Effects of Environmental pH on Membrane Proteins in Borrelia burgdorferi

Borrelia burgdorferi, the causative agent of Lyme disease, alternates between the microenvironments of the tick vector, Ixodes scapularis, and a mammalian host. The environmental conditions the spirochete encounters during its infectious cycle are suspected to differ greatly in many aspects, including available nutrients, temperature, and pH. Here we identify alterations in the membrane protein profile, as determined by immunoblotting and two-dimensional nonequilibrium pH gradient gel electrophoresis (2D-NEPHGE), that occur in virulent B. burgdorferi B31 as the pH of the medium is altered. Initial comparisons of cultures incubated at pHs 6.0, 7.0, and 8.0 yielded alterations in the expression of seven membrane proteins as determined by probing with hyperimmune rabbit serum. Six of these membrane proteins (54, 45, 44, 43, 35, and 24 kDa) were either present in increased amounts in or solely expressed by cultures incubated at pHs 6.0 and 7.0. The 24-kDa protein that decreased in expression at pH 8.0 was identified as outer surface protein C (OspC). In addition, a 42-kDa membrane protein increased in amount in cultures incubated at pH 8.0. Similar changes were observed with serum from a mouse infected by tick bite, with the recognition of two additional bands (48 and 46 kDa) unique to pHs 6. 0 and 7.0. When membrane fractions were analyzed by 2D-NEPHGE, at least 37 changes in the membrane protein profile between cells incubated at pHs 6.0, 7.0, and 8.0 were observed by immunoblotting and silver staining. Environmental cues such as pH may prove important in the regulation of virulence determinants and factors necessary for the adaptation of B. burgdorferi to the tick or mammalian microcosm.     

The thermophilic, homohexameric aminopeptidase of Borrelia burgdorferi is a member of the M29 family of metallopeptidases

Proteases are implicated in several aspects of the physiology of microorganisms, as well as in host-pathogen interactions. Aminopeptidases are also emerging as novel drug targets in infectious agents. In this study, we have characterized an aminopeptidase from the spirochete Borrelia burgdorferi, the causative agent of Lyme disease. The aminopeptidolytic activity was identified in cell extracts from B. burgdorferi by using the substrate leucine-7-amido-4-methylcoumarin. A protein displaying this activity was purified from B. burgdorferi by a two-step chromatographic procedure, yielding a approximately 300-kDa homo-oligomeric enzyme formed by monomers of approximately 50 kDa. Gel enzymography experiments showed that enzymatic activity depends on the oligomeric structure of the protease but does not involve interchain disulfide bonds. The enzyme was identified by peptide mass fingerprinting as the putative aminopeptidase II of B. burgdorferi, encoded by the gene BB0069. It shares significant identity to members of the M29/T family of metallopeptidase, is sensitive to bestatin, has a neutral pH optimum, and displays maximal activity at 60 degrees C. Its activity is 1.75-fold higher at the temperature of the mammalian host than at that of the insect host of the pathogen. The activity of this thermophilic aminopeptidase of B. burgdorferi (TAP(Bb)) depends on Zn2+, and temperatures over 70 degrees C promoted its inactivation through a transition from the hexameric state to the monomeric state. Since B. burgdorferi is deficient in pathways for amino acid synthesis, TAP(Bb) could play a role in supplying required amino acids. Alternatively, the enzyme could be involved in peptide and/or protein processing.     

Borrelia burgdorferi proteins whose expression is similarly affected by culture temperature and pH

Previously, we had demonstrated the upregulation in the expression of several proteins, including the lipoproteins OspC and P35, of Borrelia burgdorferi in the stationary growth phase. Since the expression of OspC is also known to be affected by culture temperature and pH, we examined the effects of both variables on the expression of the remaining stationary-phase-upregulated proteins. Our study revealed that the expression of each of the remaining stationary-phase-upregulated proteins, P35 included, was also influenced by culture temperature; these proteins were selectively expressed at 34 degrees C but not at 24 degrees C. Significantly, the expression of a majority of these proteins was also affected by culture pH, since they were abundantly expressed at pH 7.0 (resembling the tick midgut pH of 6.8 during feeding) but only sparsely at pH 8.0 (a condition closer to that of the unfed tick midgut pH of 7.4). We propose that this group of B. burgdorferi proteins, which in culture is selectively expressed under conditions of 34 degrees C and pH 7.0, may be induced in the tick midgut during the feeding event. Furthermore, the differential and coordinate expression of these proteins under different environmental conditions suggests that the encoding genes may be coregulated.     

Evaluation of RevA,a Fibronectin-Binding Protein of Borrelia burgdorferi,as a Potential Vaccine Candidate for Lyme Disease

Previous studies indicated that the Lyme disease spirochete Borrelia burgdorferi expresses the RevA outer surface protein during mammalian infection. As an adhesin that promotes bacterial interaction with fibronectin, RevA appears to be a good target for preventive therapies. RevA proteins are highly conserved across all Lyme borreliae, and antibodies against RevA protein are cross-reactive among RevA proteins from diverse strains. Mice infected with B. burgdorferi mounted a rapid IgM response to RevA, followed by a strong IgG response that generally remained elevated for more than 12 months, suggesting continued exposure of RevA protein to the immune system. RevA antibodies were bactericidal in vitro. To evaluate the RevA antigen as a potential vaccine, mice were vaccinated with recombinant RevA and challenged with B. burgdorferi by inoculation with a needle or by a tick bite. Cultured tissues from all treatment groups were positive for B. burgdorferi. Vaccinated animals also appeared to have similar levels of B. burgdorferi DNA compared to nonvaccinated controls. Despite its antigenicity, surface expression, and the production of bactericidal antibodies against it, RevA does not protect against Borrelia burgdorferi infection in a mouse model. However, passive immunization with anti-RevA antibodies did prevent infection, suggesting the possible utility of RevA-based immunotherapeutics or vaccine.     

A surface enolase participates in Borrelia burgdorferi-plasminogen interaction and contributes to pathogen survival within feeding ticks

Borrelia burgdorferi, a tick-borne bacterial pathogen, causes a disseminated infection involving multiple organs known as Lyme disease. Surface proteins can directly participate in microbial virulence by facilitating pathogen dissemination via interaction with host factors. We show here that a fraction of the B. burgdorferi chromosomal gene product BB0337, annotated as enolase or phosphopyruvate dehydratase, is associated with spirochete outer membrane and is surface exposed. B. burgdorferi enolase, either in a recombinant form or as a membrane-bound native antigen, displays enzymatic activities intrinsic to the glycolytic pathway. However, the protein also interacts with host plasminogen, potentially leading to its activation and resulting in B. burgdorferi-induced fibrinolysis. As expected, enolase displayed consistent expression in vivo, however, with a variable temporal and spatial expression during spirochete infection in mice and ticks. Despite an extracellular exposure of the antigen and a potential role in host-pathogen interaction, active immunization of mice with recombinant enolase failed to evoke protective immunity against subsequent B. burgdorferi infection. In contrast, enolase immunization of murine hosts significantly reduced the acquisition of spirochetes by feeding ticks, suggesting that the protein could have a stage-specific role in B. burgdorferi survival in the feeding vector. Strategies to interfere with the function of surface enolase could contribute to the development of novel preventive measures to interrupt the spirochete infection cycle and reduce the incidences of Lyme disease.     

Borrelia burgdorferi in Tick Cell Culture Modulates Expression of Outer Surface Proteins A and C in Response to Temperature

The Lyme disease spirochete Borrelia burgdorferi sensu stricto downregulates outer surface protein A (OspA) and upregulates outer surface protein C (OspC) during tick feeding. The switching of these proteins correlates with increased spirochetal infectivity for the mammal. We examined the effect of temperature on differential expression of OspA and OspC by B. burgdorferi cocultivated with a cell line isolated from the vector tick Ixodes scapularis. The effect of incubation at 31, 34, or 37 degrees C on expression of OspA and OspC by B. burgdorferi JMNT and N40 was analyzed by indirect fluorescent-antibody microscopy, polyacrylamide gel electrophoresis, and immunoblotting. The amount of OspA relative to the amount of flagellin was highest in spirochetes cocultivated with tick cells at 31 degrees C and declined with increasing temperature in both strains. OspC production was enhanced in spirochetes cocultivated with tick cells at 37 degrees C. Spirochetes grown axenically in BSK-H medium also produced more OspC at 37 degrees C, but OspA content was not appreciably affected by temperature. Our findings indicate that temperature, along with cultivation in a tick cell culture system, plays a role in the differential expression of OspA and enhances differential expression of OspC by spirochetes.     

Cultivation at 37°C enhances Borrelia burgdorferi sensu stricto infectivity for hamsters

Borrelia burgdorferi sensu stricto (s.s.), the causative agent of Lyme disease in North America is transmitted to the mammalian host by ticks belonging to the genus, Ixodes. Antibodies to several spirochetal proteins, most notably outer surface protein C (OspC), have been observed in early infection in both humans and laboratory animals. Thus, the expression of these proteins have been postulated to play a role in tick transmission and spirochetal infectivity for the mammalian host. B. burgdorferi strain JMNT was induced to produce increased levels of OspC by cultivation in BSK medium at 37 degrees C. To diminish expression of OspC, spirochetes were cultivated at 31 degrees C. Spirochetes shifted down from 37 degrees C to 31 degrees C or up from 31 degrees C to 37 degrees C for 1 week contained equivalent amounts of OspC. To evaluate spirochetal infectivity, hamsters were inoculated subcutaneously with 1 x 10(4) or 1 x 10(6) spirochetes grown at the above-mentioned temperatures. Hamsters inoculated with spirochetes expressing high amounts of OspC all became infected, irrespective of the inoculum size. None of the hamsters inoculated with 1 x 10(4) spirochetes grown at 31 degrees C or in cultures shifted down from 37 degrees C to 31 degrees C were infected. All infected hamsters, confirmed by isolation of spirochetes in ear and/or bladder cultures, had an antibody response to OspC. In contrast, all non-infected hamsters lacked antibodies to OspC. We conclude that cultivation of spirochetes at 37 degrees C enhances their infectivity for hamsters. This study also suggests there is a correlation between enhancement of OspC expression and spirochetal infectivity for hamsters.     

Temporal analysis of Borrelia burgdorferi Erp protein expression throughout the mammal-tick infectious cycle

Previous immunological studies indicated that the Lyme disease spirochete, Borrelia burgdorferi, expresses Erp outer surface proteins during mammalian infection. We conducted analyses of Erp expression throughout the entire tick-mammal infectious cycle, which revealed that the bacteria regulate Erp production in vivo. Bacteria within unfed nymphal ticks expressed little to no Erp proteins. However, as infected ticks fed on mice, B. burgdorferi increased production of Erp proteins, with essentially all transmitted bacteria expressing these proteins. Mice infected with B. burgdorferi mounted rapid IgM responses to all tested Erp proteins, followed by strong immunoglobulin G responses that generally increased in intensity throughout 11 months of infection, suggesting continued exposure of Erp proteins to the host immune system throughout chronic infection. As naive tick larvae acquired B. burgdorferi by feeding on infected mice, essentially all transmitted bacteria produced Erp proteins, also suggestive of continual Erp expression during mammalian infection. Shortly after the larvae acquired bacteria, Erp production was drastically downregulated. The expression of Erp proteins on B. burgdorferi throughout mammalian infection is consistent with their hypothesized function as factor H-binding proteins that protect the bacteria from host innate immune responses.     

Borrelia burgdorferi binding of host complement regulator factor H is not required for efficient mammalian infection

The causative agent of Lyme disease, Borrelia burgdorferi, is naturally resistant to its host's alternative pathway of complement-mediated killing. Several different borrelial outer surface proteins have been identified as being able to bind host factor H, a regulator of the alternative pathway, leading to a hypothesis that such binding is important for borrelial resistance to complement. To test this hypothesis, the development of B. burgdorferi infection was compared between factor H-deficient and wild-type mice. Factor B- and C3-deficient mice were also studied to determine the relative roles of the alternative and classical/lectin pathways in B. burgdorferi survival during mammalian infection. While it was predicted that B. burgdorferi should be impaired in its ability to infect factor H-deficient animals, quantitative analyses of bacterial loads indicated that those mice were infected at levels similar to those of wild-type and factor B- and C3-deficient mice. Ticks fed on infected factor H-deficient or wild-type mice all acquired similar numbers of bacteria. Indirect immunofluorescence analysis of B. burgdorferi acquired by feeding ticks from the blood of infected mice indicated that none of the bacteria had detectable levels of factor H on their outer surfaces, even though such bacteria express high levels of surface proteins capable of binding factor H. These findings demonstrate that the acquisition of host factor H is not essential for mammalian infection by B. burgdorferi and indicate that additional mechanisms are employed by the Lyme disease spirochete to evade complement-mediated killing.     

Temperature-regulated protein synthesis by Leptospira interrogans

Leptospira interrogans is an important mammalian pathogen. Transmission from an environmental source requires adaptations to a range of new environmental conditions in the organs and tissues of the infected host. Since many pathogenic bacteria utilize temperature to discern their environment and regulate the synthesis of appropriate proteins, we investigated the effects of temperature on protein synthesis in L. interrogans. Bacteria were grown for several days after culture temperatures were shifted from 30 to 37 degrees C. Triton X-114 cellular fractionation identified several proteins of the cytoplasm, periplasm, and outer membrane for which synthesis was dependent on the culture temperature. Synthesis of a cytoplasmic protein of 20 kDa was switched off at 37 degrees C, whereas synthesis of a 66-kDa periplasmic protein was increased at the higher temperature. Increased synthesis of a 25-kDa outer membrane protein was observed when the organisms were shifted from 30 to 37 degrees C. A 36-kDa protein synthesized at 30 but not at 37 degrees C was identified as LipL36, an outer membrane lipoprotein. In contrast, expression of another lipoprotein, LipL41, was the same at either temperature. Immunoblotting with convalescent equine sera revealed that some proteins exhibiting thermoregulation of synthesis elicited antibody responses during infection. Our results show that sera from horses which aborted as a result of naturally acquired infection with L. interrogans serovar pomona type kennewicki recognize periplasmic and outer membrane proteins which are differentially synthesized in response to temperature and which therefore may be important in the host-pathogen interaction during infection.     

Extracellular secretion of the Borrelia burgdorferi Oms28 porin and Bgp, a glycosaminoglycan binding protein

Borrelia burgdorferi, the Lyme disease pathogen, cycles between its Ixodes tick vector and vertebrate hosts, adapting to vastly different biochemical environments. Spirochete gene expression as a function of temperature, pH, growth phase, and host milieu is well studied, and recent work suggests that regulatory networks are involved. Here, we examine the release of Borrelia burgdorferi strain B31 proteins into conditioned medium. Spirochetes intrinsically radiolabeled at concentrations ranging from 10(7) to 10(9) cells per ml secreted Oms28, a previously characterized outer membrane porin, into RPMI medium. As determined by immunoblotting, this secretion was not associated with outer membrane blebs or cytoplasmic contamination. A similar profile of secreted proteins was obtained for spirochetes radiolabeled in mixtures of RPMI medium and serum-free Barbour-Stoenner-Kelly (BSK II) medium. Proteomic liquid chromatography-tandem mass spectrometry analysis of tryptic fragments derived from strain B31 culture supernatants confirmed the identity of the 28-kDa species as Oms28 and revealed a 26-kDa protein as 5'-methylthioadenosine/S-adenosylhomocysteine nucleosidase (Pfs-2), previously described as Bgp, a glycosaminoglycan-binding protein. The release of Oms28 into the culture medium is more selective when the spirochetes are in logarithmic phase of growth compared to organisms obtained from stationary phase. As determined by immunoblotting, stationary-phase spirochetes released OspA, OspB, and flagellin. Oms28 secreted by strains B31, HB19, and N40 was also recovered by radioimmunoprecipitation. This is the first report of B. burgdorferi protein secretion into the extracellular environment. The possible roles of Oms28 and Bgp in the host-pathogen interaction are considered.     

Delineating the requirement for the Borrelia burgdorferi virulence factor OspC in the mammalian host

We previously demonstrated that outer surface protein C (OspC) of Borrelia burgdorferi is essential for establishing mammalian infection. However, the role of OspC in mammalian infection is unknown. Here, we report experiments designed to distinguish between two models of OspC function in the mammalian host: (i) OspC fulfills an essential physiological role for growth and host adaptation or (ii) OspC provides a protective role for evasion of components of the innate immune response. We found that a B. burgdorferi ospC mutant, previously demonstrated to be noninfectious in both immunocompetent and SCID mice, could survive in the relatively immune-privileged environment of dialysis membrane chambers implanted within the peritoneum of a rat. The ospC mutant also adapts to the mammalian environment, as determined by the protein profiles of the chamber-cultivated spirochetes. Therefore, OspC does not appear to provide a physiological function for the survival of B. burgdorferi within the mammalian host. The second model, evasion of the innate immune system, was tested by assessing the infectivity of the ospC mutant in mice deficient for myeloid differentiation protein 88 (MyD88). Recent studies have shown that B. burgdorferi is prevented from reaching high cell numbers in the mammalian host by MyD88-dependent signaling pathways. The ospC mutant was incapable of infecting MyD88-deficient mice, suggesting that the role of OspC cannot be related solely to evasion of MyD88-mediated innate immunity. These results reiterate the importance of OspC in mammalian infection and eliminate simple models of function for this enigmatic protein.     

Interaction of Lyme disease spirochetes with cultured eucaryotic cells.

The association of the Lyme disease spirochete, Borrelia burgdorferi, with cultured human endothelial cells was investigated. Attachment was time and temperature dependent, with optimal adherence occurring after 4 h of incubation at 37 degrees C. Pretreatment of borreliae with heat, immune human serum, or monoclonal antibodies directed against outer surface protein B (OspB) reduced the attachment of organisms to host cell monolayers. These results suggest that the adherence of B. burgdorferi may be mediated, at least in part, by borrelial surface proteins.     

Binding of human plasminogen to Borrelia burgdorferi.

We studied the binding of plasminogen to Borrelia burgdorferi, a spirochete which causes Lyme disease and produces no endogenous proteases which digest extracellular matrix proteins. Using 125I-labeled plasminogen, we demonstrated that B. burgdorferi bound human plasminogen and that this binding was inhibitable with unlabeled plasminogen. 125I-labeled plasminogen binding by B. burgdorferi was also inhibited by the lysine analog epsilon-aminocaproic acid. There was no significant difference in the binding of Glu- or Lys-plasminogen to B. burgdorferi. Binding of plasminogen was similar in low-passage (infectious) and high-passage (noninfectious) isolates of B. burgdorferi. Plasminogen bound to the surface of B. burgdorferi could be converted into plasmin by a human urokinase-type plasminogen activator. 125I-labeled plasminogen ligand blots of borrelial membrane proteins demonstrated two prominent binding proteins at approximately 70 and approximately 30 kDa. By Western blot (immunoblot), the 30-kDa protein was found to be outer surface protein A (Osp A) of B. burgdorferi. 125I-labeled plasminogen binding to both the 70-kDa protein and Osp A was inhibited by approximately 90% with a 1,000-fold excess of unlabeled plasminogen. By scanning densitometry, the 70-kDa band bound > 10 time more 125I-labeled plasminogen than did Osp A. An Osp A-deficient mutant of B. burgdorferi and wild-type B. burgdorferi bound equal amounts of 125I-labeled plasminogen. Ligand blots of membrane proteins from an Osp A-deficient mutant showed association of 125I-labeled plasminogen at only the 70-kDa protein. Two-dimensional gel electrophoresis showed that the 70-kDa protein had a pI of approximately 5.3, clearly separable from Osp A. The association of host plasmin(ogen) with borrelial surface proteins provides a mechanism by which B. burgdorferi can digest extracellular matrix and disseminate.     

Localization of BmpA on the exposed outer membrane of Borrelia burgdorferi by monospecific anti-recombinant BmpA rabbit antibodies

BmpA (P39) is an immunodominant chromosomally encoded Borrelia burgdorferi protein. The potential strong cross-reactivity of anti-BmpA antibodies with the other members of this paralogous protein family and the previous use of antibodies whose reactivity to the other Bmp proteins was uncharacterized have resulted in continued controversy over its localization in B. burgdorferi. In an effort to provide a definitive demonstration of the localization of BmpA, rabbit antibodies raised to recombinant BmpA (rBmpA) were rendered monospecific by absorption with rBmpB. This reagent did not react with rBmpB, rBmpC, or rBmpD in dot immunobinding, detected only a single 39-kDa band and a single 39-kDa, pI 5.0 spot on one- and two-dimensional immunoblots of B. burgdorferi lysates, respectively, and immunoprecipitated a single 39-kDa protein from these lysates. It detected BmpA in the Triton X-114-soluble and -insoluble fractions of B. burgdorferi, suggesting association with both inner and outer bacterial cell membranes. Treatment of intact B. burgdorferi with proteinase K partially digested BmpA, consistent with a limited surface exposure on the outer bacterial membrane, a suggestion confirmed by immunofluorescence of unfixed B. burgdorferi cultured in vitro and in vivo. Anti-rBmpA antibody was bacteriostatic for B. burgdorferi B31 in culture, again suggesting localization of BmpA on the exposed spirochetal outer surface. Surface localization of BmpA, growth inhibition by anti-rBmpA antibodies, and the previously reported conservation of bmpA in different B. burgdorferi sensu lato strains may indicate that BmpA plays an essential role in B. burgdorferi biology.     

Protective niche for Borrelia burgdorferi to evade humoral immunity

The Lyme disease spirochete, Borrelia burgdorferi, is an extracellular microbe that causes persistent infection despite the development of strong immune responses against the bacterium. B. burgdorferi expresses several ligand-binding lipoproteins, including the decorin-binding proteins (Dbps) A and B, which may mediate attachment to decorin, a major component of the host extracellular matrix during murine infection. We show that B. burgdorferi was better protected in the joints and skin, two tissues with a higher decorin expression, than in the urinary bladder and heart, two tissues with a lower decorin expression, during chronic infection of wild-type mice. Targeted disruption of decorin alone completely abolished the protective niche in chronically infected decorin-deficient mice but did not affect the spirochete burden during early infection. The nature of protection appeared to be specific because the spirochetes with higher outer surface protein C expression were not protected while the protective niche seemed to favor the spirochetes with a higher dbpA expression during chronic infection. These data suggest that spirochetal DbpA may interact with host decorin during infection and such interactions could be a mechanism that B. burgdorferi uses to evade humoral immunity and establish chronic infection.