Molecular characterization of a flagellar/chemotaxis operon in the spirochete Borrelia burgdorferi

A chemotaxis gene cluster from Borrelia burgdorferi, the spirochete that causes Lyme disease, was cloned, sequenced, and analyzed. This cluster contained three chemotaxis gene homologs (cheA, cheW and cheY) and an open reading frame we identified as cheX. Although the major functional domains for B. burgdorferi CheW and CheY were well conserved, the size of cheW was significantly different from the homolog of other bacteria. Phylogenetic analysis of CheY indicated that B. burgdorferi constitutes a distinct branch with Treponema pallidum and is closely associated with Archea and Gram-positive bacteria. RT-PCR analysis indicated that the chemotaxis genes and the upstream flagellar gene flaA constitute an operon. Western blot analysis using antibody to Escherichia coli CheA resulted in two reactive proteins in the cell lysates of B. burgdorferi that is consistent with two cheA homologs being present in this organism. The results taken together suggest both similarities and differences in the chemotaxis apparatus of B. burgdorferi compared to those of other bacteria.     

Sequence of a gene encoding a putative primary sigma factor from Borrelia burgdorferi strain B31

Utilizing a polymerase chain reaction-based approach, the gene (rpoD) encoding the primary sigma factor from Borrelia burgdorferi strain B31 was cloned and sequenced. Nucleotide sequence analysis revealed an open reading frame (ORF) of 1632 bp (543 amino acids (aa), 63.7 kDa). Comparison with Escherichia coli σ⁷⁰ and Bacillus subtilis σ⁴³ showed a high degree of similarity in the aa sequences, especially for the regions that are known to be required for promoter recognition and core binding.     

Inactivation of the fliY gene encoding a flagellar motor switch protein attenuates mobility and virulence of Leptospira interrogans strain Lai

Background  

Pathogenic Leptospira species cause leptospirosis, a zoonotic disease of global importance. The spirochete displays active rotative mobility which may contribute to invasion and diffusion of the pathogen in hosts. FliY is a flagellar motor switch protein that controls flagellar motor direction in other microbes, but its role in Leptospira, and paricularly in pathogenicity remains unknown.     

Mutational analysis of the flagellar protein FliG: sites of interaction with FliM and implications for organization of the switch complex

The switch complex at the base of the bacterial flagellum is essential for flagellar assembly, rotation, and switching. In Escherichia coli and Salmonella, the complex contains about 26 copies of FliG, 34 copies of FliM, and more then 100 copies of FliN, together forming the basal body C ring. FliG is involved most directly in motor rotation and is located in the upper (membrane-proximal) part of the C ring. A crystal structure of the middle and C-terminal parts of FliG shows two globular domains connected by an alpha-helix and a short extended segment. The middle domain of FliG has a conserved surface patch formed by the residues EHPQ(125-128) and R(160) (the EHPQR motif), and the C-terminal domain has a conserved surface hydrophobic patch. To examine the functional importance of these and other surface features of FliG, we made mutations in residues distributed over the protein surface and measured the effects on flagellar assembly and function. Mutations preventing flagellar assembly occurred mainly in the vicinity of the EHPQR motif and the hydrophobic patch. Mutations causing aberrant clockwise or counterclockwise motor bias occurred in these same regions and in the waist between the upper and lower parts of the C-terminal domain. Pull-down assays with glutathione S-transferase-FliM showed that FliG interacts with FliM through both the EHPQR motif and the hydrophobic patch. We propose a model for the organization of FliG and FliM subunits that accounts for the FliG-FliM interactions identified here and for the different copy numbers of FliG and FliM in the flagellum.     

A putative spermidine synthase interacts with flagellar switch protein FliM and regulates motility in Helicobacter pylori

The flagellar motor is an important virulence factor in infection by many bacterial pathogens. Motor function can be modulated by chemotactic proteins and recently appreciated proteins that are not part of the flagellar or chemotaxis systems. How these latter proteins affect flagellar activity is not fully understood. Here, we identified spermidine synthase SpeE as an interacting partner of switch protein FliM in Helicobacter pylori using pull‐down assay and mass spectrometry. To understand how SpeE contributes to flagellar motility, a speE‐null mutant was generated and its motility behavior was evaluated. We found that deletion of SpeE did not affect flagellar formation, but induced clockwise rotation bias. We further determined the crystal structure of the FliM‐SpeE complex at 2.7 Å resolution. SpeE dimer binds to FliM with micromolar binding affinity, and their interaction is mediated through the β1' and β2' region of FliM middle domain. The FliM‐SpeE binding interface partially overlaps with the FliM surface that interacts with FliG and is essential for proper flagellar rotational switching. By a combination of protein sequence conservation analysis and pull‐down assays using FliM and SpeE orthologues in E. coli, our data suggest that FliM‐SpeE association is unique to Helicobacter species.     

Analysis of a flagellar filament cap mutant reveals that HtrA serine protease degrades unfolded flagellin protein in the periplasm of Borrelia burgdorferi

Unlike external flagellated bacteria, spirochetes have periplasmic flagella (PF). Very little is known about how PF are assembled within the periplasm of spirochaetal cells. Herein, we report that FliD (BB0149), a flagellar cap protein (also named hook‐associated protein 2), controls flagellin stability and flagellar filament assembly in the Lyme disease spirochete Borrelia burgdorferi. Deletion of fliD leads to non‐motile mutant cells that are unable to assemble flagellar filaments and pentagon‐shaped caps (10 nm in diameter, 12 nm in length). Interestingly, FlaB, a major flagellin protein of B. burgdorferi, is degraded in the fliD mutant but not in other flagella‐deficient mutants (i.e., in the hook, rod, or MS‐ring). Biochemical and genetic studies reveal that HtrA, a serine protease of B. burgdorferi, controls FlaB turnover. Specifically, HtrA degrades unfolded but not polymerized FlaB, and deletion of htrA increases the level of FlaB in the fliD mutant. Collectively, we propose that the flagellar cap protein FliD promotes flagellin polymerization and filament growth in the periplasm. Deletion of fliD abolishes this process, which leads to leakage of unfolded FlaB proteins into the periplasm where they are degraded by HtrA, a protease that prevents accumulation of toxic products in the periplasm.     

Bioluminescent imaging of Borrelia burgdorferi in vivo demonstrates that the fibronectin-binding protein BBK32 is required for optimal infectivity

The aetiological agent of Lyme disease, Borrelia burgdorferi, is transmitted via infected Ixodes spp. ticks. Infection, if untreated, results in dissemination to multiple tissues and significant morbidity. Recent developments in bioluminescence technology allow in vivo imaging and quantification of pathogenic organisms during infection. Herein, luciferase-expressing B. burgdorferi and strains lacking the decorin adhesins DbpA and DbpB, as well as the fibronectin adhesin BBK32, were quantified by bioluminescent imaging to further evaluate their pathogenic potential in infected mice. Quantification of bacterial load was verified by quantitative PCR (qPCR) and cultivation. B. burgdorferi lacking DbpA and DbpB were only seen at the 1 h time point post infection, consistent with its low infectivity phenotype. The bbk32 mutant exhibited a significant decrease in its infectious load at day 7 relative to its parent. This effect was most pronounced at lower inocula and imaging correlated well with qPCR data. These data suggest that BBK32-mediated binding plays an important role in B. burgdorferi colonization. As such, in vivo imaging of bioluminescent Borrelia provides a sensitive means to detect, quantify and temporally characterize borrelial dissemination in a non-invasive, physiologically relevant environment and, more importantly, demonstrated a quantifiable infectivity defect for the bbk32 mutant.     

A plasmid-encoded nicotinamidase (PncA) is essential for infectivity of Borrelia burgdorferi in a mammalian host

Borrelia burgdorferi, a spirochaete that causes Lyme borreliosis, contains 21 linear and circular plasmids thought to be important for survival in mammals or ticks. Our results demonstrate that the gene BBE22 encoding a nicotinamidase is capable of replacing the requirement for the 25 kb linear plasmid lp25 during mammalian infection. Transformation of B. burgdorferi lacking lp25 with a shuttle vector containing the lp25 gene BBE22 (pBBE22) restored infectivity in mice to a level comparable to that of wild-type Borrelia. This complementation also restored the growth and host adaptation of lp25-B. burgdorferi in dialysis membrane chambers (DMCs) implanted in rats. A single Cys to Ala conversion at the putative active site of BBE22 abrogated the ability of pBBE22 to re-establish infectivity or growth in DMCs. Additional Salmonella typhimurium complementation studies and enzymatic analysis demonstrated that the BBE22 gene product has nicotinamidase activity and is most probably required for the biosynthesis of NAD. These results indicate that some plasmid-encoded products fulfil physiological functions required in the enzootic cycle of pathogenic Borrelia.     

Cloning and analysis of a Borrelia burgdorferi membrane-interactive protein exhibiting haemolytic activity

We cloned the gene encoding a membrane-interactive protein of Borrelia burgdorferi by means of its haemolytic activity in Escherichia coli . The haemolytic activity was erythrocyte-species specific, with progressively decreasing activity for erythrocytes from horse, sheep, and rabbit, respectively. Genetic analysis of the haemolytic determinant revealed two borrelia haemolysin genes, blyA and blyB , that are part of a predicted four-gene operon which is present in multiple copies on the 30 kb circular plasmid(s) of B. burgdorferi B31. blyA encodes a predicted α-helical 7.4 kDa protein with a hydrophobic central region and a positively charged C-terminus, which is structurally homologous to a large group of pore-forming toxins with cytolytic activity. blyB encodes a soluble protein which stabilized BlyA and enhanced haemolytic activity. While the majority of BlyA in E. coli was membrane-associated, only soluble protein was haemolytically active. The haemolytic activity was shown to be highly protease sensitive, heat labile, independent of divalent cations, and extremely dependent on protein concentration, consistent with a requirement for oligomerization as the mechanism of action. BlyA was highly purified from E. coli in a single step utilizing Triton X-114 phase partitioning. Genetic analysis of blyA and blyB mutants indicated that the stability, membrane association, and activity of BlyA was dependent on subtle changes in its sequence and on the BlyB protein. The bly genes were found to be expressed at a very low level in cultured B. burgdorferi .     

A quantitative model of the switch cycle of an archaeal flagellar motor and its sensory control

By reverse-engineering we have detected eight kinetic phases of the symmetric switch cycle of the Halobacterium salinarum flagellar motor assembly and identified those steps in the switch cycle that are controlled by sensory rhodopsins during phototaxis. Upon switching the rotational sense, the flagellar motor assembly passes through a stop state from which all subunits synchronously resume rotation in the reverse direction. The assembly then synchronously proceeds through three subsequent functional states of the switch: Refractory, Competent, and Active, from which the rotational sense is switched again. Sensory control of the symmetric switch cycle occurs at two steps in each rotational sense by inversely regulating the probabilities for a change from the Refractory to the Competent and from Competent to the Active rotational mode. We provide a mathematical model for flagellar motor switching and its sensory control, which is able to explain all tested experimental results on spontaneous and light-controlled motor switching, and give a mechanistic explanation based on synchronous conformational transitions of the subunits of the switch complex after reversible dissociation and binding of a response regulator (CheYP). We conclude that the kinetic mechanism of flagellar motor switching and its sensory control is fundamentally different in the archaeon H. salinarum and the bacterium Escherichia coli.     

Nucleotide sequence and characterization of a Bacillus subtilis gene encoding a flagellar switch protein.

The nucleotide sequence of the Bacillus subtilis fliM gene has been determined. This gene encodes a 38-kDa protein that is homologous to the FliM flagellar switch proteins of Escherichia coli and Salmonella typhimurium. Expression of this gene in Che+ cells of E. coli and B. subtilis interferes with normal chemotaxis. The nature of the chemotaxis defect is dependent upon the host used. In B. subtilis, overproduction of FliM generates mostly nonmotile cells. Those cells that are motile switch less frequently. Expression of B. subtilis FliM in E. coli also generates nonmotile cells. However, those cells that are motile have a tumble bias. The B. subtilis fliM gene cannot complement an E. coli fliM mutant. A frameshift mutation was constructed in the fliM gene, and the mutation was transferred onto the B. subtilis chromosome. The mutant has a Fla- phenotype. This phenotype is consistent with the hypothesis that the FliM protein encodes a component of the flagellar switch in B. subtilis. Additional characterization of the fliM mutant suggests that the hag and mot loci are not expressed. These loci are regulated by the SigD form of RNA polymerase. We also did not observe any methyl-accepting chemotaxis proteins in an in vivo methylation experiment. The expression of these proteins is also dependent upon SigD. It is possible that a functional basal body-hook complex may be required for the expression of SigD-regulated chemotaxis and motility genes.     

Torque generation in the flagellar motor of Escherichia coli: evidence of a direct role for FliG but not for FliM or FliN.

Among the many proteins needed for assembly and function of bacterial flagella, FliG, FliM, and FliN have attracted special attention because mutant phenotypes suggest that they are needed not only for flagellar assembly but also for torque generation and for controlling the direction of motor rotation. A role for these proteins in torque generation is suggested by the existence of mutations in each of them that produce the Mot- (or paralyzed) phenotype, in which flagella are assembled and appear normal but do not rotate. The presumption is that Mot- defects cause paralysis by specifically disrupting functions essential for torque generation, while preserving the features of a protein needed for flagellar assembly. Here, we present evidence that the reported mot mutations in fliM and fliN do not disrupt torque-generating functions specifically but, instead, affect the incorporation of proteins into the flagellum. The fliM and fliN mutants are immotile at normal expression levels but become motile when the mutant proteins and/or other, evidently interacting flagellar proteins are overexpressed. In contrast, many of the reported fliG mot mutations abolish motility at all expression levels, while permitting flagellar assembly, and thus appear to disrupt torque generation specifically. These mutations are clustered in a segment of about 100 residues at the carboxyl terminus of FliG. A slightly larger carboxyl-terminal segment of 126 residues accumulates in the cells when expressed alone and thus probably constitutes a stable, independently folded domain. We suggest that the carboxyl-terminal domain of FliG functions specifically in torque generation, forming the rotor portion of the site of energy transduction in the flagellar motor.     

Spirochetes flagellar collar protein FlbB has astounding effects in orientation of periplasmic flagella,bacterial shape,motility, and assembly of motors in Borrelia burgdorferi

Borrelia burgdorferi, the causative agent of Lyme disease, is a highly motile spirochete, and motility, which is provided by its periplasmic flagella, is critical for every part of the spirochete's enzootic life cycle. Unlike externally flagellated bacteria, spirochetes possess a unique periplasmic flagellar structure called the collar. This spirochete‐specific novel component is linked to the flagellar basal body; however, nothing is known about the proteins encoding the collar or their function in any spirochete. To identify a collar protein and determine its function, we employed a comprehensive strategy that included genetic, biochemical, and microscopic analyses. We found that BB0286 (FlbB) is a novel flagellar motor protein, which is located around the flagellar basal body. Deletion of bb0286 has a profound effect on collar formation, assembly of other flagellar structures, morphology, and motility of the spirochete. Orientation of the flagella toward the cell body is critical for determination of wild‐type spirochete's wave‐like morphology and motility. Here, we provide the first evidence that FlbB is a key determinant of normal orientation of the flagella and collar assembly.     

Expression and secretion of outer surface protein (OSP-A) of Borrelia burgdorferi from Escherichia coli

Abstract Outer surface protein A (OspA) is encoded by the ospA gene from Borrelia burgdorferi . This protein induces immunity against infection in mice. The cloning and expression of OspA in Escherichia coli have been previously described, but the secretion of OspA into culture media in E. coli has not yet been reported. In this report we demonstrate that a chimeric OspA protein was secreted into culture media by E. coli when it also harbors the hemolysin secretion genes hlyBD . The OspA fusion protein was also overexpressed from a T7 promoter and purified by immobilized metal ion chromatography. This was possible because the fusion protein contains ix histidyl residues in its N-terminus.     

BB0326 is responsible for the formation of periplasmic flagellar collar and assembly of the stator complex in Borrelia burgdorferi

Borrelia burgdorferi is a highly motile spirochete due to its periplasmic flagella. Unlike flagella of other bacteria, spirochetes' periplasmic flagella possess a complex structure called the collar, about which little is known in terms of function and composition. Using various approaches, we have identified a novel protein, BB0326, as a key component of the collar. We show that a peripheral portion of the collar is diminished in the Δbb0326 mutant and restored in the complemented bb0326+ cells, leading us to rename BB0326 as periplasmic flagellar collar protein A or FlcA. The ΔflcA mutant cells produced fewer, abnormally tilted and shorter flagella, as well as diminished stators, suggesting that FlcA is crucial for flagellar and stator assemblies. We provide further evidence that FlcA interacts with the stator and that this collar–stator interaction is essential for the high torque needed to power the spirochete's periplasmic flagellar motors. These observations suggest that the collar provides various important functions to the spirochete's periplasmic flagellar assembly and rotation.     

Acetyladenylate or its derivative acetylates the chemotaxis protein CheY in vitro and increases its activity at the flagellar switch.

CheY, a key protein in the mechanism of bacterial chemotaxis, is known to interact with the flagellar switch and thereby cause clockwise rotation. This activity of CheY was significantly increased by producing acetyladenylate (AcAMP) within cytoplasm-free bacterial envelopes containing purified CheY. This was achieved by including in the envelopes the enzyme acetyl-CoA synthetase (ACS) and ATP, and adding acetate externally. The fraction of clockwise-rotating envelopes, tethered to glass by their flagella, increased from 14% to 58% by the presence of AcAMP (or its derivative). In parallel experiments carried out with [14C]acetate under similar conditions, CheY became acetylated: [1-14C]acetate was as effective as [2-14C]acetate in labeling CheY, and ACS-dependent labeling of CheY by [alpha-32P]ATP was not detected. The switch proteins, FliG, FliM, and FliN, isolated to purity, were not acetylated. The acetylation was specific for CheY and dependent on its native conformation. The acetylated form the CheY was estimated to be more active than its nonacetylated form by 4-5 orders of magnitude. Acetylated CheY was stable in the presence of the strong nucleophiles hydroxylamine or ethanolamine, indicative of N-acetylation. There was a correlation between the activity of CheY in vivo and its ability to be acetylated in vitro. Thus, proteins with a single substitution at their active site, CheY57DE and CheY109KR, are not active in vivo and accordingly were not acetylated in vitro; in contrast, the protein CheY13DK is active in vivo and was normally acetylated in vitro. The possibility that CheY acetylation plays a role in bacterial chemotaxis is discussed.     

Specificity and role of the Borrelia burgdorferi CtpA protease in outer membrane protein processing

To further characterize the function of the Borrelia burgdorferi C-terminal protease CtpA, we used site-directed mutagenesis to alter the putative CtpA cleavage site of one of its known substrates, the outer membrane (OM) porin P13. These mutations resulted in only partial blockage of P13 processing. Ectopic expression of a C-terminally truncated P13 in B. burgdorferi indicated that the C-terminal peptide functions as a safeguard against misfolding or mislocalization prior to its proteolytic removal by CtpA. In a parallel study of Borrelia burgdorferi lipoprotein sorting mechanisms, we observed a lower-molecular-weight variant of surface lipoprotein OspC that was particularly prominent with OspC mutants that mislocalized to the periplasm or contained C-terminal epitope tags. Further investigation revealed that the variant resulted from C-terminal proteolysis by CtpA. Together, these findings indicate that CtpA rather promiscuously targets polypeptides that lack structurally constrained C termini, as proteolysis appears to occur independently of a specific peptide recognition sequence. Low-level processing of surface lipoproteins such as OspC suggests the presence of a CtpA-dependent quality control mechanism that may sense proper translocation of integral outer membrane proteins and surface lipoproteins by detecting the release of C-terminal peptides.