Interactions of Bartonella henselae with vascular endothelial cells

Neurobartonelloses: emerging from obscurity!

BACKGROUND

Bartonella species are fastidious, intracellular bacteria responsible for an expanding array of human pathologies. Most are considered to be transmitted by direct inoculation with infected bodily fluids from a mammalian reservoir species or vector-transmitted through a variety of arthropod species and their excrement. However, there are mounting reports of infection in the absence of documented animal or vector contact. A variety of Bartonella species have been documented in conditions affecting both the peripheral and central nervous systems. More common conditions, including neuroretinitis, are often associated with Bartonella henselae. However, Bartonella quintana, the agent of trench fever, as well as emerging pathogens related to rodent reservoir species, B. grahamii and B. elizabethae, have also been documented. Encephalitis and encephalopathy, also most often associated with B. henselae, have been reported with B. quintana, B. washoensis (ground squirrels) and B. vinsonii subsp. vinsonii (voles) infections. Bartonella infections have also been associated with peripheral neuropathies, such as cranial nerve paresis and neuropathic pain, including infection with less commonly encountered species such as Bartonella koehlerae. Recently, molecular diagnostic testing revealed that DNA from Bartonella spp. was found to be more prevalent in blood of patients with neuropsychiatric disorders such as schizophrenia and psychoses compared to healthy controls.

METHODS

A systematic literature search was conducted on PubMed, Google Scholar and Web of Science. Search terms included Bartonella and specific neurological conditions and focused on peer-reviewed case reports published after 2012 pursuant to a prior review, with limited exceptions for conditions not previously covered. Published diagnostic testing, serology, molecular testing or pathology, were necessary for inclusion, except for one case which had clinical and epidemiological evidence consistent with diagnosis along with follow-up.

RESULTS

Neurobartonelloses included neuralgic amyotrophy, complex regional pain syndrome, chronic inflammatory demyelinating polyneuropathy, cranial nerve paralysis, Guillain-Barré syndrome, peripheral vasculitic polyneuropathy, acute transverse myelopathy, neuroretinitis, encephalitis/encephalopathy, cerebral vasculitis/aneurysm and neuropsychiatric conditions.

CONCLUSIONS

The breadth of reported symptoms and clinical syndromes associated with an increasing number of Bartonella species continues to expand. Increased clinical awareness of this important zoonotic pathogen is necessary to advance One Health among the medical and veterinary communities.

Diagnosis and treatment of vascular graft and endograft infections: a structured clinical approach

A vascular graft or endograft infection (VGEI) is a severe complication that can occur after vascular graft or endograft surgery and is associated with high morbidity and mortality rates. A multidisciplinary approach, consisting of a team of vascular surgeons, infectious diseases specialists, medical microbiologists, radiologists, nuclear medicine specialists, and hospital pharmacists, is needed to adequately diagnose and treat VGEI. A structured diagnostic, antibiotic, and surgical treatment algorithm helps clinical decision making and ultimately aims to improve the clinical outcome of patients with a VGEI.

The Impact of Bartonella VirB/VirD4 Type IV Secretion System Effectors on Eukaryotic Host Cells

Bartonella spp. are facultative intracellular pathogens that infect a wide range of mammalian hosts including humans. The VirB/VirD4 type IV secretion system (T4SS) is a key virulence factor utilized to translocate Bartonella effector proteins (Beps) into host cells in order to subvert their functions. Crucial for effector translocation is the C-terminal Bep intracellular delivery (BID) domain that together with a positively charged tail sequence forms a bipartite translocation signal. Multiple BID domains also evolved secondary effector functions within host cells. The majority of Beps possess an N-terminal filamentation induced by cAMP (FIC) domain and a central connecting oligonucleotide binding (OB) fold. FIC domains typically mediate AMPylation or related post-translational modifications of target proteins. Some Beps harbor other functional modules, such as tandem-repeated tyrosine-phosphorylation (EPIYA-related) motifs. Within host cells the EPIYA-related motifs are phosphorylated, which facilitates the interaction with host signaling proteins. In this review, we will summarize our current knowledge on the molecular functions of the different domains present in Beps and highlight examples of Bep-dependent host cell modulation.

Molecular Mechanisms of Bartonella and Mammalian Erythrocyte Interactions: A Review

Bartonellosis is an infectious disease caused by Bartonella species that are distributed worldwide with animal and public health impact varying according to Bartonella species, infection phase, immunological characteristics, and geographical region. Bartonella is widely present in various mammals including cats, rodents, ruminants, and humans. At least 13 Bartonella species or subspecies are zoonotic. Each species has few reservoir animals in which it is often asymptomatic. Bartonella infection may lead to various clinical symptoms in humans. As described in the B.tribocorum-rat model, when Bartonella was seeded into the blood stream, they could escape immunity, adhered to and invaded host erythrocytes. They then replicated and persisted in the infected erythrocytes for several weeks. This review summarizes the current knowledge of how Bartonella prevent phagocytosis and complement activation, what pathogenesis factors are involved in erythrocyte adhesion and invasion, and how Bartonella could replicate and persist in mammalian erythrocytes. Current advances in research will help us to decipher molecular mechanisms of interactions between Bartonella and mammalian erythrocytes and may help in the development of biological strategies for the prevention and control of bartonellosis.

Pyogenic Granuloma: Pyogenic Again? Association between Pyogenic Granuloma and Bartonella

Background:

Pyogenic granulomas (PG) are benign vascular lesions which were thought to have an infectious etiology, yet none has been found. Bacillary angiomatosis (BA), which presents as disseminated vascular lesions in immunosuppressed patients, and verruga peruana (VP), which presents as crops of vascular nodules in immunocompetent persons, are caused by infection with Bartonella. Thus, the question was raised whether Bartonella could be associated with the development of PG, also a vasoproliferative lesion like BA and VP. The objective of this study was to determine through a case-control study whether such an association exists.

Methods:

Patients who presented with PG and age and sex-matched controls with capillary hemangiomas and senile (cherry) angiomas were tested for serum IgG antibodies against Bartonella using an immunofluorescence antibody method. The prevalence of positive serology was compared between the groups.

Results:

Twenty PG patients and 20 control patients with hemangiomas or angiomas were studied. Six out of 20 PG patients tested positive (30%), while none of the 20 control patients tested positive (0%). The difference between the proportions of seropositivity in the two groups reached statistical significance ( p = 0.02, df= 1).

Conclusions:

Pyogenic granuloma patients were determined to have a statistically higher prevalence of Bartonella seropositivity compared with control patients. Further studies are needed to confirm the association and establish a possible etiological link. Such an association could have potential therapeutic importance. A nonsurgical approach with antibiotics may be possible and may decrease the recurrence rate and occurrence of satellite lesions.

Bartonella spp. bacteremia and rheumatic symptoms in patients from Lyme disease-endemic region

Prevalence of Bartonella spp. was high, especially among patients with a history of Lyme disease.

Bartonella spp. infection has been reported in association with an expanding spectrum of symptoms and lesions. Among 296 patients examined by a rheumatologist, prevalence of antibodies against Bartonella henselae, B. koehlerae, or B. vinsonii subsp. berkhoffii (185 [62%]) and Bartonella spp. bacteremia (122 [41.1%]) was high. Conditions diagnosed before referral included Lyme disease (46.6%), arthralgia/arthritis (20.6%), chronic fatigue (19.6%), and fibromyalgia (6.1%). B. henselae bacteremia was significantly associated with prior referral to a neurologist, most often for blurred vision, subcortical neurologic deficits, or numbness in the extremities, whereas B. koehlerae bacteremia was associated with examination by an infectious disease physician. This cross-sectional study cannot establish a causal link between Bartonella spp. infection and the high frequency of neurologic symptoms, myalgia, joint pain, or progressive arthropathy in this population; however, the contribution of Bartonella spp. infection, if any, to these symptoms should be systematically investigated.

Identification of Bartonella Trw host-specific receptor on erythrocytes

Each Bartonella species appears to be highly adapted to one or a limited number of reservoir hosts, in which it establishes long-lasting intraerythrocytic bacteremia as the hallmark of infection. Recently, we identified Trw as the bacterial system involved in recognition of erythrocytes according to their animal origin. The T4SS Trw is characterized by a multiprotein complex that spans the inner and outer bacterial membranes, and possesses a hypothetical pilus structure. TrwJ, I, H and trwL are present in variable copy numbers in different species and the multiple copies of trwL and trwJ in the Bartonella trw locus are considered to encode variant forms of surface-exposed pilus components. We therefore aimed to identify which of the candidate Trw pilus components were located on the bacterial surface and involved in adhesion to erythrocytes, together with their erythrocytic receptor. Using different technologies (electron microscopy, phage display, invasion inhibition assay, far western blot), we found that only TrwJ1 and TrwJ2 were expressed and localized at the cell surface of B. birtlesii and had the ability to bind to mouse erythrocytes, and that their receptor was band3, one of the major outer-membrane glycoproteins of erythrocytes, (anion exchanger). According to these results, we propose that the interaction between TrwJ1, TrwJ2 and band 3 leads to the critical host-specific adherence of Bartonella to its host cells, erythrocytes.

Role of the spleen in Bartonella spp. infection

Bartonella spp. are intra-erythrocytic pathogens of mammals. In this study, we investigated the role of the spleen, and other tissue and organs in Bartonella infection. Using an in vivo model of mice infection by Bartonella birtlesii, we detected accumulation of bacteria in the spleen, with transient infection of the liver, but failed to detect any bacteria in brain or lymph nodes. We then compared bacteraemia in normal Balb/C mice and in splenectomized mice. Bacteraemia in splenectomized mice was 10-fold higher than in normal mice and lasted 2 weeks longer. In conclusion, the spleen seems to retain and filter infected erythrocytes rather than to be a sanctuary for chronic Bartonella infection.

Strategies of exploitation of mammalian reservoirs by Bartonella species

Numerous mammal species, including domestic and wild animals such as ruminants, dogs, cats and rodents, as well as humans, serve as reservoir hosts for various Bartonella species. Some of those species that exploit non-human mammals as reservoir hosts have zoonotic potential. Our understanding of interactions between bartonellae and reservoir hosts has been greatly improved by the development of animal models for infection and the use of molecular tools allowing large scale mutagenesis of Bartonella species. By reviewing and combining the results of these and other approaches we can obtain a comprehensive insight into the molecular interactions that underlie the exploitation of reservoir hosts by Bartonella species, particularly the well-studied interactions with vascular endothelial cells and erythrocytes.

Identification of candidate proteins for the diagnosis of Bartonella henselae infections using an immunoproteomic approach

Bartonella henselae is an emerging gram-negative facultative intracellular pathogen transmitted via Ctenocephalides felis (cat fleas) or cat scratches. Bartonellosis is present mainly in the form of cat scratch disease (CSD), bacillary angiomatosis and infective endocarditis (IE). The methods used to diagnose B. henselae rely on culturing, immunofluorescent assays and molecular techniques. The objective of the present study was to identify candidate proteins for the serodiagnosis of bartonellosis with the differential discrimination of both clinical scenarios: CSD and IE. For this, an immunoproteomic approach combined with 2-DE, immunoblotting and matrix-assisted laser desorption/ionization time-of-flight MS has been developed. Immunoproteomic profiles of sera collected from patients with CSD and IE were compared with those of blood donors. We identified several candidate proteins as phage-encoding Pap31 protein and an outer membrane protein of BH11510 that, in our view, might be useful for the serodiagnosis of bartonellosis.

Biogenesis of Afipia-containing phagosomes in non-professional phagocytes

Afipia felis is a Gram-negative alpha-proteobacterium, a rare cause of human cat scratch disease (CSD), and likely a pathogen of amoeba. Here, we show that various members of the genus Afipia attach to and are taken up by various non-professional phagocytic mammalian cells (epithelial CHO, endothelial EA.hy926, epithelial HeLa, epithelial INT407 cells, endothelial HMEC-1, endothelial HUVEC, and fibroblast L929 cells). However, only A. felis was able to do this efficiently. Invasion depended on a functional actin cytoskeleton and much less on microtubule dynamics. Bacteria were slowly taken up into HMEC-1 (and HUVEC) via pocket-like structures and they resided within membrane-surrounded phagosomes. While A. felis was found in a non-canonical endocytic compartment in macrophage cells, Afipia-containing phagosomes in HMEC-1 were transiently positive for early endosomal EEA1 and then became and remained positive for lysosome-associated membrane protein-1 (LAMP1) and the proton-pumping ATPase, suggesting undisturbed, albeit slowed, phagosome biogenesis in these cells. Similarly, at 24h of infection, most phagosomes in HeLa, INT407, HUVEC and in EA.hy926 cells were positive for LAMP1. In summary, A. felis enters various non-professional phagocytes and its compartmentation differs between macrophages and non-professional phagocytes.

Endothelial cell infection and hemostasis

As an important component of the vasculature, endothelial cell lining covers the inner surface of blood vessels and provides an active barrier interface between the vascular and perivascular compartments. In addition to maintaining vasomotor equilibrium and organ homeostasis and communicating with circulating blood cells, the vascular endothelium also serves as the preferred target for a number of infectious agents. This review article focuses on the roles of interactions between vascular endothelial cells and invading pathogens and resultant endothelial activation in the pathogenesis of important human diseases with viral and bacterial etiologies. In this perspective, the signal transduction events that regulate vascular inflammation and basis for endothelial cell tropism exhibited by certain specific viruses and pathogenic bacteria are also discussed.

Is pyogenic granuloma associated with Bartonella infection?

Lobular capillary hemangioma and bacillary angiomatosis due to Bartonella infection share several clinical and histopathologic characteristics. We sought to determine whether lobular capillary hemangioma is caused by the same agent as bacillary angiomatosis. Forty-five pathology specimens with a histologic diagnosis of lobular capillary hemangioma obtained from patients with the same clinical diagnosis were tested by immunohistochemistry and polymerase chain reaction for the presence of DNA elements of Bartonella spp. None of the 45 lobular capillary hemangioma specimens tested positive for Bartonella spp. We conclude that lobular capillary hemangioma is not associated with Bartonella spp infection. Further research is required to determine the etiologic agent.

A review of bacterial pathogens inCtenocephalides felisin New Zealand

The cat flea, Ctenocephalides felis, is the recognised vector of Bartonella henselae, B. clarridgeiae and Rickettsia felis. Although these Gram-negative bacteria were only described in the last decade, they are already known to cause a variety of diseases in people, particularly children and the immunosuppressed. Such diseases include cat-scratch disease, bacillary angiomatosis, endocarditis, bacteraemia, encephalopathy, neuroretinitis, osteomyelitis and peliosis hepatis. Although most infections in cats and dogs appear to be subclinical, recent studies have provided growing evidence that the bartonellas can also cause serious problems in pets, including hepatitis, endocarditis, central nervous system (CNS) signs, lymphadenopathy, uveitis, cataracts and reproductive failure. In 2004, DNA of B. henselae, B. clarridgeiae and R. felis was demonstrated in cat fleas from New Zealand and pets and their owners in the country are thus at risk of infection. While flea control programmes have traditionally been advocated by veterinarians to prevent pruritus and tapeworms in pets, they should now also be recommended to prevent infections with the new flea-borne bacterial pathogens. To raise awareness of the organisms amongst veterinarians and animal health workers, this review describes: the biology of the organisms; clinical and laboratory features of infections in cats, dogs and people; diagnosis; and possible treatments and control of infections with these organisms.

In vitro Bartonella quintana infection modulates the programmed cell death and inflammatory reaction of endothelial cells

Bartonella quintana is an epicellular bacterium, which in vivo as well as in vitro, invades endothelial cells and develops within them inducing proliferative effects that play a pivotal role in neovascular manifestation of this disease. We investigated the effect of live Bartonella quintana and its LPS on apoptosis and inflammatory response in HUVEC-C, an endothelial cell line. The kinetics of the programmed cell death of Bartonella quintana-infected HUVEC-C showed a peculiar course. Even if early during infection apoptosis reached a peak after 6 h, later on apoptosis was inhibited. Such apoptosis inhibition was not observed during Bartonella quintana lipopolysaccharide treatment because LPS-stimulated HUVEC-C did progress to cell death. Evaluation of multiple cell signal transduction pathways revealed an overexpression of Apaf 1 and caspase 8 in HUVEC-C after 2 h of infection, and of bcl-2 starting from 10 h post Bartonella quintana infection. Moreover, Bartonella quintana and its LPS showed a different effect on the activation of genes involved in inflammatory response as revealed by molecular analysis of host cells. Bartonella quintana appears to be able to inhibit programmed cell death, inducing intracellular signals leading to survival and proliferation through the bcl-2 gene, despite the early increase of inflammatory status induced in endothelial cells. This mechanism, together with a poor endotoxin ability to stimulate strong inflammatory response, could contribute to the capability of the bacteria to persist intracellularly, causing chronic disease and producing neovascular manifestations.

How bacteria could cause cancer: one step at a time

Helicobacter pylori highlighted the potential for bacteria to cause cancer. It is becoming clear that chronic infection with other bacteria, notably Salmonella typhi, can also facilitate tumour development. Infections caused by several bacteria (e.g. Bartonella spp., Lawsonia intracellularis and Citrobacter rodentium) can induce cellular proliferation that can be reversed by antibiotic treatment. Other chronic bacterial infections have the effect of blocking apoptosis. However, the underlying cellular mechanisms are far from clear. Conversely, several bacterial toxins interfere with cellular signalling mechanisms in a way that is characteristic of tumour promoters. These include Pasteurella multocida toxin, which uniquely acts as a mitogen, and Escherichia coli cytotoxic necrotizing factor, which activates Rho family signalling. This leads to activation of COX2, which is involved in several stages of tumour development, including inhibition of apoptosis. Such toxins could provide valuable models for bacterial involvement in cancer, but more significantly they could play a direct role in cancer causation and progression.

A heat-stable component of Bartonella henselae upregulates intercellular adhesion molecule-1 expression on vascular endothelial cells

Bartonella henselae upregulated the expression of intercellular adhesion molecule-1 (ICAM-1) on human umbilical vein endothelial cells (HUVECs). The induction level of ICAM-1 depended on the inoculation bacterial dose. ICAM-1 expression began increasing 4 h after infection and reached a sustained peak beginning at 12 h after B. henselae infection; this time course was similar to that of lipopolysaccharide (LPS) of Escherichia coli. The stimulatory effect was abolished when live B. henselae were separated from HUVECs by a filter membrane. The nonpiliated strain, which is unable to invade endothelial cells, induced ICAM-1 expression to the same extent as the piliated strain. Inactivation of B. henselae by ultraviolet (UV) irradiation, heat (56 degrees C, 30 min), or sonication did not alter its stimulatory activity. Polymyxin B, which strongly inhibited the effect of LPS, did not exert any influence on the stimulatory activity of B. henselae. Furthermore, the effect of sonicated B. henselae was not inhibited even by boiling, which was also the case with LPS. Our data suggest that some heat-stable component of B. henselae binds to the endothelial cell surface, inducing ICAM-1 expression. Though the participation of LPS could not be completely ruled out, we suppose that some unidentified heat-stable proteins, lipids, or polysaccharides may be the stimulatory factor(s). The ability of B. henselae to enhance the expression of adhesion molecules on endothelial cells may be an important mechanism in the pathogenesis of B. henselae infection.

Intracellular induction of the Bartonella henselae virB operon by human endothelial cells

One of the more recently identified bacterial exportation systems is the type IV secretion mechanism, which is characterized by a multiprotein complex that spans the inner and outer bacterial membranes and contains a pilin component. The most thoroughly studied type IV secretion system is encoded by the virB operon of Agrobacterium tumefaciens. In Bartonella henselae, 8 of the 10 virB operon genes share extensive homology and arrangement with the virB operon of A. tumefaciens. Sequencing of the region upstream of the B. henselae virB2 gene revealed a region with sequence homology to the vir box of A. tumefaciens. This possible promoter region was cloned upstream of the green fluorescent protein reporter gene in the promoterless vector pANT3 and used to transform B. henselae. Minimal reporter gene expression was seen in the transformed bacteria cultivated in the absence of host cells, but expression was strongly induced in intracellular bacteria cultivated with human microvascular endothelial cells. Deletion of an 87-bp fragment, which contained the putative vir box from the 5' end of the promoter region, diminished intracellular induction of the reporter gene. Host cell induction of the 17-kDa antigen gene, which replaces virB5 in B. henselae, was also demonstrated at the protein level using specific antiserum. Thus, expression of the virB genes of B. henselae is induced in bacteria, which have invaded host cells, through a mechanism that may be similar to the environment-sensing mechanism found in the virB operon of A. tumefaciens.

Bartonella henselae induces NF-kappaB-dependent upregulation of adhesion molecules in cultured human endothelial cells: possible role of outer membrane proteins as pathogenic factors

The endothelium is a specific target for Bartonella henselae, and endothelial cell infection represents an important step in the pathogenesis of cat scratch disease and bacillary angiomatosis. Mechanisms of Bartonella-endothelial cell interaction as well as signaling pathways involved in target cell activation were analyzed. B. henselae strain Berlin-1, isolated from bacillary angiomatosis lesions of a human immunodeficiency virus-infected patient, potently stimulated human umbilical cord vein endothelial cells (HUVEC), as determined by NF-kappaB activation and enhanced adhesion molecule expression. These effects were accompanied by increased PMN rolling on and adhesion to infected endothelial cell monolayers, as measured in a parallel-plate flow chamber assay. Monoclonal antibodies against E-selectin significantly reduced PMN rolling and adhesion. In our hands, B. henselae Berlin-1 was substantially more active than the typing strain B. henselae ATCC 49882. E-selectin and ICAM-1 upregulation occurred for up to 9 days, as verified by Northern blotting and cell surface enzyme-linked immunosorbent assay. Induction of adhesion molecules was mediated via NF-kappaB activation and could be blocked by a specific NF-kappaB inhibitor. Additional studies indicated that B. henselae-induced effects did not require living bacteria or Bartonella lipopolysaccharides. Exposure of HUVEC to purified B. henselae outer membrane proteins (OMPs), however, reproduced all aspects of endothelial cell activation. In conclusion, B. henselae, the causative agent of cat scratch disease and bacillary angiomatosis, infects and activates endothelial cells. B. henselae OMPs are sufficient to induce NF-kappaB activation and adhesion molecule expression followed by enhanced rolling and adhesion of leukocytes. These observations identify important new properties of B. henselae, demonstrating its capacity to initiate a cascade of events culminating in a proinflammatory phenotype of infected endothelial cells.

Bartonella interactions with endothelial cells and erythrocytes

Bartonella species are emerging human pathogens responsible for a wide range of clinical manifestations, including Carrion's disease, trench fever, cat-scratch disease, bacillary angiomatosis-peliosis, endocarditis and bacteraemia. During infection of their human or animal reservoir host(s), these arthropod-borne pathogens typically invade and persistently colonize mature erythrocytes. However, in both reservoir and incidentally infected hosts, endothelial cells are target cells for bartonellae. Endothelial interactions involve a unique mode of cellular invasion, the activation of a proinflammatory phenotype and the formation of vasoproliferative tumours. Based on the establishment of bacterial genetics and appropriate infection models, recent work has begun to elucidate the cell and molecular biology of these unusual pathogen-host cell interactions.

Invasion and persistent intracellular colonization of erythrocytes. A unique parasitic strategy of the emerging pathogen Bartonella

The expanding genus Bartonella includes zoonotic and human-specific pathogens that can cause a wide range of clinical manifestations. A productive infection allowing bacterial transmission by blood-sucking arthropods is marked by an intraerythrocytic bacteremia that occurs exclusively in specific human or animal reservoir hosts. Incidental human infection by animal-adapted bartonellae can cause disease without evidence for erythrocyte parasitism. A better understanding of the intraerythrocytic lifestyle of bartonellae may permit the design of strategies to control the reservoir and transmittable stages of these emerging pathogens. We have dissected the process of Bartonella erythrocyte parasitism in experimentally infected animals using a novel approach for tracking blood infections based on flow cytometric quantification of green fluorescent protein-expressing bacteria during their interaction with in vivo-biotinylated erythrocytes. Bacteremia onset occurs several days after inoculation by a synchronous wave of bacterial invasion into mature erythrocytes. Intracellular bacteria replicate until reaching a stagnant number, which is sustained for the remaining life span of the infected erythrocyte. The initial wave of erythrocyte infection is followed by reinfection waves occurring at intervals of several days. Our findings unravel a unique bacterial persistence strategy adapted to a nonhemolytic intracellular colonization of erythrocytes that preserves the pathogen for efficient transmission by blood-sucking arthropods.

Immune aspects of Bartonella

Bartonella species have been recognized as important human pathogens only recently. Until the early 1990s, this genus was represented by one species, Bartonella bacilliformis. The recent identification of other Bartonella species as the agents of cat-scratch disease and bacillary angiomatosis has left little doubt of their emerging importance as opportunistic human pathogens. Over the last decade, extensive research has been performed on Bartonella species, resulting in an explosion in our knowledge of the genetic diversity of this genus. Unusual aspects of disease sequelae have fueled worldwide interest in defining the natural history, pathology, and molecular biology of Bartonella species. While much information about these interests has been presented, the advancement of immunological knowledge regarding Bartonella species has been slow. This review discusses immunological data on Bartonella species, focusing on the three primary human pathogens of this genus: B. bacilliformis, B. quintana, and B. henselae.

Passive antibody to Bartonella henselae protects against clinical disease following homologous challenge but does not prevent bacteremia in cats

We challenged cats transfused with anti-Bartonella serum and kittens born to antibody-positive queens with Bartonella henselae to determine the contribution of antibodies to the control of B. henselae in cats. In both experiments, antibody-positive cats were protected from clinical disease but passive antibody to the homologous strain of B. henselae did not prevent bacteremia.

Transcriptional activation of the htrA (High-temperature requirement A) gene from Bartonella henselae

Bacterial htrA genes are typically activated as part of the periplasmic stress response and are dependent on the extracytoplasmic sigma factor rpoE. A putative promoter region, P1, of the sigma(E)-type heat-inducible promoters has previously been identified upstream of the htrA gene of Bartonella henselae. Further analysis of the htrA mRNA by primer extension demonstrated that transcription initiates from P1 and a second region downstream of P1. This second promoter region, termed P2, had no sequence identity to sigma(E)-type heat-inducible promoters. Promoter regions were cloned individually and in tandem into pANT3 upstream of a promoterless version of the green fluorescent protein (GFP) gene (gfpmut3) and transformed into B. henselae by electroporation. The contiguous promoter region containing both P1 and P2 were necessary for the optimal transcriptional activation of the htrA gene. Promoter activity at 37 degrees C was distinctively higher than at 27 degrees C. However, thermal induction at 47 degrees C did not increase expression of gfpmut3. Invasion of human microvascular endothelial cells (HMEC-1) by B. henselae resulted in the formation of well-defined vacuoles containing clusters of bacteria exhibiting marked expression of gfpmut3 transcribed from the P1-P2 region. In addition, a moderate yet significant increase in the ratio of bacterial GFP to DNA was detected for intracellular bacteria compared to extracellular bacteria, indicating upregulation of htrA upon invasion of HMEC-1. The activation of specific genes in the intracellular environment may help us better understand the novel pathogenic mechanisms used by this bacterium.

Bartonella henselae, B. quintana, and B. bacilliformis: historical pathogens of emerging significance

Bartonella species were virtually unrecognized as modern pathogens of humans until the last decade. However, identification of Bartonella species as the agents of cat-scratch disease, bacillary angiomatosis, urban trench fever, and possible novel presentations of Carrion's disease has left little doubt of the emerging medical importance of this genus of organisms. The three primary human pathogenic bartonellae, Bartonella bacilliformis (Carrion's disease), B. henselae (cat-scratch disease), and B. quintana (trench fever), present noteworthy comparisons in the epidemiology, natural history, pathology, and host-microbe interaction that this review will briefly explore.

Isolation, sequencing and expression of Bartonella henselae omp43 and predicted membrane topology of the deduced protein

The infection of and interaction of human endothelial cells with Bartonella henselae is one of the most interesting aspects of Bartonella -associated disease. The gene encoding the 43 kDa B. henselae outer membrane protein (Omp43) that binds endothelial cells was cloned and sequenced. Sequence analysis revealed an open reading frame of 1206 nucleotides coding for a protein of 402 amino acids. Analysis of the deduced amino acid sequence shows 38% identity over the entire sequence to the Brucella spp. In addition to this Omp2b porin also shows a signal sequence and peptidase cleavage site. Cleavage of the signal peptide results in a mature 380 amino acid polypeptide with a predicted molecular weight of 42 kDa. Omp43 was expressed in Escherichia coli as a fusion protein. Purified recombinant Omp43 at concentrations of 11 and 2.75 microg/ml bound to intact human umbilical vein endothelial cells. Membrane topology analysis predicts that Omp43 exists as a 16 stranded beta barrel protein, similar to that predicted for the Omp2b Brucella abortus porin. Characterization and expression of the gene encoding Omp43 should provide a tool for further investigation of the role of adherence to endothelial cells in the pathogenesis of B. henselae.

Rickettsia prowazekii and Bartonella henselae: differences in the intracellular life styles revisited

Within the alpha subdivision of proteobacteria, the arthropod-borne human pathogens Rickettsia prowazekii and Bartonella henselae provide examples of bacteria with obligate and facultative intracellular life styles, respectively. The complete genome sequence of R. prowazekii has been published, whereas the sequencing of the B. henselae genome is in its final stage. Here, we provide a brief overview of a comparative analysis of both genomes based on the delineated metabolic properties. The relative proportion of genes devoted to basic information processes is similar in the two genomes. In contrast, a full set of genes encoding proteins involved in the biosynthesis of amino acids and nucleotides is present in B. henselae, while the majority of these genes is absent from R. prowazekii. This suggests that B. henselae has a better potential for growth in the free-living mode, whereas R. prowazekii is more specialised to growth in an intracellular environment. Functional genomics will provide the potential to further resolve the genetic basis for successful human infections by these important parasites.

In vitro susceptibilities of four Bartonella bacilliformis strains to 30 antibiotic compounds

We have evaluated for the first time in vitro antibiotic susceptibilities of four human strains of Bartonella bacilliformis, the agent of Carrion's disease. Our results show that B. bacilliformis, like other Bartonella species, is highly susceptible to antibiotics, including most beta-lactams, aminoglycosides, chloramphenicol, rifampin, macrolides, tetracyclines, cotrimoxazole, and fluoroquinolones.