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RON2, a novel gene in Babesia bigemina, contains conserved, immunodominant B-cell epitopes that induce antibodies that block merozoite invasion

Published online by Cambridge University Press:  13 September 2019

Juan Mosqueda*
Affiliation:
Immunology and Vaccines Laboratory. Facultad de Ciencias Naturales, Universidad Autónoma de Querétaro, Querétaro, Qro, Mexico
Mario Hidalgo-Ruiz
Affiliation:
Immunology and Vaccines Laboratory. Facultad de Ciencias Naturales, Universidad Autónoma de Querétaro, Querétaro, Qro, Mexico
Diana Alexandra Calvo-Olvera
Affiliation:
Immunology and Vaccines Laboratory. Facultad de Ciencias Naturales, Universidad Autónoma de Querétaro, Querétaro, Qro, Mexico
Diego Josimar Hernandez-Silva
Affiliation:
Immunology and Vaccines Laboratory. Facultad de Ciencias Naturales, Universidad Autónoma de Querétaro, Querétaro, Qro, Mexico
Massaro Wilson Ueti
Affiliation:
U. S. Department of Agriculture, Animal Disease Research Unit, Agricultural Research Service, Pullman, WA, 99164, USA
Miguel Angel Mercado-Uriostegui
Affiliation:
Immunology and Vaccines Laboratory. Facultad de Ciencias Naturales, Universidad Autónoma de Querétaro, Querétaro, Qro, Mexico
Angelina Rodriguez
Affiliation:
Facultad de Ciencias Naturales, Universidad Autónoma de Querétaro, Querétaro, Qro, Mexico
Juan Alberto Ramos-Aragon
Affiliation:
CENID-Parasitologia-INIFAP, Morelos, Mexico
Ruben Hernandez-Ortiz
Affiliation:
CENID-Parasitologia-INIFAP, Morelos, Mexico
Shin-ichiro Kawazu
Affiliation:
National Research Center for Protozoan Diseases, Obihiro University of Agriculture and Veterinary Medicine, Inada, Obihiro, Japan
Ikuo Igarashi
Affiliation:
National Research Center for Protozoan Diseases, Obihiro University of Agriculture and Veterinary Medicine, Inada, Obihiro, Japan
*
Author for correspondence: Juan Mosqueda, E-mail: joel.mosqueda@uaq.mx

Abstract

Bovine babesiosis is the most important protozoan disease transmitted by ticks. In Plasmodium falciparum, another Apicomplexa protozoan, the interaction of rhoptry neck protein 2 (RON2) with apical membrane antigen-1 (AMA-1) has been described to have a key role in the invasion process. To date, RON2 has not been described in Babesia bigemina, the causal agent of bovine babesiosis in the Americas. In this work, we found a ron2 gene in the B. bigemina genome. RON2 encodes a protein that is 1351 amino acids long, has an identity of 64% (98% coverage) with RON2 of B. bovis and contains the CLAG domain, a conserved domain in Apicomplexa. B. bigemina ron2 is a single copy gene and it is transcribed and expressed in blood stages as determined by RT-PCR, Western blot, and confocal microscopy. Serum samples from B. bigemina-infected bovines were screened for the presence of RON2-specific antibodies, showing the recognition of conserved B-cell epitopes. Importantly, in vitro neutralization assays showed an inhibitory effect of RON2-specific antibodies on the red blood cell invasion by B. bigemina. Therefore, RON2 is a novel antigen in B. bigemina and contains conserved B-cell epitopes, which induce antibodies that inhibit merozoite invasion.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Authors 2019

Introduction

Bovine babesiosis is the most important protozoan disease transmitted by ticks. It is caused by intraerythrocytic parasites of the genus Babesia that belong to the phylum Apicomplexa. This phylum also includes numerous other pathogens of veterinary and medical importance, for example, Plasmodium spp., Eimeria spp., and Toxoplasma gondii. Apicomplexans are characterized by the presence of apical organelles loaded with molecules that facilitate invasion or escape from host cells (Bock et al., Reference Bock, Jackson, De Vos and Jorgensen2004; Schnittger et al., Reference Schnittger, Rodriguez, Florin-Christensen and Morrison2012; Yabsley and Shock, Reference Yabsley and Shock2013). Babesia sporozoites directly invade bovine red blood cells (RBCs), and by binary fission, each develops into two merozoites, which eventually escape from the RBCs into the bloodstream. Each merozoite infects a new RBC to continue the replication cycle (Potgieter and Els, Reference Potgieter and Els1977, Reference Potgieter and Els1979; Gohil et al., Reference Gohil, Kats, Seemann, Fernandez, Siddiqui and Cooke2013). The invasion process consists of four steps: (1) parasite attachment to an RBC; (2) merozoite reorientation, which brings the apical organelles close to the attachment interface; (3) RBC membrane penetration, involving various molecular interactions of the protozoan ligands with the target receptors of the host cell surface; and (4) merozoite internalization. The process is completed when the parasite is inside the RBC (Dubremetz et al., Reference Dubremetz, Garcia-Réguet, Conseil and Fourmaux1998; Soldati et al., Reference Soldati, Dubremetz and Lebrun2001; Yokoyama et al., Reference Yokoyama, Okamura and Igarashi2006). In each step of the invasion process, Babesia parasites secrete proteins from the apical organelles (rhoptries, micronemes, and spherical bodies) towards the invagination site to form moving junctions to the RBC membrane (Yokoyama et al., Reference Yokoyama, Okamura and Igarashi2006). To date, there are few proteins characterized in Babesia species involved in this step of the process. In Plasmodium falciparum, AMA-1 is translocated onto the merozoite surface where it can interact with the rhoptry neck protein 2 (RON2), forming a structure known as a ‘moving junction’ (MJ), an irreversible step that commits the parasite to invasion. It is postulated that formation of the MJ is initiated when RON2 is secreted from the rhoptries in a complex formed of RON4, 5, and 8 (Alexander et al., Reference Alexander, Mital, Ward, Bradley and Boothroyd2005; Straub et al., Reference Straub, Cheng, Sohn and Bradley2009; Besteiro et al., Reference Besteiro, Dubremetz and Lebrun2011). This complex is discharged towards the RBC, and RON2 is integrated into the RBC membrane where it acts as an AMA-1 ligand on the parasite surface (Silvie et al., Reference Silvie, Franetich, Charrin, Mueller, Siau, Bodescot, Rubinstein, Hannoun, Charoenvit, Kocken, Thomas, van Gemert, Sauerwein, Blackman, Anders, Pluschke and Mazier2004; Shen and Sibley, Reference Shen and Sibley2012). Blocking this interaction halts merozoite invasion, suggesting that RON2 may be a target for vaccine development (Srinivasan et al., Reference Srinivasan, Yasgar, Luci, Beatty, Hu, Andersen, Narum, Moch, Sun, Haynes, Maloney, Jadhav, Simeonov and Miller2013, Reference Srinivasan, Ekanem, Diouf, Tonkin, Miura, Boulanger, Long, Narum and Miller2014; Zhang et al., Reference Zhang, Yin, Li, Wang, Meng and Yin2015; Bittencourt et al., Reference Bittencourt, Leite, Silva, Pimenta, Silva-Filho, Cassiano, Lopes, Dos-Santos, Bourgard, Nakaya, da Silva Ventura, Lacerda, Ferreira, Machado, Albrecht and Costa2018; Salgado-Mejias et al., Reference Salgado-Mejias, Alves, Françoso, Riske, Silva, Miranda and Soares2019). Although RON2 has been described in Babesia divergens, B. microti and B. bovis (Ord et al., Reference Ord, Rodriguez, Cursino-Santos, Hong, Singh, Gray and Lobo2016; Hidalgo-Ruiz et al., Reference Hidalgo-Ruiz, Suarez, Mercado-Uriostegui, Hernandez-Ortiz, Ramos, Galindo-Velasco, León-Ávila, Hernández and Mosqueda2018), to date, there is no evidence of RON2 in other species of Babesia, such as B. bigemina, where the presence of AMA-1 has been reported (Torina et al., Reference Torina, Agnone, Sireci, Mosqueda, Blanda, Albanese, La Farina, Cerrone, Cusumano and Caracappa2010). Therefore, the aims of the present study were (a) to identify a homologue of RON2 in B. bigemina, (b) to evaluate whether RON2 is transcribed and expressed in merozoites, (c) to determine whether bovines from endemic areas generate antibodies that recognize RON2 conserved epitopes, and (d) to determine the neutralizing activity of specific antibodies.

Materials and methods

Identification of the ron2 gene in the Babesia bigemina genome

The Plasmodium falciparum RON2 amino acid (aa) sequence (BAH22615.1) was used as a query in a BLASTP search in the BLAST database of the Sanger Institute against the Babesia bigemina reference genome (https://www.sanger.ac.uk/resources/downloads/protozoa/babesia-bigemina.html) (Altschul et al., Reference Altschul, Gish, Miller, Myers and Lipman1990). The sequence obtained was analyzed with bioinformatics programs with the following purposes: (a) Identify open reading frames using the ORF finder program (Rombel et al., Reference Rombel, Sykes, Rayner and Johnston2002), (b) Determine the signal peptide with the programs SignalP 4.0 (Petersen et al., Reference Petersen, Brunak, von Heijne and Nielsen2011) and SMART (Schultz et al., Reference Schultz, Milpetz, Bork and Ponting1998), (c) Find functional domains and their localization with SMART (Schultz et al., Reference Schultz, Milpetz, Bork and Ponting1998), (d) Assess whether the predicted protein has transmembrane helices with TMHMM (Krogh et al., Reference Krogh, Larsson, von Heijne and Sonnhammer2001), and (e) Determine the isoelectrical point and the molecular weight using the CLC Genomics Workbench 7.5 program.

To sequence the full gene, five pairs of primers were designed to amplify overlapping fragments of B. bigemina ron2 in Oligoanalyzer 3.1 (Owczarzy et al., Reference Owczarzy, Tataurov, Wu, Manthey, McQuisten, Almabrazi, Pedersen, Lin, Garretson, McEntaggart, Sailor, Dawson and Peek2008) using the sequence in the Sanger database as a template (Table 1). The combinations used were Fw0RON2-Rv0RON2, which amplified a 913 bp fragment; Fw1RON2-Rv1RON2, which amplified a 701 bp fragment; Fw2RON2-Rv2RON2, which amplified 1,007 bp; Fw3RON2-Rv3RON2, which amplified a 1,045 bp fragment; and Fw4RON2-Rv4RON2, which amplified 627 bp.

Table 1. Primers designed for the amplification of Babesia bigemina ron2

Blood from a splenectomized steer infected with B. bigemina Chiapas strain was obtained as described previously (Rodríguez-Hernández et al., Reference Rodríguez-Hernández, Mosqueda, Alvarez-Sánchez, Neri, Mendoza-Hernández and Camacho-Nuez2012), and the blood was maintained at −20 °C until used. The DNA was extracted using the illustra blood genomicPrep mini Spin Kit (GE Healthcare, Chicago, Illinois, USA) following the manufacturer's protocol. Prior to sequencing, all amplicons were cloned into the pCR 4-TOPO® vector using the TOPO® TA Cloning® kit (Invitrogen, Carlsbad, California, USA) and transformed into E. coli TOP10 cells following the manufacturer's instructions (Invitrogen). Plasmid DNA was used as a template for Taq FS dye terminator cycle sequencing, which was commercially performed at the Instituto de Biotecnologia, Universidad Nacional Autonoma de Mexico (Cuernavaca, Morelos, Mexico), using an automatic DNA sequencer (model 3130xl, Applied Biosystems, Foster City, California, USA). The B. bigemina Chiapas strain consensus sequence for RON2 was obtained from the assembly of three cloned sequences. The full ron2 gene consensus sequence assembly was performed with the CLC Genomic Workbench 7.5 program, and was used in a BLASTp search. The global identity of this sequence with the sequences that showed a similarity in the BLASTp search was calculated with the Pairwise Sequence Alignment tool EMBOSS Needle.

Transcription analysis

To evaluate the transcription of ron2 in blood stages, intraerythrocytic parasites were obtained by inoculating 7 mL of blood infected with the Chiapas strain of B. bigemina into a splenectomized steer. Five days after the inoculation, the steer was monitored daily, and when the parasitemia reached 4%, determined by microscopic analysis of blood smears stained with Giemsa, whole blood was collected and used for total RNA extraction with Trizol® Reagent (Invitrogen, Carlsbad, California, USA). The mRNA obtained was reverse-transcribed using the Super Script II kit (Invitrogen, Carlsbad, California, USA) according to the manufacturer's protocol. The cDNA was obtained with an oligo-dT primer and amplified using the following protocol: an initial denaturation at 95 °C for 5 min, followed by 30 cycles consisting of denaturation at 94 °C for 1 min, annealing at 50 °C for 30 s, and extension at 72 °C for 1 min, followed by a final extension at 72 °C for 7 min. The primers Fwron2 and Rvron2 were used, which amplified a 380 bp fragment (Table 1). The amplification was visualized by 1.8% agarose gel electrophoresis stained with ethidium bromide. The amplicon obtained was cloned into the pCR 4-TOPO® vector using the TOPO® TA Cloning® kit (Invitrogen, Carlsbad, California, USA) and transformed into E. coli TOP10 cells as described above. Plasmid DNA was sent for commercial sequencing.

Selection of peptides containing B-cell epitopes and generation of antibodies against Babesia bigemina RON2

Based on the predicted amino acid sequence of RON2, two peptides were selected in conserved regions identified among the sequences obtained of B. bigemina RON2 (Chiapas strain and the reference sequence) with multiple sequence alignments using Clustal Omega (Sievers et al., Reference Sievers, Wilm, Dineen, Gibson, Karplus, Li, Lopez, McWilliam, Remmert, Söding, Thompson and Higgins2011), excluding the signal peptide (Schultz et al., Reference Schultz, Milpetz, Bork and Ponting1998; Petersen et al., Reference Petersen, Brunak, von Heijne and Nielsen2011) and the hydrophobic, transmembrane or intracellular domains (Krogh et al., Reference Krogh, Larsson, von Heijne and Sonnhammer2001). B-cell epitopes and antigenic regions were identified using the programs ABCpred (Saha and Raghava, Reference Saha and Raghava2006), BCEpred (Saha and Raghava, Reference Saha, Raghava, Nicosia, Cutello, Bentley and Timmis2004), and antibody epitope prediction using IEDB (Zhang et al., Reference Zhang, Wang, Kim, Haste-Andersen, Beaver, Bourne, Bui, Buus, Frankild, Greenbaum, Lund, Lundegaard, Nielsen, Ponomarenko, Sette, Zhu and Peters2008). Two conserved peptide sequences with the highest value in all three algorithms were selected as peptides: Peptide A (IPSVNPLYTRMTPDERKVEFQQ) and Peptide B (FGRVVPPPVYNNKWKR). Both peptides were commercially synthetized as a multiple antigen peptide system of 8 branches (MAPS-8) by GL Biochem (Shanghai, China). To produce antisera against each individual peptide, two New Zealand male rabbits were immunized with each peptide. Four immunizations were applied and each dose was inoculated subcutaneously near the iliac lymph nodes, with 100 µg of each synthetic peptide suspended in 0.5 mL of PBS at pH 7.4 and emulsified with 0.5 mL of Montanide ISA 50 V2 adjuvant (Seppic, Puteaux, France). The immunizations were performed every 15 days, and serum samples were obtained before each immunization. A final serum sample was obtained 15 days after the last immunization. All serum samples were stored at −20 °C until use. All animal handling and experimentation were performed under the UAQ's Bioethics Committee procedures with the approval number FCN/2011-0221.

Expression analysis

To evaluate the expression of RON2, a Western blot analysis was performed. For this, a pellet of B. bigemina-infected erythrocytes (iRBC) was washed five times in ice-cold PBS containing protease inhibitors (Roche-Applied Science, Penzberg, Upper Bavaria, Germany). Each washing step consisted of keeping the iRBC on ice for 5 min, mixing with vortex every 20 s, and then centrifuging the iRBC at 1940 × g at 4 °C. The supernatant was discarded, and the pellet was suspended in 500 µL of ice-cold PBS containing protease inhibitors. Freezing and thawing occurred at the end of each washing step. At the end of this procedure, the sample was centrifuged at 7500 × g at 4 °C for 5 min, the supernatant was discarded, and the pellet was suspended carefully in 50 µL of lysis buffer (50 mm Tris-l, 150 mm NaCl, 0.5% Triton X-100, 10 mm EDTA) and mixed with 100 µL of protein loading buffer. This mix was boiled for 5 min and centrifuged briefly. Using 15 µL of this mix per well, an SDS-PAGE (8%) was performed (100 volts, 3 h). Then, the proteins were transferred to a nitrocellulose membrane for 1 h at 100 volts. The membrane was washed with TBS for 5 min and blocked with TBS with 5% skim milk (TBS-M) for 2 h at room temperature. The rabbit anti-RON2 antiserum was diluted at 1:250 in TBS-M (2%) and incubated with the membrane overnight at 4 °C. The membrane was washed two times with TBS-M (2%) and incubated and blocked again for 1 h. The membrane was incubated with a donkey anti-rabbit IgG antibody conjugated with HRP (Jackson ImmunoResearch, West Grove, Pennsylvania, USA) diluted 1:5000 in TBS-M (2%) for 1 h in agitation at room temperature. The membrane was washed three times with TBS and two times with TBS and 0.1% Tween (TBS-T). All washes were agitated at room temperature. Finally, the reaction was developed with ECL (GE, Boston, MA, USA) in autoradiography (X-ray) films (Santa Cruz, Dallas, Texas, USA). Commercial protein standards were used as reference to estimate the molecular weight (PageRuler Plus, Thermo Scientific, Waltham, Massachusetts, USA). As controls, uninfected bovine erythrocytes were incubated with post-immune serum and B. bigemina infected erythrocytes were incubated with pre-immune serum.

A confocal microscopy analysis was performed with each antiserum. For this, the Texas strain of Babesia bigemina was maintained in vitro with daily changes of complete medium, consisting of M199 medium (Sigma-Aldrich, St. Louis Missouri, USA) supplemented with 40% bovine serum and antibiotic-antimycotic (Sigma-Aldrich, St. Louis Missouri, USA). When the parasitized erythrocytes reached >4%, iRBCs were washed with M199 and resuspended in VYM solution. Smears were made in ProbeOn slides (Fisher Scientific, Ontario, Canada) and fixed with methanol for 5 min. The slides were stored at −80 °C until used. Each slide was dried and fixed with 90% acetone 10% methanol for 1 h at −20 °C. The tissue was blocked with 5% horse serum in PBS – 0.2% Tween-20 (PBS-T). Then, they were incubated with each rabbit anti-RON2 antiserum diluted 1:50 in PBS-T for 1 h at 37 °C, followed by ten washes with PBS-T. A second incubation was performed with a goat anti-rabbit IgG antibody coupled with Alexa-488 (Thermo Scientific, Waltham, Massachusetts, USA) diluted 1:200 in PBS-T containing Hoechst 33 342 for nuclei staining (Thermo Scientific, Waltham, Massachusetts, USA) for 1 h at 37 °C, followed by ten washes with PBS-T. As negative controls, rabbit preimmune sera were used in the same conditions. The slides were mounted with ImmunoSelect antifade mounting medium (Dianova, Hamburg, Germany) and a coverslip. Each slide was analyzed in a confocal microscope (Leica TCS SP5 Confocal Laser Scanning Microscope) using lasers specific for Alexa-488, Hoechst 33 342 and brightfield. Images were processed and merged with the LAS Advanced Fluorescence software (Leica, Wetzlar, Alemania).

Recognition of RON2 peptides by antibodies from naturally infected bovines

To assess the presence of antibodies to B. bigemina RON2 in naturally infected bovines, we analyzed the serum of bovines from endemic areas and positive for B. bigemina. First, serum samples collected from bovines living in endemic areas from different locations in four different states of Mexico and positive for B. bigemina infection were tested against each RON2 peptide by an indirect ELISA. For this, one hundred and twenty-one bovine serum samples were first analyzed by the indirect immunofluorescence test (IFAT) to confirm exposure: 115 were positive for B. bigemina and 6 were negative for the presence of anti-B. bigemina antibodies. None of the sera included in this experiment were positive to the presence of antibodies anti-B. bovis by IFAT. The protocol for immunofluorescence has been published elsewhere and the cut-off dilution value was 1:80 (OIE – World Organisation for Animal Health, 2019). Additionally, sera from three bovines born and raised in a tick-free area and negative to B. bigemina by both IFAT and nested PCR were used as negative controls (Figueroa et al., Reference Figueroa, Chieves, Johnson and Buening1993). Each peptide was covalently bound to Pierce® amine-binding, maleic anhydride ELISA plates (Thermo Scientific, Waltham, Massachusetts, USA) according to the manufacturer's protocol. The plates were activated by washing them three times with PBS, pH 7.4. Then, 100 µL of each peptide at 10 µg mL−1 in PBS pH 7.4 was added to each well, and the plates were incubated overnight at 4 °C. Each well was blocked with 100 µL of SuperBlock™ blocking buffer (Thermo Scientific, Waltham, Massachusetts, USA) for 60 min at 37 °C. A total of 100 µL of each bovine serum diluted 1:50 was added to each well and incubated for 60 min at 37 °C. The plates were washed three times with PBS-T and incubated with 100 µL of donkey anti-bovine IgG antibody conjugated with alkaline phosphatase (Jackson ImmunoResearch, West Grove, Pennsylvania, USA) diluted 1:500 in PBS, pH 7.4. After an incubation period of 60 min at 37 °C, the plates were washed three times. Each plate always included a blank sample and a negative control serum in the same position. Finally, the reaction was revealed with OPD (Sigma-Aldrich, St. Louis Missouri, USA), and after an incubation period of 20 min at room temperature, the reaction was read at 450 nm with an iMark Microplate Absorbance Reader with the Microplate Manager® 6 Software (Bio-Rad Laboratories, Richmond, California, USA). Each serum sample was analyzed in triplicate, and the cut-off value of the test was determined using the mean OD value of triplicate wells plus 3 standard deviations (s.d.) of the negative control serum samples. All the OD values below this cut-off value were considered negative.

Neutralization assay

To test the capacity of RON2 antibodies to block merozoite invasion, an in vitro neutralization assay was performed. For this, the Babesia bigemina Puerto Rico strain was cultured essentially as described by Levy and Ristic (Levy and Ristic, Reference Levy and Ristic1980) with modifications as follows: This strain was cultured in 96-well plates using HL-1 medium supplemented with 5% bovine red blood cells, 40% bovine serum, 0.1 M TAPSO, and a pH of 7.2. The cultures were incubated at 37 °C and 5% CO2. When the cultured parasites reached 6% parasitized erythrocytes, approximately 1 × 106 iRBCs contained in 16.5 µL were added to fresh medium supplemented with normal red blood cells and serum. Cultures were prepared in triplicate for each neutralization assay, and after inactivating the complement by heating at 56 °C for 30 min, each rabbit antiserum against RON2 was added in a 1:5 proportion to each well. The amount of a normal rabbit serum added to the culture was tested previously to avoid interference with culture development. The statistical analysis demonstrated that there was no significant difference between the control culture without rabbit serum and the culture tested with a 1:5 serum proportion (data not shown). The cultures were incubated at 37 °C in 5% CO2 for 48 h, and a drop of homogenized culture was obtained and used to prepare smears, which were fixed in methanol and stained with Giemsa. The percentage of parasitized erythrocytes (PPE) was determined by counting the infected and noninfected red blood cells in five representative fields (Figueroa and Buening, Reference Figueroa and Buening1991; Hines et al., Reference Hines, Palmer, Jasmer, McGuire and McElwain1992). A student's t-test was carried out to make a comparative media analysis of nonpaired samples to test differences between the culture supplemented with preimmunization sera and the postimmunization sera. The data were analyzed using SPSS 22.0 Software.

Results

Babesia bigemina has a ron2 gene

The amino acid sequence of Plasmodium falciparum RON2 was used as a BLASTP query in the Sanger Institute database before the genome was annotated and migrated to NCBI (Altschul et al., Reference Altschul, Gish, Miller, Myers and Lipman1990). We found an ORF of 4056 bp in the Babesia bigemina genome with 27.82% identity (87% Coverage). The predicted protein contained 1351 aa, a putative signal peptide sequence in the N-terminal region from aa 1 to 26, a CLAG domain comprised of amino acids 718 to 1162 (Fig. 1) and a region of three hydrophobic domains which failed to reach a predicted value for transmembrane helices from amino acids 1093–1112, 1143–1160 and 1214–1232 (not shown). The mature protein had an expected molecular weight of 149 kDa and an isoelectric point of 9.38. Currently, B. bigemina RON2 in the NCBI is CDR95447.1. This is a single copy gene located on chromosome II (LK391708.1) (Fig. 1). The percentage of global identity between RON2 of the Chiapas strain (AQU42588.1) with other homologous sequences that showed a similarity in the BLASTp search are shown in Table 2. These results demonstrate the presence of a ron2 gene in the B. bigemina genome. Importantly, the predicted protein sequence contained the typical structure and features of RON2 present in other Apicomplexa parasites.

Fig. 1. Genome location and bioinformatics analysis of B. bigemina ron2. (A) Position of ron2 in chromosome II. BLASTP analysis identified a sequence in GenBank (CDR95447.1) referred to as the ‘putative membrane protein of B. bigemina” in the locus BBBOND_0206050. (B) Results of the SMART and Pfam analysis of the predicted RON2 protein showing the signal peptide (SP) and the functional CLAG domain (gray boxes). The position of the selected peptides A and B in the domain is indicated with black boxes and the alignment of several apicomplexan species for peptide A and B sequences.

Table 2. Percentage of global identity of B. bigemina RON2 Chiapas strain (AQU42588.1) with other homologues proteins

RON2 is transcribed and expressed in Babesia bigemina

There are no reports on the expression of the ron2 gene in B. bigemina to date. To evaluate the expression, the erythrocytic stages of B. bigemina were first analyzed for mRNA transcription. As observed in Fig. 2, Panel A, cDNA of B. bigemina-infected erythrocytes was amplified by PCR, showing a band of the expected size (380 bp) in agarose gel electrophoresis. The cDNA sequence obtained was 100% identical to the B. bigemina RON2 (accession number: KU696964, data not shown). No amplification was observed when the same mRNA sample was amplified without reverse transcriptase, indicating specific amplification of cDNA but not DNA, thus confirming that the ron2 gene is transcribed in erythrocytic stages of B. bigemina. Second, erythrocytic stages were analyzed for protein expression by Western blot. For this, a RON2 antiserum identified a specific band with a molecular weight equivalent to the predicted weight of 149 kDa (Fig. 2 Panel B, lane 2). No signal was observed when the same antiserum was incubated with proteins from uninfected red blood cells, nor when infected erythrocytes where incubated with pre-immune serum, used as control (Fig. 2, Panel B, lanes 3 and 4, respectively). These results confirm that the antibodies generated against RON2 specifically recognize a protein band of the expected molecular weight of RON2 in B. bigemina-infected RBCs.

Fig. 2. Babesia bigemina ron2 is transcribed and expressed in erythrocytic stages. Panel A. RT-PCR was visualized on a 1.8% agarose gel stained with ethidium bromide using a pair of primers to amplify a 358 bp fragment. Lane 1: DNA ladder marker; Lane 2: B. bigemina mRNA with reverse transcriptase; Lane 3: B. bigemina mRNA without reverse transcriptase. Panel B. Western blot showing a specific band of approximately 149 kDa detected by anti-RON2 antiserum. Lane 1. Prestained Protein Ladder shown in kiloDaltons; Lane 2. Total extracts of iRBCs; Line 3. Total extracts of noninfected RBCs. Line 4. Total extracts of iRBCs incubated with pre-immune serum.

Additionally, anti-RON2 antisera were evaluated by confocal microscopy to determine the expression pattern of RON2 in the merozoite stage. Rabbit antisera generated against two RON2 peptides were used to identify intraerythrocytic merozoites. Using a rabbit anti-serum for each peptide, merozoites were recognized by the respective antiserum (Fig. 3, Panels B and F). In contrast, as expected, no signal was detected when the parasites were incubated with preimmunization sera used as controls (Fig. 3, Panels J and N). A pattern consisting of a defined and intense stain was observed towards the apical end of each paired merozoite, right after the nucleus, where typically, the apical organelles, including the rhoptries, are located (Fig. 3, Panels B, D, F, and H). Together, these results confirm that RON2 is expressed in B. bigemina blood stages and that antibodies against RON2, specifically recognize the protein in intraerythrocytic merozoites.

Fig. 3. RON2 is expressed in the apical end of B. bigemina merozoites. Intraerythrocytic parasites were incubated with rabbit antiserum against peptide A (Panels B and D) or rabbit antiserum against peptide B (Panels F and H). No signal was observed when merozoites were incubated with the preimmunization serum from each rabbit for peptide A (Panels J and L) or peptide B (Panels N and P). Nuclei were stained with Hoechst 33342 (Panels A, E, I M). Bright field images (Panels C, G, K O) were also used to obtain merged images (Panels D, H, L, P). Bar = 10 µm.

RON2 has conserved B-cell epitopes that are recognized by naturally infected bovines

RON2 is a highly conserved protein in other Apicomplexa protozoa and is secreted during host cell invasion. To determine whether cattle naturally infected with B. bigemina generate antibodies against RON2, two peptides containing conserved, predicted B-cell epitopes were exposed to serum samples from B. bigemina-infected bovines obtained from endemic areas. As shown in Table 3, one hundred and fifteen serum samples from naturally infected bovines were analyzed. Our results indicate that 113 out of 115 (98.26%) cattle serum samples contained antibodies against peptide A, and 114 out of 115 (99.13%) serum samples contained specific antibodies against peptide B. These sera samples are from naturally infected cattle from different geographical regions as it is shown in Table 3. Two bovines with antibodies against B. bigemina did not recognize peptide A, while one bovine failed to recognize peptide B. These animals were not the same nor from the same farm. The six negative serum samples analyzed did not react with either of the two peptides.

Table 3. Presence of antibodies against RON2 peptides in B. bigemina naturally infected bovines

‘+’, Positive; ‘−’, Negative.

Neutralization assay

To evaluate the capacity of specific antibodies against RON2 to block merozoite invasion, a neutralization assay was carried out. Babesia bigemina in vitro cultures containing antibodies against RON2 showed a statistically significant difference in the percentage of inhibition in comparison to that of the culture supplemented with preimmunization serum (Fig. 4). The antibodies against peptide A induced the highest neutralization activity with a 62.22% reduction of PPE (culture with pre-immune serum: 7.65% PPE, culture with post-immunization serum: 2.89% PPE) (P < 0.05), while the anti-peptide B antibodies reduced the PPE by 51.28% (culture with pre-immunization serum: 7.16% PPE, culture with post-immunization serum: 3.49% PPE) compared to that of their respective preimmune sera (P < 0.05). Furthermore, we analyzed the inhibition capacity of both antisera mixed in a 1:1 proportion, and the results of this assay showed a 46.04% reduction of PPE (culture with pre-immune serum: 4.29% PPE, culture with post-immunization serum: 2.28% PPE) (P < 0.05) (Fig. 4). The antiserum of a rabbit immunized with adjuvant alone used as control serum (CS) induced a 0% reduction of PPE (culture with pre-immunization serum: 3.25% PPE, culture with post-immunization serum: 3.3% PPE) compared to the respective preimmunization serum used as control for a possible adjuvant effect. Together, these results show that antibodies against RON2 reduce B. bigemina invasion of erythrocytes, suggesting a role for RON2 in the invasion process.

Fig. 4. Neutralization assay using antibodies against B. bigemina RON2. The percentage of parasitized erythrocytes (PPE) inhibition was determined in B. bigemina cultures supplemented with antibodies anti-peptide A (α Pep A), antibodies anti-peptide B (α Pep B), and a mix of antibodies to both peptides (α Pep AB). Serum from a rabbit immunized only with adjuvant was used as a control serum (CS). All data are expressed as percentage of parasitized erythrocytes inhibition considering all the cells counted in five representative fields as the total. The inhibition percentage for each treatment was as follows: peptide A: 62.22%; peptide B: 51.28% and peptide A + B mix: 46.04%. The asterisks indicate the values that are significantly different from the control and cultures with preimmune serum (P < 0.05).

Discussion

To date, RON2 has not been identified in B. bigemina, and the present work represents the first report of the identification, transcription and expression of this protein in B. bigemina. The moving junction (MJ) is the irreversible interaction between AMA-1 and RON2 in Apicomplexa parasites, and both proteins have an important role in parasite invasion of erythrocytes (Richard et al., Reference Richard, MacRaild, Riglar, Chan, Foley, Baum, Ralph, Norton and Cowman2010; Srinivasan et al., Reference Srinivasan, Yasgar, Luci, Beatty, Hu, Andersen, Narum, Moch, Sun, Haynes, Maloney, Jadhav, Simeonov and Miller2013; Bermúdez et al., Reference Bermúdez, Arévalo-Pinzón, Rubio, Chaloin, Muller, Curtidor and Patarroyo2018; Salgado-Mejias et al., Reference Salgado-Mejias, Alves, Françoso, Riske, Silva, Miranda and Soares2019). AMA-1 and RON2 were initially characterized in Toxoplasma and Plasmodium (Curtidor et al., Reference Curtidor, Patiño, Arévalo-Pinzón, Patarroyo and Patarroyo2011); where RON2 is integrated into the RBC membrane and there it is used as an AMA-1 ligand on the cell surface (Silvie et al., Reference Silvie, Franetich, Charrin, Mueller, Siau, Bodescot, Rubinstein, Hannoun, Charoenvit, Kocken, Thomas, van Gemert, Sauerwein, Blackman, Anders, Pluschke and Mazier2004; Shen and Sibley, Reference Shen and Sibley2012). AMA-1 is a protein required for invasion of the host cell (Remarque et al., Reference Remarque, Faber, Kocken and Thomas2008) and has been described previously in B. bigemina (Torina et al., Reference Torina, Agnone, Sireci, Mosqueda, Blanda, Albanese, La Farina, Cerrone, Cusumano and Caracappa2010). In this study, we focused on the identification and characterization of the RON2 protein. The ron2 gene was identified as a single copy gene, using an initial bioinformatics approach, and the full sequence of the gene was amplified using several sets of primers. The mature predicted protein contains 1351 aa, excluding the signal peptide. RON2 proteins are highly conserved among different species of the phylum Apicomplexa. RON2 proteins in Apicomplexa species share some structural and functional characteristics, such as a signal peptide and a CLAG domain (Kaneko et al., Reference Kaneko, Yim Lim, Iriko, Ling, Otsuki, Grainger, Tsuboi, Adams, Mattei, Holder and Torii2005; Rungruang et al., Reference Rungruang, Kaneko, Murakami, Tsuboi, Hamamoto, Akimitsu, Sekimizu, Kinoshita and Torii2005; Ghoneim et al., Reference Ghoneim, Kaneko, Tsuboi and Torii2007; Cao et al., Reference Cao, Kaneko, Thongkukiatkul, Tachibana, Otsuki, Gao, Tsuboi and Torii2009). Babesia bigemina RON2 also contains these features, including the CLAG domain. This domain identified as pfam03805 is part of a gene family in P. falciparum, it is found in at least, nine proteins that are expressed in blood stages. Some proteins with this domain have been related to the cytoadherence to endothelial receptors in the sequestration of iRBCs in blood vessels of the brain causing cerebral malaria. Other proteins with this domain have been described as essential for the binding of merozoites to RBCs or in the invasion of midgut lumen cells and salivary gland cells by sporozoites (Holt et al., Reference Holt, Gardiner, Thomas, Mayo, Bourke, Sutherland, Carter, Myers, Kemp and Trenholme1999). Interestingly, by bioinformatics, we did not find the three transmembrane domains in B. bigemina RON2 as they were found in B. bovis (Hidalgo-Ruiz et al., Reference Hidalgo-Ruiz, Suarez, Mercado-Uriostegui, Hernandez-Ortiz, Ramos, Galindo-Velasco, León-Ávila, Hernández and Mosqueda2018). Instead, three hydrophobic domains were predicted from amino acids 1093–1112, 1143–1160 and 1214–1232. These transmembrane domains are used in other species as ligands for AMA-1 (Richard et al., Reference Richard, MacRaild, Riglar, Chan, Foley, Baum, Ralph, Norton and Cowman2010; Srinivasan et al., Reference Srinivasan, Yasgar, Luci, Beatty, Hu, Andersen, Narum, Moch, Sun, Haynes, Maloney, Jadhav, Simeonov and Miller2013; Bermúdez et al., Reference Bermúdez, Arévalo-Pinzón, Rubio, Chaloin, Muller, Curtidor and Patarroyo2018; Salgado-Mejias et al., Reference Salgado-Mejias, Alves, Françoso, Riske, Silva, Miranda and Soares2019), suggesting that, although the function of this protein is also conserved in this species, the topology of B. bigemina RON2 could be not the same as that of B. bovis RON2. More functional studies are necessary to test this hypothesis.

Due to the implication of RON2 in the erythrocyte invasion process, in this study, we determined whether B. bigemina ron2 was a functional gene; therefore, we analyzed its transcription and expression in the blood stages of the parasite. Transcripts of ron2 were detected by RT-PCR in blood stages of B. bigemina, and a defined band of the expected molecular weight of the mature protein (149 kDa) was detected in blood stages as well by Western blot. Therefore, we conclude that RON2 is a functional gene and is expressed in the erythrocytic stages of B. bigemina. Additionally, specific antibodies against two conserved RON2 peptides were generated and evaluated on native antigen by confocal microscopy. We successfully generated antibodies against RON2, which bound to intraerythrocytic merozoites. The expression pattern observed consisted of an intense localization in the anterior end of paired merozoites, with no staining in the posterior end and this staining pattern was consistent with that observed for B. divergens (Ord et al., Reference Ord, Rodriguez, Cursino-Santos, Hong, Singh, Gray and Lobo2016). In other Apicomplexa merozoites, this protein is stored in the anterior rhoptry neck (Proellocks et al., Reference Proellocks, Coppel and Waller2010), which might explain the localization in the apical end. More specific experiments, including electron microscopy are necessary to identify the exact subcellular localization of RON2 in B. bigemina merozoites. The results obtained confirm the hypothesis that RON2 is a protein expressed in erythrocytic merozoites, as in other Babesia parasites.

It is known that cattle naturally infected with Babesia spp. in endemic areas generate antibodies that protect them from disease (Bock et al., Reference Bock, Jackson, De Vos and Jorgensen2004). To evaluate whether cattle infected naturally with B. bigemina generate antibodies that recognize RON2, an indirect ELISA was performed. The results showed that 98.26% of the infected cattle had antibodies that recognized peptide A, while 99.13% of the cattle had antibodies that recognized peptide B. For the difference in the sera recognition of the two different peptides we can only speculate that since B-cell epitope recognition is influenced by antigenic dominance, these two peptides contain B-cell epitopes with different immunogenicity, therefore, they do not generate the same antibodies titters in the same animals. Our finding supports the fact that RON2 is recognized by the immune system of cattle naturally exposed to B. bigemina in endemic areas. These results together with those described by Hidalgo-Ruiz et al. (Reference Hidalgo-Ruiz, Suarez, Mercado-Uriostegui, Hernandez-Ortiz, Ramos, Galindo-Velasco, León-Ávila, Hernández and Mosqueda2018), demonstrate that conserved B-cell epitopes of RON2 are implicated in humoral immune responses in bovine babesiosis under natural conditions. Since the cattle sera analyzed were obtained from nineteen farms in four different states in Mexico, where bovine babesiosis antigens have been reported to be highly variable (Borgonio et al., Reference Borgonio, Mosqueda, Genis, Falcon, Alvarez, Camacho and Figueroa2008; Genis et al., Reference Genis, Mosqueda, Borgonio, Falcón, Alvarez, Camacho, de Lourdes Muñoz and Figueroa2008), our findings support the hypothesis that RON2 is highly immunogenic and contains conserved B-cell epitopes, as it was previously described in P. vivax (Bittencourt et al., Reference Bittencourt, Leite, Silva, Pimenta, Silva-Filho, Cassiano, Lopes, Dos-Santos, Bourgard, Nakaya, da Silva Ventura, Lacerda, Ferreira, Machado, Albrecht and Costa2018; López et al., Reference López, Yepes-Pérez, Díaz-Arévalo, Patarroyo and Patarroyo2018). However, broader analyses including sera from other endemic countries are needed to confirm this hypothesis. Additionally, since both peptides designed in this work have a high percentage similarity with RON2 of B. bovis (82 and 88%, for peptide 1 and peptide 2, respectively), there is a high probability of cross-reaction, and more studies are necessary to test this hypothesis. However, while not definitive, the failure of the sera to react with B. bovis iRBCs by IFAT indicate that it is unlikely that the ELISA reactions were due to infection of any individual animal with B. bovis. Finally, to test the capacity of anti-RON2 antibodies to block invasion of erythrocytes, an in vitro neutralization assay was performed. A reduction in the percentage of PPE of 62.22 and 51.28% for peptide A and peptide B, respectively, confirmed this hypothesis. These results were expected, since RON2 induces invasion-blocking antibodies in other Babesia species. For example, Ord et al. (Reference Ord, Rodriguez, Cursino-Santos, Hong, Singh, Gray and Lobo2016), demonstrated that RON2 is able to inhibit the erythrocyte invasion by B. divergens up to 44%. Even when we obtained similar results to those described by Hidalgo-Ruiz et al. (Reference Hidalgo-Ruiz, Suarez, Mercado-Uriostegui, Hernandez-Ortiz, Ramos, Galindo-Velasco, León-Ávila, Hernández and Mosqueda2018), it is worth noting that when B. bovis RON2 peptides were individually tested in an in vitro neutralization assay, antibodies against both peptides did have an additive effect, which was not observed in this study. Moreover, the PPE diminished when they were evaluated together. This could be due to several factors, including dilution of each antiserum in the mix (50% each), allosteric interference or different antibody titers, which were not determined in this study. More studies are needed to test these hypotheses. It has been reported for Plasmodium yoelii that antibodies against a peptide complex of AMA1-RON2 reached a complete inhibition (Srinivasan et al., Reference Srinivasan, Ekanem, Diouf, Tonkin, Miura, Boulanger, Long, Narum and Miller2014) by an apparent disruption of the interaction between these proteins. In our studies, B. bigemina AMA-1 was not evaluated; however, our findings suggest that B. bigemina RON2 could be considered as a part of a multiantigen vaccine.

In summary, this study demonstrates that B. bigemina has a ron2 gene and that the predicted protein contains a CLAG domain, a key feature in RON2 like other Apicomplexa. In B. bigemina, RON2 is expressed in merozoites and contains conserved B-cell epitopes. Importantly, RON2 is recognized by naturally infected cattle and induces neutralizing antibodies. All of this is consistent with the ideal characteristics for vaccine or diagnostic candidates against bovine babesiosis caused by B. bigemina.

Accession number

The sequence obtained from the B. bigemina Chiapas strain in this study was submitted to GenBank (National Center for Biotechnology Information, https://www.ncbi.nlm.nih.gov/nucleotide) with the accession number KU696964.

Acknowledgements

Technical support provided by Paul Lacy is greatly appreciated.

Author contributions

JM conceived and supervised the project and wrote and edited the manuscript. MHR cloned and sequenced the Chiapas strain of ron2, performed the bioinformatics analysis, interpreted the results, designed the table and figures and wrote the paper. DACO identified ron2 by bioinformatics, designed the primers and performed the transcription analysis in B. bigemina, designed peptides, generated antibodies and performed immunofluorescence analysis. DJHS performed the neutralization assay. MU contributed reagents/materials/analysis tools and helped design and interpret neutralization assays; MAMU contributed indirect ELISA analysis. AR carried out the Western blot. RAJA and HOR obtained the field serum samples and performed the IFAT test. SK and II contributed confocal microscopy equipment and reagents. All coauthors revised the manuscript.

Financial support

Mario Hidalgo-Ruiz, Diego Josimar Hernández-Silva, and Miguel Angel Mercado-Uriostegui received a fellowship from CONACyT-Mexico. Diana Alexandra Calvo-Olvera received a fellowship from PRODEP. The research work was funded by FOPER-UAQ and CONACyT-Ciencia Basica (167129).

Conflict of interest

None.

Ethical standards

Not applicable.

References

Alexander, DL, Mital, J, Ward, GE, Bradley, P and Boothroyd, JC (2005) Identification of the moving junction complex of toxoplasma gondii: a collaboration between distinct secretory organelles. PLoS Pathogens 1, e:17.Google Scholar
Altschul, SF, Gish, W, Miller, W, Myers, EW and Lipman, DJ (1990) Basic local alignment search tool. Journal of Molecular Biology 215, 403410.Google Scholar
Bermúdez, M, Arévalo-Pinzón, G, Rubio, L, Chaloin, O, Muller, S, Curtidor, H and Patarroyo, MA (2018) Receptor-ligand and parasite protein-protein interactions in Plasmodium vivax: Analysing rhoptry neck proteins 2 and 4. Cellular Microbiology 20, e12835.Google Scholar
Besteiro, S, Dubremetz, J-F and Lebrun, M (2011) The moving junction of apicomplexan parasites: a key structure for invasion. Cellular Microbiology 13, 797805.Google Scholar
Bittencourt, NC, Leite, JA, Silva, ABIE, Pimenta, TS, Silva-Filho, JL, Cassiano, GC, Lopes, SCP, Dos-Santos, JCK, Bourgard, C, Nakaya, HI, da Silva Ventura, AMR, Lacerda, MVG, Ferreira, MU, Machado, RLD, Albrecht, L and Costa, FTM (2018) Genetic sequence characterization and naturally acquired immune response to Plasmodium vivax Rhoptry Neck Protein 2 (PvRON2). Malaria Journal 17, 401.Google Scholar
Bock, R, Jackson, L, De Vos, A and Jorgensen, W (2004) Babesiosis of cattle. Parasitology 129, S247S269.Google Scholar
Borgonio, V, Mosqueda, J, Genis, AD, Falcon, A, Alvarez, JA, Camacho, M and Figueroa, JV (2008) msa-1 and msa-2c gene analysis and common epitopes assessment in Mexican Babesia bovis isolates. Annals of the New York Academy of Sciences 1149, 145148.Google Scholar
Cao, J, Kaneko, O, Thongkukiatkul, A, Tachibana, M, Otsuki, H, Gao, Q, Tsuboi, T and Torii, M (2009) Rhoptry neck protein RON2 forms a complex with microneme protein AMA1 in Plasmodium falciparum merozoites. Parasitology International 58, 2935.Google Scholar
Curtidor, H, Patiño, LC, Arévalo-Pinzón, G, Patarroyo, ME and Patarroyo, MA (2011) Identification of the Plasmodium falciparum rhoptry neck protein 5 (PfRON5). Gene 474, 2228.Google Scholar
Dubremetz, JF, Garcia-Réguet, N, Conseil, V and Fourmaux, MN (1998) Apical organelles and host-cell invasion by Apicomplexa. International Journal for Parasitology 28, 10071013.Google Scholar
Figueroa, JV and Buening, GM (1991) In vitro inhibition of multiplication of Babesia bigemina by using monoclonal antibodies. Journal of Clinical Microbiology 29, 9971003.Google Scholar
Figueroa, JV, Chieves, LP, Johnson, GS and Buening, GM (1993) Multiplex polymerase chain reaction based assay for the detection of Babesia bigemina, Babesia bovis and Anaplasma marginale DNA in bovine blood. Veterinary Parasitology 50, 6981.Google Scholar
Genis, AD, Mosqueda, JJ, Borgonio, VM, Falcón, A, Alvarez, A, Camacho, M, de Lourdes Muñoz, M and Figueroa, JV (2008) Phylogenetic analysis of Mexican Babesia bovis isolates using msa and ssrRNA gene sequences. Annals of the New York Academy of Sciences 1149, 121125.Google Scholar
Ghoneim, A, Kaneko, O, Tsuboi, T and Torii, M (2007) The Plasmodium falciparum RhopH2 promoter and first 24 amino acids are sufficient to target proteins to the rhoptries. Parasitology International 56, 3143.Google Scholar
Gohil, S, Kats, LM, Seemann, T, Fernandez, KM, Siddiqui, G and Cooke, BM (2013) Bioinformatic prediction of the exportome of Babesia bovis and identification of novel proteins in parasite-infected red blood cells. International Journal for Parasitology 43, 409416.Google Scholar
Hidalgo-Ruiz, M, Suarez, CE, Mercado-Uriostegui, MA, Hernandez-Ortiz, R, Ramos, JA, Galindo-Velasco, E, León-Ávila, G, Hernández, JM and Mosqueda, J (2018) Babesia bovis RON2 contains conserved B-cell epitopes that induce an invasion-blocking humoral immune response in immunized cattle. Parasites & Vectors 11, 575.Google Scholar
Hines, SA, Palmer, GH, Jasmer, DP, McGuire, TC and McElwain, TF (1992) Neutralization-sensitive merozoite surface antigens of Babesia bovis encoded by members of a polymorphic gene family. Molecular and Biochemical Parasitology 55, 8594.Google Scholar
Holt, DC, Gardiner, DL, Thomas, EA, Mayo, M, Bourke, PF, Sutherland, CJ, Carter, R, Myers, G, Kemp, DJ and Trenholme, KR (1999) The cytoadherence linked asexual gene family of Plasmodium falciparum: are there roles other than cytoadherence? International Journal for Parasitology 29, 939944.Google Scholar
Kaneko, O, Yim Lim, BYS, Iriko, H, Ling, IT, Otsuki, H, Grainger, M, Tsuboi, T, Adams, JH, Mattei, D, Holder, AA and Torii, M (2005) Apical expression of three RhopH1/Clag proteins as components of the Plasmodium falciparum RhopH complex. Molecular and Biochemical Parasitology 143, 2028.Google Scholar
Krogh, A, Larsson, B, von Heijne, G and Sonnhammer, ELL (2001) Predicting transmembrane protein topology with a hidden markov model: application to complete genomes1. Journal of Molecular Biology 305, 567580.Google Scholar
Levy, MG and Ristic, M (1980) Babesia bovis: continuous cultivation in a microaerophilous stationary phase culture. Science (New York, N.Y.) 207, 12181220.Google Scholar
López, C, Yepes-Pérez, Y, Díaz-Arévalo, D, Patarroyo, ME and Patarroyo, MA (2018) The in vitro antigenicity of Plasmodium vivax Rhoptry Neck Protein 2 (PvRON2) B- and T-Epitopes selected by HLA-DRB1 binding profile. Frontiers in Cellular and Infection Microbiology 8, 156.Google Scholar
OIE – World Organisation for Animal Health (2019) Manual of diagnostic test and vaccines for terrestrial animals. Retrieved from OIE World Organization for Animal Health. website: https://www.oie.int/en/standard-setting/%20terrestrial-manual/access-online/ (accessed 26 July 2019).Google Scholar
Ord, RL, Rodriguez, M, Cursino-Santos, JR, Hong, H, Singh, M, Gray, J and Lobo, CA (2016) Identification and characterization of the rhoptry neck protein 2 in babesia divergens and B. microti. Infection and Immunity 84, 15741584.Google Scholar
Owczarzy, R, Tataurov, AV, Wu, Y, Manthey, JA, McQuisten, KA, Almabrazi, HG, Pedersen, KF, Lin, Y, Garretson, J, McEntaggart, NO, Sailor, CA, Dawson, RB and Peek, AS (2008) IDT scitools: a suite for analysis and design of nucleic acid oligomers. Nucleic Acids Research 36, W163W169.Google Scholar
Petersen, TN, Brunak, S, von Heijne, G and Nielsen, H (2011) Signalp 4.0: discriminating signal peptides from transmembrane regions. Nature Methods 8, 785786.Google Scholar
Potgieter, FT and Els, HJ (1977) The fine structure of intra-erythrocytic stages of Babesia bigemina. The Onderstepoort Journal of Veterinary Research 44, 157168.Google Scholar
Potgieter, FT and Els, HJ (1979) An electron microscopic study of intra-erythrocytic stages of Babesia bovis in the brain capillaries of infected splenectomized calves. The Onderstepoort Journal of Veterinary Research 46, 4149.Google Scholar
Proellocks, NI, Coppel, RL and Waller, KL (2010) Dissecting the apicomplexan rhoptry neck proteins. Trends in Parasitology 26, 297304.Google Scholar
Remarque, EJ, Faber, BW, Kocken, CHM and Thomas, AW (2008) Apical membrane antigen 1: a malaria vaccine candidate in review. Trends in Parasitology 24, 7484.Google Scholar
Richard, D, MacRaild, CA, Riglar, DT, Chan, J-A, Foley, M, Baum, J, Ralph, SA, Norton, RS and Cowman, AF (2010) Interaction between Plasmodium falciparum apical membrane antigen 1 and the rhoptry neck protein complex defines a key step in the erythrocyte invasion process of malaria parasites. The Journal of Biological Chemistry 285, 1481514822.Google Scholar
Rodríguez-Hernández, E, Mosqueda, J, Alvarez-Sánchez, ME, Neri, AF, Mendoza-Hernández, G and Camacho-Nuez, M (2012) The identification of a VDAC-like protein involved in the interaction of Babesia bigemina sexual stages with Rhipicephalus microplus midgut cells. Veterinary Parasitology 187, 538541.Google Scholar
Rombel, IT, Sykes, KF, Rayner, S and Johnston, SA (2002) ORF-FINDER: a vector for high-throughput gene identification. Gene 282, 3341.Google Scholar
Rungruang, T, Kaneko, O, Murakami, Y, Tsuboi, T, Hamamoto, H, Akimitsu, N, Sekimizu, K, Kinoshita, T and Torii, M (2005) Erythrocyte surface glycosylphosphatidyl inositol anchored receptor for the malaria parasite. Molecular and Biochemical Parasitology 140, 1321.Google Scholar
Saha, S and Raghava, GPS (2004) Bcepred: prediction of continuous B-cell epitopes in antigenic sequences using physico-chemical properties. In Nicosia, G, Cutello, V, Bentley, PJ and Timmis, J (eds), Artificial Immune Systems. Heidelberg, Berlin: Springer, pp. 197204.Google Scholar
Saha, S and Raghava, GPS (2006) Prediction of continuous B-cell epitopes in an antigen using recurrent neural network. Proteins: Structure, Function, and Bioinformatics 65, 4048.Google Scholar
Salgado-Mejias, P, Alves, FL, Françoso, KS, Riske, KA, Silva, ER, Miranda, A and Soares, IS (2019) Structure of rhoptry neck protein 2 is essential for the interaction in vitro with apical membrane antigen 1 in plasmodium vivax. Malaria Journal 18, 25.Google Scholar
Schnittger, L, Rodriguez, AE, Florin-Christensen, M and Morrison, DA (2012) Babesia: a world emerging. Infection, Genetics and Evolution 12, 17881809.Google Scholar
Schultz, J, Milpetz, F, Bork, P and Ponting, CP (1998) SMART, a simple modular architecture research tool: identification of signaling domains. Proceedings of the National Academy of Sciences of the United States of America 95, 58575864.Google Scholar
Shen, B and Sibley, LD (2012) The moving junction, a key portal to host cell invasion by apicomplexan parasites. Current Opinion in Microbiology 15, 449455.Google Scholar
Sievers, F, Wilm, A, Dineen, D, Gibson, TJ, Karplus, K, Li, W, Lopez, R, McWilliam, H, Remmert, M, Söding, J, Thompson, JD and Higgins, DG (2011) Fast, scalable generation of high-quality protein multiple sequence alignments using Clustal Omega. Molecular Systems Biology 7, 539.Google Scholar
Silvie, O, Franetich, J-F, Charrin, S, Mueller, MS, Siau, A, Bodescot, M, Rubinstein, E, Hannoun, L, Charoenvit, Y, Kocken, CH, Thomas, AW, van Gemert, G-J, Sauerwein, RW, Blackman, MJ, Anders, RF, Pluschke, G and Mazier, D (2004) A role for apical membrane antigen 1 during invasion of hepatocytes by plasmodium falciparum sporozoites. Journal of Biological Chemistry 279, 94909496.Google Scholar
Soldati, D, Dubremetz, JF and Lebrun, M (2001) Microneme proteins: structural and functional requirements to promote adhesion and invasion by the apicomplexan parasite Toxoplasma gondii. International Journal for Parasitology 31, 12931302.Google Scholar
Srinivasan, P, Yasgar, A, Luci, DK, Beatty, WL, Hu, X, Andersen, J, Narum, DL, Moch, JK, Sun, H, Haynes, JD, Maloney, DJ, Jadhav, A, Simeonov, A and Miller, LH (2013) Disrupting malaria parasite AMA1–RON2 interaction with a small molecule prevents erythrocyte invasion. Nature Communications 4, 2261.Google Scholar
Srinivasan, P, Ekanem, E, Diouf, A, Tonkin, ML, Miura, K, Boulanger, MJ, Long, CA, Narum, DL and Miller, LH (2014) Immunization with a functional protein complex required for erythrocyte invasion protects against lethal malaria. Proceedings of the National Academy of Sciences of the United States of America 111, 1031110316.Google Scholar
Straub, KW, Cheng, SJ, Sohn, CS and Bradley, PJ (2009) Novel components of the Apicomplexan moving junction reveal conserved and coccidia-restricted elements. Cellular Microbiology 11, 590603.Google Scholar
Torina, A, Agnone, A, Sireci, G, Mosqueda, JJ, Blanda, V, Albanese, I, La Farina, M, Cerrone, A, Cusumano, F and Caracappa, S (2010) Characterization of the apical membrane antigen-1 in Italian strains of Babesia bigemina. Transboundary and Emerging Diseases 57, 5256.Google Scholar
Yabsley, MJ and Shock, BC (2013) Natural history of Zoonotic Babesia: Role of wildlife reservoirs. International Journal for Parasitology: Parasites and Wildlife 2, 1831.Google Scholar
Yokoyama, N, Okamura, M and Igarashi, I (2006) Erythrocyte invasion by Babesia parasites: current advances in the elucidation of the molecular interactions between the protozoan ligands and host receptors in the invasion stage. Veterinary Parasitology 138, 2232.Google Scholar
Zhang, Q, Wang, P, Kim, Y, Haste-Andersen, P, Beaver, J, Bourne, PE, Bui, H-H, Buus, S, Frankild, S, Greenbaum, J, Lund, O, Lundegaard, C, Nielsen, M, Ponomarenko, J, Sette, A, Zhu, Z and Peters, B (2008) Immune epitope database analysis resource (IEDB-AR). Nucleic Acids Research 36, W513W518.Google Scholar
Zhang, T-E, Yin, L-T, Li, R-H, Wang, H-L, Meng, X-L and Yin, G-R (2015) Protective immunity induced by peptides of AMA1, RON2 and RON4 containing T-and B-cell epitopes via an intranasal route against toxoplasmosis in mice. Parasites & Vectors 8, 15.Google Scholar
Figure 0

Table 1. Primers designed for the amplification of Babesia bigemina ron2

Figure 1

Fig. 1. Genome location and bioinformatics analysis of B. bigemina ron2. (A) Position of ron2 in chromosome II. BLASTP analysis identified a sequence in GenBank (CDR95447.1) referred to as the ‘putative membrane protein of B. bigemina” in the locus BBBOND_0206050. (B) Results of the SMART and Pfam analysis of the predicted RON2 protein showing the signal peptide (SP) and the functional CLAG domain (gray boxes). The position of the selected peptides A and B in the domain is indicated with black boxes and the alignment of several apicomplexan species for peptide A and B sequences.

Figure 2

Table 2. Percentage of global identity of B. bigemina RON2 Chiapas strain (AQU42588.1) with other homologues proteins

Figure 3

Fig. 2. Babesia bigemina ron2 is transcribed and expressed in erythrocytic stages. Panel A. RT-PCR was visualized on a 1.8% agarose gel stained with ethidium bromide using a pair of primers to amplify a 358 bp fragment. Lane 1: DNA ladder marker; Lane 2: B. bigemina mRNA with reverse transcriptase; Lane 3: B. bigemina mRNA without reverse transcriptase. Panel B. Western blot showing a specific band of approximately 149 kDa detected by anti-RON2 antiserum. Lane 1. Prestained Protein Ladder shown in kiloDaltons; Lane 2. Total extracts of iRBCs; Line 3. Total extracts of noninfected RBCs. Line 4. Total extracts of iRBCs incubated with pre-immune serum.

Figure 4

Fig. 3. RON2 is expressed in the apical end of B. bigemina merozoites. Intraerythrocytic parasites were incubated with rabbit antiserum against peptide A (Panels B and D) or rabbit antiserum against peptide B (Panels F and H). No signal was observed when merozoites were incubated with the preimmunization serum from each rabbit for peptide A (Panels J and L) or peptide B (Panels N and P). Nuclei were stained with Hoechst 33342 (Panels A, E, I M). Bright field images (Panels C, G, K O) were also used to obtain merged images (Panels D, H, L, P). Bar = 10 µm.

Figure 5

Table 3. Presence of antibodies against RON2 peptides in B. bigemina naturally infected bovines

Figure 6

Fig. 4. Neutralization assay using antibodies against B. bigemina RON2. The percentage of parasitized erythrocytes (PPE) inhibition was determined in B. bigemina cultures supplemented with antibodies anti-peptide A (α Pep A), antibodies anti-peptide B (α Pep B), and a mix of antibodies to both peptides (α Pep AB). Serum from a rabbit immunized only with adjuvant was used as a control serum (CS). All data are expressed as percentage of parasitized erythrocytes inhibition considering all the cells counted in five representative fields as the total. The inhibition percentage for each treatment was as follows: peptide A: 62.22%; peptide B: 51.28% and peptide A + B mix: 46.04%. The asterisks indicate the values that are significantly different from the control and cultures with preimmune serum (P < 0.05).