wellbeing for the animals in endemic areas, thus this information can be valuable for gauging efficiency upon the application of measures for the control of the disease. Previous studies suggest that there are large numbers of cattle in Egypt infected with subclinical babesiosis [5]. In addition, although clinical evidence suggests that buffaloes are likely more tolerant to Babesia infections [10], the hematological response of buffaloes to Babesia infection in Egypt remains poorly investigated [10, 11].

Accurate diagnosis of babesial infections plays an important role in monitoring, management and control [12]. A large diversity of diagnostic techniques including blood smear examination, serological tests, and molecular (DNA-based) assays exist currently, yet, each of these methods has limitations. It is increasingly recognized that accurate diagnosis requires a combination of distinct approaches.

Blood smear examination is often considered to be the standard technique for routine diagnosis of babesiosis, particularly in acute cases, and it is considered by some as a gold standard [13]. It is less time consuming than most other methods and is relatively inexpensive [14]. However, the examination of the stained blood smears is insufficient for accurate detection and identification of B. bovis and B. bigemina during mixed infections and in particular for the detection of carrier cases or sub-clinical infections with low parasitemia [15].

The serological tests, including the indirect fluorescent antibody test (IFAT) and the enzyme-linked immune-sorbent assay (ELISA) are capable of detecting antibodies in carrier animals; therefore they are often used for monitoring surveillance and export certification [16]. Moreover, specific and sensitive competitive ELISA (cELISA) methods have been developed for B. bovis and B. bigemina, and their use has been validated in several diagnostic laboratories around the world [1719]. Drawbacks of serological tests include that antibodies can still be detected even years after recovery of infection though no active infection is prevalent, so these methods cannot help in revealing the exact picture of prevalence of infection at that particular point [20]. Nevertheless, the use of serological methods in conjunction with molecular methods aimed at detecting the B. bovis and B. bigemina DNA in the blood of infected animals can provide a more complete representation of the incidence of bovine babesiosis in endemic areas.

Most of the DNA based methods employed in the diagnosis of B. bovis and B. bigemina babesiosis are based on standard polymerase chain reaction (PCR) techniques [21, 22]. Appropriate targets for PCR assays include well conserved and species specific genes. PCR techniques permit the identification of parasites at levels far below those identified by the commonly used conventional parasitological techniques for B. bovis and B. bigemina [20], which is critical for the diagnosis of sub-clinical and latent infection. Consequently, DNA amplification for the diagnostic detection of babesiosis is considered as a powerful tool both in the early phase of infection and in carrier animals. PCR results for Babesia sp. can be rapidly made available and as few as three parasites in 100 μl of blood can yield a positive result [23]. Additionally, the sensitivity of a PCR assay can be increased several fold by performing a semi-nested (snPCR) or nested PCR (nPCR), where two different sets of amplification primers are used [2]. This feature not only improves the sensitivity of the assay, but also confirms the specificity of the first round product [24].

The aim of the present study is to estimate the presence of bovine and buffaloes babesiosis in distinct populations in Egypt using blood smear examination, competitive inhibition ELISA and novel PCR procedures based on the amplification of the recently identified and highly conserved rhoptry associated protein (rap)-1c gene of B. bigemina [25] and rap-1 related antigen (rra) gene of B. bovis [26]. We also compared Babesia-associated hematological alterations in the cattle and buffalo populations sampled in this study.

Methods

Collection and processing of blood samples

Blood samples were collected from clinically healthy 253 cattle and 81 buffaloes examined for diagnosis of babesiosis from Kafr El-Sheikh, El-Behaira and Cairo governorate. The blood collected without anti-coagulants were processed for serum. Sera were stored in -20 °C until used in serological tests. The blood collected with anti-coagulant EDTA (ethylenediaminetetraacetic acid tripotassium) was used for PCR and hematology. For PCR, blood was washed three times with PBS pH 7.2 and stored at -20 °C. Blood from B. bigemina experimentally infected animals used in the PCR comparative studies was kindly provided by Dr. Massaro Ueti (ADRU-USDA), and the B. bovis Mo7 experimentally infected samples were derived from a previously published experiment [27]. The protocol of infection and all animal handling, was approved by the Institutional Animal Care and Use Committee, IACUC, Washington State University (#03735-008 approved on 12/9/2009).

Analysis of samples

Blood film examination

Blood smears stained with DIFF-3 Rapid Staining kit were prepared from all animals included in this study and examined by light microscopy at 1000x magnification.

Competitive ELISA

The B. bovis and B. bigemina Antibody Test Kits (cELISA) were kindly donated by VMRD Inc. (Pullman, WA, USA). Optical density (O.D.) values were determined at 650 nm using ELX 800 Universal microplate reader Bio-TEK instruments, INC, USA. The results were expressed as a value of the percent inhibition (%I) according to the following formula:

$$ \left(\%\mathrm{I}\right):\;\%\mathrm{I}=100\hbox{-} \left[\left( sample\;O.D.\times 100\right)/\left( mean\; negative\; control\;O.D.\right)\right] $$

Samples were classified as positive if the %I value was above 40 % and negative if the %I value was less than 40 %. These cut-off values were established by the manufacturer of the kit.

Extraction of DNA

The DNA was extracted from the blood samples according to the instructions of the manufacturer using FTA® Elute cards, Whatman Cat. No.WB120410.

Novel PCR methods for the molecular diagnostic of bovine and buffalo babesiosis

Selection of the B. bovis rra and B. bigemina rap-1c genes as targets for the development of novel PCR molecular diagnostic tools for the detection of bovine babesiosis was based on their high degree of species-specific conservation among distinct strains, and their limited levels of expression in merozoites [25, 26]. Semi-nested and nested PCR techniques were developed to amplify regions of the rra gene [26] (GenBank accession number: XM_001610900) from B. bovis DNA and the rap-1c gene [25] (GenBank Accession number: AY146983.1) from B. bigemina DNA. Sequences derived from the rra (bp 114-937) and rap-1c (bp 1-602) genes were amplified from B. bovis and B. bigemina genomic DNA using the set of primers described in Table 1, and cloned into pCR™ 2.1-TOPO® (Life technologies) plasmids. Taking into consideration the size of each resulting plasmid, it was estimated that 1 ng of B. bovis rra 2.1-TOPO plasmid contains 2.1 × 108 molecules of the target gene and 1 ng of B. bigemina rap-1c 2.1-TOPO plasmid contains 2.2 × 108 molecules of the target gene. To estimate the sensitivity of the assays, we performed serial dilutions of known amounts of plasmid that we then amplified by PCR using the protocol described below. The presence and size of the final PCR products was determined in 1.5 % agarose gels and stained with SYBR Safe (Invitrogen). All PCR amplicons were sequenced for confirming specificity. PCR reactions were performed in a final volume of 25 μl containing (12.5 μl JumpStart RED Taq Ready Mix PCR reaction mix (Sigma- Aldrich), 10 pmol of each primer and 9.5 μl water). All primers were synthesized by Integrated DNA technologies Inc. (California, USA). 2 μl of template DNA was used for the primary PCR. The snPCR and nPCR utilized 0.5 μl of primary PCR product as template.

Table 1 Sequences of the oligonucleotide primers used in the PCR assays and expected PCR product sizes

The thermo-cycling conditions used for the B. bovis primary PCR were: 95 °C for 3 min followed by 25 cycles, each consisting of denaturation at 94 °C for 30 sec, annealing at 60 °C for 1 min, and extension at 72 °C for 1 min. The program also included a final extension step at 72 °C for 5 min. For the semi-nested PCR the same conditions were used except the number of cycles used was 35.

The thermocycling conditions used for the B. bigemina primary PCR consisted of: 95 °C for 3 min followed by 25 cycles, each consisting of denaturation at 95 °C for 30 sec, annealing at 61.2 °C for 30 sec, and extension at 72 °C for 30 sec, followed by a final extension step at 72 °C for 5 min. The thermocycling conditions used for the B. bigemina nPCR were: 95 °C for 3 min followed by 35 cycles, each consisting of denaturation at 95 °C for 30 sec, annealing at 63.1 °C for 30 sec, and extension at 72 °C for 30 sec, followed by a final extension step at 72 °C for 5 min.

The B. bovis and B. bigemina genomic DNA derived from cultured T3Bo B. bovis and Puerto Rico B. bigemina strains respectively used as positive controls were provided by the Animal Disease Research Unit, Agricultural Research Service, USDA, WSU, Pullman. A negative control with no DNA template was always included for PCR amplification. Bovine DNA extracted from blood from non-infected calves was also used as a control for the nested and semi-nested PCRs. Amplified DNA samples were electrophoresed on 1.5 % agarose gels and stained with SYBR Safe. The length of the amplified products was estimated using a 100 base pair (bp) DNA ladder and the amplified products were visualized with an UV trans-illuminator (Bachofer D7410) and photographed using gel Documentation system (BioDocAnalyze-Biometra Analytic GmbH). Amplicons presenting visible unique bands of approximately 387 base pairs (bp) and 236 bp in gel electrophoresis analysis were considered positive for B. bovis rra and the B. bigemina rap-1c genes, respectively. The relative sensitivities of the B. bovis and B. bigemina nested and semi-nested-PCR reactions of the tests based on the B. bovis rra and the B. bigemina rap-1c genes were compared with standardized nested PCR tests described previously [28]. The two new PCR methods were initially tested on gDNA extracted from B. bovis and B. bigemina in vitro cultures and from B. bovis and B. bigemina experimentally infected calves in order to compare their performance with previously standardized nested PCR methods for the detection of B. bovis and B. bigemina in bovine samples by Figueroa et al. 1993 [28]. The previously reported nested PCR for B. bovis, based on the rap-1 gene as the target of amplification [28] was compared with a semi-nested PCR targeting the B. bovis rra gene, using serial dilutions of genomic DNA extracted from in vitro cultured B. bovis parasites from the T3Bo strain. Similar comparative analysis was performed for the novel rap-1c gene based nested PCR for the detection of B. bigemina.

Sequencing of PCR products

The PCR products were purified for sequencing using the QIA quick Spin PCR Purification kit (Qiagen, Courtaboeuf, France) according to the manufacturer’s instructions. Sequencing reactions were performed using oligonucleotide primers that were used in the PCR (Table 1). Sequencing of the PCR products was performed by the GATC Company with an ABI 3730xl DNA sequencer, using the nested forward and reverse primers. Each sequencing reaction was repeated three times in both the forward and reverse directions before being accepted for analysis. Sequences derived from Babesia sp. were assembled using ChromasPro 1.49 beta (Technelysium Pty. Ltd., Tewantin, QLD, Australia).

Hematological investigations

Complete blood analysis was performed on 133 blood samples (107 cattle and 26 buffaloes) from the three Egyptian governorates using a hematological analyzer (MEDONIC CA620, Sweden). The criteria for the selection of the blood samples for hematological examinations were based on: breed consistency; cross-bred cattle and water buffaloes; gender (all animals studied are male); and age range (all animals tested are between 2-3 years old). The analysis included erythrogram consisted of red blood cell count (RBC), hematocrit (HCT), hemoglobin (Hb) concentration and red cell indices, mean corpuscular volume (MCV), mean corpuscular hemoglobin (MCH), mean corpuscular hemoglobin concentration (MCHC), red blood cell distribution width absolute (RDWA), red cell distribution width percentage (RDW%), leukogram (including white blood cell count (WBC), lymphocytes, granulocytes and mid cells (MID) and platelet count (PLT)), mean platelet volume (MPV), platelet distribution width (PDW), plateletcrit (PCT), and large platelet concentration ratio (LPCR).

Statistical analysis

All data were subjected to statistical analysis including the calculation of the mean and standard error. Differences between infected groups detected by different techniques and non-infected groups were tested for significance using a one-way analysis of variance followed by Duncan’s multiple range test. Differences were considered significant at P < 0.05 level [29] using SPSS software version 15.

Results

Diagnosis of bovine babesiosis using direct blood film microscopic examination

We examined a total of 253 cattle and 81 buffaloes’ microscopic stained slide samples. Because of the difficulties in objectively providing differential diagnosis among B. bovis and B. bigemina parasites using this method, added to the possibility of frequent double B. bovis and B. bigemina infections in bovines, we decided to report our microscopic examination findings as “Babesia sp.” Direct microscopic examination resulted in the detection of Babesia infected erythrocytes in 13.8 % and 7.4 % samples of cattle and buffaloes respectively.

Serological diagnosis of bovine and buffalo babesiosis using cELISA

We performed cELISA tests for the detection of B. bovis and B. bigemina antibodies on serum samples obtained from the 253 bovines and 81 buffaloes as described above. The cELISA data performed on cattle sera (Table 2) revealed 32.8 %, 21.3 % and 10.3 % infection with B. bigemina, B. bovis and mixed infection, respectively. The cELISA test performed on buffaloes sera (Table 3), detected 22.2 %, 22.2 % and 6.2 % infection with B. bigemina, B. bovis and mixed infection, respectively.

Table 2 Results of cELISA and PCR tests for the diagnosis of B. bovis and B. bigemina performed on sera from cattle from Kafr El-Sheikh, El-Beheira and Cairo governorates in Egypt
Table 3 Results of cELISA and PCR tests for the diagnosis of B. bovis and B. bigemina performed on sera from buffalo sera from Kafr El-Sheikh and El-Beheira governorates in Egypt

Molecular detection of B. bovis and B. bigemina in infected bovines and buffaloes using PCR

We first determined the optimal conditions and sensitivity of nested and semi-nested PCR reactions for the detection of B. bigemina and B. bovis, respectively. When these two methods were compared using plasmid DNA encoding for the target genes, both reactions have similar levels of sensitivity, and are able to clearly detect down to 0.1 fg for the B. bigemina rap-1c and B. bovis rra genes (Fig. 1a and b) using nPCR and snPCR respectively. In addition, the performances of the novel rra based semi-nested PCR and rap-1c tests were compared with previously established B. bovis rap-1- based nPCR and B. bigemina nPCR tests respectively, before applying them for the analysis of the field samples. Results on the application of the rap-1 nested PCR on genomic DNA (gDNA) from in vitro cultured parasites are shown in the upper panel of Fig. 2a, and results for the rra semi-nested PCR are shown the in the lower panel. Both tests are capable of producing PCR products reliably down to at least 5×10−2 ng of gDNA, and so, they appear to have comparable sensitivity. Importantly, the rra-based PCR method generates single PCR final products upon gel analysis. When similar comparisons were performed using 10 fold serial dilutions of gDNA extracted from persistently and experimentally B. bovis Mo7 strain infected bovines with unknown parasitemia (less than 0.5 % PPE) (Fig. 2b), both tests again appear to perform similarly and to have a comparable level for detection of B. bovis DNA. In addition, sequencing of the PCR products of 291 bp (rap-1 targeted PCR) and 387 bp (rra targeted PCR) demonstrated the specificity of the amplicons as true rap-1 and rra sequences. Importantly, none of the tests amplify bovine gDNA (data not shown), the sequences of the rra gene were previously shown to be identical among the T3Bo and the Mo7 strains [26], and sequencing demonstrates that the novel PCRs only amplify their expected target genes. Taking together the comparisons of both PCR tests performed on DNA extracted from in vitro grown cultures and in vivo B. bovis infected calves, suggests that both tests have similar performances in terms of sensitivity and specificity. However, the rra-based test seems to have a slight advantage in terms of specificity since it invariably generated a single product upon PCR.

Fig. 1
figure 1

Agarose gel electrophoresis analysis: Serial dilutions of known amounts of purified plasmid DNA amplified by PCR. Molecular size ladder in base pair (bp), 100 bp DNA ladder, (lane M). a. Plasmid pCR™ 2.1-TOPO-B. bovis rra amplified using snPCR. The amounts of plasmid amplified are as follows: 10 femtogram (fg) (lane 1), 1 fg (lane 2), 0.1 fg (lane 3), 0.01 fg (lane 4), 0.001 fg (lane 5), negative control, no plasmid (lane 6). b. Plasmid pCR™ 2.1-TOPO-B. bigemina rap-1c amplified using nPCR. The amounts of plasmid amplified are as follows: 10 fg (lane 1), 1 fg (lane 2), 0.1 fg (lane 3), 0.01 fg (lane 4), 0.001 fg (lane 5), negative control, no plasmid (lane 6)

Fig. 2
figure 2

Agarose gel electrophoresis separation of PCR products of the B. bovis PCR detection methods: Two replica comparisons of the relative sensitivity of the nested PCR and semi-nested PCR methods for the detection of B. bovis DNA using genomic DNA extracted from in vitro cultured parasites from the B. bovis T3B strain (A) and from experimentally infected bovine (Mo7 strain) (B). a. The two PCR methods used were based on the B. bovis rap-1 (U) and on the rra (L) genes. The amounts of DNA amplified were 5 ng (lanes 1,8); 5×10−1 ng (lanes 2,9); 5×10−2 ng (lanes 3,10); 5×10−3 ng (lanes 4,11); 5×10−4 ng (lanes 5,12); 5×10−5 ng (lanes 6,13); 5×10−6 ng (lanes 7,14). Lane 15 represents PCR amplifications without adding DNA, and lane 16 represents PCR amplifications using plasmid pCR™ 2.1-TOPO B. bovis-rap-1 (U) or plasmid pCR™ 2.1-TOPO B. bovis-rra-1 (L) as positive controls. b. The two PCR methods used were based on the B. bovis rap-1 (U) and on the rra (L) genes. The amounts of DNA amplified were 5 ng (lanes 1,10); 5×10−1 ng (lanes 2,11); 5×10−2 ng (lanes 3,12); 5×10−3 ng (lanes 4,13); 5×10−4 ng (lanes 5,14); 5×10−5 ng (lanes 6,15); 5×10−6 ng (lanes 7,16); 5×10−7 ng (lanes 8,17); and 5×10−8 ng (lanes 9,18). Lane 19 represents PCR amplification without adding DNA, and lane 20 represents PCR amplifications using plasmid pCR™ 2.1-TOPO B. bovis-rap-1 (U) or plasmid pCR™ 2.1-TOPO B. bovis-rra-1 (L) as positive controls. Molecular size ladder in base pair (bp), 100 bp DNA ladder (lane m). The amplicons of interest are indicated at the left

The data shown in the upper panel of the gel in Fig. 3a depicts nested PCR amplification using the rap-1c primer sets performed on 5 ng of in vitro cultured B. bigemina gDNA, where lanes 2-9 represent identical PCR amplifications performed on serial 10-fold dilutions from this material. The lower panel of the gel shows the data obtained from nested PCR amplifications performed on identical ten-fold dilutions in vitro cultured infected erythrocytes, but using the previously described by Figueroa et al primer set [28]. All experiments were performed in duplicate. Overall, the data suggests that both PCR methods have similar limits for the detection of B. bigemina in in vitro cultured parasites, consistently detecting up to 5x10−4 ng of gDNA. We also compared the performance of these two B. bigemina nPCR amplification methods on an identical set of target genomic DNAs extracted from a B. bigemina infected bovine with an unknown parasitemia. None of these PCR methods generated PCR products when used on purified bovine gDNA and sequencing of the nPCR products of 236 and 170 bps confirmed specificity of the assays. However, the data in Fig. 3b shows that the PCR products generated using the B. bigemina rap-1c nPCR primer set on the DNA extracted from the experimentally infected animals were better visualized than the previously published B. bigemina primer set [28]. Overall, the two PCR procedures tested for the amplification of B. bigemina DNA showed similar levels of sensitivity and specificity. Yet, because better PCR product visualization in gels was obtained using the rap-1c-based PCR method, we decided to use this method for the molecular detection of B. bigemina field samples derived from cattle from distinct areas in Egypt, as described below.

Fig. 3
figure 3

Agarose gel electrophoresis separation of PCR products of the Babesia bigemina PCR detection methods: Two replica comparisons of the relative sensitivity of the nested PCR and semi-nested PCR methods for the detection of B. bigemina DNA using genomic DNA extracted from in vitro cultured parasites from the B. bigemina Puerto Rico strain (A) and from an experimentally infected bovine with the B. bigemina Puerto Rico strain (B). a. The two PCR methods used were based on the amplification of a B. bigemina specific (U) and on the rap-1c (L) genes. The amounts of DNA amplified were 5 ng (lanes 1 and 8); 5×10−1 ng (lanes 2,8); 5×10−2 ng (lanes 3,9); 5×10−3 ng (lanes 4,10); 5×10−4 ng (lanes 5, 11); 5×10−5 ng (lanes 6,12); and 5×10−6 ng (lanes 7,13); lane 14 represents PCR amplifications without adding DNA, and lane 16 represents PCR amplifications using plasmid pCR™ 2.1-TOPO B. bigemina-1 (U) or plasmid pCR™ 2.1-TOPO B. bigemina-rap-1c (L) as positive controls. b. The two PCR methods used were based on the B. bigemina gene (U) and on the rap-1c (L) genes. The amounts of DNA amplified were 5 ng (lanes 1,10); 5x10−1 ng (lanes 2,11); 5×10−2 ng (lanes 3,12); 5×10−3 ng (lanes 4,13); 5×10−4 ng (lanes 5,14); 5×10−5 ng (lanes 6,15); 5×10−6 ng (lanes 7,16); 5×10−7 ng (lanes 8,17); and 5×10−8 ng (lanes 9, 18). Lane 19 represents PCR amplification without adding DNA, and lane 20 represents PCR amplifications using plasmid pCR™ 2.1-TOPO B. bigemina (U) or plasmid pCR™ 2.1-TOPO B. bigemina-rap-1 (L) as positive controls. Molecular size ladder in base pair (bp), 100 bp DNA ladder (lane m). The amplicons of interest are indicated at the left

The rap-1c B. bigemina and rra B. bovis based PCR methods described above were used to detect the presence of B. bigemina and B. bovis on total genomic DNA blood samples of cattle (n = 253) and buffaloes (n = 81). Fifteen percent of the cattle samples and 3.7 % of the buffaloes samples tested were found positive for B. bovis using snPCR. The percent of infection with B. bigemina calculated in cattle using nPCR was 32.4 %, whereas none of the buffalo samples were positive in nPCR for B. bigemina. In addition, mixed infection with B. bigemina and B. bovis was found in 8.7 % of cattle samples (Tables 2 and 3).

Sequencing of the 236 nucleotides long nPCR amplicons originating from the samples positive for B. bigemina revealed 100 % identity with the expected B. bigemina rap-1c gene of the strain S1A. In addition, the 283 nucleotide snPCR products positive for B. bovis were also 100 % identical to the sequence in the B. bovis rra gene. Sequences originating from the Egyptian positive samples were deposited in GenBank with accession number: KM212998 for B. bigemina, and KM213000 for B. bovis.

Hematological findings

The data for the hematological analysis performed on control non-infected and naturally Babesia sp-infected cattle and buffaloes detected by different techniques are illustrated in Tables 4 and 5.

Table 4 Hematological profiles in non-infected and Babesia sp infected, cattle as detected by different methods
Table 5 Hematological profiles in non-infected and Babesia sp infected buffaloes as detected by different methods

Compared to the control non-infected group, there was a significant decrease in the mean levels of RBCs, HCT%, Hb and MCHC in the samples derived from Babesia sp.-infected cattle, regardless of the method of detection (blood film, cELISA, PCR, or all of them combined). In contrast, MCV values were found increased in the infected group compared to the control group regardless of the method of detection. The result suggests that Babesia caused macrocytic hypochromic anemia in the persistently infected animals. In addition, the Babesia sp.-infected animals had, on average, significant reduced platelet counts (Table 4).

In infected groups of cattle with Babesia sp., as detected by blood film, total leukocyte count (WBCs) and granulocytic counts (neutrophils, eosinophils and basophils) were markedly increased compared to the control non-infected group. On the other hand, there was a decrease in lymphocytic count in infected groups with Babesia sp. detected by PCR and all other diagnostic methods (Blood film + cELISA + PCR) compared to the control group. Additionally, no significant changes in the count of MID cell were recorded in all groups (Table 4).

Interestingly, no significant differences were found in any of these blood parameters among buffaloes naturally infected with Babesia sp. and the control non-infected group (Table 5).

Discussion

Bovine and buffalo babesiosis remains neglected in Egypt, since its incidence and overall impact remains poorly assessed, and no preventive control measures, including the use of attenuated vaccines, are applied currently.

Our direct blood film microscopic examination data is generally consistent with previous reports of the presence of bovine babesiosis in distinct regions in Egypt, such as 12.5 % in Cairo [5], 11.1 % in Gharbia Governorate [30], 13 % in Giza Governorate [31], 13 % in Port Said Governorate [32]. Abd-El-Gawad [33] and Mazyad and Khalaf [34] reported 9.9 % in Beni-Suef Governorate and 8.1 % in North Sinai Governorate.

Competitive ELISA is an adequate serological tool for the epidemiological surveillance of the spread of bovine babesiosis, as it can be easily standardized, is less subjective and less time-consuming than the traditionally used IFAT. In addition, cELISA has the potential to display higher specificity than an indirect ELISA [35]. In the current study, the cELISA assays detected a higher number of infected animals than the PCR assays; this could be explained by differences in the timing of the parasite presence and the antibody responses in the infected animals as well as the stage of infections [36, 37]. Consistently, similar studies such as those by Ibrahim et al. [38], Silva et al. [39] in Portugal, Terkawi et al [40] in Thailand and Dominguez et al [35] in Argentina, recorded higher babesiosis infection rates when using ELISA assays compared to that using nPCR methods. Yet, the combination of serologic testing and PCR is considered to offer the greatest sensitivity for babesiosis diagnosis especially through the sub-clinical phase.

Results in the current study, suggests that B. bigemina infections in bovines are more frequent than B. bovis, which is consistent with previous surveys performed in other locations in Africa. Furthermore, a similar finding has been observed by Ibrahim et al [38], who reported that B. bigemina is more prevalent than B. bovis in Egypt. It is possible that B. bigemina is more prevalent than B. bovis due likely in part to the pattern of geographic distribution of the R. annulatus tick vectors [41], added to the fact that the prevalence of B. bigemina is higher than B. bovis in this vector in Egypt [5]. We also found a significant number of animals that were co-infected with B. bovis and B. bigemina. This is not surprising, since similar co-infections are commonly reported in endemic areas, and is in part justified by both parasites sharing the same tick vectors. However, transmission of these two parasites by Rhiphicephalus sp. ticks is by different mechanisms. While B. bovis is transmitted by the larval stage of the ticks, B. bigemina is transmitted by the nymph tick stages. Some previous reports suggested that priming the bovine immune system by infection with B. bigemina could protect animals of future co-infections with B. bovis. Because ticks can also be co-infected, it can be speculated that co-infected animals receive both parasites simultaneously, before they were able to mount cross-protective immune responses that would prevent super-infections [42].

In this study we developed novel snPCR and nPCR methods based on the recently described B. bovis rra gene [26] and B. bigemina rap-1c gene [25], respectively. Sequence comparisons demonstrated that these two genes are highly conserved among distinct strains worldwide, and, importantly, as these two genes are species-specific, they may be better candidates for PCR-based diagnosis of bovine babesiosis. In addition, these two genes generate transcripts in the blood stages of the parasites in a tightly regulated fashion, yet they appear to be expressed in minute amounts [25, 26]. This feature, at least in theory, minimizes the possibility for sequence variation due to immune pressure, and further supports the use of these two genes as ideal targets for developing PCR reactions with diagnostic applications. Additionally, comparisons performed using the new tests with the previously developed nPCR methods, show similar performances in terms of sensitivity and specificity; however, the PCR products are more clearly visualized upon performing both novel PCR tests. Furthermore, searches of the buffalo and bovine genomes demonstrate lack of significant identity of the nPCR primers and full target genes with any bovine or buffalo genes (data not shown), thus diminishing the risk of potential interferences and/or non-specific PCR amplifications. The PCR results obtained regarding the presence of B. bovis in cattle in our study are similar to those of Adam et al [5], Rania [43] and El-Fayomi et al [31] who reported 20 %, 25.33 % and 23 % infection rates in Egypt, respectively. Also, Silva et al [39] in Portugal, Chaudry et al [44] in Pakistan and Longzheng et al [45] in Philippines used nPCR methods for diagnosis of Babesia sp. in cattle, and found infection rates of 78.5 %, 29 % and 18.8 %, respectively. However, percentages of B. bovis infected buffaloes in our dataset, as detected by PCR, were higher than previously published for samples analyzed from other Egyptian herds. These variations in the prevalence rates are expectable due to geographic diversity and other environmental factors that can influence the population densities of the tick vectors [46]. It is well known that increases in temperature and changes in environmental humidity may influence the migration of vectors into new areas, and/or allow significant development of parasites [31, 47].

Interestingly, despite the identification of buffaloes infected by B. bigemina using the cELISA serological method and the presence of infected erythrocytes in the stained slides, B. bigemina infections in buffaloes were not detected by the PCR method. On one hand, these observations suggest that the parasites found in the direct microscopy analysis of the buffalo samples are likely B. bovis. On the other hand, these data also suggests that the numbers of B. bigemina parasites circulating in infected buffaloes may be below the level of detection of the PCR methods, or alternatively, that these B. bigemina infected buffaloes successfully cleared the parasites at the time of the samplings. Consistently, and in contrast to B. bovis, B. bigemina parasites do not sequester in capillaries, and bovines are able to clear B. bigemina faster than B. bovis. Also, these data is in agreement with a recent survey performed in Egypt using a PCR method which failed to identify a single B. bigemina infected buffalo using PCR assays in a sample of 50 animals from different locations [11]. It follows that B. bigemina infections in buffaloes might perhaps be more accurately performed using serological, rather than molecular methods, and that, in contrast to B. bovis, buffaloes might not be highly significant as potential reservoirs of B. bigemina in Egypt.

Hematological findings in this study revealed a marked decrease in the mean levels of RBCs, HCT%, Hb and MCHC and increase in MCV values in cattle infected with B. bovis and/or B. bigemina regardless of the method of detection (Blood film, cELISA, and PCR) used in this study, and even assuming that these parameters can be affected in these animals due to other unknown reasons different from Babesia infections. However, this is an unlikely occurrence, since the non-infected population consistently shows hematological values that are in the normal range. Collectively, these results revealed that B. bovis and/or B. bigemina likely caused macrocytic hypochromic anemia, indicative of severe intravascular hemolysis of red blood cells in cattle affected with persistent babesiosis [38, 48, 49]. These may be due to the fact that although Babesia sp. may cause direct damage on some erythrocytes, immune-mediated injury of parasite may be more important in the pathogenesis of anemia [7]. Yet, the increase in erythrophagocytosis by activated macrophages [50, 51] and the production of anti-erythrocyte antibodies [8] may also contribute to the development of anemia.

The reduced platelet counts (thrombocytopenia) were noted in B. bovis and/or B. bigemina infected cattle with acute, chronic and sub-acute stages of babesiosis, as detected by all the diagnostic methods used in this study (blood film, cELISA, PCR, Blood film + cELISA + PCR). Thrombocytopenia is usually present with protozoal infections of erythrocytes. The increased platelet consumption may be attributed to an immune-mediated process, or it can result from intravascular disseminated coagulation in severe disorders [52, 53]. However, thrombocytopenia is more often associated with increased phagocytosis of platelets in response to antibodies on their surfaces and/or because of macrophage activation by inflammatory cytokines such as macrophage colony-stimulating factor (M-CSF) and Interferon gamma (IFN-γ) [54]. Consistently, splenomegaly, which is concurrent with many parasitic tick-borne diseases, may also be associated with increased platelet sequestration and destruction by splenic macrophages [9].

The increase in total leukocyte count (WBCs) and granulocytic counts found in cattle infected with B. bovis and/or B. bigemina as detected by blood film (acute stage of babesiosis) compared to control group together with decrease in lymphocyte counts in the groups infected with Babesia, when compared to the control group are in agreement with results previously reported by Court et al. [51]. These authors also proposes that the significant increase in neutrophils of cattle infected with B. bovis could be attributed to their role as active mediators in the innate immune response. Taken together the observations derived from the hematological studies collected in this study can help to assess the overall impact of babesiosis on the health of the cattle and buffalo populations exposed to babesiosis in Egypt.

Remarkably, no such significant hematological changes were recorded in buffaloes naturally infected with B. bovis and/or B. bigemina in acute, chronic and sub-acute stages of babesiosis. Similar results were reported by Mahmmod [55], who recorded that buffaloes infected with B. bovis have less significant hematological changes than cattle infected with the same parasite. These observations, added to the inability of the nPCR to detect B. bigemina infections in buffaloes are consistent with the perceived decreased susceptibility of buffalos to Babesia infections.

Conclusions

We estimated high presence of babesiosis caused by B. bovis and B. bigemina in a diverse population of bovines in Egypt using distinct diagnostic classic, serological and novel molecular approaches. The cELISA data suggests that both parasites are able to circulate among both, bovines and buffalo herds in Egypt, perhaps due to sharing vectors competent for the transmission of both B. bovis and B. bigemina parasites. Hematological profiles in bovines indicate that infected populations present hematological disorders compatible with intravascular hemolysis and thrombocytopenia regardless of the stage of the disease. However, hematological changes were less evident in buffaloes naturally infected with Babesia sp. when compared to cattle.

Abbreviations

B. bovis :

Babesia bovis

B. bigemina :

Babesia bigemina

EDTA:

Ethylene diamine tetra-acetic acid

IFAT:

Indirect fluorescent antibody test

ELISA:

Enzyme-linked immune-sorbent assay

cELISA:

competitive ELISA

gDNA:

Genomic DNA

PCR:

Polymerase chain reaction

nPCR:

Nested PCR

snPCR:

Semi-nested PCR

rap-1c:

rhoptry associated protein-1c

rra:

rap-1 related antigen

fg:

femtograms

O.D.:

Optical density

RBC:

Red blood cell count

HCT:

Hematocrite

Hb:

Hemoglobin

MCV:

Mean corpuscular volume

MCH:

Mean corpuscular hemoglobin

MCHC:

Mean corpuscular hemoglobin concentration

RDWA:

Red blood cell distribution width absolute

RDW%:

Red cell distribution width percentage

WBC:

White blood cell count

MID:

Mid cells

PLT:

Platelet count

MPV:

Mean platelet volume

PDW:

Platelet distribution width

PCT:

Plateletcrit

LPCR:

Large platelet concentration ratio

ME:

Microscopy examination

PPE:

Percentage of parasitized erythrocytes

References

  1. Zintl A, Mulcahy G, Skerrett HE, Taylor SM, Gray JS. Babesia divergens, a bovine blood parasite of veterinary and zoonotic importance. Clin Microbiol Rev. 2003;16(4):622–36.

    Article  PubMed Central  PubMed  Google Scholar 

  2. Mosqueda J, Olvera-Ramirez A, Aguilar-Tipacamu G, Canto GJ. Current advances in detection and treatment of babesiosis. Curr Med Chem. 2012;19(10):1504–18.

    Article  CAS  PubMed Central  PubMed  Google Scholar 

  3. Spickler ARaJA R. Emerging and Exotic Diseases of Animal, 3rd ed. Ames, Iowa: CFSPH Iowa State University; 2008. p. 132–5.

    Google Scholar 

  4. Lozano DFA. Modelling of Parasitic Diseases with Vector OF Transmission: Toxoplasmosis and Babesiosis Bovine. Departamento de Matematica Aplicada: Universidad Politecnica de Valenci; 2011.

    Google Scholar 

  5. Adham FK, Abd-el-Samie EM, Gabre RM, El-Hussein H. Detection of tick blood parasites in Egypt using PCR assay I--Babesia bovis and Babesia bigemina. Parasitol Res. 2009;105(3):721–30.

    Article  CAS  PubMed  Google Scholar 

  6. Abdel-Shafy S, Mona S. Mahmoud: Morphological and ultrastructural studies on Babesia bigemina local strain in haemolymph and salivary glands of infected Boophilus annulatus females. J Egypt Vet Med Assoc. 2002;62(6):247–56.

    Google Scholar 

  7. Messick JB. Hemotrophic mycoplasmas (hemoplasmas): a review and new insights into pathogenic potential. Veterinary clinical pathology/American Society for Veterinary Clinical Pathology. 2004;33(1):2–13.

    Article  PubMed  Google Scholar 

  8. Goes TS, Goes VS, Ribeiro MF, Gontijo CM. Bovine babesiosis: anti-erythrocyte antibodies purification from the sera of naturally infected cattle. Vet Immunol Immunopathol. 2007;116(3-4):215–8.

    Article  CAS  PubMed  Google Scholar 

  9. LP. Mechanisms of Thrombocytopenia in Tick-Borne Diseases. Internet J Infect Dis. 2002;2(2). https://ispub.com/IJID/2/2/3023

  10. Mahmmod YS. Molecular detection of natural Babesia bovis infectioon from clinically infected and apparently healthy water buffaloes (Bubalis bubalis) and crossbred cattle. J Buffalo Sci. 2012;1:55–60.

    CAS  Google Scholar 

  11. Elsify A, Sivakumar T, Nayel M, Salama A, Elkhtam A, Rizk M, et al. An epidemiological survey of bovine Babesia and Theileria parasites in cattle, buffaloes, and sheep in Egypt. Parasitol Int. 2014;64(1):79–85.

    Article  PubMed  Google Scholar 

  12. Bashir HA. Modeling of development time for hydro electric generators using factor and multiple regression analyses. J Project Manage. 2008;26:457–64.

    Article  Google Scholar 

  13. Bose R, Jorgensen WK, Dalgliesh RJ, Friedhoff KT, de Vos AJ. Current state and future trends in the diagnosis of babesiosis. Vet Parasitol. 1995;57(1-3):61–74.

    Article  CAS  PubMed  Google Scholar 

  14. Salih DA, El Hussein AM, Seitzer U, Ahmed JS. Epidemiological studies on tick-borne diseases of cattle in Central Equatoria State, Southern Sudan. Parasitol Res. 2007;101(4):1035–44.

    Article  CAS  PubMed  Google Scholar 

  15. Jacobson LS. The South African form of severe and complicated canine babesiosis: clinical advances 1994-2004. Vet Parasitol. 2006;138(1-2):126–39.

    Article  PubMed  Google Scholar 

  16. Araujo FR, Madruga CR, Leal CR, Schenk MA, Kessler RH, Marques AP, et al. Comparison between enzyme-linked immunosorbent assay, indirect fluorescent antibody and rapid conglutination tests in detecting antibodies against Babesia bovis. Vet Parasitol. 1998;74(2-4):101–8.

    Article  CAS  PubMed  Google Scholar 

  17. Goff WL, Molloy JB, Johnson WC, Suarez CE, Pino I, Rhalem A, et al. Validation of a competitive enzyme-linked immunosorbent assay for detection of antibodies against Babesia bovis. Clin Vaccine Immunol. 2006;13(11):1212–6.

    Article  CAS  PubMed Central  PubMed  Google Scholar 

  18. Goff WL, McElwain TF, Suarez CE, Johnson WC, Brown WC, Norimine J, et al. Competitive enzyme-linked immunosorbent assay based on a rhoptry-associated protein 1 epitope specifically identifies Babesia bovis-infected cattle. Clin Diagn Lab Immunol. 2003;10(1):38–43.

    CAS  PubMed Central  PubMed  Google Scholar 

  19. Goff WL, Johnson WC, Molloy JB, Jorgensen WK, Waldron SJ, Figueroa JV, et al. Validation of a competitive enzyme-linked immunosorbent assay for detection of Babesia bigemina antibodies in cattle. Clin Vaccine Immunol. 2008;15(9):1316–21.

    Article  CAS  PubMed Central  PubMed  Google Scholar 

  20. Sharma A, Das Singla L, Tuli A, Kaur P, Batth BK, Javed M, et al. Molecular prevalence of Babesia bigemina and Trypanosoma evansi in dairy animals from Punjab, India, by duplex PCR: a step forward to the detection and management of concurrent latent infections. BioMed rsesearch international. 2013;2013:893862.

    Google Scholar 

  21. Fahrimal Y, Goff WL, Jasmer DP. Detection of Babesia bovis carrier cattle by using polymerase chain reaction amplification of parasite DNA. J Clin Microbiol. 1992;30(6):1374–9.

    CAS  PubMed Central  PubMed  Google Scholar 

  22. Figueroa JV, Chieves LP, Johnson GS, Buening GM. Detection of Babesia bigemina-infected carriers by polymerase chain reaction amplification. J Clin Microbiol. 1992;30(10):2576–82.

    CAS  PubMed Central  PubMed  Google Scholar 

  23. Hunfeld KP, Hildebrandt A, Gray JS. Babesiosis: recent insights into an ancient disease. Int J Parasitol. 2008;38(11):1219–37.

    Article  CAS  PubMed  Google Scholar 

  24. Tang YW, Procop GW, Persing DH. Molecular diagnostics of infectious diseases. Clin Chem. 1997;43(11):2021–38.

    CAS  PubMed  Google Scholar 

  25. Suarez CE, Palmer GH, Florin-Christensen M, Hines SA, Hotzel I, McElwain TF. Organization, transcription, and expression of rhoptry associated protein genes in the Babesia bigemina rap-1 locus. Mol Biochem Parasitol. 2003;127(2):101–12.

    Article  CAS  PubMed  Google Scholar 

  26. Suarez CE, Laughery JM, Bastos RG, Johnson WC, Norimine J, Asenzo G, et al. A novel neutralization sensitive and subdominant RAP-1-related antigen (RRA) is expressed by Babesia bovis merozoites. Parasitology. 2011;138(7):809–18.

    Article  CAS  PubMed  Google Scholar 

  27. Suarez CE, Laughery JM, Schneider DA, Sondgeroth KS, McElwain TF. Acute and persistent infection by a transfected Mo7 strain of Babesia bovis. Mol Biochem Parasitol. 2012;185(1):52–7.

    Article  CAS  PubMed  Google Scholar 

  28. Figueroa JV, Chieves LP, Johnson GS, Buening GM. Multiplex polymerase chain reaction based assay for the detection of Babesia bigemina, Babesia bovis and Anaplasma marginale DNA in bovine blood. Vet Parasitol. 1993;50(1-2):69–81.

    Article  CAS  PubMed  Google Scholar 

  29. Snedecor GW. CWG: Statistical Methods. 7th ed. Iowa: The State University Press American; 1989.

    Google Scholar 

  30. El-Ghaysh A. Studies on Babesia species infecting cattle and water Buffaloes in Egypt, PhDVSc. Egypt: Faculty of Veterinary Medicine, Cairo University; 1993.

    Google Scholar 

  31. El-Fayomy AO, Ghoneim AM, Abu-Samak OA, Khidr AA. Contribution of Babesia to the Illness of Cows in Port Said Governorate. Egypt Glob Vet. 2013;11:118–22.

    Google Scholar 

  32. Adel EM. Studies on some blood parasites infecting farm animals in Gharbia Governorate, PhD thesis. Cairo, Egypt: Faculty of Veterinary Medicine, Cairo University; 2007.

    Google Scholar 

  33. Abd-El Gawad M. Some studies on Babesia species in cattle in Beni-Suef governorate, PhD Thesis. Cairo, Egypt: Faculty of Veterinary Medicine, Cairo University; 1993.

    Google Scholar 

  34. Mazyad SA, Khalaf SA. Studies on theileria and babesia infecting live and slaughtered animals in Al Arish and El Hasanah, North Sinai Governorate, Egypt. J Egypt Soc Parasitol. 2002;32(2):601–10.

    PubMed  Google Scholar 

  35. Dominguez M, Echaide I, de Echaide ST, Wilkowsky S, Zabal O, Mosqueda JJ, et al. Validation and field evaluation of a competitive enzyme-linked immunosorbent assay for diagnosis of Babesia bovis infections in Argentina. Clin Vaccine Immunol. 2012;19(6):924–8.

    Article  CAS  PubMed Central  PubMed  Google Scholar 

  36. Ibrahim HMAMP, Mohammed-Gebaa K, Sheira SK, Ihab SY, Hashemc S, Caob MA, et al. Molecular and serological prevalence of Babesia bigemina and Babesia bovis in cattle and water buffalos under small-scale dairy farming in Beheira and Faiyum Provinces. Egypt Vet Parasitol. 2013;198:187–92.

    Article  CAS  Google Scholar 

  37. Bock R, Jackson L, de Vos A, Jorgensen W. Babesiosis of cattle. Parasitology. 2004;129(Suppl):S247–69.

    Article  PubMed  Google Scholar 

  38. Ibrahim A, EL Behairy AM, Mahran KA, Awad WS. Clinical and laboratory diagnosis of piroplasmids in naturally infected cattle in Egypt. J Egypt Vet Med Assoc. 2009;69:191–203.

    Google Scholar 

  39. Silva MG, Henriques G, Sanchez C, Marques PX, Suarez CE, Oliva A. First survey for Babesia bovis and Babesia bigemina infection in cattle from Central and Southern regions of Portugal using serological and DNA detection methods. Vet Parasitol. 2009;166(1-2):66–72.

    Article  CAS  PubMed  Google Scholar 

  40. Terkawi MA, Thekisoe OM, Katsande C, Latif AA, Mans BJ, Matthee O, et al. Serological survey of Babesia bovis and Babesia bigemina in cattle in South Africa. Vet Parasitol. 2011;182(2-4):337–42.

    Article  PubMed  Google Scholar 

  41. World Organization for Animal Health [OIE]. Bovine babesiosis. http://www.oie.int/fileadmin/Home/eng/Health_standards/tahm/2.04.02_BOVINE_BABESIOSIS.pdf. (Online) 2008.

  42. Wright IG, Goodger BV, Leatch G, Aylward JH, Rode-Bramanis K, Waltisbuhl DJ. Protection of Babesia bigemina-immune animals against subsequent challenge with virulent Babesia bovis. Infect Immun. 1987;55(2):364–8.

    CAS  PubMed Central  PubMed  Google Scholar 

  43. Rania YE. Some studies on diagnosis on babesiosis, MVSc thesis. Benha, Egypt: Faculty of Veterinary Medicine, Benha University; 2009.

    Google Scholar 

  44. Chaudhry ZI, Suleman M, Younus M, Aslim A. Molecular Detection of Babesia bigemina and Babesia bovis in Crossbred Carrier Cattle through PCR. Pakistan J Zool. 2010;42:201–4.

    CAS  Google Scholar 

  45. Yu L, Terkawi MA, Cruz-Flores MJ, Claveria FG, Aboge GO, Yamagishi J, et al. Epidemiological survey of Babesia bovis and Babesia bigemina infections of cattle in Philippines. The Journal of veterinary medical science/the Japanese Society of Veterinary Science. 2013;75(7):995–8.

    Article  PubMed  Google Scholar 

  46. L’Hostis M, Seegers H. Tick-borne parasitic diseases in cattle: current knowledge and prospective risk analysis related to the ongoing evolution in French cattle farming systems. Vet Res. 2002;33(5):599–611.

    Article  PubMed  Google Scholar 

  47. Coles GC. The future of veterinary parasitology. Vet Parasitol. 2001;98(1-3):31–9.

    Article  CAS  PubMed  Google Scholar 

  48. Zulfiqar S, Shahnawaz S, Ali M, Bhutta AM, Iqbal S, Hayat S, et al. Detection of Babesia bovis in blood samples and its effect on the hematological and serum biochemical profile in large ruminants from Southern Punjab. Asian Pacific journal of tropical biomedicine. 2012;2(2):104–8.

    Article  CAS  PubMed Central  PubMed  Google Scholar 

  49. Pandy NaM S. Haematological and Biochemical response to haemolytic anaemia of clinical Babesiosis in cattle and therapy. Ind Vet J. 1987;64:882–6.

    Google Scholar 

  50. Murase TaM Y. Increased erythophagocytosis activity of macrophages in dogs with Babesia gibsoni infection. Nippon Juigaku Zasshi. 1990;52:321–7.

    Article  Google Scholar 

  51. Court RA, Jackson LA, Lee RP. Elevated anti-parasitic activity in peripheral blood monocytes and neutrophils of cattle infected with Babesia bovis. Int J Parasitol. 2001;31(1):29–37.

    Article  CAS  PubMed  Google Scholar 

  52. Taboada JaL R. Babesiosis. In: Greene CE, editor. Infectious diseases of the dog and Cat. 3rd ed. St Louis: Saunders Elsevier; 2006. p. 722–36.

    Google Scholar 

  53. Riond BMM, Braun U, Deplazes P, Joerger K, Thoma R, Lutz H, et al. Concurrent infections with vector-borne pathogens associated with fatal anaemia in cattle: Haematology and blood chemistry. Comp Clin Pathol. 2008;17(3):171–7.

    Article  Google Scholar 

  54. Musaji A, Cormont F, Thirion G, Cambiaso CL, Coutelier JP. Exacerbation of autoantibody-mediated thrombocytopenic purpura by infection with mouse viruses. Blood. 2004;104(7):2102–6.

    Article  CAS  PubMed  Google Scholar 

  55. Mahmmod Y. Natural Babesia bovis Infection in Water Buffaloes (Bubalus bubalis) and Crossbred Cattle under Field Conditions in Egypt: a Preliminary Study. J Arthropod-Borne Dis. 2014;8(1):1–9.

    PubMed Central  PubMed  Google Scholar 

Download references

Acknowledgements

This work was supported by the USAID Grant 3866 funded through the STDF. We are thankful to Dr. Chungwon Chung and Dr. Scott Adams from VMRD (Pullman, WA) for kindly providing the cELISA kits used for the serological diagnosis of bovine and buffalo babesiosis, to Paul Lacy for technical help in the development of the PCR reactions and to Jacob Laughery for technical help. We also would like to thank Dr. Don Knowles for facilitating the development of this project.

Author information

Authors and Affiliations

Authors

Corresponding author

Correspondence to Marta G. Silva.

Additional information

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

MM, CES and MGS designed the study and wrote the manuscript. MM, OK, SAN, SHH, SH and DM collected the blood samples from the cattle and buffaloes (Cairo, Behaira and Kafr El-Sheikh governments). OK, SHH and SH performed the cELISA and the DNA extractions. OK and DM performed the PCR. SAN performed the hematological analysis and statistical analysis. All authors read and approved the final version of the manuscript.

Rights and permissions

Open Access  This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.

The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder.

To view a copy of this licence, visit https://creativecommons.org/licenses/by/4.0/.

The Creative Commons Public Domain Dedication waiver (https://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Mahmoud, M.S., Kandil, O.M., Nasr, S.M. et al. Serological and molecular diagnostic surveys combined with examining hematological profiles suggests increased levels of infection and hematological response of cattle to babesiosis infections compared to native buffaloes in Egypt. Parasites Vectors 8, 319 (2015). https://doi.org/10.1186/s13071-015-0928-9

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://doi.org/10.1186/s13071-015-0928-9

Keywords