Infected cattle

Five 12-mo old Bos taurus-cross steers were purchased from a local breeder in the Municipality of Cuauhtémoc, west-central Chihuahua State, Mexico which is classified as tick-free by the Servicio Nacional de Sanidad, Inocuidad y Calidad Agroalimentaria (http://www.gob.mx/senasica/documentos/34495). These steers were certified free of tuberculosis and brucellosis by federally certified laboratories. The animals were kept tick-free, and were free of A. marginale as certified by endpoint nPCR for msp5 gene.

The CENID-PAVET laboratories and stalls are located on the outskirts, within the city limits of the small urban area of Progreso, in the Jiutepec Municipality of the state of Morelos, central Mexico. The quarters are free of ticks. Tick treatment is required for animals entering these quarters and all animals housed in outdoor stalls are periodically sprayed for fly control. All animals used in these experiments were housed at the Cattle Isolation Unit of the CENID-PAVET, a tick and fly-proof confinement stall, which includes a double door, screened windows and an electronic indoor insect killer.

Steers 1 - 5 were infected under non-life-threatening conditions for this experiment and are maintained as antibody donors for the following A. marginale strains as follows: Steer 1, Yautepec Mor.; steer 2, with Veracruz, Tizimín, and Yautepec strains; steers 3, 4, and 5 were infected with Tlapacoyan-1, Tlapacoyan-2 and Pt. de Ixtla strains, respectively. Steers 6 and 7 acquired infection under natural conditions and harbor Tlapacoyan-1 and Tlapacoyan-2 strains respectively; infected blood and serum samples from these two steers are kept under storage at -70 ºC.

Microorganisms

Nine Mexican A. marginale strains from different locations were used according to their differences in repeats in the Msp1a repeats¹⁵ as observed in Table 1.

Purification of Anaplasma marginale initial bodies

A. marginale initial bodies were purified from frozen bovine infected blood as described¹⁵ with modifications, briefly: once initial bodies were extruded form the erythrocytes, the material was separated through a 30 ml preformed linear 0-60% sucrose density gradient. 1.5 ml of the homogenized pellet was carefully layered on top of the preformed gradient and centrifuged at 7,000 xg for 30 min in a fixed angle rotor. After centrifugation, the intermediate phase containing the initial bodies (IB) was carefully recovered. IB were suspended in Puck’s saline in 30 mL tubes and centrifuged at 15,000 xg for 15 min at 4°C, twice in order to remove the sucrose. The supernatant was then removed and the pellet was suspended in 500 μl of Puck’s saline. The protein in the samples was quantitated by the Bradford method¹⁶, using bovine serum albumin (BSA) as standard. The IB were used immediately or stored at -70 °C, until use.

Cloning and sequencing of A. marginale virB11 gene

virb11 gene was amplified by PCR from genomic DNA (UltraClean® BloodSpin®DNA, MOBIO Laboratories Inc) obtained from cryopreserved (-70 ºC) blood, using Primers (F5’ GTGTTGTGTGCGCATATG 3’, R5’ CATTGCCTTGTGAACATTTAGTG 3’) under the following amplification program: 95 °C for 5 min, followed by 30 cycles at 95 °C for 45 sec, 56 °C for 1 min, 72 °C for 45 sec, with a final extension step at 72 °C for 10 min, using GoTaq® Green Master Mix 2X commercial mix (Promega, Madison, WI, USA). PCR products were separated by electrophoresis on 1% agarose gels and, as reference, the 1 kb Plus DNA Ladder (Invitrogen) weight marker was used; the image was captured with a KODAK Gel Logic 1500 System Picture system. PCR products were purified using a Wizard® SV Gel and PCR Clean-Up System commercial kit, and resuspended in 50 μl of water. One (1) μl of the product of each gene was cloned in a cloneJET PCR Cloning Kit (8878 Thermo-Scientific), and the mixture used for the transformation of competent Top10 E. coli cells. Plasmids from each gene were sequenced using T7 promoter forward and reverse primers, respectively. Sequencing was performed at the Biotechnology Institute, UNAM.

Bioinformatics analysis

The comparative identity among sequenced PCR products was determined with ClustalW¹⁷, using the putative virB11 gene of the A. marginale St. Maries strain as reference. The consensus sequences for each gene were translated into amino acids and used in the bioinformatics analysis. The prediction of the exposed extracellular domains was made with TMHMM program¹⁸. The ProtScale program was used for prediction of hydrophobic regions¹⁹ and the presence of linear type B epitopes was predicted with BCEPred, ABCPred and IEDB^20,21 programs all available on-line.

Multiple antigenic peptide (MAP) design

Based on the analysis of linear Type B epitopes a multiple antigenic peptide was designed considering the highest scores for the following characteristics: antigenicity, hydrophobicity, flexibility, surface exposure and synthesis ease such as, sequence size and solubility of the present amino acids. MAPVirB11 was designed as a tetramer and its synthesis was commercially commissioned to American Peptide Company, Inc. (Fischer Scientific, USA).

MAPVirB11 is recognized by IgG of cattle infected with A. marginale by ELISA

MAPVirB11 tetramer antigenicity against A. marginale immune bovine sera was tested by indirect ELISA in 96-well microtiter plates (Corning 3595) coated with 100 μL/well of MAPVirB11 at a 10 μg/mL concentration, in carbonate buffer solution (CBS) pH 9.6; incubated overnight at 4 °C. Plates were washed three times with PBS pH 7.2 /0.05% Tween 20 (PBS/Tween), and blocked with 7% skim milk in PBS/Tween for 1 h at 37 °C; the contents was discarded, wells were washed, and probed with 100 μL/well of A. marginale immune bovine sera serially diluted from 1/25, up to 1/100. Antigen-antibody reaction was made visible by probing with anti-bovine IgG alkaline phosphatase conjugate (Phosphatase-Conjugated AffiniPure Goat Anti-Bovine, Jackson ImmunoResearch, Laboratories, Inc.) diluted at 1/5000. The plates were read on a BioRad iMark™ Microplate Absorbance Reader #1681135 at 405 nm.

Preparation of anti-MAP-VirB11 rabbit polyclonal monospecific serum

New Zealand rabbits were subcutaneously immunized weekly on five occasions at 7 d intervals; with 50 μg of MAPVirB11 tetramer diluted in 1 mL PBS and emulsified in 1 mL Montanide™ ISA 70 adjuvant. Before the first immunization (T0) serum was used as negative control for each rabbit. Serum samples were obtained on T0, and each immunization time T1, T2, T3, T4 and T5. Rabbit anti MAPVirB11 antibody specificity was determined by ELISA, as described above with modifications. 96-well microtiter plates (Corning 3595) were coated with 100 μL of MAPVirB11 with a concentration of 10 μg/mL in carbonate buffer. Rabbit serum samples were serially diluted from 1/25 to 1/100 in 0.05% PBS Tween. To detect the Ag-Ac reaction, was made visible with Anti-IgG-Rabbit Gtx Rbt IgG2 Alkaline Phosphate (Alka Phos) conjugate (Chemicon International; Cat. No. AP307P) was used and read as described.

Identification of native VirB11 in A. marginale by Western blot

Twenty (20) μg of total initial body (IB) protein of Tlapacoyan-2, A. marginale, were run on denaturing and reductive SDS-PAGE gels with a 3%/15% pre-separation/separation phases. Electrophoresis was performed at 150 V, at constant voltage for one hour. One replicate gel was washed for one hour in distilled water and stained in Coomassie GelCode ™ Blue Solution (Thermo Fisher Scientific).

The second replicate was transferred to a 0.45 μm pore (Immobilon®-P Millipore) PVDF membrane on a semi-dry system at 15 volts for 15 min. At the end of the transference, the membrane was blocked for 2 h with 5% skim milk in Tris buffered solution (TBS) pH 7.5 and washed three times with TBS-0.05% Tween (TBS Tween). The membrane was incubated at room temperature with a 1:100 dilution of T5 rabbit serum in TBS Tween for 2 h; after three washes the membrane was incubated with the Anti-IgG-Rabbit Gtx Rbt IgG2 Alka Phos diluted 1:5000 in PBS_0.05% Tween-20 for 2 h; (Chemicon International). The bands were detected by incubating the membrane with alkaline phosphatase substrate (BCIP / NBT SIGMA) for 5 to 20 min.

Rabbit monospecific polyclonal anti-MAPVirB11 antibodies react with bovine infected erythrocytes by immunofluorescence

Antigen slides prepared from a 15% rickettsemic steer (Puente de Ixtla strain), were air-dried and stored at -70 ºC. Ten (10) μL of rabbit T0 and T5 anti MAPVirB11, at a 1:50 dilution in PBS (pH 7.2), were placed on an antigen slide and incubated for 60 min as described²². Antigen slides were incubated at 37 °C for 30 min and washed three times with PBS, then, incubated with FITC-anti-rabbit antibody conjugate (Jackson Immuno Research Laboratories, Inc.). Slides were washed three times with PBS pH 7.4 and air-dried at room temperature and examined by epifluorescent microscopy.

Cell localization of VIRB11 in A. marginale by transmission electron microscopy

Density gradient-purified A. marginale initial bodies from Yautepec Strain (see supplemental material for extraction and purification of initial bodies) were placed on copper grids coated with Formvar 200 mesh (Senna Science) and incubated for 1 h at room temperature. After incubation, grids were washed three times with TBS and incubated with anti-MAP-VirB11 primary rabbit antibodies and a pre-immunization control serum in a 1:5 TBS dilution for 1 h. Grids were washed again three times for three minutes each, and incubated for 1 h with Sigma-Aldrich gold-labeled conjugated anti-rabbit secondary antibody (particle size of 10 nm). Grids were negatively stained with uranyl acetate and observed under a microscope at 4K, 8K and 20K (MET Microscopic, ZEISS, Libra 120 model with camera Gatan Multiscan Camera, 794 Model).

Bioinformatics analysis

At amplification, each virB11 PCR product of the six Mexican A. marginale isolates showed an approximate 1,000 bp, molecular weight, consistent to that reported for the St. Marie strain. Nucleotide sequence alignments of nine Mexican isolates, showed 100 % identity among them (Table 2).

The computational inference analyzes of the consensus sequences showed two hydrophobic regions, absence of signal peptide and the probable external localization on the membrane, according to the amino acid analysis.

VirB11 protein type B epitope analysis and selection of relevant epitope

B type epitope analysis showed that VFSIRKPSTVQLSD amino acid sequence filled the criteria for immunogenicity, ease of synthesis and used for tetramer design. This sequence is located at the 107 to 122 positions, within the hydrophobic extramembranal region of the protein. This peptide sequence showed the highest scores as a linear type B epitope in the BCpred, ACBpred and IEDB prediction programs (Table 3).

Sera of cattle naturally or experimentally infected with A. marginale reacts with MAPVirB11

Serum samples of seven cattle naturally or experimentally infected with A. marginale gave a response above the negative control absorbance value, some reaching ≥2 OD values at ELISA (Figure 1A). The serum from a susceptible animal, serologically and PCR negative to A. marginale was included as negative control, which showed a 0.5 OD value. In order to confirm these results, the sera from bovines 1 and 3, were tested by western blot (Figure 1B). Both sera reacted with a 6 kDa band, which coincides with the molecular weight of MAP-VirB11.

Figure 1 A) MAP-VirB11 reacts with bovine immune serum in ELISA: Sera from seven A. marginale-infected bovines were tested. The description of the animals is as above in Materials and Methods; B) Infected bovines serum reacts with Map-VirB11 in western blot. MAP-VirB11 was separated by SDS-PAGE and blotted onto PVDF membrane and probed with 1). A. marginale negative bovine serum; 2) Bovine 1 serum or 3) Bovine 3 serum. C) Rabbit T5 anti-MAP-VirB11 reacts with native de VirB11; purified A. marginale initial bodies were separated on a 15% polyacrylamide gel and transferred to a PVDF membrane and probed with: 1, non-immune rabbit serum; 2, immune Rabbit T5 serum. 

Rabbit specific anti MAP-VirB11 antibody react with A. marginale native VirB11

Rabbit anti-MAPVirB11 antibodies reacted with MAPVirB11 in an ELISA (data not shown). All three sera reacted with similar OD values ≥ 0.3 to 0.5, which were higher than the one obtained for the control serum; the negative control had an OD value less than 0.1. In order to verify the rabbit immune serum specificity, rabbit antibodies were tested by western blot against the tetramer and proteins of the purified initial bodies. Figure 1C shows (lane 2) recognition of a 40 kDa band by T5 immune sera from the same rabbit whereas T0 non immune serum shows no signal.

Rabbit immune anti-MAPVirB11 serum reacts with intraerythrocytic A. marginale by immunofluorescence

Preimmune (T0) and immune sera (T5) were used to test if the immune anti MAPVirB11 antibodies reacted with intra-erythrocytic A. marginale in a direct immunofluorescence assay. Blood-smears of both non-infected (Figure 2A and 2B) and erythrocytes infected with Tlapacoyan-2 strain (2C and 2D). Smears were probed with both T0 (2A and 2C) and T5 (2B and 2D) immune sera. Figure 2D shows typical intraerythrocytic A. marginale bodies by direct fluorescence, in contrast to T0 serum, which shows no reaction (Figure 2C).

Figure 2 Recognition of intraerythrocytic A. marginale by rabbit immune serum anti-MAPVirB11 by direct immunofluorescence. Pre-immune rabbit serum was tested against A) non-infected erythrocytes or; B) infected erythrocytes; T5 rabbit anti-MAPVirB11 immune serum was tested against C) non-infected erythrocytes, and D) infected erythrocytes (100X magnification). 

Cellular localization of VirB11 protein in A. marginale by transmission electron microscopy (TEM)

In order to determine the location of VirB11 native protein in A. marginale, purified initial bodies were probed with rabbit pre-immune T0 and immune T5 anti-MAPVirB11 sera and a second anti-rabbit IgG antibody coupled with colloidal gold. Figure 3B shows that T5 rabbit anti-MAPVirB11 antibodies recognized the VirB11 native protein on the surface of A. marginale, located within an associated region on the outer side of the rickettsial membrane (indicated by arrows). This recognition can be observed in more detail in Figures 3B1 and 3B2. Figure 3A shows the initial body of A. marginale probed with pre-immune serum as negative control. Additionally, it was evaluated the T5 rabbit anti-MAP antibodies against E. coli, which is not known to express the VirB11 protein (Figure 3C). No recognition was observed in this case (Figures 3C1), which is evidence of the anti-MAPVirB11 specificity (Figure 3B).

Figure 3 Rabbit anti-MAPVirB11 immune serum reacts with the outer membrane of A. marginale initial bodies by Transmission electron microscopy. A) Pre-immune rabbit serum incubated with A. marginale initial bodies, (A1 4K and A2 8K; B) MAPVirB11 specific rabbit serum incubated with A. marginale initial bodies (B1 and B2 are magnification views from image B); C) MAPVirB11 specific rabbit serum incubated with E. coli as control (C1 is a magnification view from image C).  

Ethics Statement

Two month-old New Zealand rabbits were kept in the Laboratory Animal Facility of the National Institute of Public Health, Cuernavaca, Mor., under the guidelines of the Institutional Committee for the Care and Use of Experimental Animals (SICUAE) of the National Autonomous University of Mexico, under Protocol No. DC-2013/1-3.

Competing interests/Funding Sources

The Mexican National Council for Science and Technology (CONACyT), and the National Institute for Research on Agriculture, Forestry and Livestock (INIFAP) funded this work under agreements No. 168167 and SIGI 1320382022 respectively.

The funding sources provided financial support for the conduction of the research and preparation of the manuscript. The content of the manuscript however is the authors’ sole responsibility, solely to acknowledge this fact.

This work is part of the requirements for graduation of the first author América Ivette Barrera Molina