Hook-length control of the export-switching machinery involves a double-locked gate in Salmonella typhimurium flagellar morphogenesis

During flagellar morphogenesis in Salmonella typhimurium, the genes involved in filament assembly are expressed fully only after completion of hook-basal body assembly. This coupling of gene expression to morphogenesis is achieved by exporting the flagellum-specific anti-sigma factor, FlgM, out of the cell through the mature hook-basal body structure. Therefore, the flagellum-specific export apparatus must be able to sense the assembly state of the flagellar structure and to turn on FlgM export at a specific stage of hook assembly. It has been suggested that FlhB may act as the molecular switch which mediates this ordered export. Here, I report genetic evidence that in addition to FlhB, the product of a newly identified gene, rflH, is involved in the negative regulation of FlgM export. FlgM is released through the basal body structure lacking the hook and the filament only when the flhB and rflH genes are both defective. Therefore, the export gate for FlgM should be double locked by FlhB and RflH. The rflH gene is located at around 52 min, where no flagellum-related gene has been found. I propose a revised model of the export-switching machinery which consists of two systems, the hook-length signal transduction pathway and the double-locked gate for FlgM export.     

Flagellin, a major protein present in SDS-PAGE profiles of Sarkosyl-OMP-enriched fractions from Bordetella bronchiseptica Bvg- or modulated Bvg+ strains

The bvg or vir locus positively regulates the expression of many Bordetella virulence-associated determinants (encoded by vag genes), including cell envelope proteins, in response to environmental stimuli. On the other hand, several genes named vrg genes are negatively controlled by the bvg regulon (Knapp and Mekalanos, 1988). Flagellin is encoded by a vrg gene, which is expressed when the principal virulence factors are eliminated during antigenic modulation or in phase variants (Akerley et al., 1992). We have previously analyzed SDS-PAGE profiles of Sarkosyl-outer membrane protein (OMP)-enriched fractions from B. bronchiseptica Bvg- and modulated Bvg+ strains and reported a major band associated with the avirulent phenotype (Passerini de Rossi et al., 1995). In order to characterize this band we have purified flagellar filaments from Bvg- and modulated Bvg+ strains, and analyzed them by SDS-PAGE. These profiles revealed a single major band of 40 or 45 kDa depending on the strain. The N-terminal amino acid sequence of the putative flagellin expressed by BB7200a was identical over the first 21 residues analyzed to that of the flagellin from the modulated strain BB7865 reported by Akerley et al. (1992). Comparison of the SDS-PAGE profile of flagellar filaments with that of the OMP-enriched fraction of the corresponding strain showed that the flagellum-associated polypeptide had the same electrophoretic mobility as that of the characteristic band of the avirulent phenotype. Furthermore, this band was absent in the OMP-enriched fraction profile from a Bvg- strain subjected to a treatment that removes flagella. Our results indicate that the major protein observed in SDS-PAGE profiles of Sarkosyl-OMP-enriched fractions from B. bronchiseptica Bvg- and modulated Bvg+ strains corresponds to flagellin.     

Role of the outermost subdomain of Salmonella flagellin in the filament structure revealed by electron cryomicroscopy

A mutant strain of Salmonella typhimurium, SJW46, has flagellar filaments supercoiled in the same form as the wild-type strain, SJW1103, and swims normally. However, its flagellar filaments are mechanically unstable and show anomalous behaviors of polymorphism. Flagellin from SJW46 has a large central deletion from Ala204 to Lys292 of SJW1103 flagellin, which has been thought to be located in the outer surface of the filament. Since the filament structure is determined by intersubunit interactions of the terminal regions in the densely packed core of the filament, no serious involvement of the deleted portion was expected in the filament stability and polymorphism. In order to locate the deleted portion and to understand the underlying mechanism of these anomalous characteristics, we carried out structure analysis of the L-type straight filament reconstituted from a mutant flagellin of SJW46 (SJW46S) and compared the structure with that of the SJW1660 filament, which is also the L-type but composed of flagellin with no deletion. The deleted portion was identified as the outermost subdomain, and the structure in the core region showed no appreciable differences. The structure revealed the previously identified folding of flagellin in further detail, and the significance of intersubunit interactions between outer domains, which are present in the SJW1660 filament but absent in the SJW46 filament. This suggests that these contacts have a significant contribution to the filament stability and polymorphic behavior, despite the fact that the contacting surface area occupies only a minor portion of the whole intersubunit interactions.     

A new class of Caulobacter crescentus flagellar genes

Eight Caulobacter crescentus flagellar genes, flmA, flmB, flmC, flmD, flmE, flmF, flmG, and flmH, have been cloned and characterized. These eight genes are clustered in pairs (flmAB, flmCD, flmEF, and flmGH) that appear to be structurally organized as operons. Homology comparisons suggest that the proteins encoded by the flm genes may be involved in posttranslational modification of flagellins or proteins that interact with flagellin monomers prior to their assembly into a flagellar filament. Expression of the flmAB, flmEF, and flmGH operons was shown to occur primarily in predivisional cells. In contrast, the flmCD operon was expressed throughout the cell cycle, with only a twofold increase in predivisional cells. The expression of the three temporally regulated operons was subject to positive regulation by the CtrA response regulator protein. Mutations in class II and III flagellar genes had no significant effect on the expression of the flm genes. Furthermore, the flm genes did not affect the expression of class II or class III flagellar genes. However, mutations in the flm genes did result in reduced synthesis of the class IV flagellin proteins. Taken together, these data indicate that the flm operons belong to a new class of flagellar genes.     

Effects of some chemical factors on flagellation and swarming of Vibrio alginolyticus

Vibrio alginolyticus strains recently isolated from Dutch coastal seawater changed flagellar organization when cultivated in the presence of certain chemical agents. On agar media with more than 4.0% (w/v) NaCl the number of lateral flagella per cell decreased with increasing salt concentration. Both on agar media and in broth cultures with 6.0-9.0% (w/v) NaCl, cells with polar tufts of 2-4 sheathed or unsheathed flagella were frequently found. Cells grown on agar media with 7.3-9.8% (w/v) Na2SO4 had drastically reduced numbers of lateral flagella, but lacked polar tufts. EDTA suppressed growth, but did not affect flagellar arrangement. In the presence of 0.1-0.3% boric acid or 0.05-0.1% aluminum hydroxide, cells in liquid media tended to produce lateral, in addition to the polar flagella normally observed in broth cultures. Of a number of surface-active agents tested, Tween 80 and Na-taurocholate, even in high concentrations, did not affect flagellation. Bile salts (0.1%) and Na deoxycholate (0.05%) strongly reduced the number of both polar and lateral flagella. In agar cultures, Na-lauryl sulphate (0.01-0.1%) inhibited the formation of lateral, but increased the incidence of polar flagella. Teepol (0.05-0.2%) had a similar effect and also it had a deteriorating effect on the sheaths of the polar flagella. Concomitant with the reduction in the number of lateral flagella, induced by these agents, swarming on agar media was inhibited.     

Quasi- and nonequivalence in the structure of bacterial flagellar filament

In supercoiled forms of flagellar filaments, which are thought to be produced by combinations of two distinct subunit lattices, the lattices are elastically deformed in 11 different ways, depending on their azimuthal positions on the circumference of a tube with 11 protofilaments. Those two interactions are nonequivalent as opposed to quasiequivalent ones in elastically deformed lattices of otherwise identical interactions. The term nonequivalence is defined to represent different bonding interactions, and quasiequivalent is used to describe deformed but conserved bonding interactions. By using two distinct lattices that were accurately determined by x-ray fiber diffraction, 10 possible supercoiled forms of flagellar filaments were simulated, based on a bistable-subunit packing model. Comparison to the observed forms showed good agreement, indicating that the model and determined lattice parameters effectively represent realistic features of the structure. The simulated quasiequivalent lattices have been compared to the two nonequivalent lattices, revealing an interesting feature: the maximum deviation in the intersubunit distance by elastic deformation is almost three-quarters of the difference between the two distinct lattices, demonstrating a balanced coexistence of a well-defined conformational distinction and extensive adaptability in the molecular structure of flagellin and its packing interactions.     

Restriction fragment length polymorphism analysis of some flagellin genes of Salmonella enterica

Salmonellae often have the ability to express two different flagellar antigen specificities (phase 1 and phase 2). At the cell level, only one flagellar phase is expressed at a time. Two genes, fliC, encoding phase-1 flagellin, and fljB, encoding phase-2 flagellin, are alternatively expressed. Flagellin genes from 264 serovars of Salmonella enterica were amplified by two phase-specific PCR systems. Amplification products were subjected to restriction fragment length polymorphism (RFLP) analysis by using endonucleases HhaI and HphI. RFLP with HhaI and HphI yielded 64 and 42 different restriction profiles, respectively, among 329 flagellin genes coding for 26 antigens. The phase-1 gene showed 46 patterns with HhaI and 30 patterns with HphI. The phase-2 gene showed 23 patterns with HhaI and 17 patterns with HphI. When the data from both enzymes were combined, 116 patterns were obtained: 74 for fliC, 47 for fljB, and 5 shared by both genes. Of these combined patterns, 80% were specifically associated with one flagellar antigen and 20% were associated with more than one antigen. Each flagellar antigen was divided into 2 to 18 different combined patterns. In the sample of strains used, determination of the phase-1 and phase-2 flagellin gene RFLP, added to the knowledge of the O antigen, allowed identification of all diphasic serovars. Overall, the diversity uncovered by flagellin gene RFLP did not precisely match that evidenced by flagellar agglutination.     

Human immune cells mediate catecholamine secretion from adrenal chromaffin cells

OBJECTIVES: To determine the ability of human mononuclear cells to produce factors that cause catecholamine secretion from adrenomedullary chromaffin cells; to determine conditions that stimulate mononuclear cells to produce such factors; and to compare these results with catecholamine secretion in response to the cytokines interleukin (IL)-1 and IL-2. DESIGN: Randomized, controlled, prospective study using in vitro conditions. SETTING: University research laboratory. SUBJECTS: Human mononuclear cells and porcine chromaffin cells. INTERVENTIONS: Circulating human mononuclear cells were isolated and cultured overnight in RPMI media. Cell-free media from these cultures (conditioned media) were then tested for the ability to cause epinephrine secretion from porcine chromaffin cells. Mononuclear cells were stimulated with phytohemagglutinin or by mixing cells from two different individuals while suppression was tested with dexamethasone. Catecholamine secretion in response to IL-1 and IL-2 (50 and 500 units/well, respectively), or nicotinic agonist dimethylphenylpiperazinium (10 microM, which mimics the action of acetylcholine), was tested for comparison. MEASUREMENTS AND MAIN RESULTS: Isolated porcine chromaffin cells had stable catecholamine content at the time of secretion measurements, and catecholamine release from cells into the media was measured using electrochemical detection after high-performance liquid chromatography separation. Catecholamine secretion was expressed as a percentage of the total cellular content. Epinephrine secretion due to human conditioned media was 6.9 +/- 1.0% compared with 1.4 +/- 0.6% for control media (p < .05) and 14.6 +/- 3.3% for dimethylphenylpiperazinium (p < .05). Epinephrine secretion with conditioned media from mixed cells (mixed leukocyte reaction) was 16.6 +/- 1.2%, which was higher than the epinephrine secretion caused by media from a single donor (6.9% +/- 1.0, p < .001). Pretreatment with dexamethasone inhibited the formation of bioactive products from mixed mononuclear cell preparations. Cytokines IL-1 and IL-2 did not stimulate chromaffin cell epinephrine secretion above background release with control media incubation. In all cases, norepinephrine secretion was similar to that of epinephrine, and results are included in all figures. CONCLUSIONS: Factors released from human immune cells can mediate epinephrine and norepinephrine release from adrenomedullary cells through a nonneural mechanism. Such immune cell factor release can be modulated by immunostimulation and steroid suppression. Release of such factors in vivo may contribute to increased circulating epinephrine in response to infectious challenge and may be an important factor in the critically ill patient.     

Functional expression of a GLT-1 type Na+-dependent glutamate transporter in rat pinealocytes

We recently showed that treatment with actin antagonists perturbed stomatal behavior in Commelina communis L. leaf epidermis and therefore suggested that dynamic changes in actin are necessary for signal responses in guard cells (M. Kim, P.K. Hepler, S.O. Eun, K.-S. Ha, Y. Lee [1995] Plant Physiol 109: 1077-1084). Here we show that actin filaments of guard cells, visualized by immunofluorescence microscopy, change their distribution in response to physiological stimuli. When stomata were open under white-light illumination, actin filaments were localized in the cortex of guard cells, arranged in a pattern that radiates from the stomatal pore. In marked contrast, for guard cells of stomata closed by darkness or by abscisic acid, the actin organization was characterized by short fragments randomly oriented and diffusely labeled along the pore site. Upon abscisic acid treatment, the radial pattern of actin arrays in the illuminated guard cells began to disintegrate within a few minutes and was completely disintegrated in the majority of labeled guard cells by 60 min. Unlike actin filaments, microtubules of guard cells retained an unaltered organization under all conditions tested. These results further support the involvement of actin filaments in signal transduction pathways of guard cells.     

Flagellin-containing membrane vesicles excreted from Vibrio alginolyticus mutants lacking a polar-flagellar filament

Polar flagellum-defective mutants (Pof- Laf-) have been isolated from a lateral flagella-defective mutant (Pof+ Laf-). Among these Pof- Laf- mutants, polar-filamentless mutants, which have the hook structure but not the filament, were identified by electron microscopy. Their hooks were covered with a sheath structure which is contiguous to the outer membrane. The filament proteins, flagellins, were shed into the culture medium of these mutants. These flagellins could be sedimented by high-speed centrifugation even after heat or low pH treatment whereas the depolymerized flagellin of the Pof+ strain was degraded by these treatments. After Triton X-100 treatment, most flagellin of the filamentless mutants could no longer be sedimented, and was degraded. We observed vesicle-like structures on the tips of the hooks and in the flagellin fraction sedimented by high speed centrifugation. These results suggest that flagellin of the filamentless mutants is not assembled into the tip of the hook, but is excreted together with a membrane structure which is probably the sheath of polar flagella.     

Genetic analysis of hook, a gene required for endocytic trafficking in drosophila

The Drosophila hook gene encodes a novel component of the endocytic compartment. Previously identified hook alleles, which still expressed truncated Hook proteins, affected the accumulation of internalized transmembrane ligands into multivesicular bodies (MVBs). To determine the hook null phenotype, we isolated nine new hook alleles on the basis of their characteristic hooked-bristle phenotype. At least one of these alleles, hk11, is a complete loss-of-function allele. Flies carrying the hk11 allele are viable and fertile but neither transmembrane ligands nor soluble ligands accumulate in MVBs. This effect on endocytosed ligands can be mimicked by the expression of Hook proteins truncated for the N- and C-terminal domains flanking the central coiled-coil region. The importance of all three domains for Hook function was confirmed by their conservation between two Drosophila and two human Hook proteins.     

Expression of tissue factor pathway inhibitor in vascular smooth muscle cells and its regulation by growth factors

Tissue factor pathway inhibitor (TFPI) in vivo is thought to be synthesized mainly by endothelial cells. To date, no significant regulator of TFPI synthesis has been described. Vascular smooth muscle cells (VSMC) express tissue factor in vitro and in vivo, which may contribute to vascular thrombosis. We hypothesized that VSMC might also express TFPI. To determine this, we examined growth-arrested coronary VSMC in culture and found that VSMC secreted an amount of TFPI similar to that seen in endothelial cells. Immunohistochemistry of normal human coronary arteries showed TFPI staining throughout the media and intima of the vessel with localization to VSMC and endothelial cells. To determine regulation of TFPI expression in VSMC, we examined the effects of serum stimulation on TFPI secretion and found that FBS induced a 5-fold increase in TFPI antigen and activity levels in conditioned medium at 48 hours (P<0.001) when compared with serum-free conditions. A similar stimulatory effect was seen with 10% pooled human serum. Moreover, epidermal growth factor and platelet-derived growth factor-B increased TFPI secretion by 4- to 5-fold and 2- to 3-fold, respectively (P<0.05), and these growth factors accounted for approximately 50% of the TFPI secretion effects of human serum. The serum effect was associated with a 3-fold increase in TFPI mRNA 24 hours after release from growth arrest and a 50% decrease in TFPI secretion after treatment with actinomycin D. Taken together, this study suggests that there is significant TFPI expression in VSMC in culture and in VSMC within the intima and media of the normal coronary artery wall. We present the first evidence for TFPI regulation by serum in VSMC and more specifically by its constituent growth factors, epidermal growth factor and platelet-derived growth factor-B.     

Effect of cellular level of FliK on flagellar hook and filament assembly in Salmonella typhimurium

Frameshift mutations in the fliK gene of Salmonella result in abnormal elongation of the hook and the failure to assemble filament (polyhook phenotype). Second-site suppressor mutations restore filament assembly, but the cells often remain defective in hook-length control (polyhook-filament phenotype). Where the suppressor mutations are intragenic, the second mutation restores the original frame, generating a region of frameshifted sequence, but restoring the natural C terminus. Some of these frameshifted sequences contain a UGA (opal) termination codon. These cells have few flagella and swarm poorly. We suspected that readthrough of UGA by tRNATrp might be the reason for the partial function. When the UGA codon was changed to the Trp codon UGG, flagellar assembly and function were restored to wild-type levels. Conversely, underexpression of the wild-type fliK gene, achieved by changing the sole Trp codon in the sequence (Trp271) to UGA, decreased both the number of flagella and the ability to swarm. These results validate the readthrough hypothesis and indicate that low levels of FliK sustain some degree of flagellation and motility. At low levels of FliK, most flagella had polyhooks. With increasing amounts, the morphology progressively changed to polyhook-filament, and eventually to wild-type hook-filament. When FliK was overproduced, the hook length was slightly shorter (46(+/-7) nm) than that of the wild-type strain (55(+/-9) nm). FliK levels were measured by immunoblotting. Wild-type levels were about 40 to 80 molecules/cell. FliK synthesized by UGA readthrough could be detected when overproduced from plasmid fliK-W271opal, and the levels indicated a probability of readthrough of 0.002 to 0.01. This value was used to estimate the cellular level of underexpressed FliK, which could partly restore function to a fliK mutant, at about 0.07 to 0.8 molecule/cell. These results suggest that FliK does not form a large structure in the cytoplasm and may function as a regulatory protein for protein export. A model for hook-length control is presented that involves feedback from the assembly point to the export apparatus.     

The type III secretion determinants of the flagellar anti-transcription factor, FlgM, extend from the amino-terminus into the anti-sigma28 domain

The flagellar-specific anti-sigma factor, FIgM, inhibits the expression of late flagellar genes until the hook-basal body structure is assembled and competent for export of the flagellins and hook-associated proteins (flagellar late proteins). FIgM monitors this assembly checkpoint by being a substrate for export via the hook-basal body structure, which includes a type III protein secretion complex. Amino acid sequence alignment of late-secreted flagellar proteins identified a region of homology present in the amino-terminus of FIgM and the other late flagellar proteins, but not in flagellar proteins secreted earlier during flagellar biosynthesis. Single amino acid substitutions at specific positions within this motif decreased the export of FIgM. Deletion of this region (S3-P11) resulted in lower intracellular FIgM levels, but did not prevent recognition and export by the flagellar-specific secretion system. Mutations were isolated in a second region of FIgM spanning residues K27 to A65 that exhibited increased anti-sigma28 activity. These FIgM 'hyperinhibitor' mutants were secreted less than wild-type FIgM. Mutations that interfere with the secretion of FIgM without abolishing anti-sigma28 activity have a negative effect upon the secretion of a His-tagged FIgM mutant that lacks anti-sigma28 activity. Models are proposed to explain the dominant negative phenotype of the FIgM secretion mutants reported in this study.     

Mechanism of self-association and filament capping by flagellar HAP2

HAP2 forms a capping structure, which binds very tightly to the distal end of flagellar filaments and still allows insertion of flagellin subunits below the cap by an unknown mechanism. Terminal regions of HAP2 from Salmonella typhimurium were found to be quickly degraded by various proteases, indicating that HAP2 also possesses disordered terminal regions like other axial proteins of bacterial flagellum. Removal of these portions by trypsin results in a fragment of 40 kDa (HP40), which lacks 42 NH2-terminal and 51 COOH-terminal residues. HAP2 in solution readily associates into a decameric structure without any significant population of intermediate oligomeric forms. The HP40 fragments, however, do not form decamers, while they can assemble into pentamers, as revealed by chemical cross-linking and analytical ultracentrifugation. Decameric HAP2 also dissociates into pentamers and smaller oligomers upon a heat induced conformational transition around 36 degreesC. While the highly mobile terminal regions are immobilized in decameric HAP2 complexes, they are still largely disordered in the pentameric state. These results demonstrate that the intersubunit interactions within the pentamers are mainly through the HP40 portions, whereas the terminal regions are responsible for association of pentamers into decameric complexes. Several observations indicate that HAP2 performs its capping function as a pentamer. We suggest that binding of the pentameric HAP2 cap to the filament is mediated by the highly flexible terminal regions. Indeed, HP40 fragments are unable to cap the end of filaments, while removal of about 30 residues from both terminal regions of HAP2 results in a highly reduced capping ability. A model is presented to explain the molecular mechanism of capping, in which conformational entropy in the disordered terminal regions moderates the otherwise too tight HAP2-filament interactions to allow insertion of flagellin subunits below the cap.     

IF钢连铸坯凝固钩数学模拟与试验

 根据IF钢连铸坯凝固钩的形成机理,通过建立二维纵向切片传热模型,模拟了凝固钩的演变行为;结合金相试验结果分析了连铸工艺参数对凝固钩深度的影响。结果表明,在初始凝固过程中,凝固钩中经历了形成、熔化及生长等阶段,在数学模拟条件下,当结晶器内由浸入式水口流出的钢液温度为1 555 ℃、拉速为1.3 m/min时,在距离弯月面55.12 mm处,即凝固钩生长达到稳定状态,其深度为2.368 mm。当拉坯速度、结晶器内钢水温度、振动频率增加时,凝固钩深度均减小。凝固钩数学模拟结果符合实际生产。