Characterization of the plasma proteome of nonhuman primates during Ebola virus disease or melioidosis: a host response comparison.

BACKGROUND: In-depth examination of the plasma proteomic response to infection with a wide variety of pathogens can assist in the development of new diagnostic paradigms, while providing insight into the interdependent pathogenic processes which encompass a host's immunological and physiological responses. Ebola virus (EBOV) causes a highly lethal infection termed Ebola virus disease (EVD) in primates and humans. The Gram negative non-spore forming bacillus Burkholderia pseudomallei (Bp) causes melioidosis in primates and humans, characterized by severe pneumonia with high mortality. We sought to examine the host response to infection with these two bio-threat pathogens using established animal models to provide information on the feasibility of pre-symptomatic diagnosis, since the induction of host molecular signaling networks can occur before clinical presentation and pathogen detection. METHODS: Herein we report the quantitative proteomic analysis of plasma collected at various times of disease progression from 10 EBOV-infected and 5 Bp-infected nonhuman primates (NHP). Our strategy employed high resolution LC-MS/MS and a peptide-tagging approach for relative protein quantitation. In each infection type, for all proteins with > 1.3 fold abundance change at any post-infection time point, a direct comparison was made with levels obtained from plasma collected daily from 5 naïve rhesus macaques, to determine the fold changes that were significant, and establish the natural variability of abundance for endogenous plasma proteins. RESULTS: A total of 41 plasma proteins displayed significant alterations in abundance during EBOV infection, and 28 proteins had altered levels during Bp infection, when compared to naïve NHPs. Many major acute phase proteins quantitated displayed similar fold-changes between the two infection types but exhibited different temporal dynamics. Proteins related to the clotting cascade, immune signaling and complement system exhibited significant differential abundance during infection with EBOV or Bp, indicating a specificity of the response. CONCLUSIONS: These results advance our understanding of the global plasma proteomic response to EBOV and Bp infection in relevant primate models for human disease and provide insight into potential innate immune response differences between viral and bacterial infections.

Effect of timing and duration of azithromycin therapy of leptospirosis in a hamster model.

OBJECTIVES: Azithromycin is not associated with significant adverse effects or restricted usage in certain populations unlike standard antileptospirosis agents. In this study, the utility of short courses of azithromycin in treating or preventing leptospirosis was investigated in a lethal hamster model. METHODS: All hamsters were infected intraperitoneally with 10(5) leptospires. In experiment one, animals received 5 mg/kg of doxycycline or 10 mg/kg of azithromycin via intraperitoneal injection beginning on the second day after infection and continuing once daily for 1, 2, 3 or 5 days. In experiment two, animals received 1 or 2 day courses of azithromycin initiated 2 or 4 days following infection, or 4 days prior to infection. RESULTS: All untreated control animals died between the sixth and ninth day following infection. In experiment one, survival rates in the doxycycline groups were 0, 50, 80 and 100% for those animals treated for 1, 2, 3 and 5 days, respectively. Except for the 1 day treatment group (which had an 80% survival), there was 100% survival in all azithromycin-treated groups. In experiment two, all animals treated after infection survived until study completion. No animals survived with 1 day of therapy started 4 days prior to infection while only 20% survived if they received 2 days. CONCLUSIONS: These results suggest short-course therapy with azithromycin, even started well after infection, is efficacious in preventing mortality from acute leptospirosis.

Development of species-specific PCR primer sets for the detection of Leptospira.

Spirochetes of the genus Leptospira infect animals and humans and are the causative agents for the emerging infectious disease leptospirosis. Rapid and simple assays for the identification of individual Leptospira species are currently not available. For identification of individual Leptospira species, PCR primers that detect the ompL1 gene sequence for the majority of pathogenic leptospires were developed in this study. The primer pairs detect Leptospira interrogans, Leptospira borgpetersenii, Leptospira kirschneri, Leptospira santarosai, Leptospira weilii and Leptospira noguchii, without cross-reacting with other Leptospira species. The development of the primers revealed a divergence of the ompL1 gene within L. interrogans, splitting this species into two separate groups. The species-specific primers will be especially useful in epidemiological studies and disease outbreak investigations for the detection of Leptospira species in human, animal and environmental samples.