Abstracts

INTRODUCTION

Strangles is a highly contagious and economically important infection in horses caused by Streptococcus equi subsp. equi (S. equi), a Gram-positive Streptococcus belonging to Lancefield group C (Harrington et al., 2002HARRINGTON, D.J; SUTCLIFFE, I.C.; CHANTER, N. The molecular basis of Streptococcus equi infection and disease. Microb. Infect., v.4, p.501-510, 2002.; Waller and Jolley, 2007WALLER, A.S.; JOLLEY, A.K. Getting a grip on Strangles: Recent progress towards improved diagnostics and vaccines. Vet. J., v.173, p.492-501, 2007.). The disease occurs with high morbidity and low mortality rates, and its economic impact is due to veterinarian expenses and the need to restrain animals from their activities (Newton et al., 1997NEWTON, J.R.; WOOD, J.L.; DUNN, K.A. et al. Naturally occurring persistent and asymptomatic infection of the guttural pouches of horses with Streptococcus equi. Vet. Rec., v.140, p.84-90, 1997.). Efficient identification and treatment of carriers is important for prevention and eradication of this disease (Boyle, 2011BOYLE, A. Streptococcus equi subspecies equi infection (strangles) in horses. Compend. Contin. Educ. Vet., v.33, p.E1-7, 2011.).

Presumptive diagnosis is readily accomplished by using the clinical signs; however, the gold standard for definitive diagnosis is a bacterial culture (Sweeney et al., 2005SWEENEY, C.R.; TIMONEY, J.F.; NEWTON, J.R.; HINES, M.T. ACVIM Consensus Statement - Streptococcus equi infections in horses: Guidelines for treatment, control and prevention of Strangles. J. Vet. Int. Med., v.19, p.123-134, 2005.). The diagnosis based on the isolation and identification of S. equi subsp. equi and the differentiation amongst the subspecies is traditionally based on biochemical tests (Kuwamoto et al., 2001KUWAMOTO, Y.; ANZAY, T.; WADA, R. Microplate sugar-fermentation assay distinguishes Streptococcus equi from other streptococci of Lancefield's group C. Equi. Vet. Sci., v.2, p.47-49, 2001.). Nevertheless, one needs to be aware that strains with atypical patterns of fermentation of trehalose, lactose or both might be isolated (Grant et al., 1993GRANT, S.T.; EFSTRATION, A.; CHANTER, N. Laboratory diagnosis of strangles and the isolation of atypical Streptococcus equi. Vet. Record, v.133, p.215-216, 1993.).

Another method is through polymerase chain reaction (PCR), although PCR being more sensitive than bacterial culture, does not distinguish living from dead organisms. Thus, its use should be together with bacterial culture (Timoney, 2004TIMONEY, J.F. The pathogenic equine streptococci. Vet. Res., v.35, p.397-409, 2004.). Since antibodies against the pathogen rise during the infection (Timoney, 2004TIMONEY, J.F. The pathogenic equine streptococci. Vet. Res., v.35, p.397-409, 2004.; Robinson et al., 2013ROBINSON, C.; STEWARD, K.F.; POTTS, N. et al. Combining two serological assays optimises sensitivity and specificity for the identification of Streptococcus equi subsp. equi exposure. The Vet. J., v.197, p.188-191, 2013.), ELISA (Enzyme Linked Immuno Sorbent Assay) is a Strangles diagnostic alternative. The use of ELISA for indirect diagnosis of the disease has become a subject of interest for researchers who wish to use the test as an auxiliary tool of equine adenitis control. (Knowles et al.,2010KNOWLES, E.J.; MAIR, T.S.; BUTCHER, N. et al. Use of a novel serological test for exposure to Streptococcus equi subspecies equi in hospitalised horses. Vet. Rec., v.166, p.294-297, 2010.; Knowles, 2011KNOWLES, E.J. Serological ELISA Test for Streptococcus equi (strangles). In: AHT / BEVA / DEFRA Equine Quarterly Disease Surveillance Report. v.7, p.1-2, 2011.).

S. equi synthesizes an outer membrane protein of 58 kDa encoded by the SeM gene that is particularly important due to its antiphagocytic and adherence properties. This protein has been used as a vaccine and diagnostic antigen for strangles (Timoney et al, 1997TIMONEY, J.F. The pathogenic equine streptococci. Vet. Res., v.35, p.397-409, 2004.; Anzai et al., 1999ANZAI, T.; TIMONEY, J.F.; KUWAMOTO, Y. et al. In vivo pathogenicity and resistance to phagocytosis of Streptococcus equi strains with different levels of capsule expression. Vet. Microbiol., v.67, p.277-286, 1999.; Harrington et al., 2002HARRINGTON, D.J; SUTCLIFFE, I.C.; CHANTER, N. The molecular basis of Streptococcus equi infection and disease. Microb. Infect., v.4, p.501-510, 2002.; Lindahl et al., 2011LINDAHL, S.; SÖDERLUND, R.; FROSTH, S. et al. Tracing outbreaks of Streptococcus equi infection (strangles) in horses using sequence variation in the seM gene and pulsed-field gel electrophoresis. Vet. Microbiol., v.153, p.144-149, 2011.).

Brazil has the fourth largest herd of horses in the world, and Rio Grande do Sul state has the third largest squad in the country, with more than 452,000 heads (IBGE, 2009). For this reason studies to assist in the epidemiological investigation and diagnosis of important diseases for this animal species are extremely relevant.

The aim of this study focused on cloning, expressing and characterizing the recombinant SeM protein of S. equi subsp. equi and evaluating it as antigen in an indirect ELISA.

MATERIAL AND METHODS

For the execution of this work the serum samples were collected in the South of Brazil, in Rio Grande do Sul State. Peripheral blood, collected from different farms, was drawn using a 19g needle attached to Vacutainer tubes (Becton-Dickinson, Rutherford, NJ) from the jugular vein of 40 colostrum deprived foals (negative control), from 46 horses vaccinated with commercially available vaccine against strangles, and also from 46 horses with clinical and etiological diagnosis of strangles (positives). The presence of carrier animals in different groups was not considered in this work. The vaccinated animals received three intramuscular doses of 5mL of commercial vaccine (bacterin adjuvanted with alumen hydroxide), (Vacina contra garrotilho Leivas Leite S/A Indústrias Químicas e Biológicas), with the first dose given 180 days after birth, the second 21 days later, and the third 30 days after the second. The clinical diagnosis of the disease was based on clinical signs, and etiology was confirmed by bacterial isolation and biochemical confirmation using the commercial kit API 20 STREP (BioMerieux, France). The same methodology was used to isolate and characterize the field used to clone the recombinant protein. Sera samples were stored at -20ºC until usage.

The bacterial strain used to extract DNA to be used as a template for rSEM was a field strain isolated and characterized previously. It was grown in Brain Heart Infusion (Difco, USA), enriched with 2% Peptone (Difco, USA), and incubated at 37ºC overnight. Genomic DNA was extracted, according to Sambrook and Russel (2001)SAMBROOK, J.; RUSSELL, D.W. Molecular cloning: a laboratory manual. 3. ed. New York: Cold Spring Harbor Laboratory Press, 2001. 800 p., using cetyltrimethylammonium bromide (CTAB) protocol after treatment with 5μL of proteinase K (20mg/mL) for 60min at 37°C. The nucleic acid was extracted with buffered phenol-chloroform and precipitated with isopropanol and ethanol 70GL. Escherichia coli Top10F and BL21 (DE3) pLysS strains (Invitrogen^TM, USA) were used, respectively, for cloning procedures and expression of the recombinant protein.

Primers for SeM amplification (Primer forward: 5'CGGGATCCTCGAGGTTAGTCGTAC3'; primer reverse: 5'GGGGTACCTTAGTTTTCTTTGCGT3') were designed based on GenBank^TM SeM of S. equi subsp. equi sequence (access number U73162), using the Vector NTI 8.0 software (Informax(r), USA). The amplicon was purified using Ilustra^TM DNA and Gel Band Purification kit (GE Healthcare, USA) and, after restriction digestion and ligation into pAE vector (Ramos et al., 2004RAMOS, C.R.; ABREU, P.A.; NASCIMENTO, A.L.; HO, P.L. A high-copy T7 Escherichia coli expression vector for the production of recombinant proteins with a minimal N-terminal His-tagged fusion peptide. Braz. J. Med. Biol. Res., v.37, p.1103-1109, 2004.), the ligation product was used to transform by electroporation Escherichia coli Top10F (Invitrogen^TM, USA). All cloning procedures were carried out according to standard procedures (Sambrook and Russel, 2001SAMBROOK, J.; RUSSELL, D.W. Molecular cloning: a laboratory manual. 3. ed. New York: Cold Spring Harbor Laboratory Press, 2001. 800 p.). The recombinant plasmid, named pAE/SeM, was verified by sequencing of the entire insert with an automated DNA sequencer (MegaBACE 500, GE Healthcare, USA). The expression of the recombinant protein by E. coli BL21 (DE3) pLysS (Invitrogen^TM, USA) was induced with 1 mM Isopropyl-β-D-thiogalactopyranoside (IPTG - Sigma, USA) for 3h, once the absorbance at 600 nm reached 0.6-0.8. Pellets of the culture were obtained by centrifugation at 10,000×g for 10 min at 4°C, suspended in lysis buffer (50 mM NaH2PO4, 300 mM NaCl, 15 mM Imidazole, N-lauroylsarcosine 0.2% and 1mg/mL of lysozyme), incubated at 4°C in an orbital shaker (CERTOMAT(r) BS-T, B. Braun Biotech International) for 30 min and sonicated. After centrifugation at 10,000×g for 30min at 4°C, the supernatant was purified by affinity chromatography in a nickel-charged Sepharose column using the ÄKTAprime chromatography system (GE Healthcare, UK) following the manufacturer's instructions. Fractions containing the recombinant protein were pooled and dialyzed in PBS containing 0.1% and without N-lauroylsarcosine pH 7.4 for a 48h period. The protein was quantified with the BCA^TM Protein Assay Kit (Pierce, USA) following manufacturer's instructions.

Purified fractions of rSeM were separated in a 10% sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) resolving gel and dyed with Comassie blue following Sambrook and Russel (2001)SAMBROOK, J.; RUSSELL, D.W. Molecular cloning: a laboratory manual. 3. ed. New York: Cold Spring Harbor Laboratory Press, 2001. 800 p.. Western blotting was done using 12 µL of a solution containing 250 μg/mL of rSeM through transfer of SDS-PAGE to a nitrocellulose membrane (Hybond-C Extra, GE Healthcare, UK). The membrane was then blocked for 1 h with 5% non-fat dry milk, 1:10,000 anti-6×His alkaline phosphatase conjugated monoclonal antibodies - MAb (Sigma, USA) was added and incubated for 1h. Then DAB-chromogen substrate (9mL Tris-HCl 50 mM, 1mL nickel sulphate 0.3%, 10μL of 30% hydrogen peroxide and 6mg 3.3-diaminobenzidine tetrahydrochloride - Sigma, USA) was placed over the membrane and the reaction was recorded.

Dot blot was performed using rSeM and sera from horses clinically infected with S. equi diluted 1:2,000 in PBS-T. Ten µL of a solution containing 250μg/mL of rSeM were applied on a nitrocellulose membrane (Hybond-C Extra, GE Healthcare, UK). The membrane was dried and then blocked with 5% non-fat dry milk in PBS-T. After 3 washes the same amount of serum was placed over the antigen. After incubation for 1h, 1:10,000 peroxidase conjugated anti-horse IgG (whole molecule, Sigma, USA) was added and incubated for 1h. Anti-6×His alkaline phosphatase conjugated MAb (Sigma, USA) was used as positive control and serum from colostrum deprived foals was used as negative control. The reaction was detected with DAB-chromogen substrate (Sigma, USA).

To standardize the ELISA test in order to determine the best serum dilution to be used, a check board was performed using different antigen concentration and sera dilutions (pool of sera from the day that supposedly would have the higher titer). Then the dilution that fell within the linear range of the ELISA was used. For detection of specific antibodies against S. equi, individual sera were tested in triplicate. The ELISA was standardized using polystyrene ELISA plates (CRAL, Brazil) sensitized at 4ºC overnight with 50μL of rSeM containing 12μg/mL suspended in carbonate-bicarbonate buffer pH 9.6. After this period the plates were washed 3 times with PBS-T and blocked using PBS-T with 5% non fat milk at 37°C, for 1h. Sera of horses diluted 1:2000 were added in duplicate to the wells and incubated for 1.5 h at 37ºC. After 3 washes with PBS-T, 1:10.000 peroxidase conjugated anti-horse (whole molecule, Sigma, USA) was added and incubated for 1.5h at 37ºC. Ortho-phenyl diamine was used as chromogen Optical densities (OD) were read at 492nm in a MR 700 ELISA reader (Dynatech Labs. Inc., USA). A pool of sera from negative and positive animals was used in all plates, working as an intra-plate control.

The Receiver Operating Characteristics (ROC) analysis was used to estimate the specificity, sensitivity, cut-off, and the predictive values. The significance of the differences of mean absorbances was estimated by ANOVA, and the difference in means among the groups was estimated by the t-Test, using the Statistix software version 8 (Analytical Software, USA). The ROC analysis was performed by MedCalc statistical software, version 10.3.0.0., according to that described by Borsuk et al. (2011)BORSUK, S.; ANDREOTTI, R.; LEITE, F.P. et al. Development of an indirect ELISA-NcSRS2 for detection of Neospora caninum antibodies in cattle. Vet. Parasitol., v.177, p.33-38, 2011..

The study has approval from the Federal university of Pelotas Animal Ethic Committee under number CEEA 2133.

RESULTS

Sequencing of the cloned SeM gene showed 100% of identity with the GenBank^TM sequences. The rSeM, with an apparent molecular mass of 58kDa, was successfully produced by transformed E. coli BL21 (DE3) pLysS strains (Invitrogen^TM, USA) and purified by affinity chromatography. The vector (pAE) used in this work has a histidine tail that served as tool for purification and detection of the recombinant protein.

The rSeM reacted in Western blots with anti-6×His alkaline phosphatase conjugated MAb (Figure 1A) and in dot blot with sera of horses with clinical and etiological strangles diagnosis (Figure 1B), showing that it has antigenic properties similar to native SeM.

The correlation between the groups assessed by ROC analysis with a cut-off OD value of 0.374 was able to discriminate the 46 positive animals from the 132 horses examined. Using this same OD cut-off value (0.374) we could differentiate the vaccinated animals from the negative control ones. Using an ELISA OD threshold value of 0.374 to distinguish between positive and negative sera samples, this ELISA was able to yield a specificity of 100% and a sensitivity of 100% for this equine population. Using this same cut-off, and considering a population where the prevalence can range from 10 to 90%, the test gives a positive predictive value of 82 to 99% and negative predictive value of 100%, respectively, with the prevalence of the disease in a particular area (Figure 2).

Analyzing the vaccinated and negative control groups using the ELISA OD value of 0.374 as threshold we observed a sensitivity of 91.3 % (79.2- 97.5) and a specificity of 100 % (91.1-100). Using this same value as a cut-off point and considering prevalence that can range from 10 to 90%, it shows a positive predictive value of 80.2 to 99.6% respectively, and a negative predictive value that can range from 99 to 55% (Figure 2).

Considering a cut-off of 0.641 OD discriminates between the positive and the vaccinated animals, and observed a specificity of 89.1 % and a sensitivity of 93.5 %. This test cut-off value gives a positive predictive value of 93.2 % and a negative predictive value of 89.6 % for a prevalence that can range from 10 to 90 % in a specific area (Figure 2).

DISCUSSION

Equine adenitis, also known as "Strangles" is currently considered the most often diagnosed infectious equine disease world-wide (Waller and Jolley, 2007WALLER, A.S.; JOLLEY, A.K. Getting a grip on Strangles: Recent progress towards improved diagnostics and vaccines. Vet. J., v.173, p.492-501, 2007.). The disease has a low mortality rate, but high morbidity, which is highly significant where there are large concentrations of horses. In Brazil, the large number of animals coupled with the need for increased production leads to increased occurrence of this and other diseases and associated economic losses to the Equine (Silva and Vargas, 2006SILVA, M.S.; VARGAS, A.P.C. Adenite Equina: Aspectos clínicos, agente etiológico e métodos de diagnóstico. Arq. Inst. Biol., v.4, p.493-498, 2006.; Ribas et al., 2009RIBAS, L.M.; MORAES, C.M; LINS, L.A. et al. Fatores de risco associados a doenças respiratórias em potros Puro Sangue Inglês do nascimento ao sexto mês de vida. Cienc. Rural, v.39, p.1789-1794, 2009.). In the state of Rio Grande do Sul strangles outbreaks occur in various areas (Libardoni et al., 2013LIBARDONI, F.; VIELMO, A.; FARIAS, L. et al. Diversity of seM in Streptococcus equi subsp. equi isolated from strangles outbreaks. Vet. Microbiol., v.162, p.663-669, 2013.).

Since immunologically mediated protection against strangles resides in antibodies (Galan et al., 1986GALAN, J.E.; TIMONEY, J.F.; LENGEMANN, F.W. Passive transfer of mucosal antibody to Streptococcus equi in the foal. Infect. Immun., v.54, p.202-206, 1986.; Sheoran et al., 1997SHEORAN, A.S.; SPONSELLER, B.T.; HOLMES, M.A.; TIMONEY, J.F. Serum and mucosal antibody isotype responses to M-like protein (SeM) of Streptococcus equi in convalescent and vaccinated horses. Vet Immunol Immunopathol., v.59, p.239-251, 1997.), ELISA is well suited to evaluate the immunity herd status for S. equi and for Strangles diagnosis (Robinson et al., 2013ROBINSON, C.; STEWARD, K.F.; POTTS, N. et al. Combining two serological assays optimises sensitivity and specificity for the identification of Streptococcus equi subsp. equi exposure. The Vet. J., v.197, p.188-191, 2013.).

The ELISA method for the detection of serum antibodies against the SeM protein is commercially available, and can provide some information regarding the exposure of horses to S. equi (Waller and Jolley, 2007WALLER, A.S.; JOLLEY, A.K. Getting a grip on Strangles: Recent progress towards improved diagnostics and vaccines. Vet. J., v.173, p.492-501, 2007.). This test, however, does not distinguish between vaccine and infection responses (Sweeney et al., 2005SWEENEY, C.R.; TIMONEY, J.F.; NEWTON, J.R.; HINES, M.T. ACVIM Consensus Statement - Streptococcus equi infections in horses: Guidelines for treatment, control and prevention of Strangles. J. Vet. Int. Med., v.19, p.123-134, 2005.).

The results showed that rSeM of S. equi subsp. equi and the statisticals parameters defined to be used in ELISA were able to discriminate negative and positive, negative and vaccinated and vaccinated and strangles positive horses. These results are in accordance with the strong serum IgG responses to surface exposed proteins, including SeM, which is produced as a result of strangle infection (Timoney, 2004TIMONEY, J.F. The pathogenic equine streptococci. Vet. Res., v.35, p.397-409, 2004.).

ELISA was subjected to Receiver Operating Characteristic analysis (Greiner, 2000GREINER, M.; PFEIFFER, D.; SMITH, R.D. Principles and practical application of the receiver-operating characteristic analysis for diagnostic tests. Prev. Vet. Med., v.45, p.23-41, 2000.), where this analysis has been successfully used for interpretation of ELISA results (Fosgate et al., 2007FOSGATE, G.T.; SCOTT, H.M.; JORDAN, E.R. Development of a method for Bayesian nonparametric ROC analyses with application to an ELISA for Johne's disease in dairy cattle. Prev. Vet. Med., v.81, p.178-193, 2007.), including the Strangles diagnostics (Robinson et al., 2013ROBINSON, C.; STEWARD, K.F.; POTTS, N. et al. Combining two serological assays optimises sensitivity and specificity for the identification of Streptococcus equi subsp. equi exposure. The Vet. J., v.197, p.188-191, 2013.). The rationale for the optimal ROC curve is that one wants the highest true-positive rate (sensitivity) for the lowest false positive rate (1-specificity).

It has been reported that the IgG isotypes in horses vaccinated and infected with S. equi are different. Vaccinated animals showed high levels of IgGb (IgG4 and IgG7) in the serum, but not IgGa (IgG1), IgGc (IgG6) and IgG (T) (IgG3 and IgG5), while convalescent animals showed a high level of all isotypes (Sheoran et al., 1997SHEORAN, A.S.; SPONSELLER, B.T.; HOLMES, M.A.; TIMONEY, J.F. Serum and mucosal antibody isotype responses to M-like protein (SeM) of Streptococcus equi in convalescent and vaccinated horses. Vet Immunol Immunopathol., v.59, p.239-251, 1997., Lewis et al., 2008LEWIS, M.J.; WAGNER, B.; WOOF, J.M. The different effector function capabilities of the seven equine IgG subclasses have implications for vaccine strategies. Mol. Immunol., v.45, p.818-827, 2008.). Therefore, analysis of the data suggests that the difference in the isotype present in infected animals might be responsible for the OD difference observed when compared to vaccinated animals. However, the possibility would not be excluded that in convalescent horse the drop in titer with time might give confounding results. It is also possible to use the data from the ROC analysis cut-off to infer discrimination between the three groups, showing that ELISA is an effective tool to be used for monitoring and differentiating horse herds respiratory diseases.

Various diseases affect the respiratory tract of horses and depending on the presented clinical signs some of these diseases can be misinterpreted as Strangles, which can disrupt the diagnosis. Frey Junior (2006)FREY JUNIOR, F. Índices epidemiológicos em potros Puro Sangue de Inglês, do nascimento ao sexto mês de vida, na região de Bagé-RS. Dissertação (Mestrado em Medicina Veterinária) - Curso de Pós-graduação em Veterinária, Universidade Federal de Pelotas. 2006. 46f. , reports that in the farms in southern Brazil the second group of diseases with higher occurrence in young horses are those associated with the respiratory tract. This fact demonstrates the importance of the ELISA assay described in this work, because the test can be an important tool to aid veterinarians.

The identification of antibodies against S.equi is important for determining the time of vaccination against the disease, as some animals may have complications related to deposition of antigen -antibody complexes. Purpura hemorrhagica is a aseptic necrotizing vasculitis that can occur in horses after natural exposure or after vaccination of horses that have had strangles, which is related to high concentrations of serum antibodies against SeM protein (Sweeney et al ., 2005SWEENEY, C.R.; TIMONEY, J.F.; NEWTON, J.R.; HINES, M.T. ACVIM Consensus Statement - Streptococcus equi infections in horses: Guidelines for treatment, control and prevention of Strangles. J. Vet. Int. Med., v.19, p.123-134, 2005.). For this reason, serological tests such as ELISA are indicated for monitoring horses that may be predisposed to this disease complication. (Boyle, 2011BOYLE, A. Streptococcus equi subspecies equi infection (strangles) in horses. Compend. Contin. Educ. Vet., v.33, p.E1-7, 2011.).

One of the main problems in the production of serological tests is the use of antigens that produce cross-reactivity with antibodies raised against different etiologic agents. Timoney et al. (1997)TIMONEY, J.F. The pathogenic equine streptococci. Vet. Res., v.35, p.397-409, 2004. reported that proteins produced by some species of Streptococcus may high cross reactivity. The rSeM used in this paper is an antigen showing low cross reactivity with other proteins in the Streptococcus species, making the test presented here more efficient.

One limitation of this work is the number of animals studied. An increase in the number of sera tested may produce different results, therefore reducing the specificity and sensitivity observed. Nevertheless, the difference in absorbance between negative and positive animals by the ROC analyses is so distinct that the test will be very helpful for monitoring the immunological status of the herd. Since immunologically mediated protection against strangles predominantly resides in antibodies, information on the kinetics of protective immunity is of great importance, making the prophylactic measures easier to be conducted by the producer.

CONCLUSIONS

The rSeM produced in this work suggests a promising antigen to use in the immune diagnostic of strangles. The ELISA method described in this study demonstrates sensitivity and specificity that allows discriminating a horse population into negative, vaccinated and positive for S. equi subsp. equi antibodies. This assay might constitute an important tool for monitoring herd immune status for strangles.

ACKNOWLEDGEMENTS

The PROPESP/UFPA, due to support for the publication of this paper.

REFERENCES

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