Identical phosphatase mechanisms achieved through distinct modes of binding phosphoprotein substrate.

Two-component signal transduction systems are widespread in prokaryotes and control numerous cellular processes. Extensive investigation of sensor kinase and response regulator proteins from many two-component systems has established conserved sequence, structural, and mechanistic features within each family. In contrast, the phosphatases which catalyze hydrolysis of the response regulator phosphoryl group to terminate signal transduction are poorly understood. Here we present structural and functional characterization of a representative of the CheC/CheX/FliY phosphatase family. The X-ray crystal structure of Borrelia burgdorferi CheX complexed with its CheY3 substrate and the phosphoryl analogue reveals a binding orientation between a response regulator and an auxiliary protein different from that shared by every previously characterized example. The surface of CheY3 containing the phosphoryl group interacts directly with a long helix of CheX which bears the conserved (E - X(2) - N) motif. Conserved CheX residues Glu96 and Asn99, separated by a single helical turn, insert into the CheY3 active site. Structural and functional data indicate that CheX Asn99 and CheY3 Thr81 orient a water molecule for hydrolytic attack. The catalytic residues of the CheX.CheY3 complex are virtually superimposable on those of the Escherichia coli CheZ phosphatase complexed with CheY, even though the active site helices of CheX and CheZ are oriented nearly perpendicular to one other. Thus, evolution has found two structural solutions to achieve the same catalytic mechanism through different helical spacing and side chain lengths of the conserved acid/amide residues in CheX and CheZ.

Effect of glucose on Treponema denticola cell behavior.

INTRODUCTION: Treponema denticola inhabits the oral subgingival environment and is part of a proteolytic benzoyl-dl-arginine-naphthylamide-positive 'red complex' associated with active periodontal disease. Spirochetes have a unique form of chemotactic motility that may contribute to their virulence. Chemotaxis is essential for efficient nutrient-directed translocation. METHODS: We examined the effect of glucose on T. denticola cell velocity, expression of periplasmic flagella proteins, and chemotaxis, e.g. translocation into capillary tubes. RESULTS: The presence of glucose did not significantly effect T. denticola cell velocity in high viscosity conditions nor did it alter periplasmic flagella protein expression. The addition of glucose to capillary tubes resulted in greater numbers of T. denticola cells in tubes containing glucose. A non-motile mutant did not migrate into capillary tubes containing glucose. CONCLUSION: These results are consistent with a chemotactic response to glucose that is motility dependent.

Complementation of a nonmotile flaB mutant of Borrelia burgdorferi by chromosomal integration of a plasmid containing a wild-type flaB allele.

With the recent identification of antibiotic resistance phenotypes, the use of reporter genes, the isolation of null mutants by insertional inactivation, and the development of extrachromosomal cloning vectors, genetic analysis of Borrelia burgdorferi is becoming a reality. A previously described nonmotile, rod-shaped, kanamycin-resistant B. burgdorferi flaB::Km null mutant was complemented by electroporation with the erythromycin resistance plasmid pED3 (a pGK12 derivative) containing the wild-type flaB sequence and 366 bp upstream from its initiation codon. The resulting MS17 clone possessed erythromycin and kanamycin resistance, flat-wave morphology, and microscopic and macroscopic motility. Several other electroporations with plasmids containing wild-type flaB and various lengths (198, 366, or 762 bp) of sequence upstream from the flaB gene starting codon did not lead to functional restoration of the nonmotile flaB null mutant. DNA hybridization, PCR analysis, and sequencing indicated that the wild-type flaB gene in nonmotile clones was present in the introduced extrachromosomal plasmids, while the motile MS17 clone was a merodiploid containing single tandem chromosomal copies of mutated flaB::Km and wild-type flaB with a 366-bp sequence upstream from its starting codon. Complementation was thus achieved only when wild-type flaB was inserted into the borrelial chromosome. Several possible mechanisms for the failure of complementation for extrachromosomally located flaB are discussed.

First evidence for a restriction-modification system in Leptospira sp.

The LE1 leptophage exhibited a host range restricted to the saprophytic Leptospira biflexa [Saint Girons et al., Res. Microbiol. 141 (1990) 1131-1133] and mainly to the Patoc 1 strain (hereafter called PFRA) kept in the Paris, France collection. Results of titration of LE1 lysates indicated the presence of a host-controlled modification and restriction system within PUSA (Patoc 1 strain maintained in the Morgantown, WV, USA collection) that was absent in PFRA. Because genomic DNA of PITAL (Patoc 1 strain maintained in Trieste, Italy) appeared smeared in pulsed field gel electrophoresis (PFGE), this strain is likely to contain nucleases that are activated upon DNA isolation. Moreover, comparative NotI digestions of PUSA and PFRA DNAs, as visualized by PFGE, indicated that PUSA belonged to a different serovar than PFRA. Finally, 16S ribosomal sequence analysis indicated that PUSA belonged to the saprophytic Leptospira meyeri species, while PITAL and PFRA appertained to L. biflexa. The evolutionary significance and the importance of the restriction and modification enzymes or non-specific nucleases within strains for genetic experiments are discussed.

The spirochete FlaA periplasmic flagellar sheath protein impacts flagellar helicity.

Spirochete periplasmic flagella (PFs), including those from Brachyspira (Serpulina), Spirochaeta, Treponema, and Leptospira spp., have a unique structure. In most spirochete species, the periplasmic flagellar filaments consist of a core of at least three proteins (FlaB1, FlaB2, and FlaB3) and a sheath protein (FlaA). Each of these proteins is encoded by a separate gene. Using Brachyspira hyodysenteriae as a model system for analyzing PF function by allelic exchange mutagenesis, we analyzed purified PFs from previously constructed flaA::cat, flaA::kan, and flaB1::kan mutants and newly constructed flaB2::cat and flaB3::cat mutants. We investigated whether any of these mutants had a loss of motility and altered PF structure. As formerly found with flaA::cat, flaA::kan, and flaB1::kan mutants, flaB2::cat and flaB3::cat mutants were still motile, but all were less motile than the wild-type strain, using a swarm-plate assay. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blot analysis indicated that each mutation resulted in the specific loss of the cognate gene product in the assembled purified PFs. Consistent with these results, Northern blot analysis indicated that each flagellar filament gene was monocistronic. In contrast to previous results that analyzed PFs attached to disrupted cells, purified PFs from a flaA::cat mutant were significantly thinner (19.6 nm) than those of the wild-type strain and flaB1::kan, flaB2::cat, and flaB3::cat mutants (24 to 25 nm). These results provide supportive genetic evidence that FlaA forms a sheath around the FlaB core. Using high-magnification dark-field microscopy, we also found that flaA::cat and flaA::kan mutants produced PFs with a smaller helix pitch and helix diameter compared to the wild-type strain and flaB mutants. These results indicate that the interaction of FlaA with the FlaB core impacts periplasmic flagellar helical morphology.

Spirochete periplasmic flagella and motility.

Spirochetes have a unique structure, and as a result their motility is different from that of other bacteria. They also have a special attribute: spirochetes can swim in a highly viscous, gel-like medium, such as that found in connective tissue, that inhibits the motility of most other bacteria. In spirochetes, the organelles for motility, the periplasmic flagella, reside inside the cell within the periplasmic space. A given periplasmic flagellum is attached only at one end of the cell, and depending on the species, may or may not overlap in the center of the cell with those attached at the other end. The number of periplasmic flagella varies from species to species. These structures have been shown to be directly involved in spirochete motility, and they function by rotating within the periplasmic space. The mechanics of motility also vary among the spirochetes. In Leptospira, a motility model developed several years ago has been extensively tested, and the evidence supporting this model is convincing. Borrelia burgdorferi swims differently, and a model of its motility has been recently put forward. This model is based on analyzing the motion of swimming cells, high voltage electron microscopy of fixed cells, and mutant analysis. To better understand spirochete motility on a more molecular level, the proteins and genes involved in motility are being analyzed. Spirochete periplasmic flagellar filaments are among the most complex of bacterial flagella. They are composed of the FlaA sheath proteins, and in many species, multiple FlaB core proteins. Allelic exchange mutagenesis of the genes which encode these proteins is beginning to yield important information with respect to periplasmic flagellar structure and function. Although we are at an early stage with respect to analyzing the function, organization, and regulation of many of the genes involved in spirochete motility, unique aspects have already become evident. Future studies on spirochete motility should be exciting, as only recently have complete genome sequences and tools for allelic exchange mutagenesis become available.

Borrelia burgdorferi periplasmic flagella have both skeletal and motility functions.

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 rod-shaped cell cylinder to enable the cell to swim, and to confer in part its flat-wave morphology.

Effect of temperature and viscosity on the motility of the spirochete Treponema denticola.

Treponema denticola is an oral spirochete associated with periodontal diseases. Because bacterial motility is likely to be a potential virulence factor, we investigated the effect of viscosity and temperature on cell speed. In agreement with the work of others, translational motility was a function of the macroscopic viscosity of the medium. In addition, we found that although the speed of spirochetes was slow at 25 degrees C (4 microns s-1), it increased quite markedly at 35 degrees C (19 microns s-1). The results indicate that both viscosity and temperature are critical factors in T. denticola translational motility.

Structure and expression of the FlaA periplasmic flagellar protein of Borrelia burgdorferi.

The spirochete which causes Lyme disease, Borrelia burgdorferi, has many features common to other spirochete species. Outermost is a membrane sheath, and within this sheath are the cell cylinder and periplasmic flagella (PFs). The PFs are subterminally attached to the cell cylinder and overlap in the center of the cell. Most descriptions of the B. burgdorferi flagellar filaments indicate that these organelles consist of only one flagellin protein (FlaB). In contrast, the PFs from other spirochete species are comprised of an outer layer of FlaA and a core of FlaB. We recently found that a flaA homolog was expressed in B. burgdorferi and that it mapped in a fla/che operon. These results led us to analyze the PFs and FlaA of B. burgdorferi in detail. Using Triton X-100 to remove the outer membrane and isolate the PFs, we found that the 38.0-kDa FlaA protein purified with the PFs in association with the 41.0-kDa FlaB protein. On the other hand, purifying the PFs by using Sarkosyl resulted in no FlaA in the isolated PFs. Sarkosyl has been used by others to purify B. burgdorferi PFs, and our results explain in part their failure to find FlaA. Unlike other spirochetes, B. burgdorferi FlaA was expressed at a lower level than FlaB. In characterizing FlaA, we found that it was posttranslationally modified by glycosylation, and thus it resembles its counterpart from Serpulina hyodysenteriae. We also tested if FlaA was synthesized in a spontaneously occurring PF mutant of B. burgdorferi (HB19Fla-). Although this mutant still synthesized flaA message in amounts similar to the wild-type amounts, it failed to synthesize FlaA protein. These results suggest that, in agreement with data found for FlaB and other spirochete flagellar proteins, FlaA is likely to be regulated on the translational level. Western blot analysis using Treponema pallidum anti-FlaA serum indicated that FlaA was antigenically well conserved in several spirochete species. Taken together, the results indicate that both FlaA and FlaB comprise the PFs of B. burgdorferi and that they are regulated differently from flagellin proteins of other bacteria.

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.

FlaA, a putative flagellar outer sheath protein, is not an immunodominant antigen associated with Lyme disease.

FlaA was recently found to be associated with flagellar filaments of Borrelia burgdorferi. We tested whether antibodies to this protein are a good indicator of infection, as antibodies to FlaA proteins in other spirochetal infections show an increase in titer. Although overproduction of intact FlaA was highly toxic to Escherichia coli, truncated proteins which lacked the N-terminal signal sequence could be successfully overexpressed. Immunoblotting with sera from mammalian hosts infected with B. burgdorferi indicated that FlaA is not an immunodominant antigen in Lyme disease. However, sera from two patients reacted with both recombinant and native FlaA protein, suggesting that B. burgdorferi FlaA was antigenic and expressed in vivo.

Identification of a large motility operon in Borrelia burgdorferi by semi-random PCR chromosome walking.

Motility has been implicated in the invasive process of Borrelia burgdorferi (Bb), the etiologic agent of Lyme disease. To identify Bb motility related genes, we used a method termed 'semi-random PCR chromosome walking' (SRPCW) to walk through a large motility gene cluster. The major advantage of this approach over other PCR walking methods is that it employs a secondary PCR amplification of cloned fragments which can be readily sequenced and analyzed. Starting with a primer specific to flgE, we identified and sequenced 14 open reading frames (ORFs) spanning 11 kb downstream of the flgE gene. The genes identified include flbD, motA, motB, fliL, fliM, fliN, fliZ, fliP, fliQ, fliR, flhB, flhA, flhF and flbE. Twelve of the deduced proteins shared extensive homology with flagellar proteins from other bacteria. The gene products and order of genes within this cluster are most similar to those of Treponema pallidum (Tp) and Bacillus subtilis (Bs). One of the unique genes identified, flbD, demonstrated homology to an ORF from the same operon of Tp. Another ORF, flbE, showed similarity to genes from both Tp and Bs. RT-PCR and primer extension analysis revealed that this gene cluster is transcribed as a single unit indicating that it is part of a large motility operon spanning more than 21 kb. Antisera to Escherichia coli and Salmonella typhimurium FliN, FliM, FlhB and FlhA reacted with proteins of the predicted molecular weights in cell lysates of Bb. The results suggest that the flagellar system is highly conserved in evolution and thus underscore the importance of motility in bacterial survival and pathogenesis.

Molecular characterization of a large Borrelia burgdorferi motility operon which is initiated by a consensus sigma70 promoter.

A large motility operon, referred to as the flgB operon, was identified, characterized, and mapped at 310 to 320 kb on the linear chromosome of the spirochete Borrelia burgdorferi. This is the first report that a sigma70-like promoter rather than a sigma28-like promoter is involved in the transcription of a major motility operon in bacteria. From these results in conjunction with results from a previous study (Y. Ge and N. W. Charon, Gene, in press), we have identified 26 genes in this operon that are relevant to motility and flagellar synthesis. With few exceptions, the gene order and deduced gene products were most similar to those of other spirochetes and Bacillus subtilis. Primer extension analysis indicated that transcription initiated from a conserved sigma70-like promoter immediately upstream of flgB; this promoter mapped within the heat-shock-induced protease gene hslU. Reverse transcriptase PCR analysis indicated that a single transcript of 21 kb initiated at this promoter and extended through flgE and (with our previous results) onto the putative motility gene flbE. The flgB promoter element had strong activity in both Escherichia coli and Salmonella typhimurium. As expected, a mutant of S. typhimurium with an inactivated flagellum-specific sigma28 factor did not affect the function of this promoter. Western blot analysis indicated that B. burgdorferi recombinant FliG and FliI were antigenically similar to those of E. coli and other spirochetes. Although complementation of E. coli or S. typhimurium fliG or fliI mutants with the B. burgdorferi genes was unsuccessful, B. burgdorferi recombinant FliI completely inhibited flagellar synthesis and motility of wild-type E. coli and S. typhimurium. These results show that spirochete motility genes can influence flagellar synthesis in other species of bacteria. Finally, Western blot analysis with sera from infected humans and animals indicated a weak or nondetectable response to recombinant FliG and FliI. These results indicate that these antigens are not favorable candidate reagents to be used in the diagnosis of Lyme disease.

Relationship of Treponema denticola periplasmic flagella to irregular cell morphology.

Treponema denticola is an anaerobic, motile, oral spirochete associated with periodontal disease. We found that the periplasmic flagella (PFs), which are located between the outer membrane sheath and cell cylinder, influence its morphology in a unique manner. In addition, the protein composition of the PFs was found to be quite complex and similar to those of other spirochetes. Dark-field microscopy revealed that most wild-type cells had an irregular twisted morphology, with both planar and helical regions, and a minority of cells had a regular right-handed helical shape. High-voltage electron microscopy indicated that the PFs, especially in those regions of the cell which were planar, wrapped around the cell body axis in a right-handed sense. In those regions of the cell which were helical or irregular, the PFs tended to lie along the cell axis. The PFs caused the cell to form the irregular shape, as two nonmotile, PF-deficient mutants (JR1 and HL51) were no longer irregular but were right-handed helices. JR1 was isolated as a spontaneously occurring nonmotile mutant, and HL51 was isolated as a site-directed mutant in the flagellar hook gene flgE. Consistent with these results is the finding that wild-type cells with their outer membrane sheath removed were also right-handed helices similar in shape to JR1 and HL51. Purified PFs were analyzed by two-dimensional gel electrophoresis, and several protein species were identified. Western blot analysis using antisera to Treponema pallidum PF proteins along with N-terminal amino acid sequence analysis indicated T. denticola PFs are composed of one class A sheath protein of 38 kDa (FlaA) and three class B proteins of 35 kDa (FlaB1 and FlaB2) and one of 34 kDa (FlaB3). The N-terminal amino acid sequences of the FlaA and FlaB proteins of T. denticola were most similar to those of T. pallidum and Treponema phagedenis. Because these proteins were present in markedly reduced amounts or were absent in HL51, PF synthesis is likely to be regulated in a hierarchy similar to that found for flagellar. synthesis in other bacteria.

An unexpected flaA homolog is present and expressed in Borrelia burgdorferi.

Most investigators have assumed that the periplasmic flagella (PFs) of Borrelia burgdorferi are composed of only one flagellin protein. The PFs of most other spirochete species are complex: these PFs contain an outer sheath of FlaA proteins and a core filament of FlaB proteins. During an analysis of a chemotaxis gene cluster of B. burgdorferi 212, we were surprised to find a flaA gene homolog with a deduced polypeptide having 54 to 58% similarity to FlaA from other spirochetes. Like other FlaA proteins, B. burgdorferi FlaA has a conserved signal sequence at its N terminus. Based on reverse transcription-PCR and primer extension analysis, this flaA homolog and five chemotaxis genes constitute a motility-chemotaxis operon. Immunoblots using anti-FlaA serum from Treponema pallidum and a lysate of B. burgdorferi showed strong reactivity to a protein of 38.0 kDa, which is consistent with the expression of flaA in growing cells.

Structural analysis of the Leptospiraceae and Borrelia burgdorferi by high-voltage electron microscopy.

Spirochetes are an evolutionary and structurally unique group of bacteria. Outermost is a membrane sheath (OS), and within this sheath are the protoplasmic cell cylinder (PC) and periplasmic flagella (PFs). The PFs are attached at each end of the PC and, depending on the species, may or may not overlap in the center of the cell. The precise location of the PFs within the spirochetal cells is unknown. The PFs could lie along the cell axis. Alternatively, the PFs could wrap around the PC in either a right- or a left-handed sense. To understand the factors that cause the PFs to influence cell shape and allow the cells to swim, we determined the precise location of the PFs in the Leptospiraceae (Leptonema illini) and Borrelia burgdorferi. Our approach was to use high-voltage electron microscopy and analyze the three-dimensional images obtained from thick sections of embedded cells. We found that a single PF in L. illini is located in a central channel 29 nm in diameter running along the helix axis of the right-handed PC. The presence of the PFs is associated with the end being hook shaped. The results obtained agree with the current model of Leptospiraceae motility. In B. burgdorferi, which forms a flattened wave, the relationship between the PFs and the PC is more complicated. A multistrand ridge 67 nm in diameter, which was shown to be composed of PFs by cross-sectional and mutant analysis, was found to extend along the entire length of the cell. We found that the PFs wrapped around the PC in a right-handed sense. However, the PFs formed a left-handed helix in space. The wavelength of the cell body and the helix pitch of the PFs were found to be identical (2.83 microm). The results obtained were used to propose a model of B. burgdorferi motility whereby backward-propagating waves, which gyrate counterclockwise as viewed from the back of the cell, are generated by the counterclockwise rotation of the internal PFs. Concomitant with this motion, the cell is believed to rotate clockwise about the body axis as shown for the Leptospiraceae.

FliH and fliI of Borrelia burgdorferi are similar to flagellar and virulence factor export proteins of other bacteria.

Two motility genes (fliH and fliI) of the Lyme disease spirochete Borrelia burgdorferi were cloned, physically mapped and sequenced, FliH and FliI showed extensive homology to the proteins involved in the export of flagellar components and to virulence factors found in both animal and plant bacterial pathogens. The results suggest that the flagellar apparatus and associated protein export pathway are well conserved in evolution.

Borrelia burgdorferi swims with a planar waveform similar to that of eukaryotic flagella.

Borrelia burgdorferi is a motile spirochete with multiple internal periplasmic flagella (PFs) attached near each end of the cell cylinder; these PFs overlap in the cell center. We analyzed the shape and motion of wild type and PF-deficient mutants using both photomicrography and video microscopy. We found that swimming cells resembled the dynamic movements of eukaryotic flagella. In contrast to helically shaped spirochetes, which propagate spiral waves, translating B. burgdorferi swam with a planar waveform with occasional axial twists; waves had a peak-to-peak amplitude of 0.85 micron and a wavelength of 3.19 microns. Planar waves began full-sized at the anterior end and propagated toward the back end of the cell. Concomitantly, these waves gyrated counter-clockwise as viewed from the posterior end along the cell axis. In nontranslating cells, wave propagation ceased. Either the waveform of nontranslating cells resembled the translating form, or the cells became markedly contorted. Cells of the PF-deficient mutant isolated by Sadziene et al. [Sadziene, A., Thomas, D. D., Bundoc, V. G., Holt, S. C. & Barbour, A. G. (1991) J. Clin. Invest. 88, 82-92] were found to be relatively straight. The results suggest that the shape of B. burgdorferi is dictated by interactions between the cell body and the PFs. In addition, the PFs from opposite ends of the cell are believed to interact with one another so that during the markedly distorted nontranslational form, the PFs from opposite ends rotate in opposing directions around one another, causing the cell to bend.

Molecular genetic analysis of a class B periplasmic-flagellum gene of Treponema phagedenis.

Treponema phagedenis is a host-associated spirochete with multiple polypeptides making up its periplasmic flagella (PFs). Each PF has a 39-kDa polypeptide making up the sheath (class A PF polypeptide) and two to four antigenically similar 33- to 34-kDa polypeptide species making up the core (class B PF polypeptides). A genetic analysis of the PF-deficient mutants T-40 and T-55 has shown that the PFs are involved in motility. To better understand the synthesis and assembly of these complex organelles and to compare the PF genes with those of other spirochetes, we cloned and characterized the T. phagedenis flaB2 gene, which encodes one class B polypeptide. The flaB2 gene consists of an open reading frame of 858 nucleotides capable of encoding a protein of 31.5 kDa. The predicted amino acid sequence of the FlaB2 polypeptide was 92% identical to that of T. pallidum FlaB2, with a 76% identity at the nucleotide level. These results confirm previous immunological and N-terminal-sequence analyses which suggested that the PF genes are well conserved in the spirochetes. Primer extension analysis of T. phagedenis flaB2 indicated that the start site of transcription was 127 nucleotides upstream from the ATG initiation codon. Preceding the start site is a DNA sequence similar to the sigma 28 consensus promoter sequence commonly found associated with motility genes. Northern (RNA) blots probed with a segment of flaB2 DNA revealed a 1,000-nucleotide monocistronic transcript in the wild type and in PF-deficient mutants T-40 and T-55. DNA sequencing of most of the flaB2 gene of the mutants revealed no differences from the wild-type gene. Because the mutants fail to synthesize detectable class B PF polypeptides yet synthesize extensive amounts of flaB2 mRNA, PF synthesis in T. phagedenis is likely to involve regulation at the translational level.

Spirochete chemotaxis, motility, and the structure of the spirochetal periplasmic flagella.

Spirochetes have a unique motility system that is characterized by flagellar filaments contained within the outer membrane sheath. Direct evidence using video microscopy has recently been obtained which indicates that these periplasmic flagella (PF) rotate in several spirochetal species. This rotation generates thrust. As shown for one spirochete, Spirochaeta aurantia, motility is driven by a proton motive force. Spirochete chemotaxis has been most thoroughly studied in S. aurantia. This spirochete exhibits three distinct behaviours, runs of smooth swimming, reversals and flexing. These behaviours are modulated by addition of attractants such that S. aurantia swims towards higher concentrations of attractants in a spatial gradient. Unlike the prototypical bacterium, Escherichia coli, chemotaxis in S. aurantia involves fluctuations in membrane potential. The PF of a number of spirochetes have been examined in considerable detail. For most species, the PF filaments are complex, consisting of an assembly of several different polypeptides. There are several antigenically related core polypeptides surrounded by an outer layer consisting of a different polypeptide. Borrelia burgdorferi and Spirochaeta zuelzerae represent exceptions where the filaments are composed of a single major polypeptide species. The genes encoding the filament polypeptides from several spirochete species have been cloned and analysed. Apparently, the outer layer polypeptides of S. aurantia, Treponema pallidum and Serpulina hyodysenteriae are transcribed from sigma-70-like promoters, whereas the core polypeptide genes are transcribed from sigma-28-like promoters. A gene encoding the hook polypeptide in Treponema phagedenis has been cloned and analysed. The product of this gene shows significant similarity to the E. coli hook protein, FlgE, and homologs have been identified in T. pallidum and B. burgdorferi.(ABSTRACT TRUNCATED AT 250 WORDS)