Antigenic profiling of yersinia pestis infection in the Wyoming coyote (Canis latrans).

Although Yersinia pestis is classified as a "high-virulence" pathogen, some host species are variably susceptible to disease. Coyotes (Canis latrans) exhibit mild, if any, symptoms during infection, but antibody production occurs postinfection. This immune response has been reported to be against the F1 capsule, although little subsequent characterization has been conducted. To further define the nature of coyote humoral immunity to plague, qualitative serology was conducted to assess the antiplague antibody repertoire. Humoral responses to six plasmid-encoded Y. pestis virulence factors were first examined. Of 20 individual immune coyotes, 90% were reactive to at least one other antigen in the panel other than F1. The frequency of reactivity to low calcium response plasmid (pLcr)-encoded Yersinia protein kinase A (YpkA) and Yersinia outer protein D (YopD) was significantly greater than that previously observed in a murine model for plague. Additionally, both V antigen and plasminogen activator were reactive with over half of the serum samples tested. Reactivity to F1 was markedly less frequent in coyotes (35%). Twenty previously tested antibody-negative samples were also examined. While the majority were negative across the panel, 15% were positive for 1-3 non-F1 antigens. In vivo-induced antigen technology employed to identify novel chromosomal genes of Y. pestis that are up-regulated during infection resulted in the identification of five proteins, including a flagellar component (FliP) that was uniquely reactive with the coyote serum compared with immune serum from two other host species. Collectively, these data suggest that humoral immunity to pLcr-encoded antigens and the pesticin plasmid (pPst)-encoded Pla antigen may be relevant to plague resistance in coyotes. The serologic profile of Y. pestis chromosomal antigens up-regulated in vivo specific to C. latrans may provide insight into the differences in the pathogen-host responses during Y. pestis infection.

Identification of Brucella abortus genes in elk (Cervus elaphus) using in vivo-induced antigen technology (IVIAT) reveals novel markers of infection.

Elk in the Greater Yellowstone Area are a major reservoir for brucellosis, which represents an obstacle to eradication of the disease in domestic livestock. Furthermore, immune responses to Brucella abortus infection in the wild host are not well-understood. In this regard, in vivo-induced antigen technology (IVIAT) was employed to identify novel B. abortus antigens expressed during infection in elk. Sera collected from sero-positive Wyoming elk were pooled and absorbed against in vitro-grown cultures of B. abortus. Approximately 35,000 E. coli clones, expressing B. abortus DNA, were then screened by colony immunoblot, yielding ten genes with immuno-reactive products, to include seven proteins secreted beyond the inner membrane. Three products, an outer membrane protein (D15), malate dehydrogenase (Mdh), and an ion transporter (AfuA), were examined by Western blot against individual elk serum samples. Sero-reactivity was significantly more frequent for both Mdh and D15 in naturally infected animals, compared to vaccinated and uninfected elk, indicating that antibody to these two antigens is a predictor of natural infection. Cross-reactivity of all three proteins was next examined with serum samples from confirmed brucellosis-positive cattle. While variable patterns of reactivity were seen with the antigens, the sample group was equivalently reactive to AfuA and Mdh, compared to elk, suggesting that these antigens are commonly expressed during infection in both hosts. We conclude that the application of IVIAT to B. abortus may not only facilitate the identification of serologic markers for brucellosis in elk, but may provide further insight into biological processes of the pathogen in different hosts.