Q fever is a worldwide zoonosis caused by Coxiella burnetii bacterium. Two clinical forms are present: acute Q fever and chronic disease, including endocarditis. Currently, the diagnosis of Q fever endocarditis is based on the detection of anti-phase I antibodies. The objective of the study was to identify candidate proteins for the serological diagnosis of endocarditis due to C. burnetii. The immunoreactivities of sera from 12 patients with C. burnetii infections, including the sera from patients with endocarditis and with the acute clinical form of Q fever, were compared with those of three control subjects who did not have Q fever. We identified 29 candidate antigenic proteins by mass spectrometry. Two proteins, arginine repressor and OmpH, were recognised exclusively by the sera of patients with Q fever endocarditis. These proteins are promising candidates for the development of serodiagnostic assays for Q fever endocarditis.
The aim of this study was to identify candidate proteins for serodiagnostics of Q fever by monoclonal antibodies (MAbs), and to clone, express, and purify the selected proteins for use as antigens in ELISA. The reactivity of three MAbs to Coxiella burnetii (C. b.) Nine Mile strain and one MAb to Priscilla strain was tested using SDS-PAGE, 2-D gel electrophoresis, immunoblot analysis, and mass spectrometry. Three immunoreactive Q fever-specific proteins discriminated by MAbs, namely the CBU_0937 protein, outer membrane Com1 (CBU_1910) protein, and elongation factor Tu (CBU_0236) were identified. Successful PCR-amplification, cloning, expression, and purification of the recombinant proteins Com1 and CBU_0937 allowed their use for the screening of sera from patients with Q fever endocarditis (18) or acute Q fever (16) in ELISA. The recombinant protein CBU_0937 with unknown biological function proved to be a more applicable diagnostic tool for Q fever ELISA as compared to the Com1 protein. # Both authors equally participated in this work. Abbreviations: C. b. = Coxiella burnetii; CNE = culture-negative endocarditis; IE = infective endocarditis; IF = immunofluorescence; MAb (s) = monoclonal antibody(ies); M r = relative molecular mass; NPV = negative predictive value; NRL = negative likelihood ratio; PPV = predictive positive value; PRL = positive likelihood ratio; Se = sensitivity; Sp = specificity
Whipple's disease (WD) is a chronic multisystemic infection, caused by Tropheryma whipplei, a Gram-positive rod. Recently, a reliable method has been developed for cultivating T. whipplei in vitro. This together with the availability of complete genome sequence of T. whipplei prompted us to initiate proteome analysis of T. whipplei. The objective of the present study was to identify candidate proteins for serological diagnosis of WD. Immunoreactivities of sera collected from 18 patients with WD were compared with those of 24 control subjects who did not have WD. For this, we used 2-DE, immunoblotting, and MS. In total, we identified 23 candidate antigenic proteins. These included a subset of six proteins, each of which was found significantly more frequently in cases as compared to their controls. The remaining 17 proteins were found exclusively in cases. The methods we used in the current study enabled us to identify candidate antigens that, in our view, might be useful for serological diagnosis of WD.
Arthropod-borne Rickettsia species are obligate intracellular bacteria which are pathogenic for humans. Within this genus, Rickettsia slovaca and Rickettsia conorii cause frequent and potentially severe infections, whereas Rickettsia raoultii and Rickettsia massiliae cause rare and milder infections. All four species belong to spotted fever group (SFG) rickettsiae. However, R. slovaca and R. raoultii cause scalp eschar and neck lymphadenopathy (SENLAT) and are mainly associated with Dermacentor ticks, whereas the other two species cause Mediterranean spotted fever (MSF) and are mainly transmitted by Rhipicephalus ticks. To identify the potential genes and protein profiles and to understand the evolutionary processes that could, comprehensively, relate to the differences in virulence and pathogenicity observed between these four species, we compared their genomes and proteomes. The virulent and milder agents displayed divergent phylogenomic evolution in two major clades, whereas either SENLAT or MSF disease suggests a discrete convergent evolution of one virulent and one milder agent, despite their distant genetic relatedness. Moreover, the two virulent species underwent strong reductive genomic evolution and protein structural variations, as well as a probable loss of plasmid(s), compared to the two milder species. However, an abundance of mobilome genes was observed only in the less pathogenic species. After infecting Xenopus laevis cells, the virulent agents displayed less up-regulated than down-regulated proteins, as well as less number of identified core proteins. Furthermore, their similar and distinct protein profiles did not contain some genes (e.g., ompA/B and rickA) known to be related to rickettsial adhesion, motility and/or virulence, but may include other putative virulence-, antivirulence-, and/or disease-related proteins. The identified evolutionary forces herein may have a strong impact on intracellular expressions and strategies in these rickettsiae, and that may contribute to the emergence of distinct virulence and diseases in humans. Thus, the current multi-omics data provide new insights into the evolution and fitness of SFG virulence and pathogenicity, and intracellular pathogenic bacteria.
Objective: Q fever epidemic outbreaks have been reported in French Guiana and in The Netherlands. To determine whether the C. burnetii strains involved in these epidemics had a peculiar virulence pattern, we compared the pathogenicity of the Guiana and the German strain (a clone of The Netherlands strain), in silico, in vitro, and in vivo versus the Nine Mile strain. Method: The pan-genomes of the Guiana (Cb175), German (Z3055), and the referent Nine Mile (RSA 493) C. burnetii strains were compared. In vitro, the growth rate and the morphological presentation were compared. In vivo (SCID and Balb/c mice), weight loss, histological lesions, C. burnetii bacterial load in deep organs, and serological response were reported according to each C. burnetii strain studied. Results: The Guiana strain had 77 times more missing genes and 12 times more unique genes than the German strain. The Guiana strain presented as large cell variants (LCVs) and led to the most pronounced fatality rate in SCID mice (100% at 4 weeks). The German strain presented as small cell variants (SCVs), and had an intermediate fatality rate (75% at 4 weeks). Both the Guiana and the German strains led to a significant higher serological response at 2 and 4 weeks post infection (p <0.05). Conclusion:The Guiana strain was the most virulent strain, followed by the German strain and the referent Nine Mile strain. Unique and missing genes could be implicated but further investigations are necessary to specify their role.
The culture of fastidious microorganisms is a critical step in infectious disease studies. As a proof-of-concept experiment, we evaluated an empirical medium containing eukaryotic cell extracts for its ability to support the growth of Coxiella burnetii. Here, we demonstrate the exponential growth of several bacterial strains, including the C. burnetii Nine Mile phase I and phase II strains, and C. burnetii isolates from humans and animals. Low-oxygen-tension conditions and the presence of small hydrophilic molecules and short peptides were critical for facilitating growth. Moreover, bacterial antigenicity was conserved, revealing the potential for this culture medium to be used in diagnostic tests and in the elaboration of vaccines against C. burnetii. We were also able to grow the majority of previously tested intracellular and fastidious bacterial species, including Tropheryma whipplei, Mycobacterium bovis, Leptospira spp., Borrelia spp., and most putative bioterrorism agents. However, we were unable to culture Rickettsia africae and Legionella spp. in this medium. The versatility of this medium should encourage its use as a replacement for the cell-based culture systems currently used for growing several facultative and putative intracellular bacterial species.
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