P1 bacteriophage and tellurite sensitivity in Klebsiella pneumoniae and Escherichia coli

Klebsiella pneumoniae and Escherichia coli respond inversely toward P1 bacteriophage or TeO3(-2). Klebsiella pneumoniae is resistant to both antagonists and E. coli is sensitive. However, P1 cmts lysogens (P1 cmts resistant) of K. pneumoniae became sensitive to tellurite and when cured from P1 cmts regained resistance. Escherichia coli spontaneous mutants selected for resistance to either P1 or TeO3(-2) were collaterally resistant to the other. As well, TeO3(-3) enhanced the adsorption of P1 vir to both E. coli and K. pneumoniae. Several outer membrane proteins were enhanced in the K. pneumoniae lysogens and were reduced in E. coli lysogens; one of which was the same molecular weight (77 000) in both bacteria. When partially purified it enhanced the plaque efficiency of P1 vir. Lipopolysaccharide (LPS) from E. coli C600 inactivated P1 vir, but neither the P1 lysogens nor LPS derived from the lysogens inactivated P1 vir. Escherichia coli P1 lysogens produced only heptose-deficient LPS. It is suggested that both LPS and outer membrane protein(s) comprise the P1 receptor. TeO3(-2) may interact with one or both components.     

Effect of bacteriophage P1 lysogeny on lipopolysaccharide composition and the lambda receptor of Escherichia coli.

The outer membrane of Escherichia coli was altered as a consequence of lysogeny by bacteriophages P1 and P1 cmts. The predominant change was a reduction in the size of lipopolysaccharide to a heptose-deficient form. P1 cmts lysogens were still sensitive to several bacteriophages but were resistant to lambda vir. Neither whole cells nor solubilized outer membranes from P1 cmts lysogens were able to inactivate lambda vir, and 32P-labeled lambda vir was unable to adsorb to P1 cmts lysogens. P1 cmts lysogens were also affected in maltose transport. The level of periplasmic maltose-binding protein was reduced somewhat, but there was no significant reduction in the level of the outer membrane lambda receptor (LamB). These membrane abnormalities were all corrected in strains cured of P1 cmts. It is suggested that P1 cmts affects lipopolysaccharide biosynthesis by a phage conversion mechanism and consequently the function of the lambda receptor.     

Effects of mutations in the immunity system of bacteriophage P1.

A mutant of bacteriophage P1 that made an altered c1 repressor is described. The mutant c1 product had two configurations: in lysogens, at high temperatures, it permitted constitutive expression of the normally repressed DNA replication function ban and was insensitive to the action of ant, a product expressed by the virulent mutant P1virs and by the heteroimmune phage P7 (formerly phiamp+) and normally able to overcome c1 repression; in mutant lysogens at low temperatures, the mutant repressor was apparently normal (able to repress ban and sensitive to ant action). Genetic studies of this mutant led to the isolation of a derivative that formed unstable lysogens. These studies suggested that the ban product was normally under c1 control; they further showed that ant overcame c1 repression by inactivating c1 rather than by creating a bypass of repressor activity.     

Maintenance of bacteriophage P1 plasmid.

Three mutants of bacteriophage P1 affected in their ability to maintain the lysogenic state stably are described here. These mutants were normal in lytic growth, but lysogenic derivatives segregated nonlysogens at abnormally high rates (1 to 30% per division). Cells harboring these mutant prophages were elongated or filamentous. The mutations responsible for this prophage instability fell into two classes on the bases of their genetic location, their effect on the ability to lysogenize recA bacteria, and their suppressibility by ant mutations eliminating antirepressor activity. The two mutants that were able to form recA lysogens showed the same prophage instability and partial inhibition of cell division in recA as in rec+ lysogens. The fact that plasmid-linked mutations can cause prophage instability suggests that P1 codes for at least some of the functions determining its own autonomy and segregation.     

Conditionally replicating plasmid vectors that can integrate into the Klebsiella pneumoniae chromosome via bacteriophage P4 site-specific recombination.

P4 is a satellite phage of P2 and is dependent on phage P2 gene products for virion assembly and cell lysis. Previously, we showed that a virulent mutant of phage P4 (P4 vir1) could be used as a multicopy, autonomously replicating plasmid vector in Escherichia coli and Klebsiella pneumoniae in the absence of the P2 helper. In addition to establishing lysogeny as a self-replicating plasmid, it has been shown that P4 can also lysogenize E. coli via site-specific integration into the host chromosome. In this study, we show that P4 also integrates into the K. pneumoniae chromosome at a specific site. In contrast to that in E. coli, however, site-specific integration in K. pneumoniae does not require the int gene of P4. We utilized the alternative modes of P4 lysogenization (plasmid replication or integration) to construct cloning vectors derived from P4 vir1 that could exist in either lysogenic mode, depending on the host strain used. These vectors carry an amber mutation in the DNA primase gene alpha, which blocks DNA replication in an Su- host and allows the selection of lysogenic strains with integrated prophages. In contrast, these vectors can be propagated as plasmids in an Su+ host where replication is allowed. To demonstrate the utility of this type of vector, we show that certain nitrogen fixation (nif) genes of K. pneumoniae, which otherwise inhibit nif gene expression when present on multicopy plasmids, do not exhibit inhibitory effects when introduced as merodiploids via P4 site-specific integration.     

Leakage of periplasmic enzymes from lipopolysaccharide-defective mutants of Salmonella typhimurium.

Mutants of Salmonella typhimurium with defects in the heptose region of the lipopolysaccharide (LPS) molecule (heptose-deficient, chemotype Re) leak periplasmic enzymes (acid phosphatase (EC 3.1.3.2), cyclic phosphodiesterase, ribonuclease I (EC 3.1.4.22), and phosphoglucose isomerase (EC 5.3.1.9) (PGI is at least partially periplasmic in E. coli and S. typhimurium; see below)) and do not leak an internal enzyme (glucose-6-phosphate dehydrogenase) into the growth medium. The extent of this leakage is markedly increased at higher temperature (42 degrees C). Leakage of periplasmic enzymes from the strains lacking units distal to heptose I in the LPS molecule (chemotype Rd2) occurs only at 42 degrees C, and not at 30 or 37 degrees C. The extent of leakage of these enzymes from smooth strain and mutants of other LPS chemotypes (Rc, Rd1) is not significant, and is not influenced by growth temperatures. The kinetics of leakage of periplasmic enzymes after shift to 42 degrees C in nutrient broth reveal an accelerated release into the medium from heptose-deficient strains of cyclic phosphodiesterase and ribonuclease I after 30 min at 42 degrees C, and phosphoglucose isomerase after 60 min at 42 degrees C; at 30 degrees C the rate of release of cyclic phosphodiesterase and ribonuclease I is relatively slower. After 60 min at 42 degrees C in nutrient broth, growth of these strains has either slowed down or stopped. In L-broth, which permits the growth of the heptose-deficient strain (SA1377) at 42 degrees C, leakage of cyclic phosphodiesterase and phosphoglucose isomerase occurs, whereas there is no detectable leakage of these enzymes from the isogenic smooth strain (SA1355). Thus, leakage of the periplasmic enzymes from the heptose-deficient strain occurs with or without growth. Mg2+ (0.75 mM), sodium chloride (50 mM), and sucrose (100 mM) in nutrient broth at 42 degrees C prevent the leakage of these enzymes. The shedding of LPS from the heptose-deficient as well as the smooth strains is enhanced by high temperature (42 degrees C), whereas considerable leakage of protein occurs only in the heptose-deficient strain at 42 degrees C and not in the smooth strain. The smooth and heptose-deficient strains are equally sensitive to osmotic shock although a significant proportion of acid phosphatase and cyclic phosphodiesterase activities from the heptose-deficient cells grown at 42 degrees C comes off in the Tris-NaCl wash step suggesting a rather loose attachment of these enzymes onto the cell surface.     

Use of bacteriophage Mu to isolate deletions in the his-nif region of Klebsiella pneumoniae.

Klebsiella pneumoniae M5a1 is naturally resistant to infection by bacteriophage Mu. Mutants of K. pneumoniae sensitive to Mu infection were isolated and found to support both lytic and lysogenic development of Mu. K. pneumoniae lysogens containing a heat-inducible Mu prophage integrated in his were isolated. Strains carrying deletions extending from his into nif were obtained after heat treatment of these lysogens. Such deletions should be useful for determining the map order and cistronic organization of the nif genes.     

Three enzymatic steps required for the galactosamine incorporation into core lipopolysaccharide

The core lipopolysaccharides (LPS) of Proteus mirabilis as well as those of Klebsiella pneumoniae and Serratia marcescens are characterized by the presence of a hexosamine-galacturonic acid disaccharide (αHexN-(1,4)-αGalA) attached by an α1,3 linkage to L-glycero-D-manno-heptopyranose II (L-glycero-α-D-manno-heptosepyranose II). In K. pneumoniae, S. marcescens, and some P. mirabilis strains, HexN is D-glucosamine, whereas in other P. mirabilis strains, it corresponds to D-galactosamine. Previously, we have shown that two enzymes are required for the incorporation of D-glucosamine into the core LPS of K. pneumoniae; the WabH enzyme catalyzes the incorporation of GlcNAc from UDP-GlcNAc to outer core LPS, and WabN catalyzes the deacetylation of the incorporated GlcNAc. Here we report the presence of two different HexNAc transferases depending on the nature of the HexN in P. mirabilis core LPS. In vivo and in vitro assays using LPS truncated at the level of galacturonic acid as acceptor show that these two enzymes differ in their specificity for the transfer of GlcNAc or GalNAc. By contrast, only one WabN homologue was found in the studied P. mirabilis strains. Similar assays suggest that the P. mirabilis WabN homologue is able to deacetylate both GlcNAc and GalNAc. We conclude that incorporation of d-galactosamine requires three enzymes: Gne epimerase for the generation of UDP-GalNAc from UDP-GlcNAc, N-acetylgalactosaminyltransferase (WabP), and LPS:HexNAc deacetylase.     

Lipopolysaccharide O1 antigen contributes to the virulence in Klebsiella pneumoniae causing pyogenic liver abscess

Klebsiella pneumoniae is the common cause of a global emerging infectious disease, community-acquired pyogenic liver abscess (PLA). Capsular polysaccharide (CPS) and lipopolysaccharide (LPS) are critical for this microorganism's ability to spread through the blood and to cause sepsis. While CPS type K1 is an important virulence factor in K. pneumoniae causing PLA, the role of LPS in PLA is not clear. Here, we characterize the role of LPS O antigen in the pathogenesis of K. pneumoniae causing PLA. NTUH-K2044 is a LPS O1 clinical strain; the presence of the O antigen was shown via the presence of 1,3-galactan in the LPS, and of sequences that align with the wb gene cluster, known to produce O-antigen. Serologic analysis of K. pneumoniae clinical isolates demonstrated that the O1 serotype was more prevalent in PLA strains than that in non-tissue-invasive strains (38/42 vs. 9/32, P<0.0001). O1 serotype isolates had a higher frequency of serum resistance, and mutation of the O1 antigen changed serum resistance in K. pneumoniae. A PLA-causing strain of CPS capsular type K2 and LPS serotype O1 (i.e., O1:K2 PLA strain) deleted for the O1 synthesizing genes was profoundly attenuated in virulence, as demonstrated in separate mouse models of septicemia and liver abscess. Immunization of mice with the K2044 magA-mutant (K(1) (-) O(1)) against LPS O1 provided protection against infection with an O1:K2 PLA strain, but not against infection with an O1:K1 PLA strain. Our findings indicate that the O1 antigen of PLA-associated K. pneumoniae contributes to virulence by conveying resistance to serum killing, promoting bacterial dissemination to and colonization of internal organs after the onset of bacteremia, and could be a useful vaccine candidate against infection by an O1:K2 PLA strain.     

The Klebsiella pneumoniae wabG gene: role in biosynthesis of the core lipopolysaccharide and virulence

To determine the function of the wabG gene in the biosynthesis of the core lipopolysaccharide (LPS) of Klebsiella pneumoniae, we constructed wabG nonpolar mutants. Data obtained from the comparative chemical and structural analysis of LPS samples obtained from the wild type, the mutant strain, and the complemented mutant demonstrated that the wabG gene is involved in attachment to alpha-L-glycero-D-manno-heptopyranose II (L,D-HeppII) at the O-3 position of an alpha-D-galactopyranosyluronic acid (alpha-D-GalAp) residue. K. pneumoniae nonpolar wabG mutants were devoid of the cell-attached capsular polysaccharide but were still able to produce capsular polysaccharide. Similar results were obtained with K. pneumoniae nonpolar waaC and waaF mutants, which produce shorter LPS core molecules than do wabG mutants. Other outer core K. pneumoniae nonpolar mutants in the waa gene cluster were encapsulated. K. pneumoniae waaC, waaF, and wabG mutants were avirulent when tested in different animal models. Furthermore, these mutants were more sensitive to some hydrophobic compounds than the wild-type strains. All these characteristics were rescued by reintroduction of the waaC, waaF, and wabG genes from K. pneumoniae.     

Prophage substitution and prophage loss from superinfected Escherichia coli recA(P1) lysogens.

It is shown that the plasmid prophage P1 can be displaced by a superinfecting P1 phage in Escherichia coli recA(P1) lysogens. Six widely separated phage markers were used to distinguish between residual recombination and total substitution. It is further shown that superinfection of recA lysogens can lead to loss of both phage (curing). These two phenomena, previously reported in Rec+ strains, are thus independent of host recombination and may result from perturbations of some function involved in plasmid maintenance.     

Construction of intergeneric hybrids using bacteriophage P1CM: transfer of the Klebsiella aerogenes ribitol dehydrogenase gene to Escherichia coli.

Study of many of the interesting properties of Klebsiella aerogenes is limited by the lack of a well-characterized genetic system for this organism. Our investigations of the evolution of the enzyme ribitol dehydrogenase (EC 1.1.1.56) in K. aerogenes would be greatly facilitated by the availability of such a system, and we here report two approaches to developing one. We have isolated mutants sensitive to the coliphage P1, which will efficiently tranduce genetic markers between such sensitive strains and which will thus make detailed mapping studies possible. Derivatives of K. aerogenes lysogenic for P1 can be readily isolated by using the specialized transducing particle P1CMclr100. Bacteria lysogenic for this phage are chloramphenicol resistant and temperature sensitive. Phage particles produced by temperature induction of such lysogens can be used to transfer K. aerogenes genes to the natural host of P1 phage. Escherichia coli. We have used this method to prepare derivatives of E. coli K-12 carrying the K. aerogenes genes conferring the ability to metabolize the pentitols ribitol and D-arabitol. We have shown that these E. coli-K. aerogenes hybrids synthesize a ribitol dehydrogenase with the properties of the K. aerogenes enzyme and have mapped the position of the transferred gene on the E. coli chromosome. The ramifications of this methodology are discussed.     

The incorporation of glucosamine into enterobacterial core lipopolysaccharide: two enzymatic steps are required

The core lipopolysaccharide (LPS) of Klebsiella pneumoniae is characterized by the presence of disaccharide alphaGlcN-(1,4)-alphaGalA attached by an alpha1,3 linkage to l-glycero-d-manno-heptopyranose II (ld-HeppII). Previously it has been shown that the WabH enzyme catalyzes the incorporation of GlcNAc from UDP-GlcNAc to outer core LPS. The presence of GlcNAc instead of GlcN and the lack of UDP-GlcN in bacteria indicate that an additional enzymatic step is required. In this work we identified a new gene (wabN) in the K. pneumoniae core LPS biosynthetic cluster. Chemical and structural analysis of K. pneumoniae non-polar wabN mutants showed truncated core LPS with GlcNAc instead of GlcN. In vitro assays using LPS truncated at the level of d-galacturonic acid (GalA) and cell-free extract containing WabH and WabN together led to the incorporation of GlcN, whereas none of them alone were able to do it. This result suggests that the later enzyme (WabN) catalyzes the deacetylation of the core LPS containing the GlcNAc residue. Thus, the incorporation of the GlcN residue to core LPS in K. pneumoniae requires two distinct enzymatic steps. WabN homologues are found in Serratia marcescens and some Proteus strains that show the same disaccharide alphaGlcN-(1,4)-alphaGalA attached by an alpha1,3 linkage to ld-HeppII.     

Plasmid mode of propagation of the genetic element P4

The satellite bacteriophage P4, in the presence of a helper phage, can enter either the lytic or the lysogenic cycle. In the absence of the helper, P4 can integrate in the bacterial chromosome. In addition, the partially immunity-insensitive mutant P4 vir1 maintained as a plasmid.We have found that in the absence of the helper, P4 wt also can be maintained as a plasmid, and that both P4 wt and P4 vir1 have two options for their intracellular propagation: a repressed-integrated or a derepressed-high copy number plasmid mode of maintenance. In the repressed mode, the P4 wt genome is only found integrated into the bacterial chromosome, while the P4 vir1 is found also as a low copy number plasmid coexisting with the integrated P4 vir1 genome. The clones carrying P4 in the derepressed-high copy number plasmid state are obtained at low frequency (0.3%) upon infection with P4 wt, while the vir1 mutation increases this frequency about 300-fold. Such clones can be distinguished easily because of their typical colony morphology (rosettes), due to the presence of filamentous cells. Filamentation of the bacterial host suggests that the presence of derepressed P4 genomes in high copy number interferes with the normal cell division mechanism.The derepressed clones are rather stable, but may revert spontaneously to the repressed state. Spontaneous transition from the repressed to the derepressed state was not observed; however, it can be induced by P2 or P4 vir1 superinfection of P4 wt and P4 vir1 lysogens or by growing the P4 vir1 lysogens up to the late exponential phase.The ability of P4 to choose either of two stable states and the potential to shift between these two modes of propagation indicate that the syntesis of the immunity repressor is regulated.     

Chemical and biological characterization of lipopolysaccharides from the Pseudomonas syringae pv. maculicola IMV 381 collection culture and its dissociants

Lipopolysaccharides (LPS) were isolated from the crude bacterial mass of the Pseudomonas syringae pv. maculicola IMV 381 collection culture and its virulent and avirulent subcultures isolated earlier from the heterogeneous collection culture due to its natural variability during long-term storage. The composition, immunochemical properties, and certain parameters of the biological activity of the LPS preparations obtained were studied. The structural parts of the LPS macromolecule--lipid A, the core oligosaccharide, and O-specific polysaccharide (OPS)--were isolated and characterized. The following fatty acids were identified in the lipid A composition of all cultures: 3-OH-C10:0, C12:0, 2-OH-C12:0, 3-OH-C12:0, C16:1, C16:0, C18:1, and C18:0. Glucosamine (GlcN), ethanolamine (EtN), phosphoethanolamine (EtN-P), and phosphorus (P) were revealed in the hydrophilic portion of the macromolecule. In the core portion of the LPS macromolecule, glucose (Glc), rhamnose (Rha), GlcN, galactosamine (GalN), 2-keto-3-deoxyoctulosonic acid (KDO), alanine (Ala), and P were found. The peculiarities of the structure of LPS isolated from the stable collection culture (LPS(stab)) and its virulent (LPS(vir)) and avirulent (LPS(air)) subcultures were studied. LPS(vir) and LPS(avir) were identical in the monosaccharide composition and contained as the main components L-rhamnose (L-Rha) and 3-acetamido-3,6-dideoxy-D-galactose (D-Fuc3NAc), like LPS(stab) studied earlier. The NMR spectra of LPS(vir) were identical to the spectra of LPS(stab), whose O-chain repeating unit structure was studied by us earlier, whereas LPS(avir) differed from LPS(vir) in the NMR spectrum and was identified by us as the SR form. LPS(avir) was serologically identical to LP(stab) and LPS(vir). Hence, the degree of polymerism of the LPS O-chain of P. syringae pv. maculicola IMV 381 is the main virulence factor in the infected model plants. Serological relationships were studied between P. syringae pv. maculicola IMV 381 and the strains of other pathovars with structurally similar LPS.     

Plaque forming specialized transducing phage P1: Isolation of P1CmSmSu, a precursor of P1Cm

Summary E. coli strains lysogenic for various types of P1-R hybrids were isolated. These carry all the essential genes for vegetative phage production and lysogenization including P1 immunity and P1 incompatibility, together with drug resistance genes derived from the R plasmid NR1. In particular, P1Cm and P1CmSmSu derivatives were studied. When strains lysogenic for these phages were induced in the absence of helper phage, yields of phage particles as high as with wild type P1 were obtained. All P1Cm phages isolated were of plaque forming type and usually every plaque contained Cm^r lysogens. Lysates of P1CmSmSu lysogens transduced Cm^rSm^rSu^r at high frequency and they formed plaques with an efficiency of 10^-4 to 10^-2 per phage particle. Only a minority of these plaques contained drug resistant bacteria. Cm^rSm^rSu^r transductants isolated from bacteria infected at a high multiplicity with phage P1CmSmSu were lysogens for the original P1CmSmSu. In contrast, Cm^rSm^rSu^r transductants isolated after infection at low multiplicity appeared to carry the Cm^rSm^rSu^r markers integrated into the host chromosome. The results described suggest that P1CmSmSu prophages carry the resistance genes transposed into the P1 genome without in principle causing a loss of essential gene functions. However, since these prophages are longer than the wild type P1 genome, the DNA packaged into phage particles has a reduced redundancy which seriously affects the reproduction and lysogenization abilities.Plaque forming P1Cm can be obtained from P1CmSmSu. Thus, P1CmSmSu is a precursor of P1Cm. P1Cm is also obtainable from P1 and NR1 under the recA ^- condition. The mechanism of formation of plaque forming P1Cm is discussed.     

Reproductive fitness of P1, P2, and Mu lysogens of Escherichia coli.

P1, P2, and Mu lysogens of Escherichia coli reproduce more rapidly than nonlysogens during aerobic growth in glucose-limited chemostats. Thus, prophage-containing stains of E. coli are reproductively more fit than the corresponding nonlysogens. If mixed populations are grown by serial dilution under conditions in which growth is not limited, both the lysogen and nonlysogen manifest identical growth rates. The increased fitness of the lysogens in glucose-limited chemostats correlates with a higher metabolic activity of the lysogen as compared with the nonlysogen during glucose exhaustion. We propose that P1, P2, Mu, and lambda prophage all confer an evolutionarily significant reproductive growth advantage to E. coli lysogenic strains.     

Amplification of chloramphenicol resistance transposons carried by phage P1Cm in Escherichia coli.

Summary We have characterized a number of P1Cm phages which contain the resistance genes to chloramphenicol and fusidic acid as IS1-flanked Cm transposons. Restriction cleavage and electron microscopic analysis showed that these Cm transposons were carried as monomers (M) or tandem dimers (D). Lysogens of P1Cm (D) are more resistant to chloramphenicol than those of its P1Cm (M) presumably as a result of an increased gene dosage. Amplification of the Cm transposons to tandem multimers was frequently observed in P1Cm (D) lysogens grown in the presence of high concentrations of chloramphenicol or fusidic acid and was also detected in P1Cm (M) lysogens. The degree of amplification varied in different clones which suggests that cells containing spontaneously amplified Cm transposons were selected by high doses of the antibiotics. The dimeric as well as the amplified Cm transposons carried in P1Cm lysogens grown in the absence of chloramphenicol displayed considerable stability. Mechanisms for the amplification of the IS1-flanked transposons are discussed.     

X-ray sensitivity of Escherichia coli lysogenic for bacteriophage P2.

Summary Strains of Escherichia coli C or K lysogenic for the non-inducible phage P2 show a lower survival following X-ray irradiation as compared to nonlysogenic strains. This difference in X-ray sensitivity is not accompanied by a significant difference in X-ray induced mutability. The capacity of X-irradiated P2 lysogens to multiply any of a number of unirradiated infecting phages is severely impaired. These effects of X-ray treatment can be most simply explained as a consequence of the fact that protein and RNA syntheses are strongly inhibited in P2 lysogens after X-irradiation. All the above events specifically occurring in X-rayed P2 lysogens are dependent on the P2 gene old.