Cloning and identification of Bartonella α-enolase as a plasminogen-binding protein.

Bartonella infection is distributed worldwide with animal and public health. Recent studies have shown that host cells infection by Bartonella has a series of different infection stages, beginning with encounter and adherence to the cells. In this study, we expressed and purified recombinant Bartonella henselae (B. henselae) α-enolase. And we found that B. henselae α-enolase is highly conserved in Bartonella species. The interacting protein partners of B. henselae α-enolase were showed by String-11. The interactions between B. henselae α-enolase and human plasminogen were subsequently confirmed by ELISA, pull down, T7 phage display and molecular docking assays. And the plasminogen-binding sites of B. henselae α-enolase are predicted at 247FYKNGSYFY255. These findings will help elucidate and improve the understanding of the molecular mechanisms of Bartonella infection.

Conserved inhibitory mechanism and competent ATP binding mode for adenylyltransferases with Fic fold.

The ubiquitous FIC domain is evolutionarily conserved from bacteria to human and has been shown to catalyze AMP transfer onto protein side-chain hydroxyl groups. Recently, it was predicted that most catalytically competent Fic proteins are inhibited by the presence of an inhibitory helix αinh that is provided by a cognate anti-toxin (class I), or is part of the N- or C-terminal part of the Fic protein itself (classes II and III). In vitro, inhibition is relieved by mutation of a conserved glutamate of αinh to glycine. For the class III bacterial Fic protein NmFic from Neisseria meningitidis, the inhibitory mechanism has been elucidated. Here, we extend above study by including bacterial class I and II Fic proteins VbhT from Bartonella schoenbuchensis and SoFic from Shewanella oneidensis, respectively, and the respective E->G mutants. Comparative enzymatic and crystallographic analyses show that, in all three classes, the ATP substrate binds to the wild-type FIC domains, but with the α-phosphate in disparate and non-competent orientations. In the E->G mutants, however, the tri-phosphate moiety is found reorganized to the same tightly bound structure through a unique set of hydrogen bonds with Fic signature motif residues. The γ-phosphate adopts the location that is taken by the inhibitory glutamate in wild-type resulting in an α-phosphate orientation that can be attacked in-line by a target side-chain hydroxyl group. The latter is properly registered to the Fic active center by main-chain ß-interactions with the ß-hairpin flap. These data indicate that the active site motif and the exposed edge of the flap are both required to form an adenylylation-competent Fic protein.

Identification of a novel nanoRNase in Bartonella.

In Escherichia coli, only one essential oligoribonuclease (Orn) can degrade oligoribonucleotides of five residues and shorter in length (nanoRNA). In Bacillus subtilis, NrnA and NrnB, which do not show any sequence similarity to Orn, have been identified as functional analogues of Orn. Sequence comparisons did not identify orn, nrnA or nrnB homologues in the genomes of the Chlamydia/Cyanobacteria and Alphaproteobacteria family members. Screening a genomic library from Bartonella birtlesii, a member of the Alphaproteobacteria, for genes that can complement a conditional orn mutant in E. coli, we identified BA0969 (NrnC) as a functional analogue of Orn. NrnC is highly conserved (more than 80 % identity) in the Bartonella genomes sequenced to date. Biochemical characterization showed that this protein exhibits oligo RNA degradation activity (nanoRNase activity). Like Orn from E. coli, NrnC is inhibited by micromolar amounts of 3'-phosphoadenosine 5'-phosphate in vitro. NrnC homologues are widely present in genomes of Alphaproteobacteria. Knock down of nrnC decreases the growth ability of Bartonella henselae, demonstrating the importance of nanoRNase activity in this bacterium.

Exotic small mammals as potential reservoirs of zoonotic Bartonella spp.

To evaluate the risk for emerging human infections caused by zoonotic Bartonella spp. from exotic small mammals, we investigated the prevalence of Bartonella spp. in 546 small mammals (28 species) that had been imported into Japan as pets from Asia, North America, Europe, and the Middle and Near East. We obtained 407 Bartonella isolates and characterized them by molecular phylogenetic analysis of the citrate synthase gene, gltA. The animals examined carried 4 zoonotic Bartonella spp. that cause human endocarditis and neuroretinitis and 6 novel Bartonella spp. at a high prevalence (26.0%, 142/546). We conclude that exotic small mammals potentially serve as reservoirs of several zoonotic Bartonella spp.

Characterization of Bartonella strains isolated from black-tailed prairie dogs (Cynomys ludovicianus).

Thirty bartonella strains were isolated from the blood of black-tailed prairie dogs (Cynomys ludovicianus) from Boulder County, Colorado, USA. The bacteria appeared as small, fastidious, aerobic, Gram-negative rods. The partial sequences of the citrate synthase gene (gltA) demonstrated five unique genetic variants. Phylogenetic analysis based on sequences of gltA, 16S rRNA, rpoB, ftsZ, and ribC showed that the black-tailed prairie dog-related Bartonella variants comprise a distinct monophyletic clade that is closely related to Bartonella washoensis, a species isolated from a human patient and subsequently from ground squirrels. These variants, however, are grouped together in 100% of the bootstrapped trees. These variants were not found in other small mammals trapped during the same study, showing some evidence of host specificity. We believe that the group being described here is typical of the black-tailed prairie dog. We propose to name the bacteria Candidatus Bartonella washoensis subsp. cynomysii. The type strain is CL8606co(T)(=ATCC BAA-1342(T) = CCUG 53213(T)), which is the representative isolate of the dominant variant of the characterized group.

Role of Hippoboscidae flies as potential vectors of Bartonella spp. infecting wild and domestic ruminants.

The putative role of biting flies in Bartonella transmission among ruminants was investigated. Amplification of the Bartonella citrate synthase gene from 83 Hippoboscidae was detected in 94% of 48 adult Lipoptena cervi flies, 71% of 17 adult Hippobosca equina flies, 100% of 20 adult Melophagus ovinus flies, and 100% of 10 M. ovinus pupae. Our findings suggest that Hippoboscidae play a role in the transmission of Bartonella among ruminants. The vertical transmission of Bartonella in M. ovinus and the presence of Bartonella DNA in all samples suggest a symbiotic association between Bartonella and M. ovinus.

Molecular characterization of the sucB gene encoding the immunogenic dihydrolipoamide succinyltransferase protein of Bartonella vinsonii subsp. berkhoffii and Bartonella quintana.

Members of the genus Bartonella have historically been connected with human disease, such as cat scratch disease, trench fever, and Carrion's disease, and recently have been recognized as emerging pathogens causing other clinical manifestations in humans. However, because little is known about the antigens that elicit antibody production in response to Bartonella infections, this project was undertaken to identify and molecularly characterize these immunogens. Immunologic screening of a Bartonella vinsonii subsp. berkhoffii genomic expression library with anti-Bartonella antibodies led to the identification of the sucB gene, which encodes the enzyme dihydrolipoamide succinyltransferase. Antiserum from a mouse experimentally infected with live Bartonella was reactive against recombinant SucB, indicating the mounting of an anti-SucB response following infection. Antigenic cross-reactivity was observed with antiserum against other Bartonella spp. Antibodies against Coxiella burnetti, Francisella tularensis, and Rickettsia typhi also reacted with our recombinant Bartonella SucB. Potential SucB antigenic cross-reactivity presents a challenge to the development of serodiagnostic tests for other intracellular pathogens that cause diseases such as Q fever, rickettsioses, brucelloses, tularemia, and other bartonelloses.

Investigation of the phylogenetic relationships within the genus Bartonella based on comparative sequence analysis of the rnpB gene, 16S rDNA and 23S rDNA.

A variety of genes and analytical methods have been applied to the study of phylogenetic relationships within the genus Bartonella, but so far the results have been inconsistent. While previous studies analysed single protein-encoding genes, we have analysed an alignment containing the sequences of three important phylogenetic markers, RNase P RNA, 16S rRNA and 23S rRNA, merged by catenation, to determine the phylogenetic relationships within the genus Bartonella. The dataset described here comprises 13 different Bartonella strains, including the seven strains that are known to be human pathogens. A variety of algorithms have been used to construct phylogenetic trees based on the combined alignment and, for comparison purposes, each individual gene. Trees generated from the catenated alignment are more consistent (independent of algorithm) and robust (higher bootstrap support). It is suggested that a phylogenetic analysis incorporating the RNase P RNA, 16S rRNA and 23S rRNA be used to study the phylogenetic relationships within the genus Bartonella.

Metal requirements of a diadenosine pyrophosphatase from Bartonella bacilliformis: magnetic resonance and kinetic studies of the role of Mn2+.

Recombinant IalA protein from Bartonella bacilliformis is a monomeric adenosine 5'-tetraphospho-5'-adenosine (Ap4A) pyrophosphatase of 170 amino acids that catalyzes the hydrolysis of Ap4A, Ap5A, and Ap6A by attack at the delta-phosphorus, with the departure of ATP as the leaving group [Cartwright et al. (1999) Biochem. Biophys. Res. Commun. 256, 474-479]. When various divalent cations were tested over a 300-fold concentration range, Mg2+, Mn2+, and Zn2+ ions were found to activate the enzyme, while Ca2+ did not. Sigmoidal activation curves were observed with Mn2+ and Mg2+ with Hill coefficients of 3.0 and 1.6 and K0.5 values of 0.9 and 5.3 mM, respectively. The substrate M2+ x Ap4A showed hyperbolic kinetics with Km values of 0.34 mM for both Mn2+ x Ap4A and Mg2+ x Ap4A. Direct Mn2+ binding studies by electron paramagnetic resonance (EPR) and by the enhancement of the longitudinal relaxation rate of water protons revealed two Mn2+ binding sites per molecule of Ap4A pyrophosphatase with dissociation constants of 1.1 mM, comparable to the kinetically determined K0.5 value of Mn2+. The enhancement factor of the longitudinal relaxation rate of water protons due to bound Mn2+ (epsilon b) decreased with increasing site occupancy from a value of 12.9 with one site occupied to 3.3 when both are occupied, indicating site-site interaction between the two enzyme-bound Mn2+ ions. Assuming the decrease in epsilon(b) to result from cross-relaxation between the two bound Mn2+ ions yields an estimated distance of 5.9 +/- 0.4 A between them. The substrate Ap4A binds one Mn2+ (Kd = 0.43 mM) with an epsilon b value of 2.6, consistent with the molecular weight of the Mn2+ x Ap4A complex. Mg2+ binding studies, in competition with Mn2+, reveal two Mg2+ binding sites on the enzyme with Kd values of 8.6 mM and one Mg2+ binding site on Ap4A with a Kd of 3.9 mM, values that are comparable to the K0.5 for Mg2+. Hence, with both Mn2+ and Mg2+, a total of three metal binding sites were found-two on the enzyme and one on the substrate-with dissociation constants comparable to the kinetically determined K0.5 values, suggesting a role in catalysis for three bound divalent cations. Ca2+ does not activate Ap4A pyrophosphatase but inhibits the Mn2+-activated enzyme competitively with a Ki = 1.9 +/- 1.3 mM. Ca2+ binding studies, in competition with Mn2+, revealed two sites on the enzyme with dissociation constants (4.3 +/- 1.3 mM) and one on Ap4A with a dissociation constant of 2.1 mM. These values are similar to its Ki suggesting that inhibition by Ca2+ results from the complete displacement of Mn2+ from the active site. Unlike the homologous MutT pyrophosphohydrolase, which requires only one enzyme-bound divalent cation in an E x M2+ x NTP x M2+ complex for catalytic activity, Ap4A pyrophosphatase requires two enzyme-bound divalent cations that function in an active E x (M2+)2 x Ap4A x M2+ complex.

The MutT motif family of nucleotide phosphohydrolases in man and human pathogens (review).

Human cells express at least eight members of the MutT motif protein (or nudix hydrolase) family. These enzymes are believed to eliminate toxic nucleotide derivatives from the cell and regulate the levels of important signalling nucleotides and their metabolites. Six have been fully or partially characterized: i) hMTH1 is a nucleoside triphosphatase which restricts AT-->CG transversions by specifically degrading the oxidized nucleotide 8-oxo-dGTP; ii) hAPAH1 preferentially degrades the signalling dinucleotide Ap4A; iii) DIPP is unusual in hydrolysing two seemingly unrelated signalling substrate groups - the dinucleotides Ap6A and Ap5A, and the diphosphoinositol polyphosphates; iv) DIPP2 is closely related to DIPP; v) hYSAH1 is an NDP-sugar hydrolase which prefers ADP-ribose, and vi) hGFG is a protein of unknown function encoded by the antisense transcript of the basic fibroblast growth factor gene. Although not yet associated with known hereditary or acquired disorders, the functional loss of any one of these hydrolases would be expected to be detrimental to cellular function. Furthermore, the ialA invasion gene of Bartonella bacilliformis and other invasive pathogens encodes a MutT motif Ap4A hydrolase while poxviruses express two MutT motif proteins, at least one of which is essential for infectivity. This protein family, therefore, occupies a position of some importance in controlling human health and disease.

The IalA invasion gene of Bartonella bacilliformis encodes a (de)nucleoside polyphosphate hydrolase of the MutT motif family and has homologs in other invasive bacteria.

The product of the ialA invasion gene of Bartonella bacilliformis has been expressed as a thioredoxin fusion protein. It is a (di)nucleoside polyphosphate hydrolase of the MutT motif protein family with strong sequence similarity to plant diadenosine tetraphosphate hydrolases. It hydrolyses nucleoside and dinucleoside polyphosphates with four or more phosphate groups, always producing an NTP as one product. Diadenosine tetraphosphate (Ap4A) is the preferred substrate with a Km of 10 microM and a kcat of 3.0 s-1. It is inhibited by Ca2+ and F- (Ki = 30 microM). Hydrolysis of Ap4A in H218O yielded [18O]AMP as the only labelled product. In terms of sequence, reaction mechanism and properties, IalA is very similar to eukaryotic Ap4A hydrolases and unlike previously described bacterial Ap4A hydrolases. Homologs are present in the genomes of other invasive pathogens. They may function to reduce stress-induced dinucleotide levels during invasion and so enhance pathogen survival.

Cloning, functional expression, and complementation analysis of an inorganic pyrophosphatase from Bartonella bacilliformis.

We have cloned the inorganic pyrophosphatase gene (ppa) from the facultative intracellular pathogen Bartonella bacilliformis and characterized its encoded product. The 531-bp gene is located approximately 1 kb downstream of, and in opposite orientation to, the invasion-associated locus (ialAB) of B. bacilliformis. The predicted protein encoded by ppa is 177 amino acid residues, which is in agreement with in vitro and in vivo synthesis of a protein with an apparent molecular mass of 22-23 kDa. The predicted B. bacilliformis pyrophosphatase (PPase) sequence is 53% identical and 85% similar to the E. coli PPase (EC 3.6.1.1), and contains all 12 of the amino acid residues implicated in the catalytic active site. The isolated B. bacilliformis PPase exhibits an activity of 51 +/- 2 mumol PO4 released/(mg protein.min) at 28 degrees C and pH 8, and is sensitive to inhibition by Ca2+. In keeping with other prokaryotic PPases, B. bacilliformis PPase activity occurs from pH 6 to 10 (optimal pH = 8) and demonstrates high thermostability in the presence of Mg2+ (highest activity at 55 degrees C, relative activity = 80 +/- 3% at pH 8). The cloned B. bacilliformis ppa is able to genetically complement a ppa- mutant strain of E. coli.

A carboxy-terminal processing protease gene is located immediately upstream of the invasion-associated locus from Bartonella bacilliformis.

A gene with homology to those encoding an unusual class of C-terminal processing proteases that flanks the invasion-associated locus ialAB of Bartonella bacilliformis has been identified. The 1302 bp gene, termed ctpA, is located immediately upstream of the ialA gene and encodes a predicted nascent product of 434 amino acids, producing a mature protein of 411 amino acid residues. The Bartonella CtpA appears to undergo autolysis in vitro, producing multiple products of 43-46 kDa, and a second group of products of 36-37 kDa. Production of CtpA in vivo gives a single product of 41.8 kDa. In addition to a computer-predicted N-terminal secretory signal sequence, the molecular mass difference in vivo versus in vitro indicates that CtpA is likely to be secreted and post-translationally modified. The full-length CtpA protein shows 30% identify to the CtpA protein of Synechocystis sp. 6803 (69% overall sequence similarity). The mature CtpA protein also has significant homology to the tail-specific protease (Tsp) of Escherichia coli, with 22% identify and 62% similarity to an internal region of the 660 amino acid Tsp. The CtpA protein does not appear to exhibit haemolysin, collagenase, or caseinase activity. The ctpA gene is conserved in all Bartonella species examined, as determined by hybridization analyses, but it was not found in Brucella abortus or E. coli. The ctpA gene does not directly affect the erythrocyte-invasion phenotype conferred by ialAB, but its homology to other stress-response processing proteases implies an important role in survival of this intracellular pathogen.

Differentiation of Bartonella-like isolates at the species level by PCR-restriction fragment length polymorphism in the citrate synthase gene.

The citrate synthase gene (gltA) of Bartonella henselae was cloned and sequenced to compare genetic divergence among alpha and gamma branches of the class Proteobacteria and to develop enhanced genotypic reagents for B. henselae identification. B. henselae gltA is 1,293 nucleotides in length and 63 to 66% homologous with corresponding gene sequences of Rickettsia prowazekii, Escherichia coli, and Coxiella burnetii. The observed genetic variability suggests that gltA sequences can provide a useful means for studying moderate divergence among related bacteria. Oligonucleotides specific for B. henselae gltA were evaluated for the ability to prime PCR amplification within the alpha and gamma branches of the proteobacteria. Under the conditions used, only B. henselae, Bartonella quintana, and R. prowazekii template DNAs yielded amplification products (approximately 380 bp). DNAs from 28 Bartonella-like isolates of feline origin were amplified by B. henselae primers and analyzed for restriction fragment length polymorphism. The resulting patterns for all 28 isolates were similar or identical to that of the recognized B. henselae strain. Current studies are aimed at optimization of PCR conditions for specificity and sensitivity of amplification of Bartonella sequences from clinical isolates.

Identification of Bartonella (Rochalimaea) species among fastidious gram-negative bacteria on the basis of the partial sequence of the citrate-synthase gene.

The bacterial genus Bartonella (Rochalimaea) includes emerging human pathogens with five recognized species. These are fastidious gram-negative bacteria, exhibiting few phenotypic characteristics and whose identification relies upon serotyping, cellular fatty acid analysis, and molecular typing. Most of the isolates have been recovered from the blood of patients, and three of the four pathogenic Bartonella species are associated with infectious endocarditis. We performed PCR-restriction fragment length polymorphism (RFLP) analysis of the blood culture bottle supernatant for the routine identification of Bartonella species among fastidious gram-negative bacteria. The amplification of the citrate-synthase gene with primers previously reported (R. L. Regnery, C. L. Spruill, and B. D. Plikaytis, J. Bacteriol. 173:1576-1589, 1991) yielded a 379-bp product from Bartonella species and a 382-bp product for Capnocytophaga ochracea but no product from any of the other 15 genotypically or phenotypically related species tested. We determined the sequences of the citrate-synthase gene-amplified products for Bartonella species and C. ochracea in order to predict the optimal restriction enzyme to be used in RFLP analysis. TaqI and AciI allowed identification of Bartonella species and C. ochracea. We propose that acridine orange and Gram staining, followed by PCR-RFLP analysis of the blood bottle supernatant, be included in the examination of blood samples from patients with suspected infectious endocarditis.