Figures
Abstract
Histophilosis, a mucosal and septicemic infection of cattle is caused by the Gram negative pathogen Histophilus somni (H. somni). As existing vaccines against H. somni infection have shown to be of limited efficacy, we used a reverse vaccinology approach to identify new vaccine candidates. Three groups (B, C, D) of cattle were immunized with subunit vaccines and a control group (group A) was vaccinated with adjuvant alone. All four groups were challenged with H. somni. The results demonstrate that there was no significant difference in clinical signs, joint lesions, weight change or rectal temperature between any of the vaccinated groups (B,C,D) vs the control group A. However, the trend to protection was greatest for group C vaccinates. The group C vaccine was a pool of six recombinant proteins. Serum antibody responses determined using ELISA showed significantly higher titers for group C, with P values ranging from < 0.0148 to < 0.0002, than group A. Even though serum antibody titers in group B (5 out of 6 antigens) and group D were significantly higher compared to group A, they exerted less of a trend towards protection. In conclusion, the vaccine used in group C exhibits a trend towards protective immunity in cattle and would be a good candidate for further analysis to determine which proteins were responsible for the trend towards protection.
Citation: Madampage CA, Wilson D, Townsend H, Crockford G, Rawlyk N, Dent D, et al. (2016) Cattle Immunized with a Recombinant Subunit Vaccine Formulation Exhibits a Trend towards Protection against Histophilus somni Bacterial Challenge. PLoS ONE 11(8): e0159070. https://doi.org/10.1371/journal.pone.0159070
Editor: Syed Faisal, National Institute of Animal Biotechnology, INDIA
Received: February 26, 2016; Accepted: June 27, 2016; Published: August 8, 2016
Copyright: © 2016 Madampage et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: The authors received funding for this study from Alberta Livestock and Meat Agency Ltd (ALMA) and Alberta Cattle Feeders Association. Co-author JVD received support in the form of salary from Alberta Beef Health Solutions Inc. Co-author CD received support in the form of salary from Veterinary Agri-Health Solutions. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. The specific roles of these authors are articulated in the 'author contributions' section.
Competing interests: The authors received commercial funding from Alberta Livestock and Meat Agency Ltd (ALMA) and Alberta Cattle Feeders Association. JVD is affiliated with Alberta Beef Health Solutions Inc., and CD is affiliated with Veterinary Agri-Health Solutions. There are no patents, products in development or marketed products to declare. This does not alter the authors' adherence to PLOS ONE policies on sharing data and materials.
Abbreviations: OMPs, outer membrane proteins; ORFs, open reading frames
1. Introduction
Histophilus somni, previously known as Haemophilus somnus, is an economically important pathogen that affects the cattle industry by causing a variety of mucosal and systemic infections [1–5], including septicemia, respiratory disease, reproductive tract disorders, pericarditis, pleuritis, infectious thrombotic meningoencephalitis (ITME), myocarditis, and arthritis [5–9]. H. somni is also associated with the bovine respiratory disease (BRD) complex, a leading cause of illness and death in the cattle industry [10]. The most common factors contributing to virulence include interaction of H. somni with bovine mononuclear phagocytic cells that results in inhibition of phagocytic cell function, attachment to non-epithelial and bovine aortic endothelial host cells, uptake of iron and other nutrients from the host, and antigenic variation of H. somni outer membrane proteins (OMPs) [6,11,12]. Additionally, expression of high-molecular-weight surface immunoglobulin binding protein A (IbpA), that binds the Fc portion of IgG2, increases H. somni serum resistance and, sialyation (addition of neuraminic acid) of lipooligosaccharides (LOS) may hinder antibody binding to certain epitopes increasing serum resistance [13–16]. Also, under favorable growth conditions the formation of branched mannose-galactose exopolysaccharide polymers for biofilm formation may contribute towards the virulence of H. somni [13–16]. Previously, Corbeil and co-workers assessed antibody responses to three immunoglobulin binding proteins (IgBPs) such as (IbpA3, IbpA5, IbpA DR2) encoded by the 12.2 Kb gene ibpA. The results implied that IbpA DR2 may be a protective antigen [17]. Additionally, the same group used subcutaneous immunization followed by H. somni challenged (intrabronchially) that showed for the first time protection in a natural host [18].
Vaccination has proven to be the most cost-effective intervention in protecting animals from infectious diseases and increasing livestock productivity [19]. The present day vaccines for H. somni associated disease have limited efficacy based, in part, to the strategies used by this pathogen to evade host immunity [5,20,21]. Commercial vaccines for H. somni include killed cells or outer membrane proteins that have helped prevent ITME and pneumonia [22,23]. Reverse vaccinology coupled with modern bioinformatics and next generation whole genome sequencing techniques has opened a pathway to identify reservoirs of genes that encode all surface exposed proteins that are more likely to be potential antigenic vaccine candidates [24]. The development of vaccines using a reverse vaccinology strategy introduces a robust in silico method of analyzing the entire genome of the pathogen to identify genes that encode proteins that are surface-localized and could potentially elicit an immune response [25–28]. These proteins can be further classified based on their antigenicity (surface exposed, signal peptides, and B-cell epitopes) [27–29]. Surface exposed proteins (e.g. outer membrane proteins) are considered good vaccine candidates since they have the capacity to induce an immune response following natural infection [27,28]. Reverse vaccinology has the added advantage of identifying a large number of target gene products that may induce the desired immunogenicity in a shorter length of time compared to traditional vaccinology approaches [27,28]. This was proven for serogroup B Neisseria meningitidis (MenB) where nearly 600 potential vaccine candidates were identified in a short period of 18 months compared to 40 years of conventional vaccinology [27,28]. Additionally, reverse vaccinology also holds the prospect of identifying novel proteins that may set the stage for the discovery of new host-pathogen interactions, new multivalent vaccine antigens, and the development of novel vaccines with long-term protective immunity [25–30].
The limited efficacy of most current H. somni vaccines could be due to many reasons and have been explained in references [16,31,32,33]. For example, present vaccines may only address the planktonic form and overlook other bacterial profiles (e.g. H. somni may form biofilms during myocarditis) [16,31,33]. Also, vaccines manufactured under artificial conditions may not represent the true antigenic profile of H. somni in the host [33]. Recently, small non-coding RNAs (sRNAs) identified in pathogenic H. somni strain 2336 (NCBI, GenBank accession number NC_010519) may suggest strain specific variation that in turn may affect protection through vaccination [32]. Finally, in this present study we hypothesize that current H. somni bacterial strains circulating in the field may be different from strains used for existing vaccines (based on bacterial isolates from the 1980s) [33,34]. Based on the information from previous studies [33,34], we applied a reverse vaccinology strategy and tested vaccine induced immunity using a large animal model (bovine).
2. Materials and Methods
2.1 Bacterial strains and Growth conditions
As previously stated [33,34], the new isolates of H. somni were collected from Alberta feedlot calves that died during 2012–13 while strains from the 1980s were stored in -80°C at VIDO-InterVac. The tissue samples from Alberta feedlot calves were obtained from swabs (Amies transport with charcoal, used for collecting, transporting and maintenance of microorganisms) of heart, lung, liver and synovial fluid that were cultured for H. somni [33,34]. TSA-Blood Agar plates were streaked and incubated for 24–48 hours in 5% CO2 at 37°C. Overnight growth of bacteria was accomplished at 37°C (with shaking) by inoculating a single colony of H. somni in brain heart infusion broth containing 0.1% trizma base, and 0.01% thiamine monophosphate (BHITT). Stocks of the overnight culture were made using 30% heat inactivated fetal calf serum in 15% glycerol and stored at -80°C [33,34]. As previously described [33], PCR of the 16S ribosomal RNA gene was carried out for verification of H. somni. Plates containing H. somni bacterial growth were scraped and transferred to BHITT for overnight growth at 37°C (with shaking). Genomic DNA isolation was carried out with cell pellets collected from overnight cultures using a Qiagen genomic DNA extraction kit (Qiagen genomic-tip as described by the manufacturer; Qiagen Canada, 181 Bay Street, Suite 4400, Toronto, Ontario M5J 2T3) followed by electrophoresis on a 1% agarose gel [33,34].
2.2 Genome sequencing, de novo assembly of next generation sequencing (NGS), antigen prediction, and ranking of outer membrane proteins (OMPs)
As described previously [33,34], genomic DNA from 12 H. somni isolates that included six new isolates (year, 2012–2013) and six old isolates (year, 1980s) were sequenced using Illumina Miseq with paired end 150 bp read type, at Cofactor genomics (Cofactor genomics, 4044 Clayton Avenue, Saint Louis, Missouri, 63110, USA). The methods used for de novo assembly of Illumina reads, antigen prediction, and ranking of OMPs have been described in reference [34–39]. A single new strain (AVI1) was selected as the template for cloning in Escherichia coli (E. coli) based on the rank of its proteins which were also conserved between all 12 isolates [34].
2.3 Cloning, expression, and protein purification
In order to test the protective efficacy against H. somni related septicemia, myocarditis, and arthritis AVI1 antigens were used as multiple subunit vaccines in a bovine vaccination and H. somni challenge model. Two animal trials comprising 40 (Trial # 1) or 32 (Trial # 2) cattle, respectively, were carried out. Here we publish the results from trial # 2 which included 4 groups of 8 animals each.
As was described earlier [34], a new H. somni strain (AVI1) was selected and used for amplification of genes using PCR (rank of each gene or protein is denoted by “R”) for animal trial # 2 (Table 1). Antigens, R1, R2, R5, R8, R13, R15 and R18 were previously described in reference [34] and were also used in trial # 1. PCR amplification (initial denaturation at 98°C for 30 seconds, denaturation at 98°C for 10 seconds, annealing at 62–65°C for 30 seconds, extension at 72°C for 2 minutes, and a final extension at 72°C for 5 minutes) of the rest of the antigens used in trial # 2 was also performed in a PTC-100 Thermal Cycler (Bio-Rad Laboratories, Hercules, California, USA) with 30 cycles [33,34]. The DNA sequences and amino acid sequences of antigens used in animal trial # 2 have been stated in (S1 Table). PCR products of R1, R2, R8, R18, R15, R34, and R35 were double digested with restriction enzyme pairs, (BglII, NcoI), or (XmaI, NcoI) as stated in Table 1, and inserted into an N-terminal hexa-histidine affinity tag in-house cloning vector pGH433His.2 [34,40] downstream of an Isopropyl-β-d-thiogalactopyranoside (IPTG) inducible tac promoter. As previously stated [34], pGH433 which is identical to pGH433His.2 except for the exclusion of the histidine tag, was used on double digested PCR products R5 and R13 using restriction enzyme pair (BglII, NcoI) [34,40]. Another in-house cloning vector pAA352 [41], was used on PCR products R4, R21, R23, R24, R27, R35, R36, and R37. The genes inserted into pAA352 via (BamHI, NcoI) restriction sites expressed a leukotoxin (Lkt) fusion protein [41]. The Lkt-antigen(R) fusion protein had the antigen expressed as a C-terminal fusion relative to Lkt [41]. Lkt alone is expressed as a 99259 Da molecular weight protein [41]. Vectors, pGH433, pGH433His.2 and pAA352 all contain an ampicillin resistance gene. All DNA sequences were verified by dideoxy DNA sequencing.
“R” is denoted for rank of gene or protein. The vaccine for the control group A did not contain antigens.
Transformation of plasmids into E. coli DH5αF’Iq was performed using conventional techniques [34]. For protein expression, an overnight sterile 20 mL Luria-Bertani (LB) medium + ampicillin (100 μg/mL) with E. coli DH5αF’Iq containing plasmid pGH433-antigen(R) or pGH433His.2-antigen(R) or pAA352-antigen(R) was transferred to 1 liter of LB medium containing 100 μg/mL ampicillin and grown at 37°C (with shaking) until the optical density (OD) at 600 nm reached 0.6. Protein expression was induced with IPTG (catalog No: I5502, Sigma) at a final concentration of 1 mM with further incubation for 3–4 hours at 37°C (with shaking). The cells were harvested by centrifugation at 10,000 × g for 15 min at 4°C and the pellet resuspended in lysis buffer (50 mM NaH2PO4, 300 mM NaCl, 10 mM imidazole at pH 8.0) for proteins having histidine tag. For proteins which need to be purified as aggregate or Lkt fusions, the cell pellet was resuspended in 50 mM Tris containing 25% sucrose at pH 8.0 and frozen at -80°C for 20 minutes (Table 1).
Antigens fused with an N-terminal histidine tag (R1, R2, R8, R15, R18, R34, R35) were purified as described in reference [34]. As mentioned earlier, cell pellets collected for inclusion body preparations (antigens: R5, R13) or LktA fusion proteins (R4, R21, R22, R23, R24, R27, R36,R37) were resuspended in 50 mM Tris containing 25% sucrose at pH 8.0 and frozen at -80°C for 20 minutes. These cells were lysed using lysozyme (1 mg/mL) and stored on ice for 15 minutes. Next, RIPA (20 mM Tris at pH 7.5, 300 mM NaCl, 2% w/v deoxycholic acid, 2% w/v Nonidet P-40)) and TET (100 mM Tris at pH 8.0, 50 mM EDTA at pH 8.0, 2% w/v Triton X-100) were added at a 5:4 ratio respectively and the cell lysate gently vortexed for 20 seconds. The lysate was further stored on ice for 5 minutes. The bacteria were sonicated and the cell pellet collected by centrifugation at 10,000 × g for 30 min at 4°C. The inclusion bodies were solubilized in 8 M urea containing 100 mM NaH2PO4 and 10 mM Tris at pH 8.0. Proteins (5–10 μL) were analyzed using 10–12% SDS-PAGE gels in an equal volume of 2 × Laemmli SDS-PAGE loading dye containing 0.5% v/v β-mercaptoethanol. Molecular weights of the predicted proteins are stated in Table 1 [34].
2.4 Experimental animals
Healthy 8–10 month old cattle were obtained from a commercial ranch in Saskatchewan, Canada. All animals were screened for the presence of H. somni-specific antibodies prior to the trial. Cattle were housed outdoors under feedlot conditions and fed limited barley based rations and free-choice hay. Cattle were randomly assigned to four groups of 8 animals each. All experiments were approved by the University Committee on Animal Care and Supply (University Animal Care Committee, Animal Research Ethics Board, University of Saskatchewan, protocol # 20150001).
2.5 Vaccination and challenge of cattle
2.5.1 Vaccine groups.
Cattle were randomly assigned to four groups (groups, A, B, C, & D) of 8 animals each. Group A was the control group of animals that received a formulation containing adjuvant alone. Cattle in groups B, C, and D were immunized with antigen pools consisting of multiple proteins (see below). All four groups were challenged with H. somni.
2.5.2 Vaccine formulation.
All vaccines were formulated at VIDO-InterVac, Saskatoon and delivered in a 2 mL dose via the subcutaneous route with two immunizations being given four weeks apart. Vaccines were coded so that the experimental team was blinded to the composition of each formulation and group. Each vaccine dose contained 100 μg of the appropriate antigen [Group B: R2 (100 μg), R5 (100 μg), R8 (100 μg), R18 (100 μg), R27 (100 μg), R37 (100 μg) = total 600 μg’s of antigens; Group C: R13 (100 μg), R15 (75 μg), R21 (100 μg), R24 (100 μg), R34 (100 μg), R36 (100 μg) = total 575 μg’s of antigens; Group D: R1 (100 μg), R4 (100 μg), R22 (100 μg), R23 (100 μg), R35 (100 μg) = total 500 μg’s of antigens], except for antigen R15 which contained 75 μg due to low protein yield. Group A, the control group, only received the Emulsigen Plus (MVP Laboratories, Omaha, NE, USA) supplemented with CpG2007 (lot # NBZ5347/08) [42]. The composition of each vaccine used in the animal trial is described in Table 2.
“R” is denoted for rank of gene or protein. The vaccine for group A (placebo/control group) did not contain antigens. The vaccine for groups B, C and D contained antigens (R2, R5, R8, R18, R27, R37), (R13, R15, R21, R24, R34, R36) and (R1, R4, R22, R23, R35) respectively. Emulsigen and CpG oligodeoxynucleotides were used together to achieve a balanced Th1/Th2 immune response.
2.5.3 H. somni preparation for bacterial challenge.
Initial immunization of animals was followed by a booster injection after 28 days. Each animal was challenged with 7.5 x 108 CFU H. somni (AVI1) 42 days after initial immunization via intravenous inoculation. The animals were euthanized on day 63. After the H. somni challenge all animals were monitored on a daily basis for changes in body weight, body temperature and clinical signs of disease (depression, lameness, and respiratory distress).
2.5.4 Clinical examination.
All animals were monitored on a daily basis for changes in body weight, body temperature and clinical signs of disease (depression, lameness, and respiratory distress) for three weeks post H. somni challenge. A clinical scoring points system (from 0 to 4) was used for assessing depression, lameness and respiratory distress. Clinical scores for the assessment of depression were based on the following scale: 0 = bright alert (ears erect, eyes bright, chews cud, stays with group, eating, drinking); 1 = mildly depressed (ears may droop, attempts to stay with group, difficult to corner, eating, drinking); 2 = depressed (walks slowly, lethargic, stands alone with head low, easy to corner, appetite decrease, come to eat but not aggressively); 3 = severely depressed (uninterested, stands alone, head down, does not move with pen mates, may lie in sternal recumbency, reluctant to stand, not eating); 4 = moribund (recumbent, rarely stands, oblivious to surrounding, not eating). Clinical scores for the assessment of lameness were based on the following scale: 0 = normal gait (moves freely, no swellings); 1 = mild lameness (may have swollen joints, favours sore leg (legs) weight bearing all four legs); 2 = moderate lameness [does not weight bear when standing, walks with limp, prefers to lie, swollen joint (joints)]; 3 = severely lame (recumbent, reluctant to rise, none weight bearing, swollen joints); 4 = extreme lameness (unable to rise). Respiratory distresses were based on the following scale: 0 = normal nasal breathing; 2 = mild respiratory distress (intermittent mouth breathing, moist nose and mouth); 3 = moderate respiratory distress (mouth breathing when stressed, laboured breathing); 4 = severe respiratory distress (stands with head low, open mouth breathing, drools, tongue extended). All animals euthanized (animals restrained and administered an overdose of sodium pentobarbital by intra-venous injection) 3 weeks post H. somni bacterial challenge were subjected to a full post mortem analysis with bacteriological analysis carried out on samples of heart, lung, kidney and joints at PDS (Prairie Diagnostic Services, 52 Campus Drive, Saskatoon, SK, S7N 5B4, Canada). Additionally, animals that died or were euthanized during the trial due to extreme illness (humane intervention points) were also subjected to a full post-mortem with bacteriological analysis.
2.6 Enzyme-Linked Immunosorbent Assay (ELISA)
H. somni antigens described in Table 1 were diluted in 0.05 M carbonate/bicarbonate buffer at pH 9.6 to 1 μg/ml and applied to 96-well plates (Immulon 2HB 96U: Thermo Scientific, catalog No. 3655) at 100 μl per well. Plates were covered and left overnight at 4°C. Plates were washed 6 times with reverse osmosis H2O and then blocked with 125 μl diluent (Tris buffered saline with 0.5% fish gelatin, Sigma G7765) for 45 minutes at room temperature. Plates were washed and serum samples (from animal trial # 2) diluted 1/100 were added, and serial four-fold dilutions were done. After two hours at room temperature, plates were washed and KPL Goat anti Bovine IgG (H+L) alkaline phosphatase labelled affinity purified antibody (Mandel catalogue No. KP-15-12-06) diluted 1/5000 was added at 100 μl/well and incubated for 1 hour. After washing, 100 μl PNPP substrate (1 g PNPP (Sigma catalog No. N3254) per 10 ml of 1% Diethanolamine (Sigma catalog No. D8885) with 0.5 mM MgCl2 at pH 9.8 was added for color development. The reaction was stopped by the addition of 30 μl 0.3 M EDTA per well. Plates were read at λ = 405 nm, reference λ = 490 nm on an ELISA reader (Molecular Devices SpectraMax Plus 384). Data was analyzed using microsoft excel.
2.7 Statistical analyses
Statistical analyses were performed using one way ANOVA, Brown-Forsythe test and Bartlett’s test for weight change. Statistical determination for sum of joints affected and sum of clinical scores was completed using Kruskal-Wallis test. Statistical determination of serum polyclonal antibodies against H. somni antigens in ELISAs was determined using Mann Whitney in GraphPad Prism 6 (http://www.graphpad.com/scientific-software/prism/). A P < 0.05 was considered statistically significant.
3. Results
3.1 Serological response to vaccination
Serum antibodies against H. somni antigens were determined using an ELISA procedure with individual serum samples taken prior to vaccination, at the time of boost, immediately prior to H. somni challenge, and immediately prior to euthanization. The titers against each antigen are shown in Table 3. Statistical determination of serum antibodies against H. somni antigens in group B or group C or group D for 21 days post challenge compared to serum antibodies in the non vaccinated group A (shown in S2 Table) was statistically significant at P < 0.05 using Mann Whitney test in a two tailed P value, except for antigen R18 in group B. Compared to serum samples taken prior to vaccination (day 0), median values for serum antibody titers at the time of boost (day 28) or immediately prior to H. somni bacterial challenge (day 42) or immediately prior to euthanization (day 63) against antigens in group B, C, and D increased as shown in Table 3. Among the antigens in group B, R27 (60688) and R37 (58009) had the highest median values for serum antibody titers at day 42 as shown in (Table 3 and Fig 1A). In the same manner, among the antigens in group C or group D, median values for serum antibody titers at day 42 were the highest in R21(49710), R24 (63826) and R36 (48290) or R4 (50635), R22 (57298) and R23 (57180), respectively (Table 3 and Fig 1B and 1C).
(1a) Serum antibody titers to antigens in group B (R2, R5, R8, R18, R27, R37) shown in black. (1b) Serum polyclonal antibody titers to antigens in group C (R13, R15, R21, R24, R34, R36) shown in black. (1c) Serum polyclonal antibody titers to antigens in group D (R1, R4, R22, R23, R35) shown in black. Median values for serum antibody titers shown on Y axis of samples taken prior to vaccination (day 0), at the time of boost (day 28), immediately prior to H. somni bacterial challenge (day 42) and immediately prior to euthanization (day 63). “R” is denoted for rank of gene or protein. Group A, the control group, only received Emulsigen supplemented with CpG is shown in red.
Median values for serum antibody titers taken prior to vaccination (day 0), at the time of boost (day 28), immediately prior to H. somni bacterial challenge (day 42) and immediately prior to euthanization (day 63). “R” is denoted for rank of gene or protein. The vaccine for group A (placebo/control group) did not contain antigens. The vaccine for groups B, C and D contained antigens (R2, R5, R8, R18, R27, R37), (R13, R15, R21, R24, R34, R36) and (R1, R4, R22, R23, R35) respectively.
3.2 Response to infection with H. somni
The response to infection with H. somni on body weight of animals in all four groups (A, B, C, D) is shown in Fig 2A. After the H. somni challenge all animals were monitored on a daily basis for change in body weight. The initial loss/gain of body weight was observed at one day post H. somni challenge. One animal in the control group (A) and two animals in the vaccinated group (B) were euthanized on day 17 post challenge due to being severely ill. Statistical determination of weight change for 21 days post challenge that included the three euthanized animals between vaccinated groups B, C, D and control group A was not statistically significant at P < 0.05 using one way ANOVA (P value 0.3798), Brown-Forsythe test (P value 0.4931) and Bartlett’s test (P value 0.5045) in GraphPad Prism 6. In the same manner, statistical determinations of weight change for 16 days post challenge which included all animals between vaccinated groups B, C, D and control group A, was not statistically significant at P < 0.05 using one way ANOVA (P value 0.2661, Brown-Forsythe test (P value 0.5510) and Bartlett’s test (P value 0.4449). Finally, even though there was no significant difference in weight loss/gain between any groups and the control, group C (Fig 2A) continued to gain weight following infection. The response to infection with H. somni on rectal temperature of animals in all four groups (A, B, C, D) is shown in Fig 2B. As shown in Fig 2B, there was no difference in rectal temperature between vaccinated groups B, C, D and control group A.
(2a) Weight change among group A (non vaccinated/ placebo group) and groups B, C and D (vaccinated) animals measured for 21 days post challenge. (2b) Rectal temperature among group A (non vaccinated/placebo group) and groups B, C and D (vaccinated) animals measured for 21 days post challenge. Animal groups are shown in colors: group A (blue), group B (red), group C (green) and group D (purple). Standard error bars included.
The response to infection with H. somni on the sum of joint lesions is shown in Fig 3A. All animals euthanized were subjected to a full post mortem analysis with bacteriological analysis carried out on joint samples. Statistical determination of the sum of joint lesions for 21 days post challenge that included the three euthanized animals between vaccinated groups B, C, D and control group A was not significant at P < 0.05 using Kruskal-Wallis test (P value 0.5814) in GraphPad Prism 6. Group C had the lowest sum of joint lesions (six) among the three vaccinated groups (B, C, and D) as well as compared to the control group A (S3 Table).
(3a) Sum of joint lesions among control group A vs vaccinated groups B, C and D animals measured from day 1 to 21 post challenge. (3b) Sum of clinical scores measured from day 1 to 16 post challenge or day 1 to 21 days post challenge. Two animals in group (B) were euthanized on day 17 post challenge due to being severely ill.
The response to infection with H. somni on the sum of clinical scores is shown in Fig 3B. All animals were subjected to a full post mortem analysis with bacteriological analysis carried out on samples of heart, lung, kidney and joints (S4 Table). Statistical determination of the sum of clinical scores for 16 days post challenge was not statistically significant at P < 0.05 using Kruskal-Wallis test (P value 0.7152). Statistical determination of the sum of clinical scores for 21 days post challenge that included the three euthanized animals was not statistically significant at P < 0.05 using Kruskal-Wallis test (P value 0.7140) in GraphPad Prism 6. The total sum of clinical scores for 21 days post challenge for groups A, B, C, and D were 54, 87, 48 and 71 respectively (including the three euthanized animals). Even though there was no significant difference in clinical scores, group C had the lowest sum of clinical scores of 48 among the three vaccinated groups (B, C, D) as well as compared to the control group A.
Discussion
H. somni is an economically important global pathogen responsible for significant economic losses to the livestock industry not only in North America but globally (e.g. Paraná State of southern Brazil, Hungary, UK, Argentina, Nigeria, South Africa) [3,43,44,45,46,47,48]. Vaccination has proven to be the most efficient method of protecting humans and animals from infectious diseases and is also one of the most cost effective interventions in preventing epidemics [28]. Current vaccines against H. somni have shown to be of limited efficacy where feedlots, ranchers and cattle producers practising proper BRD management protocols still face considerable animal losses due to systemic infections [5,22,23,49,50]. Genome-based reverse vaccinology has the advantage of identifying a larger number of vaccine candidates in a relatively short period of time [25–28]. Using this strategy we were able to test the efficacy of a subset of proteins identified in a field isolate of H. somni (e.g. strain AVI1) isolated in 2012. Moreover, proteins localized on the cell surface (e.g. OMPs) and also conserved between strains may contribute to bacterial virulence and host immunity [4,24]. Multiple component vaccines have the added advantage of containing more than one antigen which may increase efficacy [5].
Vaccines containing a single OMP antigen or surface fibrillar network, immunoglobulin binding protein A (IbpA) have been previously assessed by other groups [5,18]. For example, lipoproteins p40 (40 kDa protein) and p31 (31 kDa protein: homologous to lipoprotein Plp4 of Mannheimia haemolytica A1) when used as vaccine candidates exert a protective effect in mice against H. somni related septicemia [5]. Calves vaccinated with a domain of the IbpA annotated as DR2 were also protected from H. somni related pneumonia [18]. In our study, vaccination with antigens in group B (R2, R5, R8, R18, R27, R37), group C (R13, R15, R21, R24, R34, R36) or group D (R1, R4, R22, R23, R35) using a large animal model (bovine) followed by H. somni bacterial challenge provided the added advantage of screening combinations of recombinant proteins (NCBI Blast comparison of antigens is shown in Table 1). The results in trial # 2 demonstrate that animals vaccinated with the combination of antigens in group C had the lowest number of clinical signs (Fig 3B), joint lesions (S3 Table), overall illness (S4 Table) and the highest gain in weight (Fig 2A) compared to the control group, but none of which was significantly different from the control group. Additionally, group C had the lowest number of clinical signs, joint lesions, overall illness and the greatest weight gain among the other vaccinated groups (B or D). Statistical determination of serum antibodies against H. somni antigens in group C compared to sera from the control group was significant. The prospect of using conserved OMPs as subunit vaccines is ideal for Gram-negative bacteria that show highly variable sequence diversity [5]. The results presented in trial # 2 show that the combination of R13, R15, R21, R24, R34 and R36 [blastp on NCBI, R13: H. somni porin, WP_012340590.1 (89%); R15: LPS assembly protein LptD, WP_012341555.1 (99%); R21: H. somni membrane protein, WP_011609419.1 (93%); R24: OMP1, ACA32123.1 (99%); two hypothetical proteins, ABI25169.1 (99%); WP_011608601.1 (99%)] provided protection against systemic infection by H. somni challenge. However, their ability to protect against the pneumonic form of the disease was not tested in this study. Among these six antigens, the genes coding for R21, R24 and R36 were fused to the M. haemolytica lktA gene. The leukotoxin from M. haemolytica has been shown to be protective against M. haemolytica infections, but it is not cross protective against other pathogens [51]. If protection against H. somni challenge was due to the leukotoxin portion of the fusion proteins, then other antigens such as R27, R37 in group B or R4, R22, R23D in group D that were also fused to leukotoxin, should have produced a similar effect. Nonetheless, titers of serum antibodies in leukotoxin fused proteins (R21, R24, R36) among the group C antigens on day 42 was above 40,000 compared to R15 and R34 (histidine tagged proteins) and R13 (inclusion body preparation) (Table 3). Similarly, leukotoxin fused antigens, R27 and R37 in group B and R4, R22 and R23 in group D had serum antibody titers above 50,000 on day 42 (Table 3). The results from this study may indicate that there is a close correlation between the antibody response and leukotoxin fused antigens. Hypothetical proteins such as R34 (NCBI accession No. ABI25169.1) or R36 (NCBI accession No. WP_011608601.1) in group C are interesting in that their biological function is unknown and may have made a significant contribution to the total protective effect exerted by the multi-component vaccine. Therefore, future structural studies of these two proteins will be necessary to determine their immunogenic properties.
The antigens in group C may not all be needed to induce protection. Future animal trials using group C antigens with animal groups receiving each antigen alone or combinations of two-to-three antigens should be tested. This may result in better protection against histophilosis in cattle. In conclusion, the subunit vaccine used in group C exhibits a trend towards protective immunity in cattle and would be a good candidate for further analysis to determine which proteins were responsible for the trend towards protection.
Supporting Information
S1 Table. DNA sequences and amino acid sequences of antigens used for vaccine groups B, C, and D, from H. somni strain (AVI1) used in the animal trial #2 at VIDO-Intervac, Saskatoon.
“R” is denoted for rank of gene or protein.
https://doi.org/10.1371/journal.pone.0159070.s001
(DOCX)
S2 Table. Statistical determination of serum antibodies using Mann Whitney test “R” is denoted for rank of gene or protein.
The vaccine for group A (placebo/control group) did not contain antigens. The vaccine for groups B, C and D contained antigens (R2, R5, R8, R18, R27, R37), (R13, R15, R21, R24, R34, R36) and (R1, R4, R22, R23, R35) respectively.
https://doi.org/10.1371/journal.pone.0159070.s002
(DOCX)
S3 Table. The sum of joint lesions for each animal measured from day 1 to 21 post challenge for all groups: A (non-vaccinated) and B, C, D (vaccinated).
https://doi.org/10.1371/journal.pone.0159070.s003
(DOCX)
S4 Table. Full post-mortem analysis of euthanized animals.
Bacteriological analysis carried out on samples of heart, lung, kidney and joints. Positive cultures for H. somni are shown in dark green.
https://doi.org/10.1371/journal.pone.0159070.s004
(DOCX)
Acknowledgments
This work was supported by Alberta Livestock and Meat Agency Ltd (ALMA) and Alberta Cattle Feeders Association.
Author Contributions
- Conceived and designed the experiments: AP CAM JVD CD.
- Performed the experiments: CAM DD GC BE NR.
- Analyzed the data: CAM DW HT AP.
- Contributed reagents/materials/analysis tools: CAM HT.
- Wrote the paper: CAM AP.
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