Multiple specificities of immunoglobulin M in equine fetuses infected with Leptospira interrogans indicate a competent immune response.

REASONS FOR PERFORMING STUDY: Foals of mares infected with Leptospira interrogans serovar Pomona type kennewicki (Lk) may be aborted/stillborn or delivered as healthy foals. Is fetal survival explained in part by the immune response of the fetus to Leptospira antigens? OBJECTIVES: To describe an outbreak of Leptospira abortion in which infected mares delivered dead/sick or normal foals and determine specificities of antibody in a collection of 54 fetuses from similar outbreaks. STUDY DESIGN: Outbreak investigation in combination with a case-control study of a larger set of samples from aborted fetuses. METHODS: Serology and polymerase chain reaction (PCR) on urine and amniotic fluids were used to diagnose infection during an outbreak of Leptospira abortion. Specificities of immunoglobulin (Ig)M, IgGa and IgGb for recombinant proteins of Lk in archived fluids of fetuses from similar outbreaks were compared by ELISA with those of fluids of fetuses not infected with Leptospira spp. RESULTS: Five fetuses of 11 infected mares in an outbreak survived in utero in the presence of persistent placental infection and were healthy at foaling. Fetuses of 6 mares in the outbreak were aborted or died soon after birth. Significantly greater (P<0.05) IgM reactivity with all recombinant proteins and with Lk sonicate was observed in 54 archived fluids from Leptospira infected fetuses than in fluids of 30 of non-Leptospira infected fetuses. Low levels of IgGa and IgGb specific for LipL32 and Lk sonicate and traces of LigA and Hsp15 specific IgGa were detected in a minority of archived fluids from Leptospira infected fetuses. CONCLUSION: Although mainly mediated by IgM, a high level of immune competence in aborted fetuses was evidenced by the multiplicity of Leptospira proteins targeted. This is likely to contribute to survival of foals in mares with evidence of placental infection at foaling as detailed in a typical outbreak.

Surface-associated Hsp60 chaperonin of Leptospira interrogans serovar Autumnalis N2 strain as an immunoreactive protein.

The present study has been formulated in order to detect an immunoreactive protein whose identification can play a major role in the early diagnosis of disease. The identified protein will be produced by recombinant methods and used for the recombinant protein based ELISA. A comparison was made between the developed method and the gold standard MAT test to evaluate the serodiagnosis potential of the protein. The protein profile, immunoblot and MALDI-TOF analysis was carried out to identify the immunoreactive protein. The immunoreactive protein identified was used to develop ELISA for the diagnosis of leptospirosis using patients' sera with various clinical manifestations. The immunoreactive protein was identified as Leptospira GroEL chaperonin of molecular weight 60 kDa. The theoretical/experimental molecular weights, pI were found to be 58.5/60 kDa and 5.41/6, respectively. The overall results of the recombinant GroEL-IgM ELISAs showed cumulative sensitivity, specificity, positive predictive value, and negative predictive values of 90.6%, 94.9%, 94.6%, and 91.0%, respectively. The performance of such ELISA appeared better than that of any other serological tests previously evaluated for the diagnosis of leptospirosis in India. Thus, a highly conserved and immunogenic outer exposed GroEL protein during infection clearly merits further use in the serodiagnosis of leptospirosis.

Characterization and immunogenicity of pyrogenic mitogens SePE-H and SePE-I of Streptococcus equi.

Two pyrogenic mitogens, SePE-H and SePE-I, were characterized in Streptococcus equi, the cause of equine strangles. SePE-H and SePE-I have molecular masses of 27.5 and 29.5 kDa, respectively, and each is almost identical to its counterpart in Streptococcus pyogenes M1. Both genes are adjacent to a gene encoding a phage muramidase of 49.7 kDa and are located immediately downstream from a phage genomic sequence almost identical to a similar phage sequence in S. pyogenes M1. Strong mitogenic responses were elicited by both proteins from horse peripheral blood mononuclear cells. However, although both were pyrogenic for rabbits, only SePE-I was pyrogenic in ponies. Convalescent sera contained antibody to each mitogen and horses recovered from strangles or immunized with SePE-I were resistant to the pyrogenic effect of SePE-I. The immunogenicity of SePE-I suggests that it should be included in new generation strangles vaccines. In isolates of S. equi sepe-I and sepe-H were consistently present but they were absent from the closely related Streptococcus zooepidemicus, suggesting that phage mediated transfer was an important event in the formation of the clonal, more virulent, S. equi from its putative S. zooepidemicus ancestor.

Comparison of the sequences and functions of Streptococcus equi M-like proteins SeM and SzPSe.

Streptococcus equi (Streptococcus equi subsp. equi), a Lancefield group C streptococcus, causes strangles, a highly contagious purulent lymphadenitis and pharyngitis of members of the family Equidae. The antiphagocytic 58-kDa M-like protein SeM is a major virulence factor and protective antigen. The amino acid sequence and structure of SeM has been determined and compared to that of a second, 40-kDa M-like protein (SzPSe) of S. equi and to those of other streptococcal proteins. Both SeM and SzPSe are mainly alpha-helical fibrillar molecules with no homology other than that between their signal and membrane anchor sequences and are only distantly related to other streptococcal M and M-like proteins. The sequence of SzPSe indicates that it is an allele of SzP that encodes the variable protective M-like and typing antigens of S. zooepidemicus (S. equi subsp. zooepidemicus). SeM is opsonogenic for S. equi but not for the closely related S. zooepidemicus, whereas SzPSe is strongly opsonogenic for S. zooepidemicus but not for S. equi. Both proteins bind equine fibrinogen. SeM and SzPSe proteins from temporally and geographically separated isolates of S. equi are identical in size. The results taken together support previous evidence that S. equi is a clonal pathogen originating from an ancestral strain of S. zooepidemicus. We postulate that acquisition of SeM synthesis was a key element in the success of the clone because of its effect in enhancing resistance to phagocytosis and because protective immunity entails a requirement for SeM-specific antibody.