Characterization of a phosphomonoesterase from Brucella abortus

A single-tube approach for in vitro diagnostics using diatomaceous earth and optical sensor

Versatile, simple and efficient sample preparation is desirable for point-of-care testing of emerging diseases such as zoonoses, but current sample preparation assays are insensitive, labour-intensive and time-consuming and require multiple instruments. We developed a single-tube sample preparation approach involving direct pathogen enrichment and extraction from human specimens using diatomaceous earth (DE). Amine-modified DE was used to directly enrich a zoonotic pathogen, Brucella, in a large sample volume. Next, a complex of amine-modified DE and dimethyl suberimidate was used for nucleic acid extraction from the enriched pathogen. Using our single-tube approach, the pathogen can be enriched and extracted within 60min at a level of 1 colony formation unit (CFU) from a 1ml sample volume in the same tube. The performance of this approach is 10-100 times better than that of a commercial kit (102 to 103CFU/ml) but does not require a large centrifuge. Finally, we combined the single-tube approach with a bio-optical sensor for rapid and accurate zoonotic pathogen detection in human urine samples. Using the combination system, Brucella in human urine can be efficiently enriched (~ 8-fold) and the detection limit is enhanced by up to 100 times (1CFU/ml bacteria in urine) compared with the commercial kit. This combined system is fast and highly sensitive and thus represents a promising approach for disease diagnosis in the clinical setting.

Evaluation of different methods for the detection of Clostridium perfringens phosphatases

In order to detect phosphatase activity a total of 137 isolates from 12 Clostridium (C.) species were examined via fluorescence on SCA-agar with methylumbelliferyl phosphate (SCA-MUP), via APIZYM and RAPID ID 32 A as well as using a phosphatase reagent containing 1-naphthyl phosphate. Fluorescence on SCA-MUP showed the presence of acid or alkaline phosphatase in almost all isolates examined. Likewise, acid or alkaline phosphatase could be detected via APIZYM and RAPID ID 32 A in most strains and species. Opposed to this, the majority of the Clostridium bifermentans isolates showed a positive reaction exclusively on SCA-MUP. On the other hand, the phosphatase reagent for the detection of acid phosphatase lead to unambiguously positive results only when examining Clostridium perfringens isolates. Therefore, the SCA-MUP-agar, in contrast to the phosphatase reagent, was proven to be unsuitable for the identification of C. perfringens via detection of acid phosphatase. Using the phosphatase reagent the activity of this enzyme was detected in 95.1% of the C. perfringens isolates included in the study. In addition, the phosphatase reagent showed identical reactions after a 24 h incubation at 37 degrees C and when used on cultures incubated for 6 h at 44 degrees C in the case of 98.5% of the C. perfringens isolates.

Live Brucella spp. fail to induce tumor necrosis factor alpha excretion upon infection of U937-derived phagocytes

Tumor necrosis factor alpha (TNF-alpha) plays a central role in activation of first-line defenses of a host against foreign organisms. To determine whether Brucella infection modulated TNF-alpha production, we measured the biological activity of this cytokine in supernatants of U937 cell-derived macrophages and of fresh human monocytes infected with Brucella spp. Neither the smooth nor rough Brucella strains used induced any measurable TNF-alpha excretion upon infection. On the contrary, as reported before for other gram-negative bacteria, phagocytosis of nonpathogenic Escherichia coli was followed by a rapid and transient induction of TNF-alpha release, suggesting an involvement of this cytokine in some autocrine process. As expected, the Brucella strains tested survived and/or multiplied within U937-derived macrophages, whereas E. coli was rapidly eliminated after phagocytosis. Immunoglobulin G opsonization of E. coli strains enhanced their intracellular killing and strongly potentiated TNF-alpha secretion. Immunoglobulin G opsonization of Brucella strains, in contrast, did not lead to TNF-alpha production, although their rate of intracellular multiplication was reduced. Killed brucellae, however, promoted a significant excretion of TNF-alpha from U937-derived macrophages into cell culture supernatants. We finally demonstrated that pretreatment of U937-derived macrophages with exogenous TNF-alpha significantly inhibited intracellular multiplication of Brucella spp. These results and experiments performed on fresh human monocytes or with isolated lipopolysaccharide (LPS) showed that (i) differences in TNF-alpha production observed during macrophage infection by Brucella spp. and E. coli were not due to differences in LPS structure but resulted from active inhibition of TNF-alpha production by a specific process linked to Brucella spp. and (ii) the capacity of Brucella spp. to use pathways avoiding TNF-alpha production during infection may be considered a major attribute of virulence.

Antigens of Brucella abortus S19 immunodominant for bovine lymphocytes as identified by one- and two-dimensional cellular immunoblotting

Cellular immune responses are influential for protection against intracellular bacteria such as brucellae. Therefore, identification of Brucella abortus antigens that activate primed bovine lymphocytes is fundamental for discerning the breadth of cellular response in bovine brucellosis. Potentially antigenic components of B. abortus S19 were isolated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by nitrocellulose blotting. Specific one-dimensional blot segments induced proliferation of peripheral blood lymphocytes from all 25 of the vaccinated cattle tested and were defined as immunodominant. Individual proteins that stimulated lymphocyte proliferation were further characterized by two-dimensional cellular immunoblotting by two different approaches. Individual one-dimensional stimulatory blot segments were eluted, concentrated, and then subjected to two-dimensional cellular immunoblotting. Alternatively, entire two-dimensional gels containing all of the B. abortus components were blotted and nitrocellulose sections containing individual proteins were assayed for lymphocyte activation. Thirty-eight Brucella proteins that induced lymphocyte proliferation were resolved by both procedures. Phenotypic analysis of the proliferating cell population demonstrated the presence of CD4+, CD8+, and immunoglobulin M+ lymphocytes. Two immunogenic proteins, 12 and 31 kDa, identified by two-dimensional cellular immunoblotting, were subjected to partial N-terminal amino acid analysis. The 12-kDa protein was within the area of greatest lymphocyte proliferation, while the 31-kDa protein was chosen for comparison with a 31-kDa protein previously reported by others. A search of the National Biomedical Research Foundation protein data bank showed that the sequences were not homologous with other known proteins. Identification of Brucella proteins immunogenic for bovine lymphocytes provides an important step in distinguishing the various proteins involved in pathogenicity and/or disease resistance.

Effect of Brucella abortus lipopolysaccharide on oxidative metabolism and lysozyme release by human neutrophils

Both Brucella abortus lipopolysaccharide (LPS) and lipid A were low activators of nitroblue tetrazolium reduction and lysozyme release in human neutrophils. The stimulation was dose dependent and was higher in the presence of autologous plasma than in its absence. The comparison between Brucella LPS and lipid A versus Salmonella LPS revealed that at least 100 times more LPS and 1,000 times more lipid A of the former genus were required to induce significant nitroblue tetrazolium reduction and a corresponding lysozyme release in neutrophils. Low Brucella LPS-mediated superoxide and lysozyme production might contribute to the survival of these facultative intracellular bacteria in phagocytic cells.