Purification and characterization of a polyhook protein from Caulobacter crescentus.

A polyhook-producing strain of Caulobacter crescentus was isolated, and the polyhook protein was purified. The antigenicity and morphology of the polyhook structure are similar to the wild-type hook except that the mutant strain produces a hook structure at least 10-fold the length of wild-type hooks (1.0 versus 0.1 micrometers). The molecular weight of the polyhook protein, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, is 72,000, and the protein has a pI of approximately 6.1. Antibodies prepared against the polyhook protein were used to show that this protein is antigenically distinct from the Caulobacter flagellins. Amino acid analysis of the polyhook protein revealed compositional similarities to other gram-negative, bacterial hook proteins.     

Function of the conserved FHIPEP domain of the flagellar type III export apparatus,protein FlhA

The Type III flagellar protein export apparatus of bacteria consists of five or six membrane proteins, notably FlhA, which controls the export of other proteins and is homologous to the large family of FHIPEP export proteins. FHIPEP proteins contain a highly‐conserved cytoplasmic domain. We mutagenized the cloned Salmonella flhA gene for the 692 amino acid FlhA, changing a single, conserved amino acid in the 68‐amino acid FHIPEP region. Fifty‐two mutations at 30 positions mostly led to loss of motility and total disappearance of microscopically visible flagella, also Western blot protein/protein hybridization showed no detectable export of hook protein and flagellin. There were two exceptions: a D199A mutant strain, which produced short‐stubby flagella; and a V151L mutant strain, which did not produce flagella and excreted mainly un‐polymerized hook protein. The V151L mutant strain also exported a reduced amount of hook‐cap protein FlgD, but when grown with exogenous FlgD it produced polyhooks and polyhook‐filaments. A suppressor mutant in the cytoplasmic domain of the export apparatus membrane protein FlhB rescued export of hook‐length control protein FliK and facilitated growth of full‐length flagella. These results suggested that the FHIPEP region is part of the gate regulating substrate entry into the export apparatus pore.     

Echinococcus granulosus: Hook-muscle systems and cellular organisation of infective oncospheres

The morphology of the oncospheres of Echinococcus granulosus has been reconstructed from thin and semi-thin serial sections. Four major types of oncospheral cells have been identified. These consist of: (1) a bi-nucleate medullary center, (2) glandular regions (eight nuclei) subdivided into three types of oncospheral glands, (3) ten germinative cells, and (4) 34 muscle cells, of which 16 are somatic and 18 are hook muscle cells. The hook muscle cells of each hook are organized functionally into the three following systems: (1) the protraction system, for hook extension, (2) the abduction system for drawing the hooks together toward the median plane of bilateral symmetry, and (3) the retraction system for pulling the hooks back into the body. The interconnections observed between different muscle fibers provide a structural basis for coordinated hook action.     

Roles of FliK and FlhB in determination of flagellar hook length in Salmonella typhimurium.

The length of flagellar hooks isolated from wild-type and mutant cells with various hook lengths were measured on electron micrographs. The length of the wild-type hook showed a narrow distribution with a peak (+/- standard deviation) at 55.0 +/- 5.9 nm, whereas fliK mutants (so-called polyhook mutants) showed a broad distribution of hook lengths ranging from 40 to 900 nm, strongly indicating that FliK is involved in hook length determination. Among pseudorevertants isolated from such polyhook mutants, fliK intragenic suppressors gave rise to polyhook filaments. However, intergenic suppressors mapping to flhB also gave rise to hooks of abnormal length, albeit they were much shorter than polyhooks. Furthermore, double mutations of flhB and flgK (the structural gene for hook-associated protein 1; HAP1) resulted in polyhooks, suggesting another way in which hook length can be affected. The roles of FliK, FlhB, and HAP1 in hook length determination are discussed.     

Three-dimensional reconstruction of the flagellar hook from Caulobacter crescentus

The structure of the bacterial flagellar hook produced by a mutant of Caulobacter crescentus was studied by electron microscopy, optical diffraction, and digital image processing techniques. The helical surface lattice of the hook is defined by a single, right-handed genetic helix having a pitch of about 23 Å, an axial rise per subunit of 4 Å and an azimuthal angle between subunits of 64·5 °. The lattice is also characterized by intersecting families of 5-start, 6-start and long-pitch 11-start helices. These helical parameters are remarkably similar to those determined for the flagellar filaments from several strains of gram-negative bacteria. The technique of three-dimensional image reconstruction (DeRosier & Klug, 1968) was applied to nine of the better preserved specimens and the diffraction data from five of these were correlated and averaged and used to generate an average three-dimensional model of the hook. The pattern of density modulations in the three-dimensional model is suggestive of an elongated, curved shape for the hook subunit (100 Å × 25 Å × 25 Å). The subunits are situated in the lattice of the polyhook such that their long axes are tilted about 45 ° with respect to the hook axis. The subunits appear to make contact with each other along the 6-start helices at a radius of 80 Å and also along the 11-start helices at a radius of 65 Å. Few structural features are revealed at radii between 15 å and 45 Å and, therefore, we are unable to decide to what extent the hook subunits extend into this region. The most striking characteristic of the model is the presence of deep, broad, continuous 6-start helical grooves extending from an inner radius of about 50 Å to the perimeter of the particle at 105 Å radius. Normal hooks usually appear curved in electron micrographs and sometimes so are the mutant hooks; the prominent 6-start grooves appear to allow for bending with minimal distortion of matter in the outer regions of the hook. A round stain-filled channel about 25 Å in diameter runs down the center of the polyhook. Such a channel supports a model for flagellar assembly in which flagellin subunits travel through the interior of the flagellum to the growing distal end of the filament.     

Structural and genetic analysis of a mutant of Rhodobacter sphaeroides WS8 deficient in hook length control.

Motility in the photosynthetic bacterium Rhodobacter sphaeroides is achieved by the unidirectional rotation of a single subpolar flagellum. In this study, transposon mutagenesis was used to obtain nonmotile flagellar mutants from this bacterium. We report here the isolation and characterization of a mutant that shows a polyhook phenotype. Morphological characterization of the mutant was done by electron microscopy. Polyhooks were obtained by shearing and were used to purify the hook protein monomer (FlgE). The apparent molecular mass of the hook protein was 50 kDa. N-terminal amino acid sequencing and comparisons with the hook proteins of other flagellated bacteria indicated that the Rhodobacter hook protein has consensus sequences common to axial flagellar components. A 25-kb fragment from an R. sphaeroides WS8 cosmid library restored wild-type flagellation and motility to the mutant. Using DNA adjacent to the inserted transposon as a probe, we identified a 4.6-kb SalI restriction fragment that contained the gene responsible for the polyhook phenotype. Nucleotide sequence analysis of this region revealed an open reading frame with a deduced amino acid sequence that was 23.4% identical to that of FliK of Salmonella typhimurium, the polypeptide responsible for hook length control in that enteric bacterium. The relevance of a gene homologous to fliK in the uniflagellated bacterium R. sphaeroides is discussed.     

FlgD is a scaffolding protein needed for flagellar hook assembly in Salmonella typhimurium.

FlgD is known to be absolutely required for hook assembly, yet it has not been detected in the mature flagellum. We have overproduced and purified FlgD and raised an antibody against it. By using this antibody, we have detected FlgD in substantial amounts in isolated basal bodies from flgA, flgE, flgH, flgI, flgK, and fliK mutants, in much smaller amounts in those from the wild type and flgL, fliA, fliC, fliD, and fliE mutants, and not at all in those from flgB, flgD, flgG, and flgJ mutants. In terms of the morphological assembly pathway, these results indicate that FlgD is first added to the structure when the rod is completed and is discarded when the hook, having reached its mature length, has the first of the hook-filament junction proteins, FlgK, added to its tip. Immunoelectron microscopy established that FlgD initially is located at the distal end of the rod and eventually is located at the distal end of the hook. Thus, it appears to act as a hook-capping protein to enable assembly of hook protein subunits, much as another flagellar protein, FliD, does for the flagellin subunits of the filament. However, whereas FliD is associated with the filament tip indefinitely, FlgD is only transiently associated with the hook tip; i.e., it acts as a scaffolding protein. When FlgD was added to the culture medium of a flgD mutant, cells gained motility; thus, although the hook cap is normally added endogenously, it can be added exogenously. When culture media were analyzed for the presence of hook protein, it was found only with the flgD mutant and, in smaller amounts, the fliK (polyhook) mutant. Thus, although FlgD is needed for assembly of hook protein, it is not needed for its export.     

Activating mutations of N-WASP alter Shigella pathogenesis

The pathogenesis of Shigella requires binding to the host protein N-WASP. To examine the roles of structural conformation and phospho-regulation of N-WASP during Shigella pathogenesis, mutant N-WASP constructs predicted to result in a constitutively open conformation (L229P and L232P) or either a phospho-mimicking (Y253E) or phospho-disruptive (Y253F) structure were constructed. Pyrene actin assays demonstrated that the N-WASP L229P and L232P constructs are constitutively active. Despite the increase in actin polymerization seen in vitro, cell lines expressing N-WASP L229P and L232P supported shorter actin tails when infected with Shigella.Shigella actin tails were unchanged in cells expressing N-WASP phospho-regulation mutant proteins. Shigella invasion, intracellular, and intercellular motility were not altered in cells expressing N-WASP L229P or L232P. However, plaque numbers were increased in cells expressing N-WASP L229P and L232P. These data demonstrate that N-WASP structural conformation is an important regulator of Shigella pathogenesis in distinct segments of its lifecycle.     

Role of svp in Drosophila Pericardial Cell Growth

The Drosophila dorsal vessel is a segmentally repeated linear organ, in which seven-up (svp) is expressed in two pairs of cardioblasts and two pairs of pericardial cells in each segment. Under the control of hedgehog (hh) signaling from the dorsal ectoderm, svp participates in diversifying cardioblast identities within each segment. In this experiment, the homozygous embryos of svp mutants exhibited an increase in cell size of Eve positive pericardial cells (EPCs) and a disarranged expression pattern, while the cardioblasts pattern of svp-lacZ expression was normal. In the meantime, the DA1 muscle founders were absent in some segments in svp mutant embryos, and the dorsal somatic muscle patterning was also severely damaged in the late stage mutant embryos, suggesting that svp is required for the differentiation of Eve-positive pericardial cells and DA1 muscle founders and may have a role in EPC cell growth.     

Length Control of the Flagellar Hook in a Temperature-Sensitive flgE Mutant of Salmonella enterica Serovar Typhimurium

The flagellar hook is a short, curved, extracellular structure located between the basal body and the filament. The hook is composed of the FlgE protein. In this study, we analyzed flagellum assembly in a temperature-sensitive flgE mutant of Salmonella enterica serovar Typhimurium. When the mutant cells were grown at 30°C, they produced flagella of a normal length (71% of the population) and short hooks without filaments (26%). At 37°C, 70% of the basal bodies lacked hooks, and intact flagella made up only 6% of the population. Mutant cells secreted monomeric FlgE in abundance at 37°C, suggesting that the mutant FlgE protein might be defective in polymerization at higher temperatures. The average length of the hooks in intact filaments was 55 nm, whereas after acid treatment, it was 45 nm. SDS-PAGE analysis of the hook-basal body showed that HAP1 was missing in the mutant but not in the wild type. We concluded that hook length in the mutant is controlled in the same way as in the wild type, but the hook appeared short after acid treatment due to the lack of HAP1. We also learned that the true length of the hook is possibly 45 nm, not 55 nm, as has been believed.     

Nucleic acid and protein factors involved in Escherichia coli polynucleotide phosphorylase function on RNA

It has been reported that polynucleotide phosphorylase (PNPase) binds to RNA via KH and S1 domains, and at least two main complexes (I and II) have been observed in RNA-binding assays. Here we describe PNPase binding to RNA, the factors involved in this activity and the nature of the interactions observed in vitro. Our results show that RNA length and composition affect PNPase binding, and that PNPase interacts primarily with the 3′ end of RNA, forming the complex I-RNA, which contains trimeric units of PNPase. When the 5′ end of RNA is blocked by a hybridizing oligonucleotide, the formation of complex II-RNA is inhibited. In addition, PNPase was found to form high molecular weight (>440 kDa) aggregates in vitro in the absence of RNA, which may correspond to the hexameric form of the enzyme. We confirmed that PNPase in vitro RNA binding, degradation and polyadenylation activities depend on the integrity of KH and S1 domains. These results can explain the defective in vivo autoregulation of PNPase71, a KH point substitution mutant. As previously reported, optimal growth of a cold-sensitive strain at 18 °C requires a fully active PNPase, however, we show that overexpression of a novel PNPaseΔS1 partially compensated the growth impairment of this strain, while PNPase71 showed a minor compensation effect. Finally, we propose a mechanism of PNPase interactions and discuss their implications in PNPase function.     

Messenger ribonucleic acid content of Bacillus amyloliquefaciens throughout its growth cycle compared with Bacillus subtilis 168

The messenger RNA contents of Bacillus amyloliquefaciens and B. subtilis 168, grown in a 1% maltose-0.5% casein hydrolysate complex medium, were determined throughout their growth cycles by a hybridization technique. In both cases there was a level equal to about 3% of the total cellular RNA during the exponential phase. In B. subtilis this level was maintained into the stationary phase. By contrast, in B. amyloliquefaciens the proportion of messenger RNA increased after the end of exponential growth levelling off in the stationary phase at a value twice that observed in exponential growth. The total messenger RNA in each organism was resolved into two components, that involved in the formation of cell proteins and that concerned in extracellular protein production, by determining the relative rates of incorporation of l-[¹⁴C]valine into the two protein fractions. In both cases the cell protein component was the same and remained a relatively constant proportion of the total cellular material throughout the growth cycles. The exoprotein mRNA paralleled exoprotein secretion in each species, remaining at a constant low level in B. subtilis and undergoing a tenfold increase after the end of exponential growth in B. amyloliquefaciens. Applying a serial hybridization procedure to B. amyloliquefaciens, no evidence was obtained for the accumulation of a specific component of the messenger RNA in the exponential or post-exponential phase of growth, which was not detected by hybridization.     

Altered plasmodial surface anion channel activity and in vitro resistance to permeating antimalarial compounds

Erythrocytes infected with malaria parasites have increased permeability to various solutes. These changes may be mediated by an unusual small conductance ion channel known as the plasmodial surface anion channel (PSAC). While channel activity benefits the parasite by permitting nutrient acquisition, it can also be detrimental because water-soluble antimalarials may more readily access their parasite targets via this channel. Recently, two such toxins, blasticidin S and leupeptin, were used to select mutant parasites with altered PSAC activities, suggesting acquired resistance via reduced channel-mediated toxin uptake. Surprisingly, although these toxins have similar structures and charge, we now show that reduced permeability of one does not protect the intracellular parasite from the other. Leupeptin accumulation in the blasticidin S-resistant mutant was relatively preserved, consistent with retained in vitro susceptibility to leupeptin. Subsequent in vitro selection with both toxins generated a double mutant parasite having additional changes in PSAC, implicating an antimalarial resistance mechanism for water-soluble drugs requiring channel-mediated uptake at the erythrocyte membrane. Characterization of these mutants revealed a single conserved channel on each mutant, albeit with distinct gating properties. These findings are consistent with a shared channel that mediates uptake of ions, nutrients and toxins. This channel's gating and selectivity properties can be modified in response to in vitro selective pressure.     

Multiple C-Terminal Tails within a Single E. coli SSB Homotetramer Coordinate DNA Replication and Repair

Escherichia coli single-stranded DNA binding protein (SSB) plays essential roles in DNA replication, recombination and repair. SSB functions as a homotetramer with each subunit possessing a DNA binding domain (OB-fold) and an intrinsically disordered C-terminus, of which the last nine amino acids provide the site for interaction with at least a dozen other proteins that function in DNA metabolism. To examine how many C-termini are needed for SSB function, we engineered covalently linked forms of SSB that possess only one or two C-termini within a four-OB-fold “tetramer”. Whereas E. coli expressing SSB with only two tails can survive, expression of a single-tailed SSB is dominant lethal. E. coli expressing only the two-tailed SSB recovers faster from exposure to DNA damaging agents but accumulates more mutations. A single-tailed SSB shows defects in coupled leading and lagging strand DNA replication and does not support replication restart in vitro. These deficiencies in vitro provide a plausible explanation for the lethality observed in vivo. These results indicate that a single SSB tetramer must interact simultaneously with multiple protein partners during some essential roles in genome maintenance.     

Role of the flaR gene in flagellar hook formation in Salmonella spp.

Flagellar filaments were reconstituted by polymerization with exogenously supplied flagellin monomers at the tips of normal hooks on Salmonella cells which were missing the filaments because of mutations in either the flaL or flaU gene or the flagellin genes H1 and H2. Reconstitution did not occur at the tips of polyhooks of the flaR mutant cells. Thus, the absence of flagellar filaments in the flaR mutant cells was probably caused by the inability of the polyhooks to work as polymerization nuclei for flagellin. A Phf+ mutant which produced polyhooks with flagellar filaments was isolated from a flaR polyhook mutant. Genetic analysis of the Phf+ mutant showed that it carried an intracistronic suppressor mutation of the original flaR mutation. This result indicated that the flaR gene regulates hook length and initiates flagellin formation.     

Kinetic analysis of the growth rate of the flagellar hook in Salmonella typhimurium by the population balance method.

The growth rate of flagellar hooks in Salmonella typhimurium was analyzed by computer-aided simulation of the length distributions of mutant hooks of uncontrolled length (polyhooks). The wild-type hook has a relatively well-controlled length, with an average of 55 nm and a standard deviation of 6 nm. Mutations in the fliK gene give rise to polyhooks. A histogram of the lengths of polyhooks from a fliK mutant shows a peak at 55 nm with a long monotonic tail extending out to 1 microm. To analyze the growth rate, we employed the population balance method. Regression analysis showed that the histogram could fit a combination of two theoretical curves. In the first phase of growth, the hook starts with a very fast growth rate (40 nm/min), and then the rate exponentially slows until the length reaches 55 nm. In the second phase of growth, where the hook length is over 55 nm, the hook grows at a constant rate of 8 nm/min. Second mutations in either the fliK or flhB genes, as found in pseudorevertants from fliK mutants, give rise to polyhook filaments (phf). The ratio between the numbers of hooks with and without filament was 6:4. The calculated probability of filament attachment to polyhooks was low so that the proportion of hooks that start filament growth was only 2% per minute. The lengths of polyhooks with and without filaments were measured. A histogram of hook length in phf's was the same as that for polyhooks in single-site fliK mutants, against the expectation that the distribution would shift to a shorter average. The role of FliK in hook length control is discussed.     

The role of a 2-on-2 haemoglobin in oxidative and nitrosative stress resistance of Antarctic Pseudoalteromonas haloplanktis TAC125

The 2-on-2 haemoglobins, previously named truncated, are monomeric, low-molecular weight oxygen-binding proteins that share the overall topology with vertebrate haemoglobins. Although several studies on 2-on-2 haemoglobins have been reported, their physiological and biochemical functions are not yet well defined, and various roles have been suggested. The genome of the psychrophilic Antarctic marine bacterium Pseudoalteromonas haloplanktis TAC125 (PhTAC125) is endowed with three genes encoding 2-on-2 haemoglobins. To investigate the function played by one of the three trHbs, PhHbO, a PhTAC125 genomic mutant strain was constructed, in which the encoding gene was knocked-out. The mutant strain was grown under controlled conditions and several aspects of bacterium physiology were compared with those of wild-type cells when dissolved oxygen pressure in solution and growth temperature were changed. Interestingly, inactivation of the PhHbO encoding gene makes the mutant bacterial strain sensitive to high solution oxygen pressure, to H₂O₂, and to a nitrosating agent, suggesting the involvement of PhHbO in oxidative and nitrosative stress resistance.     

Association of chlorophyll a/c2 complexes to photosystem I and photosystem II in the cryptophyte Rhodomonas CS24

Photosynthetic supercomplexes from the cryptophyte Rhodomonas CS24 were isolated by a short detergent treatment of membranes from the cryptophyte Rhodomonas CS24 and studied by electron microscopy and low-temperature absorption and fluorescence spectroscopy. At least three different types of supercomplexes of photosystem I (PSI) monomers and peripheral Chl a/c₂ proteins were found. The most common complexes have Chl a/c₂ complexes at both sides of the PSI core monomer and have dimensions of about 17 × 24 nm. The peripheral antenna in these supercomplexes shows no obvious similarities in size and/or shape with that of the PSI-LHCI supercomplexes from the green plant Arabidopsis thaliana and the green alga Chlamydomonas reinhardtii, and may be comprised of about 6-8 monomers of Chl a/c₂ light-harvesting complexes. In addition, two different types of supercomplexes of photosystem II (PSII) dimers and peripheral Chl a/c₂ proteins were found. The detected complexes consist of a PSII core dimer and three or four monomeric Chl a/c₂ proteins on one side of the PSII core at positions that in the largest complex are similar to those of Lhcb5, a monomer of the S-trimer of LHCII, Lhcb4 and Lhcb6 in green plants.     

The ultrastructure of the tegument and the digestive caeca of in vitro cultured metacercariae of Fasciola hepatica

Davies C. 1978. The ultrastructure of the tegument and digestive caeca of in vitro cultured metacercariae of Fasciola hepatica. International Journal for Parasitology8: 197–206. The ultrastructure of the tegument and digestive caeca of metacercariae of Fasciola hepatica grown in vitro in two different media is described and compared with the development of these two systems during maturation in vivo. Although the tegument of metacercariae grown in Medium RC showed no development, that of flukes cultured in Medium CS began to produce T-1 and T-2 granules typical of the liver phase of development in vivo. The gastrodermal cells showed some degree of conversion to an adult-like morphology in vitro with the production of typical secretory granules, a limited amount of orientation of the GER and the development of junctional complexes with adjacent parenchyma cells—this was particularly evident in flukes from Medium CS. The growth achieved in each of the culture media is correlated to the degree of development of the tegument and the digestive caeca.