Ribonucleic acid destruction and synthesis during intraperiplasmic growth of Bdellovibrio bacteriovorus.

During growth of Bdellovibrio bacteriovorus on (2-14C)uracil-labeled Escherichia coli approximately 50% of the radioactivity is incorporated by the bdellovibrio and most of the remainder is released as free nucleic acid bases. Kinetic studies showed that 50 and 30S ribosomal particles and 23 and 16S ribosomal ribonucleic acid (RNA) of E. coli are almost completely degraded by the first 90 min in a 210- to 240-min bdellovibrio developmental cycle. Synthesis of bdellovibrio ribosomal RNA was first detected after 90 min. The specific activity and the ratio of radioactivity in the bases of the synthesized bdellovibrio RNA was essentially the same as those of the substrate E. coli. The total radioactivity of the bdellovibrio deoxyribonucleic acid (DNA) exceeded that in the DNA of the substrate E. coli cell, and the ratio of radioactivity of cytosine to thymine residues differed. Intraperiplasmic growth of B. bacteriovorus in the presence of added nucleoside monophosphates (singly or in combination) significantly decreased the uptake of radioactivity from (2-14C)uracil-labeled E. coli; nucleosides or nucleic acid bases did not. It is concluded that the RNA of the substrate cell, in the form of nucleoside monophosphates, is the major or exclusive precursor of the bdellovirbrio RNA and also serves as a precursor for some of the bdellovibrio DNA.     

Intraperiplasmic growth of Bdellovibrio bacteriovorus on heat-treated Escherichia coli.

Heat treatment (55 degrees C for 40 min) of cell suspensions in buffer (ca. 3 x 10(9) cells per ml) of Escherichia coli ML35 caused a 4- to 4.5-log loss of cell viability. Similar results were found for several other E. coli strains that were examined. As a result of this heat treatment, 260-nm- and 280-nm-absorbing materials were released into the suspending buffer, along with about 10% of the total cellular radioactivity, when cells uniformly labeled with (14)C were used. In comparison with untreated cells, heat-treated E. coli ML35 cells showed (i) no significant changes in macromolecular composition other than ca. 22% less RNA content, (ii) an increased permeability to o-nitrophenyl-beta-d-galactopyranoside (a compound to which untreated cells are impermeable), (iii) almost complete loss of respiratory potential, and (iv) substantial losses of numerous glycolytic enzyme activities in cell extracts prepared from these cells. Intraperiplasmic development of Bdellovibrio bacteriovorus 109J with heat-treated E. coli ML35 as substrate cells appeared normal when observed microscopically, although bdellovibrio attachment and resultant bdelloplast formation were slightly retarded. No significant changes were observed in cell yields or in the ratios and contents of DNA, RNA, or protein between bdellovibrios harvested from untreated cells and those from heat-treated substrate cells after single-developmental-cycle growth on these cells. The average Y(ATP) values for intraperiplasmic growth on untreated and heat-treated substrate cells were 16.0 and 17.9, respectively. It is concluded that intraperiplasmic bdellovibrio growth on gently heat-treated E. coli substrate cells is very similar to growth on untreated substrate cells, even though the former substrate cells are nonviable and substantially impaired in many metabolic activities.     

Intraperiplasmic growth of Bdellovibrio bacteriovorus 109J: solubilization of Escherichia coli peptidoglycan.

During penetration of Bdellovibrio bacteriovorus into Escherchia coli, two enzymatic activities, a glycanase and a peptidase, rapidly solubilized some 10 to 15% of the E. coli peptidoglycan. The glycanase activity, which solubilizes peptidoglycan amino sugars, came to a sharp halt with completion of the penetration process. Peptidase activity, which cleaves diaminopimelic acid residues from the peptidoglycan, continued, but at a decreasing rate. By 90 min after bdellovibrio attack, some 30% of the initial E. coli diaminopimelic acid residues were solubilized and present in the culture fluid as free diaminopimelic acid. During bdellovibrio penetration some 25% of the lipopolysaccharide glucosamine was also solubilized by an as yet undefined enzymatic activity that yielded products having molecular weights below 2,000. The solubilization of E. coli lipopolysaccharide glucosamine also terminated at completion of bdellovibrio penetration. At the end of bdellovibrio growth, a second period of rapid solubilization of bdelloplast peptidoglycan began which resulted in lysis of the bdelloplast and complete solubilization of the peptidoglycan amino sugars and diaminopimelic acid. The final lytic enzyme(s) was synthesized just before the time of lysis.     

Regulated breakdown of Escherichia coli deoxyribonucleic acid during intraperiplasmic growth of Bdellovibrio bacteriovorus 109J.

During growth of Bdellovibrio bacteriovorus on [2-14C]deoxythymidine-labeled Escherichia coli, approximately 30% of the radioactivity was released to the culture fluid as nucleoside monophosphates and free bases; the remainder was incorporated by the bdellovibrio. By 60 min after bdellovibrio attack, when only 10% of the E. coli deoxyribonucleic acid (DNA) had been solubilized, the substrate cell DNA was degraded to 5 X 10(5)-dalton fragments retained within the bdelloplast. Kinetic studies showed these fragments were formed as the result of sequential accumulation of single- and then double-strand cuts. DNA fragments between 2 X 10(3) and 5 X 10(5) daltons were never observed. Chloramphenicol, added at various times after initiation of bdellovibrio intraperiplasmic growth on normal or on heated E. coli, which have inactivated deoxyribonucleases, inhibited further breakdown and solubilization of substrate cell DNA. Analysis of these intraperiplasmic culture deoxyribonuclease activities showed that bdellovibrio deoxyribonucleases are synthesized while E. coli nucleases are inactivated. It is concluded that continuous and sequential synthesis of bdellovibrio deoxyribonucleases of apparently differing specificities is necessary for complete breakdown and solubilization of substrate cell DNA, and that substrate cell deoxyribonucleases are not involved in any significant way in the degradation process.     

Kinetics of deoxyribonucleic acid destruction and synthesis during growth of Bdellovibrio bacteriovorus strain 109D on pseudomonas putida and escherichia coli

During the growth of Bdellovibrio bacteriovorus on Pseudomonas putida or Escherichia coli in either 10(-3)m tris(hydroxymethyl)aminomethane or in dilute nutrient broth, the host deoxyribonucleic acid (DNA) was rapidly degraded, and by 30 to 60 min after the initiation of the bdellovibrio development cycle essentially all host DNA became nonbandable in CsCl gradients. At this stage the host DNA degradation products were nondiffusable, and there was no appreciable pool of low-molecular-weight (cold acid soluble) DNA fragments in the cells or in the suspending medium. Bdellovibrio DNA synthesis occurred only after degradation of host DNA to a nonbandable form was complete. The synthesis occurred in a continuous fashion with P. putida as the host and in two separate periods with E. coli as host. By using E. coli containing a (3)H-thymidine label, it was shown that 73%, on the average, of the thymine residues of host DNA were incorporated into bdellovibrio DNA when E. coli was the only source of nutrient. In the presence of dilute nutrient broth, the host cells still served as the major source of precursors for bdellovibrio DNA synthesis, with only 20% of the precursors arising from the exogenous nutrients. The data indicate an efficient and controlled utilization of host DNA by the bdellovibrio. The host DNA is apparently degraded early in the developmental cycle to oligonucleotides of intermediate molecular weight from which the biosynthetic monomers are generated only as they become needed for bdellovibrio DNA synthesis.     

Permeability of the boundary layers of Bdellovibrio bacteriovorus 109J and its bdelloplasts to small hydrophilic molecules.

Measurements of the sucrose-permeable and -impermeable volumes during Bdellovibrio bacteriovorus attack on Escherichia coli or Pseudomonas putida showed that the volume of the bdelloplast increased over that of the substrate cell. Although the pattern of the increase differed with the two organisms, the volumes reached maximum at about 60 min into the bdellovibrio growth cycle. By this time, the cytoplasmic membranes of the attacked cells were completely permeable to sucrose. The kinetics of increase in sucrosepermeable volumes were similar to the kinetics of attachment and penetration (Varon and Shilo, J. Bacteriol. 95:744-753, 1968). These data show that the original cytoplasmic and periplasmic compartmentalization of the substrate cell ceases to exist with respect to small hydrophilic molecules during bdellovibrio attack. In contrast, the effective pore size of the outer membrane of the substrate cell to small oligosaccharides remains unaltered during bdelloplast formation as was shown by direct measurements of its exclusion limits. The major porin protein of E. coli, OmpF, was recoverable from the bdelloplast outer membrane fraction until the onset of lysis. The Braun lipoprotein was removed from the bdelloplast wall early, and OmpA was lost in the terminal part of the bdellovibrio growth cycle.     

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.     

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.     

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.     

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.     

Attachment of diaminopimelic acid to bdelloplast peptidoglycan during intraperiplasmic growth of Bdellovibrio bacteriovorus 109J.

An early event in the predatory lifestyle of Bdellovibrio bacteriovorus 109J is the attachment of diaminopimelic acid (DAP) to the peptidoglycan of its prey. Attachment occurs over the first 60 min of the growth cycle and is mediated by an extracellular activity(s) produced by the bdellovibrio. Some 40,000 DAP residues are incorporated into the Escherichia coli bdelloplast wall, amounting to ca. 2 to 3% of the total initial DAP content of its prey cells. Incorporation of DAP occurs when E. coli, Pseudomonas putida, or Spirillum serpens are the prey organisms. The structurally similar compounds lysine, ornithine, citrulline, and 2,4-diaminobutyric acid are not attached. The attachment process is not affected by heat-killing the prey nor by the addition of inhibitors of either energy generation (cyanide, azide, or arsenate), protein or RNA synthesis (chloramphenicol and rifamycin), or de novo synthesis of cell wall (penicillin or vancomycin). Approximately one-third of the incorporated DAP is exchangeable with exogenously added unlabeled DAP, whereas the remaining incorporated DPA is solubilized only during the lysis of the bdelloplast wall. Examination of DAP incorporation at low prey cell densities suggests that bdellovibrios closely couple the incorporation to an independent, enzymatic solubilization of DAP by a peptidase. The data indicate that DAP incorporation is a novel process, representing the second example of the ability of the bdellovibrio to biosynthetically modify the wall of its prey.     

A soluble enzyme activity that attaches free diaminopimelic acid to bdelloplast peptidoglycan

An enzyme activity, responsible for the attachment of diaminopimelic acid (DAP) to bdelloplast wall peptidoglycan, was studied in an in vitro, cell-free system. Most of the activity was found in the high-speed (20000g) supernatant fraction of homogenates of bdelloplasts prepared from a culture of the intracellular bacterium Bdellovibrio bacteriovorus 109J, growing synchronously within cells of Escherichia coli. Peptidoglycan preparations obtained either from E. coli ML35 or from the walls of bdelloplasts synchronously cultured for 40 or 90 min served as the acceptors in this reaction, whereas cell wall or peptidoglycan preparations obtained from Gram-positive bacteria could not function as acceptors of DAP. The attachment activity had an apparent Km value for DAP of 10 microM; for bdelloplast peptidoglycan, it was approximately 0.43 mg/mL, which is 13 microM with respect to peptidoglycan disaccharide peptide units. DAP attachment was partially inhibited by the structural analogues lanthionine, L-ornithine, beta-aminobutyric acid, and D-serine, as well as the cell wall synthesis inhibitors penicillin G, ampicillin, and cephalexin. This enzyme activity is present only during the intracellular stage of the bdellovibrio's developmental growth cycle and may serve a stage-specific function of biochemically modifying the cell in which it grows.     

Change in the surface hydrophobicity of substrate cells during bdelloplast formation by Bdellovibrio bacteriovorus 109J.

During intraperiplasmic growth of Bdellovibrio bacteriovorus 109J, the substrate cell surface becomes more hydrophobic. This was shown (i) by comparing the sensitivity to hydrophobic antibiotics of wild-type and lipopolysaccharide mutant strains of Salmonella typhimurium to that of the bdellovibrio growing on these strains and (ii) by measuring the binding efficiency of these strains, Escherichia coli, and their derived bdelloplasts to octyl Sepharose. The kinetics of increase in surface hydrophobicity was similar to the kinetics of the conversion of the substrate cell peptidoglycan to a lysozyme-resistant form (M. Thomashow and S. Rittenberg, J. Bacteriol. 135:1008-1014, 1978), and hydrophobicity reached a maximum at about 60 min in a synchronous culture. The change in hydrophobicity was inhibited by chloramphenicol, suggesting that bdellovibrio protein synthesis was required. Control experiments revealed that the free-swimming bdellovibrio had a more hydrophobic surface than the deep rough mutants of S. typhimurium.     

Intraperiplasmic growth of Bdellovibrio bacteriovorus 109J: attachment of long-chain fatty acids to escherichia coli peptidoglycan.

During the initial stages of intraperiplasmic growth of Bdellovibrio bacteriovorus on Escherichia coli, the peptidoglycan of the E. coli becomes acylated with long-chain fatty acids, primarily palmitic acid (60%) and oleic acid (20%). The attachment of the fatty acids to the peptidoglycan involves a carboxylic-ester bond, i.e., they were removed by treatment with alkaline hydroxylamine. Their linkage to the peptidoglycan does not involve a protein molecule. When the bdelloplast peptidoglycan was digested with lysozyme, the fatty acid-containing split products behaved as lipopeptidoglycan, i.e., they were extracted into the organic phase of 1-butanol:acetic acid:water (4:15) two-phase system; all of the lysozyme split products generated from normal E. coli peptidoglycan were extracted into the water phase. It is suggested that the function of the acylation reaction is to help stabilize the bdelloplast outer membrane against osmotic forces. In addition, a model is presented to explain how a bdellovibrio penetrates, stabilizes, and lyses a substrate cell.     

Partial characterization of lipid A of intraperiplasmically grown Bdellovibrio bacteriovorus.

The lipid A components of substrate cell origin incorporated by Bdellovibrio bacteriovorus during intraperiplasmic growth (D. R. Nelson and S. C. Rittenberg, J. Bacteriol. 147:860-868, 1981) were shown to be integrated into its lipopolysaccharide structure. Lipid A isolated from bdellovibrios grown on Escherichia coli was resolved into two fractions by thin-layer chromatography. Fraction 2 had the same Rf as the single lipid A fraction of axenicaly grown bdellovibrios, and both stained identically with aniline-diphenylamine reagent. Fraction 1 resembled, in Rf and staining reaction, the slower migrating of two lipid A fractions obtained from the E.coli used as the substrate cell. Both fractions 1 and 2 contained glucosamine, a substrate cell-derived compound. Greater than 65% of the fatty acids in fraction 1 were derived from the substrate cell, whereas more than 60% of the fatty acids of fraction 2 were synthesized by the bdellovibrio. Nevertheless, each fraction contained significant amounts of fatty acid of both origins. The substrate cell-derived fatty acids had the same distribution of N-acyl and O-acyl linkages as in E. coli lipid A. The data indicate that the two lipid A moieties in lipopolysaccharide of intraperiplasmically grown bdellovibrios are hybrids of substrate cell-derived and bdellovibrio-synthesized components. The data also suggest that disaccharide units and N- and O-acyl linkages preexisting in the substrate cell lipid A may be conserved. A possible explanation for the unequal distribution of substrate cell-derived material in the two lipid A fractions of the bdellovibrio is suggested.     

Deoxyribonucleic Acid Characterization of Bdellovibrios

The guanine plus cytosine (GC) content of the deoxyribonucleic acid (DNA) of 11 isolates of host-dependent (H-D) bdellovibrios and 18 host-independent (H-I) derivatives was determined from thermal denaturation curves and buoyant densities in CsCl. The H-D and respective H-I cultures have GC contents which are identical within the limits of experimental error. Most cultures of Bdellovibrio bacteriovorus, including the holotype culture, have 50.4 +/- 0.9 moles% GC in their DNA; two bdellovibrio isolates of presently uncertain nomenclatural status contain DNA of about 43% GC. Optical melting profiles of all the DNA from all of these organisms are particularly steep, indicating little compositional heterogeneity. Chromatography of acid hydrolysates of Bdellovibrio nucleic acids reveal no unusual components. The DNA content per cell of one H-I derivative is about one-third the amount per Escherichia coli cell growing at a comparable rate.     

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.     

Incorporation of Substrate Cell Lipid A Components into the Lipopolysaccharide of Intraperiplasmically Grown Bdellovibrio bacteriovorus

The composition of Bdellovibrio bacteriovorus lipopolysaccharide (LPS) was determined for cells grown axenically and intraperiplasmically on Escherichia coli or Pseudomonas putida. The LPS of axenically grown bdellovibrios contained glucose and fucosamine as the only detectable neutral sugar and amino sugar, and nonadecenoic acid (19:1) as the predominant fatty acid. Additional fatty acids, heptose, ketodeoxyoctoic acid, and phosphate were also detected. LPS from bdellovibrios grown intraperiplasmically contained components characteristic of both axenically grown bdellovibrios and the substrate cells. Substrate cell-derived LPS fatty acids made up the majority of the bdellovibrio LPS fatty acids and were present in about the same proportions as in the substrate cell LPS. Glucosamine derived from E. coli LPS amounted to about one-third of the hexosamine residues in intraperiplasmically grown bdellovibrio LPS. However, galactose, characteristic of the E. coli outer core and O antigen, was not detected in the bdellovibrio LPS, suggesting that only lipid A components of the substrate cell were incorporated. Substrate cell-derived and bdellovibrio-synthesized LPS materials were conserved in the B. bacteriovorus outer membrane for at least two cycles of intraperiplasmic growth. When bdellovibrios were grown on two different substrate cells successively, lipid A components were taken up from the second while the components incorporated from the lipid A of the first were conserved in the bdellovibrio LPS. The data show that substrate cell lipid A components were incorporated into B. bacteriovorus lipid A during intraperiplasmic growth with little or no change, and that these components, fatty acids and hexosamines, comprised a substantial portion of bdellovibrio lipid A.     

Factors affecting the intracellular parasitic growth of Bdellovibrio bacteriovorus developing within Escherichia coli

A procedure for one-step growth experiments on Bdellovibrio bacteriovorus growing parasitically in Escherichia coli B was developed. The resulting one-step growth curves showed that, under defined conditions at 30 C, each singly infected E. coli host cell, on the average, gave rise to 5.7 Bdellovibrio cells. This value was confirmed by single-burst experiments and by microscopic observations. In the temperature range of 25 to 38 C, the average burst size and the duration of the latent period were inversely proportional to the temperature. The effect of hydrogen ion concentration on the one-step growth kinetics in this system indicated a broad pH optimum, ranging from neutrality to slightly alkaline pH values. After Bdellovibrio cells and host cells were mixed, there was always a delay (the so-called "lag phase") before the parasite titer increased in terms of plaque-forming units. Phase-contrast microscopic observations indicated that this delay stems in part from the polyphasic nature of the Bdellovibrio life cycle. We propose the following five terms to make explicit the sequence of events in this life cycle: "attachment," "penetration," "elongation," "fragmentation," and "burst." Nutritional experiments revealed that Bdellovibrio obtains a major fraction of its cellular components from host-cell material. Infection of E. coli by Bdellovibrio without added Mg(++) or Ca(++) (0.003 m Mg(++), 0.002 m Ca(++)) resulted in partial or total lysis of the host cell soon after infection. Protoplast integrity was necessary for the normal completion of the intracellular growth phase of Bdellovibrio in E. coli; normal development of the parasite took place only in the presence of Mg(++) or Ca(++).     

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.