A new model for the penetration of prey cells by bdellovibrios.

Bdellovibrio bacteriovorus 109J and most other bdellovibrios cause prey cells to round following penetration. Bdellovibrio sp. strain W does not cause rounding of the prey. Analysis of enzyme activities during the early stages of bdellovibrio attack indicated that strain W differs from most other bdellovibrios in that there is no glycanase activity produced during penetration. Likewise, heat-killed prey were penetrated normally by strain 109J, but the resulting bdelloplast did not become round and no glycanase was detected, indicating that glycanase is not essential for penetration. Peptidoglycan from prey cells penetrated by strain W was sensitive to lysozyme, but these cells were not susceptible to attack and penetration by strain 109J, indicating that peptidoglycan deacetylation is not the primary exclusion mechanism. We propose a model in which it is the peptidase activity of the bdellovibrios which allows them to breach the peptidoglycan of their prey and in which the glycanase activity exhibited by strain 109J and other bdellovibrios is responsible for the rounding of the bdelloplast.     

Verification of the protein in the outer membrane of Bdellovibrio bacteriovorus as the OmpF protein of its Escherichia coli prey.

Two research groups showed that several Bdellovibrio strains incorporated into their outer membranes intact OmpF porin proteins derived from their Escherichia coli prey. These results could not be reproduced by another group using Bdellovibrio bacteriovorus 109J. They showed that a major protein appearing in the Bdellovibrio Triton X-100-insoluble outer membrane was coded for by the bdellovibrios. We reconciled these results by examining the strain used by this group and by reviving a freeze-dried culture of strain 109J which had been stored for almost 9 years. B. bacteriovorus 109J failed to acquire substantial amounts of the OmpF protein from E. coli ML35, and a protein coded for by the bdellovibrios was expressed in its place. However, B. bacteriovorus 109J incorporated the OmpF protein from rough K-12 strains of E. coli, and the revived 9-year-old culture of B. bacteriovorus 109J incorporated more of the OmpF protein from the smooth E. coli ML35 than did its contemporary counterpart. The protein isolated from the outer membrane of the bdellovibrios was identified as the OmpF protein of E. coli by its protease peptide profile on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by Western blot analysis. This confirmed that bdellovibrios relocalize outer membrane proteins from their prey, but relocalization may be an unstable trait which can be influenced by the prey.     

Energy metabolism of Bdellovibrio bacteriovorus. I. Energy production, ATP pool, energy charge.

Bdellovibrio bacteriovorus, strain Bd. 109 Sa, generates ATP mainly by oxidative phosphorylation during electron transport. During exponential growth the ATP pool is constant (9 mmoles/100 mugN) indicating that energy-producing and energy-consuming reactions are well balanced. The ratio of substrate respiration/endogenous respiration is approx. 2.5/1. Energy charge is constant both in endogenous and substrate respiration at values of 0.62 to 0.64. During endogenous respiration (starvation) the ATP pool oscillates at regular intervals. ATP over-production is started after the ATP pool has decreased to a minimum level of 6 nmoles/100 mug N. The alternating over- and under-production of ATP is interpreted as a special regulation which enables the organism to make economic use of its own cellular materials. Addition of substrate (glutamate) to starving cells does not influence the type of ATP pool oscillation as observed in endogenous respiration. The parasitic strain Bd. 109 Pa exhibits the same periodicity of ATP overproduction as does it saprophytic derivative, Bd. 109 Sa. Decrease of viability during starvation is paralleled by a decrease of the ATP pool.     

Metabolism of RNA-ribose by Bdellovibrio bacteriovorus during intraperiplasmic growth on Escherichia coli.

During intraperiplasmic growth of Bdellovibrio bacteriovorus 109J on Escherichia coli some 30 to 60% of the initial E. coli RNA-ribose disappeared as cell-associated orcinol-positive material. The levels of RNA-ribose in the suspending buffer after growth together with the RNA-ribose used for bdellovibrio DNA synthesis accounted for 50% or less of the missing RNA-ribose. With intraperiplasmic growth in the presence of added U-14C-labeled CMP, GMP, or UMP, radioactivity was found both in the respired CO2 and incorporated into the bdellovibrio cell components. The addition of exogenous unlabeled ribonucleotides markedly reduced the amounts of both the 14CO2 and 14C incorporated into the progeny bdellovibrios. During intraperiplasmic growth of B. bacteriovorus on [U-14C]ribose-labeled E. coli BJ565, ca. 74% and ca. 19% of the initial 14C was incorporated into the progeny bdellovibrios and respired CO2, respectively. Under similar growth conditions, the addition of glutamate substantially reduced only the 14CO2; however, added ribonucleotides reduced both the 14CO2 and the 14C incorporated into the progeny bdellovibrios. No similar effects were found with added ribose-5-phosphate. The distribution of 14C in the major cell components was similar in progeny bdellovibrios whether obtained from growth on [U-14C]ribose-labeled E. coli BJ565 or from E. coli plus added U-14C-labeled ribonucleotides. After intraperiplasmic growth of B. bacteriovorus on [5,6-3H-]uracil-[U-14C]ribose-labeled E. coli BJ565 (normal or heat treated), the whole-cell 14C/3H ratio of the progeny bdellovibrios was some 50% greater and reflected the higher 14C/3H ratios found in the cell fractions. B. bacteriovorus and E. coli cell extracts both contained 5'-nucleotidase, uridine phosphorylase, purine phosphorylase, deoxyribose-5-phosphate aldolase, transketolase, thymidine phosphorylase, phosphodeoxyribomutase, and transaldolase enzyme activities. The latter three enzyme activities were either absent or very low in cell extracts prepared from heat-treated E. coli cells. It is concluded that during intraperiplasmic growth B. bacteriovorus degrades some 20 to 40% of the ribonucleotides derived from the initial E. coli RNA into the base and ribose-1-phosphate moieties. The ribose-1-phosphate is further metabolized by B. bacteriovorus both for energy production and for biosynthesis, of non-nucleic acid cell material. In addition, the data indicate that during intraperiplasmic growth B. bacteriovorus can metabolize ribose only if this compound is available to it as the ribonucleoside monophosphate.     

A conjugation procedure for Bdellovibrio bacteriovorus and its use to identify DNA sequences that enhance the plaque-forming ability of a spontaneous host-independent mutant.

Wild-type bdellovibrios are obligate intraperiplasmic parasites of other gram-negative bacteria. However, spontaneous mutants that can be cultured in the absence of host cells occur at a frequency of 10(-6) to 10(-7). Such host-independent (H-I) mutants generally display diminished intraperiplasmic-growth capabilities and form plaques that are smaller and more turbid than those formed by wild-type strains on lawns of host cells. An analysis of the gene(s) responsible for the H-I phenotype should provide significant insight into the nature of Bdellovibrio host dependence. Toward this end, a conjugation procedure to transfer both IncQ and IncP vectors from Escherichia coli to Bdellovibrio bacteriovorus was developed. It was found that IncQ-type plasmids were capable of autonomous replication in B. bacteriovorus, while IncP derivatives were not. However, IncP plasmids could be maintained in B. bacteriovorus via homologous recombination through cloned B. bacteriovorus DNA sequences. It was also found that genomic libraries of wild-type B. bacteriovorus 109J DNA constructed in the IncP cosmid pVK100 were stably maintained in E. coli; those constructed in the IncQ cosmid pBM33 were unstable. Finally, we used the conjugation procedure and the B. bacteriovorus libraries to identify a 5.6-kb BamHI fragment of wild-type B. bacteriovorus DNA that significantly enhanced the plaque-forming ability of an H-I mutant, B. bacteriovorus BB5.     

Glycolytic and tricarboxylic acid cycle enzyme activities during intraperiplasmic growth of Bdellovibrio bacteriovorus on Escherichia coli.

Selected enzyme activities were measured in extracts of the total cell pellets obtained at various times during aerobic intraperiplasmic growth of Bdellovibrio bacteriovorus 109J on anaerobically grown Escherichia coli substrate cells. Initially, the glycolytic enzyme activities were associated with the input of E. coli and the tricarboxylic acid cycle enzyme activities with the input of bdellovibrios. During the first 90 min of Bdellovibrio development, the glycolytic activities declined about 25 to 60%, whereas the tricarboxylic acid cycle activities increased about 10%. Between 110 and 180 min, the glycolytic activities decreased to trace levels and tricarboxylic acid cycle activities increased about 50 to 90%. Both bdellovibrio cell extracts and the cell-free growth menstruum (obtained after bdellovibrio growth on E. coli) caused the inactivation of glycolytic enzymes in E. coli extracts.     

Effects of methotrexate on intraperiplasmic and axenic growth of Bdellovibrio bacteriovorus.

The intraperiplasmic growth rate and cell yield of wild-type Bdellovibrio bacteriovorus 109J, growing on Escherichia coli of normal composition as the substrate, were not markedly inhibited by 10-3 M methotrexate (4-amino-N10-methylpteroylglutamic acid). In contrast, the growth rate and cell yield of the mutant 109Ja, growing axenically in 0.5% yeast extract +0.15% peptone, were strongly inhibited by 10-4 and 10-3 M methotrexate. Thymine, thymidine, and thymidine-5'-monophosphate, in increasing order of effectiveness, partially or completely reversed the inhibition. E. coli depleted of tetrahydrofolate and having an abnormally high protein/deoxyribonucleic acid (DNA) ratio was obtained by growing it in the presence of methotrexate. B. bacteriovourus grew at a normal rate on these depleted E. coli cells but with somewhat reduced cell yield. Mexthotrexate (10-3 M) inhibited intraperiplasmic growth of bdellovibrio on the depleted E. coli somewhat more than it inhibited growth on normal E. coli, but the effects were small compared with inhibition of axenic growth of the mutant. Total bdellovibrio DNA after growth on the depleted E. coli in the presence or absence of methotrexate exceeded the initial quanity of E. coli DNA present. Thymidine-5'-monophosphate (10-3 M) largely reversed the inhibition and increased the amount of net synthesis of DNA. The data are consistent with the prediction that intraperiplasmic growth of B. bacteriovorus should be insensitive to all metabolic inhibitors that act by specifically preventing synthesis of essential monomers. The data also indicate that B. bacteriovorus possesses thymidylate synthetase, thymidine phosphorylase, and thymidine kinase, and has the potential to carry out de novo DNA synthesis from non-DNA precursors during intraperiplasmic growth. The results also suggest that methionyl tRNAfMet is not required for initiation of protein synthesis by B. bacteriovorus.     

Characterization of outer membrane protein fractions of Bdellovibrionales

Bdellovibrio-and-like organisms (BALOs) are predatory bacteria that prey upon Gram-negative bacteria and are taxonomically subsumed in the order Bdellovibrionales. Despite their unique lifestyle, these bacteria show remarkable genotypic diversities. The outer membrane of the predators is likely to play an important role during the recognition and invasion stage, as well as in the intraperiplasmic growth phase. In this study, the outer membrane protein fractions of type strains of Bdellovibrio, Bacteriovorax and Peredibacter were investigated, revealing the presence of outer membrane proteins (Omps) similar to the major Omps of Bdellovibrio bacteriovorus. The primary structures of these Omps of Bdellovibrio sp. W, Bacteriovorax stolpii and Peredibacter starrii were elucidated by a combined mass spectrometric-reverse genetic approach. The similarity between the analyzed Omps of the investigated BALOs ranges from 32% to 89% showing conserved amino acid regions in their primary structure.     

Periplasmic enzymes in Bdellovibrio bacteriovorus and Bdellovibrio stolpii.

When cells of either Bdellovibrio bacteriovorus 109J or Bdellovibrio stolpii UKi2 were subjected to osmotic shock by treatment with sucrose-EDTA and MgCl2 solutions, only trace amounts of proteins or enzyme activities were released into the shock fluid. In contrast, when nongrowing cells were converted to motile, osmotically stable, peptidoglycan-free spheroplasts by penicillin treatment, numerous proteins were released into the suspending fluid. For both species, this suspending fluid contained substantial levels of 5'-nucleotidase, purine phosphorylase, and deoxyribose-phosphate aldolase. Penicillin treatment also released aminoendopeptidase N from B. bacteriovorus, but not from B. stolpii. Penicillin treatment did not cause release of cytoplasmic enzymes such as malate dehydrogenase. The data indicated that bdellovibrios possess periplasmic enzymes or peripheral enzymes associated with the cell wall complex. During intraperiplasmic bdellovibrio growth, periplasmic and cytoplasmic enzymes of the Escherichia coli substrate cell were not released upon formation of the spherical bdelloplast during bdellovibrio penetration. Most of the E. coli enzymes were retained within the bdelloplast until later in the growth cycle, when they became inactivated or released into the suspending buffer or both.     

Incorporation of long-chain fatty acids of the substrate organism by Bdellovibrio bacteriovorus during intraperiplasmic growth.

Data are presented showing that a large proportion of the fatty acids of Bdellovibrio bacteriovorus grown intraperiplasmically are derived unaltered from the fatty acids of its substrate organism. Those fatty acids of the bdellovibrio not homologous with those of the substrate organism are derived mainly by metabolic alteration of preexisting fatty acids in the latter. De novo synthesis from acetate occurs only to a small extent. These characteristics of bdellovibrio physiology are in part responsible for its minimal energy expenditure for intraperiplasmic growth. The data presented also indicate that B. bacteriovorus is capable of hydrogenating unsaturated fatty acids, of beta-oxidation of fatty acids, and of regulating the proportion of saturated and unsaturated fatty acids in the lipids.     

Bdellovibrio bacteriovorus synthesizes an OmpF-like outer membrane protein during both axenic and intraperiplasmic growth.

Outer membrane preparations of Bdellovibrio bacteriovorus grown intraperiplasmically on Escherichia coli containing OmpF were prepared by the Triton X-100 procedure of Schnaitman (J. Bacteriol. 108:545-552, 1971). They contained a protein that migrated to almost the same position as E. coli OmpF in sodium dodecyl sulfate-acrylamide gradient gel electrophoresis and to the same position as E. coli OmpF when urea was incorporated into the gel. The mobility of this protein increased relative to that of OmpC in urea-containing gels as does E. coli OmpF. However, the same protein was also produced during axenic growth and during intraperiplasmic growth on prey lacking OmpF. The peptide profile generated by partial proteolysis of this protein showed no homology to that produced from E. coli OmpF. We conclude that B. bacteriovorus synthesizes an OmpF-like protein. Previous claims that the bdellovibrio incorporates an intact E. coli OmpF are not consistent with these observations.     

Translocation of an outer membrane protein into prey cytoplasmic membranes by bdellovibrios.

Within minutes of Bdellovibrio bacteriovorus attack on prey cells, such as Escherichia coli, the cytoplasmic membrane of the prey is altered. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of purified invaded prey cell (bdelloplast) membranes revealed the appearance of a noncytoplasmic membrane protein. This protein is not observed in preparations of noninvaded E. coli membranes and migrates in a manner similar to that of E. coli OmpF. Isoelectric focusing and two-dimensional gel electrophoresis of bdelloplast cytoplasmic membrane preparations also revealed the presence of a protein with electrophoretic properties similar to those of OmpF and the major Bdellovibrio outer membrane proteins. The protein appears in cytoplasmic membrane preparations within minutes of attack and persists throughout most of the intraperiplasmic developmental cycle. The appearance of this protein is consistent with our hypothesis that bdellovibrios translocate a pore protein into the bdelloplast cytoplasmic membrane to kill their prey and to gain access to the cytoplasmic contents for growth.     

Utilization of nucleoside monophosphates per Se for intraperiplasmic growth of Bdellovibrio bacteriovorus.

During growth of Bdellovibrio bacteriovorus on Escherichia coli, there was a marked preferential use of E. coli phosphorus over exogenous orthophosphate even though the latter permeated into the intraperiplasmic space where the bdellovibrio was growing. This preferential use occurred to an equal extent for lipid phosphorus and nucleic acid phosphorus. Exogenous thymidine-5'-monophosphate competed effectively with [3H]thymine residues of E. coli as a precursor for bdellovibrio deoxyribonucleic acid; exogenous thymidine competed less effectively and thymine and uridine not at all. A mixture of exogenous nucleoside-5'-monophosphates equilibrated effectively with E. coli phosphorus as a phosphorus source for B. bacteriovorus; the nucleotide phosphorus entered preferentially into bdellovibrio nucleic acids. A comparable mixture of exogenous nucleosides plus orthophosphate had only a small effect on utilization of E. coli phosphorus by B. bacteriovorus, as did orthophosphate alone. A mixture of exogenous deoxyriboside monophosphates equilibrium effectively with E. coli phosphorus as a phosphorus source for bdellovibrio growth; the phosphorus from this source entered preferentially into deoxyribonucleic acid. These data show that nucleoside monophosphates derived from the substrate organism are utilized directly for n-cleic acid biosynthesis by B. bacteriovorus growing intraperiplasmically. As a consequence, the phosphate ester bonds preexisting in the nucleic acids of the substrate organism are conserved by the bdellovibrio, presumably lessening its energy requirement for intraperiplasmic growth. The data also suggest, but do not prove, that the phosphate ester bonds of phospholipids are also conserved.     

Characterizing the flagellar filament and the role of motility in bacterial prey-penetration by Bdellovibrio bacteriovorus

The predatory bacterium Bdellovibrio bacteriovorus swims rapidly by rotation of a single, polar flagellum comprised of a helical filament of flagellin monomers, contained within a membrane sheath and powered by a basal motor complex. Bdellovibrio collides with, enters and replicates within bacterial prey, a process previously suggested to firstly require flagellar motility and then flagellar shedding upon prey entry. Here we show that flagella are not always shed upon prey entry and we study the six fliC flagellin genes of B. bacteriovorus, finding them all conserved and expressed in genome strain HD100 and the widely studied lab strain 109J. Individual inactivation of five of the fliC genes gave mutant Bdellovibrio that still made flagella, and which were motile and predatory. Inactivation of the sixth fliC gene abolished normal flagellar synthesis and motility, but a disordered flagellar sheath was still seen. We find that this non-motile mutant was still able to predate when directly applied to lawns of YFP-labelled prey bacteria, showing that flagellar motility is not essential for prey entry but important for efficient encounters with prey in liquid environments.     

Bdellovibrio bacteriovorus strains produce a novel major outer membrane protein during predacious growth in the periplasm of prey bacteria

Bdellovibrio bacteriovorus is a predatory bacterium that is capable of invading a number of gram-negative bacteria. The life cycle of this predator can be divided into a nonreproductive phase outside the prey bacteria and a multiplication phase in their periplasm. It was suggested that during the reproduction phase, B. bacteriovorus reutilizes unmodified components of the prey's cell wall. We therefore examined the outer membranes of B. bacteriovorus strains HD100 (DSM 50701) and HD114 (DSM 50705) by using Escherichia coli, Yersinia enterocolitica, and Pseudomonas putida as prey organisms. The combined sodium dodecyl sulfate-polyacrylamide gel electrophoresis and mass spectrometric analyses revealed novel and innate major outer membrane proteins (OMPs) of B. bacteriovorus strains. An incorporation of prey-derived proteins into the cell wall of B. bacteriovorus was not observed. The corresponding genes of the B. bacteriovorus strains were elucidated by a reverse-genetics approach, and a leader peptide was deduced from the gene sequence and confirmed by Edman degradation. The host-independent mutant strain B. bacteriovorus HI100 (DSM 12732) growing in the absence of prey organisms possesses an OMP similar to the major OMPs of the host-dependent strains. The similarity of the primary structure of the OMPs produced by the three Bdellovibrio strains is between 67 and 89%. The leader peptides of all OMPs have a length of 20 amino acids and are highly conserved. The molecular sizes of the mature proteins range from 34.9 to 37.6 kDa. Secondary-structure predictions indicate preferential alpha-helices and little beta-barrel structures.     

Uptake of intact nucleoside monophosphates by Bdellovibrio bacteriovorus 109J

The degraded nucleic acids and ribosomes of its prey cell provide Bdellovibrio bacteriovorus 109J with a source of ribonucleoside monophosphates and deoxyribonucleoside monophosphates for biosynthesis and respiration. We demonstrate that bdellovibrios, in contrast to almost all other bacteria, take up these nucleoside monophosphates into the cell in an intact, phosphorylated form. In this way they are able to assimilate more effectively the cellular contents of their prey. Studies with UMP and dTMP demonstrate that they are transported and accumulated against a concentration gradient, achieving internal levels at least 10 times the external levels. Treatment of the bdellovibrios with azide or carbonyl cyanide m-chlorophenylhydrazone eliminates their ability to either transport or maintain accumulated UMP and suggests the presence of a freely reversible exchange mechanism. There are at least two separate classes of transport systems for nucleoside monophosphates, each exhibiting partial specificity for either ribonucleoside monophosphates or deoxyribonucleoside monophosphates. Kinetic analyses of UMP transport in different developmental stages of strain 109J indicate that each stage expresses a single, saturable uptake system with a distinct apparent substrate affinity constant (Kt) of 104 microM in attack phase cells and 35 microM in prematurely released growth phase filaments. The capacity for transport of UMP by the growth phase filaments was 2.4 times that of the attack phase cells. These data, in addition to the apparent lack of environmental control of UMP transport capacity in attack phase cells, suggest that there are two transport systems for UMP in bdellovibrios and that the high-affinity, high-capacity growth phase system is developmentally regulated.     

Effect of paracrystalline protein surface layers on predation by Bdellovibrio bacteriovorus.

We determined that paracrystalline protein surface arrays (S layers) protected gram-negative eubacteria from predation by Bdellovibrio bacteriovorus. Aquaspirillum serpens VHA and MW5 and Aquaspirillum sinuosum were resistant to predation by B. bacteriovorus 6-5-S when fully covered by their S layers. The S layer of Aeromonas salmonicida A449 protected the cells from predication by B. bacteriovorus 109J. A predacious, plaque-forming vibrio that lysed an S-layer- variant of Caulobacter crescentus but was not predacious on the parental strain which possessed an S layer was isolated from raw sewage. Since S layers are stable components of many bacterial surfaces in nature, they can provide this protective function in both aquatic and terrestrial habitats where Bdellovibrio spp. are found.     

Energy efficiency of intraperiplasmic growth of Bdellovibrio bacteriovorus.

The Y-ATP (energy efficiency) of intraperiplasmic growth of Bdellovibrio bacteriovorus was determined from the distribution of radioactivity of the substrate organism ([U-14C]Escherichia coli) btween CO2 and bdellovibrio cells at the end of growth. A "best" Y-ATP value of 18.5 was obtained from single growth cycle experiments and an average value of 25.9 from multicycle experiments. Both values are much higher than the usual value of 10.5 for bacteria growing in rich media. The bases for the unusual energy efficiency for growth of B. bacteriovorus are discussed.     

Investigations into the life cycle of the bacterial predator Bdellovibrio bacteriovorus 109J at an interface by atomic force microscopy

Atomic force microscopy was used to image Bdellovibrio bacteriovorus 109J, a gram-negative bacterial predator that consumes a variety of other gram-negative bacteria. In predator-prey communities grown on filters at hydrated air-solid interfaces, repeated cycles of hunting, invasion, growth, and lysis occurred readily even though the cells were limited to near two-dimensional movement. This system allowed us to image the bacteria directly without extensive preparation or modification, and many of the cells remained alive during imaging. Presented are images of the life cycle in two species of prey organisms, both Escherichia coli (a small prey bacterium that grows two-dimensionally on a surface) and Aquaspirillum serpens (a large prey bacterium that grows three-dimensionally on a surface), including high-resolution images of invaded prey cells called bdelloplasts. We obtained evidence for multiple invasions per prey cell, as well as significant heterogeneity in morphology of bdellovibrios. Mutant host-independent bdellovibrios were observed to have flagella and to excrete a coating that causes the predators to clump together on a surface. Most interestingly, changes in the texture of the cell surface membranes were measured during the course of the invasion cycle. Thus, coupled with our preparation method, atomic force microscopy allowed new observations to be made about Bdellovibrio at an interface. These studies raise important questions about the ways in which bacterial predation at interfaces (air-solid or liquid-solid) may be similar to or different from predation in solution.