Environmentally responsive synthesis of surface proteins represents a hallmark of the infectious cycle of the Lyme disease agent, Borrelia burgdorferi. Here we created and analyzed a B. burgdorferi mutant lacking outer-surface protein C (OspC), an abundant Osp that spirochetes normally synthesize in the tick vector during the blood meal and down-regulate after transmission to the mammal. We demonstrate that B. burgdorferi strictly requires OspC to infect mice but not to localize or migrate appropriately in the tick. The induction of a spirochetal virulence factor preceding the time and host in which it is required demonstrates a developmental sequence for transmission of this arthropod-borne pathogen.
A major obstacle to studying the functions of particular gene products in the mouse-tick infectious cycle of Borrelia burgdorferi has been an inability to knock out genes in pathogenic strains. Here, we investigated conditions for site-directed mutagenesis in B31 MI, the low-passage-number, infectious B. burgdorferi strain whose genome was sequenced. We inactivated several plasmid and chromosomal genes in B31 MI and determined that clones carrying these mutations were not infectious for mice. However, we found extensive heterogeneity among clones and mutants derived from B31 MI based on colony phenotype, growth rate, plasmid content, protein profile, and transformability. Significantly, several B31 MI clones that were not subjected to mutagenesis but that lacked particular plasmids also exhibited defects at various stages in the infectious cycle. Therefore, the high degree of clonal polymorphism within B31 MI complicates the assessment of the contributions of individual genes to the observed phenotypes of the mutants. Our results indicate that B31 MI is not an appropriate strain background for genetic studies in infectious B. burgdorferi, and a well-defined isogenic clone is a prerequisite for targeted mutagenesis. To this end, we derived several wild-type clones from B31 MI that were infectious for mice, and gene inactivation was successful in one of these clones. Due to the instability of the genome with in vitro propagation, careful monitoring of plasmid content of derived mutants and complementation of inactivated genes will be crucial components of genetic studies with this pathogen.Lyme disease is caused by Borrelia burgdorferi, a spirochete transmitted by ticks of the genus Ixodes and maintained within an enzootic cycle between the tick vector and mammalian hosts, most importantly small rodents (7,11,19). The clinical manifestations of this zoonosis can include a multisystem disorder affecting skin and joints and the nervous, lymphoreticular, and cardiovascular systems (39,40).The organization of the B. burgdorferi genome is unique among bacteria in that the genome is composed of a linear chromosome and a large number of linear and circular plasmids (8, 14). The complete genome sequence of an infectious B. burgdorferi isolate, the type strain B31, identified 21 linear and circular plasmids (8). In vitro propagation of B. burgdorferi can lead to plasmid loss and concurrent loss of infectivity for mice (3,21,22,30,33). Although increasing evidence suggests that certain Borrelia plasmids are important for infection in mice (18,25), this hypothesis has not been experimentally verified, and the roles of most plasmid-encoded genes in the infectious cycle are unknown. A number of plasmid-and chromosomally encoded genes have been inactivated in the highpassage-number, noninfectious clone B31-A (4,5,12,17,20,43,45,46), but gene inactivation in a low-passage-number, infectious strain background has not been reported.Here, we investigate conditions for site-directed mutagenesis in B31 MI, the low-passage-number, inf...
Loeys-Dietz syndrome (LDS) associates with a tissue signature for high transforming growth factor (TGF)-β signaling but is often caused by heterozygous mutations in genes encoding positive effectors of TGF-β signaling, including either subunit of the TGF-β receptor or SMAD3, thereby engendering controversy regarding the mechanism of disease. Here, we report heterozygous mutations or deletions in the gene encoding the TGF-β2 ligand for a phenotype within the LDS spectrum and show upregulation of TGF-β signaling in aortic tissue from affected individuals. Furthermore, haploinsufficient Tgfb2+/− mice have aortic root aneurysm and biochemical evidence of increased canonical and noncanonical TGF-b signaling. Mice that harbor both a mutant Marfan syndrome (MFS) allele (Fbn1C1039G/+) and Tgfb2 haploinsufficiency show increased TGF-β signaling and phenotypic worsening in association with normalization of TGF-β2 expression and high expression of TGF-β1. Taken together, these data support the hypothesis that compensatory autocrine and/or paracrine events contribute to the pathogenesis of TGF-β–mediated vasculopathies.
Bacterial shape usually is dictated by the peptidoglycan layer of the cell wall. In this paper, we show that the morphology of the Lyme disease spirochete Borrelia burgdorferi is the result of a complex interaction between the cell cylinder and the internal periplasmic flagella. B. burgdorferi has a bundle of 7-11 helically shaped periplasmic flagella attached at each end of the cell cylinder and has a flat-wave cell morphology. Backward moving, propagating waves enable these bacteria to swim in both low viscosity media and highly viscous gel-like media. Using targeted mutagenesis, we inactivated the gene encoding the major periplasmic flagellar filament protein FlaB. The resulting flaB mutants not only were nonmotile, but were rod-shaped. Western blot analysis indicated that FlaB was no longer synthesized, and electron microscopy revealed that the mutants were completely deficient in periplasmic flagella. Wild-type cells poisoned with the protonophore carbonyl cyanide-m-chlorophenylhydrazone retained their flat-wave morphology, indicating that the periplasmic flagella do not need to be energized for the cell to maintain this shape. Our results indicate that the periplasmic flagella of B. burgdorferi have a skeletal function. These organelles dynamically interact with the rodshaped cell cylinder to enable the cell to swim, and to confer in part its flat-wave morphology.spirochete ͉ Lyme disease ͉ allelic exchange ͉ morphology S pirochetes have a unique position among the bacteria. These motile bacteria are one of the few bacterial phyla that can be identified by both 16S ribosomal RNA sequence analysis and morphology (1). Outermost is a membrane sheath, and within this sheath are the cell cylinder and periplasmic flagella. A given periplasmic flagellum is attached subterminally at only one end of the cell cylinder, and it resides within the periplasmic space (2). Depending on the species, the cell morphology is either a helix, a flat wave, or an irregularly shaped helix (2-4). The size of the spirochete, the number of periplasmic flagella attached at each end, and whether the filaments overlap at the center of the cell varies from species to species (2, 5). This phylum contains many medically important bacteria including Treponema pallidum (syphilis), several Borrelia species (relapsing fever), Borrelia burgdorferi (Lyme disease), Leptospira interrogans (leptospirosis), Brachyspira sp. (human diarrheal disease, swine dysentery), and oral treponemes associated with periodontal disease (5-8).The periplasmic flagella of spirochetes have been characterized in detail. Genetic evidence, including targeted mutagenesis studies in Treponema denticola and Brachyspira hyodysenteriae, have shown that these organelles are directly involved in motility (9, 10) (C. Li and N.W.C., unpublished observations). By analyzing protruding periplasmic flagella from certain motility mutants of T. phagedenis, and from stationary-phase cells of several spirochete species, these organelles have been shown to rotate in a manner similar to th...
Previous studies have shown that a 54 -S cascade regulates the expression of a few key lipoproteins in Borrelia burgdorferi, the agent of Lyme disease. Here, we demonstrate that these sigma factors, both together and independently, regulate a much more extensive number of genes and cellular processes. Microarray analyses of 54 and S mutant strains identified 305 genes regulated by 54 and 145 regulated by S , whereas the 54 -S regulatory cascade appears to control 48 genes in B. burgdorferi. In silico analyses revealed that nearly 80% of genes with altered expression in the 54 mutant were linked to potential 54 -dependent promoters. Many 54 -regulated genes are expressed in vivo, and through genetic complementation of the mutant, we demonstrated that 54 was required by B. burgdorferi to infect mammals. Surprisingly, 54 mutants were able to infect Ixodes scapularis ticks and be maintained for at least 24 wk after infection, suggesting the 54 -S regulatory network was not involved in long-term survival in ticks. However, 54 mutants did not enter the salivary glands during tick feeding, indicating that 54 -regulated genes were involved in the transmission process.infectivity ͉ microarray ͉ Lyme ͉ transcription
Genetic studies in Borrelia burgdorferi have been hindered by the lack of a nonborrelial selectable marker. Currently, the only selectable marker is gyrB r , a mutated form of the chromosomal gyrB gene that encodes the B subunit of DNA gyrase and confers resistance to the antibiotic coumermycin A 1 . The utility of the coumermycin-resistant gyrB r gene for targeted gene disruption is limited by a high frequency of recombination with the endogenous gyrB gene. A kanamycin resistance gene (kan) was introduced into B. burgdorferi, and its use as a selectable marker was explored in an effort to improve the genetic manipulation of this pathogen. B. burgdorferi transformants with the kan gene expressed from its native promoter were susceptible to kanamycin. In striking contrast, transformants with the kan gene expressed from either the B. burgdorferi flaB or flgB promoter were resistant to high levels of kanamycin. The kanamycin resistance marker allows efficient direct selection of mutants in B. burgdorferi and hence is a significant improvement in the ability to construct isogenic mutant strains in this pathogen.Borrelia burgdorferi, the spirochetal agent of Lyme disease (4), is maintained in nature by an infectious cycle involving tick vectors and small rodent hosts (13). The genome sequence of B. burgdorferi has provided a wealth of data about the genetic composition of this bacterium (7). However, relatively little is known about the function of most of the deduced proteins encoded by the genome. For example, 41% of the chromosomal open reading frames and 84% of plasmid open reading frames are either homologs to hypothetical proteins in other bacteria or have no match in databases (7). Although many B. burgdorferi gene products have been identified and characterized on the basis of antigenicity, abundance, membrane location, or pattern of synthesis, the functions of most of these proteins are unknown (5,12,20,31,32,36). As a consequence, relatively little is known about the molecular mechanisms mediating B. burgdorferi variation and adaptation and the roles of these processes in the infectious cycle.Identification of genes that encode virulence factors or participate in the transmission cycle of B. burgdorferi is hindered because this pathogen differs considerably from bacteria with well-developed genetic systems. These differences include an atypical outer membrane composition, unique genome structure with an undefined mechanism of replication, and complex, stringent in vitro growth requirements. One major factor that has impeded genetic studies in B. burgdorferi is the lack of an exogenous selectable marker. The only available selectable marker was derived by mutating the B. burgdorferi gene for the B subunit of DNA gyrase (gyrB), yielding a derivative gene (gyrB r ) whose product confers resistance to the antibiotic coumermycin A 1 (26). When the gyrB r gene is used for gene inactivation by allelic exchange or integration into the genome, the most common outcome (Ͼ99.5%) is recombination with the endogenous chr...
In this report we describe two distinct approaches to develop new antibiotic resistance cassettes that allow for efficient selection of Borrelia burgdorferi transformants. The first approach utilizes fusions of borrelial flagellar promoters to antibiotic resistance markers from other bacteria. The aacC1 gene, which encodes a gentamicin acetyltransferase, conferred a high level of gentamicin resistance in B. burgdorferi when expressed from these promoters. No cross-resistance occurred between this cassette and the kanamycin resistance cassette, which was previously developed in an analogous fashion. A second and different approach was taken to develop an efficient selectable marker that confers resistance to the antibiotic coumermycin A1. A synthetic gene was designed from the gyrB301 allele of the coumermycin-resistant B. burgdorferi strain B31-NGR by altering the coding sequence at the wobble position. The resulting gene, gyrBsyn, encodes a protein identical to the product of gyrB301, but the genes share only 66% nucleotide identity. The nucleotide sequence of gyrBsynis sufficiently divergent from the endogenous B. burgdorferigyrB gene to prevent recombination between them. The cassettes described in this paper improve our repertoire of genetic tools in B. burgdorferi. These studies also provide insight into parameters governing recombination and gene expression in B. burgdorferi.
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