We used novel immunofluorescence strategies to demonstrate that outer surface proteins (Osps) A, B, and C of Borrelia burgdorferi have limited surface exposure, a finding that contradicts the prevailing viewpoint that these antigens are exclusively surface exposed. Light labeling was observed when antibodies to OspA or OspB were added to motile organisms, whereas intense fluorescence was observed when the same slides were methanol-fixed and reprobed. Modest labeling also was observed when spirochetes encapsulated in agarose beads (gel microdroplets) were incubated with antibodies to these same two antigens. This contrasted with the intense fluorescence observed when encapsulated spirochetes were probed in the presence of 0.06% Triton X-100, which selectively removed outer membranes. Proteinase K (PK) treatment of encapsulated spirochetes abrogated surface labeling. However, PK-treated spirochetes fluoresced intensely after incubation with antibodies to OspA or OspB in the presence of detergent, confirming the existence of large amounts of subsurface Osp antigens. Modest surface labeling once again was detected when PK-treated spirochetes were reprobed after overnight incubation, a result consistent with the existence of a postulated secretory apparatus that shuttles lipoproteins to the borrelial surface. Last, experiments with the OspC-expressing B. burgdorferi strain 297 revealed that this antigen was barely detectable on spirochetal surfaces even though it was a major constituent of isolated outer membranes. We propose a model of B. burgdorferi molecular architecture that helps to explain spirochetal persistence during chronic Lyme disease.Lyme disease is a tick-borne, multisystem disorder caused by the spirochete Borrelia burgdorferi and related genospecies (1). At present, it is poorly understood how Lyme disease spirochetes evade the vigorous immune responses they elicit in mammalian hosts. This ability seems particularly enigmatic when one considers that B. burgdorferi, an extracellular pathogen (2), can survive in vivo in the presence of antibodies that are bactericidal in vitro (3, 4). We have proposed that ultrastructural features of the borrelial outer membrane facilitate immune evasion by attenuating the bacterium's surface antigenicity (5). Accordingly, our experimental strategy has been to determine the composition and ultrastructure of the B.burgdorferi outer membrane and the cellular locations of borrelial membrane proteins.A prevailing notion in the field of Lyme disease research is that the mature (i.e., lipid modified) forms of borrelial outer surface lipoproteins are exclusively outer membraneassociated and surface exposed. However, some studies using cryosection immunoelectron microscopy (6) and cell fractionation (6-9) have contradicted this viewpoint by suggesting that only minor amounts of the outer surface proteins (Osps) OspA and OspB are outer membrane-associated. In this report, we used immunofluorescence approaches to clarify the cellular distributions of the three major B. bu...
Freeze-fracture electron microscopy was used to investigate the membrane architectures of high-passage Borrelia burgdorferi B31 and low- and high-passage isolates of B. burgdorferi N40. In all three organisms, fractures occurred almost exclusively through the outer membrane (OM), and the large majority of intramembranous particles were distributed randomly throughout the concave OM leaflet. The density of intramembranous particles in the concave OM leaflet of the high-passage N40 isolate was significantly greater than that in the corresponding leaflet of the low-passage N40 isolate. Also noted in the OMs of all three organisms were unusual structures, designated linear bodies, which typically were more or less perpendicular to the axis of the bacterium. A comparison of freeze-fractured B. burgdorferi and Treponema pallidum, the syphilis spirochete, revealed that the OM architectures of these two pathogens differed markedly. All large membrane blebs appeared to be bounded by a membrane identical to the OM of B. burgdorferi whole cells; in some blebs, the fracture plane also revealed a second bilayer closely resembling the B. burgdorferi cytoplasmic membrane. Aggregation of the lipoprotein immunogens outer surface protein A (OspA) and OspB on the bacterial surface by incubation of B. burgdorferi B31 with specific polyclonal antisera did not affect the distribution of OM particles, supporting the contention that lipoproteins do not form particles in freeze-fractured OMs. The expression of poorly immunogenic, surface-exposed proteins as virulence determinants may be part of the parasitic strategy used by B. burgdorferi to establish and maintain chronic infection in Lyme disease.
The lack of methods for isolating Borrelia burgdorferi outer membranes (OMs) has hindered efforts to characterize borrelial surface-exposed proteins. Here we isolated OMs by immersion of motile spirochetes in hypertonic sucrose followed by isopycnic ultracentrifugation of the plasmolyzed cells. The unilamellar vesicles thus obtained were shown to be OMs by the following criteria: (i) they contained OspA and OspB; (ii) they did not contain flagellin, NADH oxidase activity, or the 60-kDa heat shock protein; and (iii) their morphology by freeze-fracture electron microscopy was identical to that of OMs of intact organisms. Consistent with previous studies which employed immunoelectron microscopy and detergent-based solubilization of B. burgdorferi OMs, only small proportions of the total cellular content of OspA or OspB were OM associated. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) fluorography of OMs from spirochetes metabolically radiolabeled with [ 3 H]palmitate or 35 S-amino acids demonstrated that the OMs contained both nonlipidated and lipidated proteins. This fractionation procedure was also used to isolate OMs from virulent and avirulent isolates of the well-characterized B. burgdorferi N40 strain. SDS-PAGE fluorography revealed that OMs from the two isolates differed with respect to both nonlipoprotein and lipoprotein constituents. When whole cells, protoplasmic cylinders, and OMs were immunoblotted against sera from mice persistently infected with B. burgdorferi N40, the majority of antibody reactivity was directed against intracellular proteins. The availability of isolated OMs should facilitate efforts to elucidate the complex relationship(s) between B. burgdorferi membrane composition and Lyme disease pathogenesis.
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