Amphipols: polymeric surfactants for membrane biology research

Membrane proteins classically are handled in aqueous solutions as complexes with detergents. The dissociating character of detergents, combined with the need to maintain an excess of them, frequently results in more or less rapid inactivation of the protein under study. Over the past few years, we have endeavored to develop a novel family of surfactants, dubbed amphipols (APs). APs are amphiphilic polymers that bind to the transmembrane surface of the protein in a noncovalent but, in the absence of a competing surfactant, quasi-irreversible manner. Membrane proteins complexed by APs are in their native state, stable, and they remain water-soluble in the absence of detergent or free APs. An update is presented of the current knowledge about these compounds and their demonstrated or putative uses in membrane biology.

Cryptococcus neoformans interactions with amoebae suggest an explanation for its virulence and intracellular pathogenic strategy in macrophages

Cryptococcus neoformans (Cn) is a soil fungus that causes life-threatening meningitis in immunocompromised patients and is a facultative intracellular pathogen capable of replication inside macrophages. The mechanism by which environmental fungi acquire and maintain virulence for mammalian hosts is unknown. We hypothesized that the survival strategies for Cn after ingestion by macrophages and amoebae were similar. Microscopy, fungal and amoebae killing assays, and phagocytosis assays revealed that Cn is phagocytosed by and replicates in Acanthamoeba castellanii, which leads to death of amoebae. An acapsular strain of Cn did not survive when incubated with amoebae, but melanization protected these cells against killing by amoebae. A phospholipase mutant had a decreased replication rate in amoebae compared with isogenic strains. These observations suggest that cryptococcal characteristics that contribute to mammalian virulence also promote fungal survival in amoebae. Intracellular replication was accompanied by the accumulation of polysaccharide containing vesicles similar to those described in Cn-infected macrophages. The results suggest that the virulence of Cn for mammalian cells is a consequence of adaptations that have evolved for protection against environmental predators such as amoebae and provide an explanation for the broad host range of this pathogenic fungus.

Icm/dot-dependent upregulation of phagocytosis by Legionella pneumophila

Legionella pneumophila is the causative agent of Legionnaires' disease, a severe pneumonia. Dependent on the icm/dot loci, L. pneumophila survives and replicates in macrophages and amoebae within a specialized phagosome that does not fuse with lysosomes. Here, we report that phagocytosis of wild-type L. pneumophila is more efficient than uptake of icm/dot mutants. Compared with the wild-type strain JR32, about 10 times fewer icm/dot mutant bacteria were recovered from HL-60 macrophages in a gentamicin protection assay. The defect in phagocytosis of the mutants could be complemented by supplying the corresponding genes on a plasmid. Using fluorescence microscopy and green fluorescent protein (GFP)-expressing strains, 10-20 times fewer icm/dot mutant bacteria were found to be internalized by HL-60 cells and human monocyte-derived macrophages (HMMPhi). Compared with icm/dot mutants, wild-type L. pneumophila infected two to three times more macrophages and yielded a population of highly infected host cells (15-70 bacteria per macrophage) that was not observed with icm/dot mutant strains. Wild-type and icmT mutant bacteria were found to adhere similarly and compete for binding to HMMPhi. In addition, wild-type L. pneumophila was also phagocytosed more efficiently by Acanthamoeba castellanii, indicating that the process is independent of adherence receptor(s). Wild-type L. pneumophila enhanced phagocytosis of an icmT mutant strain in a synchronous co-infection, suggesting that increased phagocytosis results from (a) secreted effector(s) acting in trans.

Phagocytosis of wild-type Legionella pneumophila occurs through a wortmannin-insensitive pathway

Wild-type Legionella pneumophila grows in human macrophages within a replicative phagosome, avoiding lysosomal fusion, while nonreplicative mutants are killed in lysosomes. Wortmannin, a phosphatidylinositol 3-kinase (PI3K) inhibitor, blocks phagocytosis of an avirulent mutant, but not of wild-type L. pneumophila, without affecting membrane ruffling and actin polymerization. These results show that wild-type and mutant Legionella strains use different entry pathways. They suggest that PI3Ks are involved in phagocytosis of an avirulent L. pneumophila mutant and regulate the ability of microorganisms to generate a replicative phagosome.

The detergent-soluble maltose transporter is activated by maltose binding protein and verapamil

The maltose transporter FGK2 complex of Escherichia coli was purified with the aid of a glutathione S-transferase molecular tag. In contrast to the membrane-associated form of the complex, which requires liganded maltose binding protein (MBP) for ATPase activity, the purified detergent-soluble complex exhibited a very high level of ATPase activity. This uncoupled activity was not due to dissociation of the MalK ATPase subunit from the integral membrane protein MalF and MalG subunits. The detergent-soluble ATPase activity of the complex could be further stimulated by wild-type MBP but not by a signaling-defective mutant MBP. Wild-type MBP increased the V(max) of the ATPase 2.7-fold but had no effect on the K(m) of the enzyme for ATP. When the detergent-soluble complex was reconstituted in proteoliposomes, it returned to being dependent on MBP for activation of ATPase, consistent with the idea that the structural changes induced in the complex by detergent that result in activation of the ATPase are reversible. The uncoupled ATPase activity resembled the membrane-bound activity of the complex also with respect to sensitivity to NaN(3), as well as a mercurial, p-chloromercuribenzosulfonic acid. Verapamil, a compound that activates the ATPase activity of the multiple drug resistance P-glycoprotein, activated the maltose transporter ATPase as well. The activation of this bacterial transporter by verapamil suggests that a structural feature that is conserved among both eukaryotic and prokaryotic ATP binding cassette transporters is responsible for this activation.

Relationships between a new type IV secretion system and the icm/dot virulence system of Legionella pneumophila

We describe here a Legionella pneumophila type IV secretion system that is distinct from the previously described icm/dot system. This type IV secretion system contains 11 genes (lvh ) homologous to genes of other type IV secretion systems, arranged in a similar manner. The lvh genes were found to be located on a DNA island with a GC content higher than the L. pneumophila chromosome. In contrast to the icm/dot system that was shown to be required for intracellular growth in HL-60-derived human macrophages and Acanthamoeba castellanii, the lvh system was found to be dispensable for intracellular growth in these two hosts. The lvh system was found to be partially required for RSF1010 conjugation, a process that was previously shown to be completely dependent on several icm/dot genes. However, results obtained from analysis of double mutants in the icm/dot genes and the lvh genes revealed that lvh genes can substitute for some components of the icm/dot system for RSF1010 conjugation, but not for intracellular growth. These results indicate that components of the icm/dot system and components of the lvh type IV secretion system are able to interact with one another.

The Legionella pneumophila rpoS gene is required for growth within Acanthamoeba castellanii

To investigate regulatory networks in Legionella pneumophila, the gene encoding the homolog of the Escherichia coli stress and stationary-phase sigma factor RpoS was identified by complementation of an E. coli rpoS mutation. An open reading frame that is approximately 60% identical to the E. coli rpoS gene was identified. Western blot analysis showed that the level of L. pneumophila RpoS increased in stationary phase. An insertion mutation was constructed in the rpoS gene on the chromosome of L. pneumophila, and the ability of this mutant strain to survive various stress conditions was assayed and compared with results for the wild-type strain. Both the mutant and wild-type strains were more resistant to stress when in stationary phase than when in the logarithmic phase of growth. This finding indicates that L. pneumophila RpoS is not required for a stationary-phase-dependent resistance to stress. Although the mutant strain was able to kill HL-60- and THP-1-derived macrophages, it could not replicate within a protozoan host, Acanthamoeba castellanii. These data suggest that L. pneumophila possesses a growth phase-dependent resistance to stress that is independent of RpoS control and that RpoS likely regulates genes that enable it to survive in the environment within protozoa. Our data indicate that the role of rpoS in L. pneumophila is very different from what has previously been reported for E. coli rpoS.

Legionella pneumophila contains a type II general secretion pathway required for growth in amoebae as well as for secretion of the Msp protease

We report the identification of a set of Legionella pneumophila genes that encode products with homology to proteins of the type II general secretion pathway of gram-negative bacteria. A strain containing a deletion-substitution mutation of two of these genes was unable to secrete the Msp protease. This strain was unable to multiply within the free-living amoeba Acanthamoeba castellanii yet was able to kill HL-60-derived macrophages. Because Msp is not required for growth in amoebae, other proteins which are important for growth in amoebae are likely secreted by this pathway.

Legionella pneumophila utilizes the same genes to multiply within Acanthamoeba castellanii and human macrophages

In previous reports we described a 22-kb Legionella pneumophila chromosomal locus containing 18 genes. Thirteen of these genes (icmT, -R, -Q, -P, -O, -M, -L, -K, -E, -C, -D, -J, and -B) were found to be completely required for intracellular growth and killing of human macrophages. Three genes (icmS, -G, and -F) were found to be partially required, and two genes (lphA and tphA) were found to be dispensable for intracellular growth and killing of human macrophages. Here, we analyzed the requirement of these genes for intracellular growth in the protozoan host Acanthamoeba castellanii, a well-established important environmental host of L. pneumophila. We found that all the genes that are completely required for intracellular growth in human macrophages are also completely required for intracellular growth in A. castellanii. However, the genes that are partially required for intracellular growth in human macrophages are completely required for intracellular growth in A. castellanii. In addition, the lphA gene, which was shown to be dispensable for intracellular growth in human macrophages, is partially required for intracellular growth in A. castellanii. Our results indicate that L. pneumophila utilizes the same genes to grow intracellularly in both human macrophages and amoebae.

The ATP-binding cassette subunit of the maltose transporter MalK antagonizes MalT, the activator of the Escherichia coli mal regulon

Transcription of the mal regulon of Escherichia coli K-12 is regulated by the positive activator, MalT. In the presence of ATP and maltotriose, MalT binds to decanucleotide MalT boxes that are found upstream of mal promoters and activates transcription at these sites. The earliest studies of the mal regulon, however, suggested a negative role for the MalK protein, the ATP-binding cassette subunit of the maltose transporter, in regulating mal gene expression. More recently, it was found that overexpression of the MalK protein resulted in very low levels of mal gene transcription. In this report we describe the use of tagged versions of MalT to provide evidence that it physically interacts with the MalK protein both in vitro and in vivo. In addition, we show that a novel malK mutation, malK941, results in an increased ability of MalK to down-modulate MalT activity in vivo. The fact that the MalK941 protein binds but does not hydrolyse ATP suggests that the MalK941 mutant protein mimics the inactive, ATP-bound form of the normal MalK protein. In contrast, cells with high levels of MalK ATPase show a reduced ability to down-modulate MalT and express several mal genes constitutively. These results are consistent with a model in which the inactive form of MalK down-modulates MalT and decreases transcription, whereas the active form of MalK does not. This model suggests that bacteria may be able to couple information about extracellular substrate availability to the transcriptional apparatus via the levels of ATP hydrolysis associated with transport.

Intracellular multiplication and human macrophage killing by Legionella pneumophila are inhibited by conjugal components of IncQ plasmid RSF1010

Previously we have reported that Legionella pneumophila can mediate plasmid DNA transfer at a frequency of about 10(-3) transconjugants per donor and that this process is dependent on several icm genes. Here we characterize the icm-dependent conjugal ability of L. pneumophila and study its relationship to intracellular multiplication and host cell killing. We found that three icm genes and the RSF1010 mobA gene are completely required and that three icm genes and the RSF1010 mobC gene are partially required for conjugation. Conjugation occurred during lag phase and stopped when the cell number increased. Inhibition of transcription or translation in the donor had only a minor effect on conjugation frequency. These results suggest that stationary-phase bacteria contain a functional icm complex that can mediate conjugal DNA transfer and probably can initiate infection of human macrophages as well. We also found that a functional RSF1010 mobilization system inhibits intracellular multiplication and killing of human macrophages by L. pneumophila. The strongest inhibition was observed in icm insertion mutants complemented with wild-type icm genes on an RSF1010-derived plasmid. These results suggest that the conjugation substrate probably competes with the natural substrate of the L. pneumophila icm system for transfer outside the bacterial cell. We propose that the function of the L. pneumophila icm system is to transfer effector molecules to the host cell. These effector molecules may interact with components of the host cell that are involved in phagosome formation and fate.

Early events in phagosome establishment are required for intracellular survival of Legionella pneumophila

During infection, the Legionnaires' disease bacterium, Legionella pneumophila, survives and multiplies within a specialized phagosome that is near neutral pH and does not fuse with host lysosomes. In order to understand the molecular basis of this organism's ability to control its intracellular fate, we have isolated and characterized a group of transposon-generated mutants which were unable to kill macrophages and were subsequently found to be defective in intracellular multiplication. These mutations define a set of 20 genes (19 icm [for intracellular multiplication] genes and dotA [for defect in organelle trafficking]). In this report, we describe a quantitative assay for phagosome-lysosome fusion (PLF) and its use to measure the levels of PLF in cells that have been infected with either wild-type L. pneumophila or one of several mutants defective in different icm genes or dotA. By using quantitative confocal fluorescence microscopy, PLF could be scored on a per-bacterium basis by determining the extent to which fluorescein-labeled L. pneumophila colocalized with host lysosomes prelabeled with rhodamine-dextran. Remarkably, mutations in the six genes that were studied resulted in maximal levels of PLF as quickly as 30 min following infection. These results indicate that several, and possibly all, of the icm and dotA gene products act at an early step during phagosome establishment to determine whether L. pneumophila-containing phagosomes will fuse with lysosomes. Although not ruled out, subsequent activity of these gene products may not be necessary for successful intracellular replication.

How is the intracellular fate of the Legionella pneumophila phagosome determined?

The following pair of articles, the first by Gil Segal and Howard Shuman, and the second by James Kirby and Ralph Isberg (Trends Microbiol. 6, 256-258), explore the genetics and function of the icm/dot genes of Legionella pneumophila. This gene family is implicated in several aspects of virulence and appears to constitute components of a conjugal transfer system that has been adopted to prevent phagosome-lysosome fusion in the host cell and to mediate host cytotoxicity by pore formation. Whether these functions are natural consequences or operate in parallel remains to be discovered.

The Legionella pneumophila icmGCDJBF genes are required for killing of human macrophages

Previously, a collection of mutants of Legionella pneumophila that had lost the ability to multiply within and kill human macrophages was generated by Tn903dIIlacZ transposon mutagenesis and classified into DNA hybridization groups. A subset of these mutants was complemented by a plasmid, pMW100, containing a 13.5-kb genomic DNA insert. This plasmid restored the ability to multiply within and produce cytopathic effects on human macrophages to members of DNA hybridization groups II, IV, VI, and XVII. A region of the genomic insert of pMW100 was sequenced, and eight potential genes were identified and named icmE, icmG, icmC, icmD, icmJ, icmB, icmF, and tphA. None of the genes encode potential protein products with significant homology to previously characterized proteins, except for tphA, whose product has significant homology to a family of metabolite/H+ symport proteins from gram-negative bacteria. The positions of the Tn903dIIlacZ insertions within the genes were determined by nucleotide sequencing. No Tn903dIIlacZ insertions mapped to icmG, icmJ, or tphA; therefore, these loci were mutated to test whether they were required for macrophage killing. Complementation analysis was used to evaluate the roles of the potential gene products and provide information on the organization of transcriptional units within the region. The results indicate that all identified open reading frames except tphA are required for killing of human macrophages.

Host cell killing and bacterial conjugation require overlapping sets of genes within a 22-kb region of the Legionella pneumophila genome

A 22-kb DNA locus of Legionella pneumophila is described that contains 18 genes, 16 of which are required for macrophage killing (icm genes). In this paper two previously described icm loci were linked by the discovery of five genes located between the two loci. Four of the newly described genes are required for macrophage killing (icmMLKE) and one is dispensable. The 16 icm genes appeared to be organized as six individual genes (icmR, icmQ, icmG, icmC, icmD, and icmF), and four operons (icmTS, icmPO, icmMLKE, and icmJB). Four icm genes (icmP, icmO, icmL, and icmE) show significant sequence similarity to plasmid genes involved in conjugation, whereas the other icm genes were found not to bear any sequence similarity to database entries. We found that L. pneumophila can mediate plasmid DNA transfer at a frequency of 10(-3) to 10(-4) per donor. Strains containing null mutations in two icm genes (icmT and icmR) showed a severe reduction in conjugation frequency and macrophage killing. Strains containing an insertion in four other icm genes (icmF, icmE, icmC, and dotA) were shown to have a less severe defect in conjugation. Mutations in the other 11 icm genes had no effect on conjugation frequency. We currently do not know whether conjugation itself plays a role in macrophage killing. It is possible either that small plasmids can take advantage of an existing secretion system to be mobilized or that DNA transfer is required for human macrophage killing by L. pneumophila.

Truncation of MalF results in lactose transport via the maltose transport system of Escherichia coli

The active accumulation of maltose and maltodextrins by Escherichia coli is dependent on the maltose transport system. Several lines of evidence suggest that the substrate specificity of the system is not only determined by the periplasmic maltose-binding protein but that a further level of substrate specificity is contributed by the inner membrane integral membrane components of the system, MalF and MalG. We have isolated and characterized an altered substrate specificity mutant that transports lactose. The mutation responsible for the altered substrate specificity results in an amber stop codon at position 99 of MalF. The mutant requires functional MalK-ATPase activity and hydrolyzes ATP constitutively. It also requires MalG. The data suggest that in this mutant the MalG protein is capable of forming a low affinity transport path for substrate.

Unliganded maltose-binding protein triggers lactose transport in an Escherichia coli mutant with an alteration in the maltose transport system

Escherichia coli accumulates malto-oligosaccharides by the maltose transport system, which is a member of the ATP-binding-cassette (ABC) superfamily of transport systems. The proteins of this system are LamB in the outer membrane, maltose-binding protein (MBP) in the periplasm, and the proteins of the inner membrane complex (MalFGK2), composed of one MalF, one MalG, and two MalK subunits. Substrate specificity is determined primarily by the periplasmic component, MBP. However, several studies of the maltose transport system as well as other members of the ABC transporter superfamily have suggested that the integral inner membrane components MalF and MalG may play an important role in determining the specificity of the system. We show here that residue L334 in the fifth transmembrane helix of MalF plays an important role in determining the substrate specificity of the system. A leucine-to-tryptophan alteration at this position (L334W) results in the ability to transport lactose in a saturable manner. This mutant requires functional MalK-ATPase activity and the presence of MBP, even though MBP is incapable of binding lactose. The requirement for MBP confirms that unliganded MBP interacts with the inner membrane MalFGK2 complex and that MBP plays a crucial role in triggering the transport process.

Characterization of a new region required for macrophage killing by Legionella pneumophila

In a previous study, a collection of 55 Legionella pneumophila mutants defective for macrophage killing was isolated by transposon mutagenesis. In this study, nine of these mutants that belong to the same DNA hybridization group (group 3) were characterized. A wild-type DNA fragment that covers this DNA hybridization group was cloned and sequenced. This region was found to contain six new genes (designated icmT, icmS, icmR, icmQ, icmP, and icmO), five of which contain at least one transposon insertion. No transposon insertion was found in icmS. However, this gene was found to be required for macrophage killing, since a kanamycin resistance cassette introduced into icmS by gene replacement resulted in a mutant that was attenuated for macrophage killing. A plasmid containing the DNA fragment that covers this region complements all the mutants for macrophage killing, although various levels of complementation were observed for mutants in different genes. Complementation tests were also performed with plasmids containing one or two of these genes, as well as with plasmids containing nonpolar in-frame deletions. The results from these complementation tests indicated that all six genes located in this region are needed for macrophage killing and that they are probably arranged as two transcriptional units (icmTS and icmPO) and two genes (icmR and icmQ). A region upstream of the coding sequence of several icm genes may contain a potential promoter and/or regulatory site. Homology searches show that icmP and icmO bear significant homology to the trbA and trbC genes from the Salmonella R64 plasmid, respectively. The sequences of the other four genes do not show significant homology with any entries in sequence databases.

Crystal structures and solution conformations of a dominant-negative mutant of Escherichia coli maltose-binding protein

A mutant of the periplasmic maltose-binding protein (MBP) with altered transport properties was studied. A change of residue 230 from tryptophan to arginine results in dominant-negative MBP: expression of this protein against a wild-type background causes inhibition of maltose transport. As part of an investigation of the mechanism of such inhibition, we have solved crystal structures of both unliganded and liganded mutant protein. In the closed, liganded conformation, the side-chain of R230 projects into a region of the surface of MBP that has been identified as important for transport while in the open form, the same side-chain takes on a different, and less ordered, conformation. The crystallographic work is supplemented with a small-angle X-ray scattering study that provides evidence that the solution conformation of unliganded mutant is similar to that of wild-type MBP. It is concluded that dominant-negative inhibition of maltose transport must result from the formation of a non-productive complex between liganded-bound mutant MBP and wild-type MalFGK2. A general kinetic framework for transport by either wild-type MalFGK2 or MBP-independent MalFGK2 is used to understand the effects of dominant-negative MBP molecules on both of these systems.

The inhibition of maltose transport by the unliganded form of the maltose-binding protein of Escherichia coli: experimental findings and mathematical treatment

Binding protein-dependent transport systems in Gram-negative enteric bacteria are multicomponent systems in which a soluble periplasmic binding protein of high substrate binding affinity establishes the major substrate recognition site. Usually, there are two integral membrane proteins which are thought to interact with the substrate loaded form of the binding protein to allow transport of substrate to occur. Transport is against the concentration gradient and needs energization by an ATP hydrolizing polypeptide. Overall transport is considered mainly unidirectional due to the high energy of ATP hydrolysis coupled to transport. In the study reported here, maltose transport in membrane vesicles in the presence of varying concentrations of unliganded maltose-binding protein but with constant amounts of maltose was measured. The conditions were chosen such that the concentration of maltose was always smaller than that of the binding protein and the initial concentration of the liganded binding protein was essentially constant. It was found that the initial rate of transport went through a maximum with increasing amounts of binding protein and declined thereafter. This finding strongly supports the conclusion that both the liganded and the unliganded forms of the binding protein interact with the membrane components of the transport system. The mathematical treatment of the experimental data allowed the ratio of the affinities for the membrane components of the substrate loaded and unloaded binding protein to be estimated. Published data on the binding protein-dependent transport of histidine in membrane vesicles of Salmonella typhimurium were also used. The data allowed the ratio of the binding affinity of the membrane components to the substrate-loaded and free binding protein to be determined. In addition, the KM of transport to the KD of binding protein was approximated.

Mathematical treatment of the kinetics of binding protein dependent transport systems reveals that both the substrate loaded and unloaded binding proteins interact with the membrane components

Binding-protein-dependent transport systems in Gram-negative bacteria are multicomponent systems in which a soluble periplasmic binding protein of high substrate binding affinity establishes the major substrate recognition site. Usually, there are two membrane proteins which are thought to interact with the substrate loaded form of the binding protein to allow transport of substrate to occur. Transport is against the concentration gradient and needs energization by an ATP hydrolyzing polypeptide. Overall transport is considered mainly unidirectional owing to the high energy of ATP hydrolysis coupled to transport. We dissected the overall transport process into three individual steps: (i) reversible binding of substrate to the binding protein; (ii) reversible binding of the binding protein to the membrane components forming the translocation complex; (iii) irreversible transport of substrate through the membrane and dissociation of the binding protein from the complex. Two models were considered. In the first, only the substrate-loaded binding protein interacts with the membrane components, while in the second model both the loaded and the unloaded form of the binding protein interact with the membrane components. The mathematical analysis of the second model revealed that the substrate concentration KM at half-maximal rate of transport approaches KD of the binding protein when the last step of transport becomes low and when the concentration of binding protein in the periplasm becomes large. This is usually observed in real systems. Under the same conditions, in model 1 KM approaches zero and is hence considerably smaller than KD. This has never been observed in any real system. In addition, the dependence of the overall rate of transport on the concentration of binding protein in the periplasm follows a sigmoidal curve only when model 2 is considered. The sigmoidal behavior becomes more pronounced when the substrate concentration is low and it is less pronounced when the last step in overall transport is low. This phenomenon has been observed with the Escherichia coli maltose transport system. Thus, at least for the maltose transport system, it seems likely that both the loaded and the unloaded forms of the binding protein interact with the membrane components. We propose that this should generally be considered in binding-protein-dependent transport systems.

Escherichia coli F plasmid transfers to and replicates within Legionella pneumophila: an alternative to using an RP4-based system for gene delivery

Derivatives of the self-transmissible F plasmid of Escherichia coli can be introduced into Legionella pneumophila by conjugation and maintained within only upon selection. In L. pneumophila. F-based replicons seem to exist as extrachromosomal elements since they were readily lost when F-containing L. pneumophila was grown on nonselective medium. The F-based plasmids were not self-transmissible in L. pneumophila. The mating defect may be due to an inability to form the F pilus since F-containing strains of L. pneumophila could neither be infected with the pilus-specific phage M13 nor transduced with f1-packaged ColE1 replicons. Currently, the most commonly used transfer system for introducing genetic information into L. pneumophila employs E. coli donors with a chromosomally integrated copy of RP4::Mu to mobilize plasmids bearing the RK2 origin of transfer (oriT). Use of this system to deliver TnphoA for mutagenesis of the L. pneumophila chromosome led to transconjugants that all contained cryptic DNA alterations that involved the plasmid RP4 and phage Mu. No TnphoA transposition was observed in L. pneumophila. The fact that F-mediated conjugation can be used to efficiently transfer plasmids containing the oriT of F to L. pneumophila provides an important alternative to the RP4-based plasmid transfer system and may avoid DNA anomalies in transconjugants that impede genetic analysis. Furthermore, our results demonstrate the promiscuous nature of the F conjugal transfer and replication systems.

The Legionella pneumophila icm locus: a set of genes required for intracellular multiplication in human macrophages

Legionella pneumophila, the causative agent of Legionnaires' disease and related pneumonias, infects, replicates within and eventually kills human macrophages. A key feature of the intracellular life-style is the ability of the organism to replicate within a specialized phagosome which does not fuse with lysosomes or acidify. Avirulent mutants that are defective in intracellular multiplication and host-cell killing are unable to prevent phagosome-lysosome fusion. In a previous study, a 12 kb fragment of the L. pneumophila genome containing the icm locus (intracellular multiplication) was found to enable the mutant bacteria to prevent phagosome-lysosome fusion, to multiply intracellularly and to kill human macrophages. The complemented mutant also regained the ability to produce lethal pneumonia in guinea-pigs. In order to gain information about how L. pneumophila prevents phagosome-lysosome fusion and alters other intracellular events, we have studied the region containing the icm locus. This locus contains four genes, icmWXYZ, which appear to be transcribed from a single promoter to produce a 2.1-2.4 kb mRNA. The deduced amino acid sequences of the Icm proteins do not exhibit significant similarity to other proteins of known sequence, suggesting that they may carry out novel functions. The icmX gene encodes a product with an apparent signal sequence suggesting that it is a secreted protein. The icmWXYZ genes are located adjacent to and on the opposite strand from the dot gene, which is also required for intracellular multiplication and the ability of L. pneumophila to modify organelle traffic in human macrophages. Five L. pneumophila Icm mutants that had been generated with transposon Tn903dIIlacZ were found to have inserted the transposon within the icmX, icmY, icmZ and dot genes, confirming their role in the ability of the organism to multiply intracellularly.

The iron superoxide dismutase of Legionella pneumophila is essential for viability

Legionella pneumophila, the causative agent of Legionnaires' disease, contains two superoxide dismutases (SODs), a cytoplasmic iron enzyme (FeSOD) and a periplasmic copper-zinc SOD. To study the role of the FeSOD in L. pneumophila, the cloned FeSOD gene (sodB) was inactivated with Tn903dIIlacZ, forming a sodB::lacZ gene fusion. By using this fusion, expression of sodB was shown to be unaffected by a variety of conditions, including several that influence sod expression in Escherichia coli: aeration, oxidants, the redox cycling compound paraquat, manipulation of iron levels in the medium, and the stage of growth. A reproducible twofold decrease in sodB expression was found during growth on agar medium containing charcoal, a potential scavenger of oxyradicals, in comparison with growth on the same medium without charcoal. No induction was seen during growth in human macrophages. Additional copies of sodB+ in trans increased resistance to paraquat. Construction of a sodB mutant was attempted by allelic exchange of the sodB::lacZ fusion with the chromosomal copy of sodB. The mutant could not be isolated, and the allelic exchange was possible only if wild-type sodB was present in trans. These results indicate that the periplasmic copper-zinc SOD cannot replace the FeSOD. The data strongly suggest that sodB is an essential gene and that FeSOD is required for the viability of L. pneumophila. In contrast, Sod- mutants of E. coli and Streptococcus mutans grow aerobically and SOD is not required for viability in these species.

Mutations that alter the transmembrane signalling pathway in an ATP binding cassette (ABC) transporter

The maltose transport system of Escherichia coli is a well-characterized member of the ATP binding cassette transporter superfamily. Members of this family share sequence similarity surrounding two short sequences (the Walker A and B sequences) which constitute a nucleotide binding pocket. It is likely that the energy from binding and hydrolysis of ATP is used to accomplish the translocation of substrate from one location to another. Periplasmic binding protein-dependent transport systems, like the maltose transport system of E.coli, possess a water-soluble ligand binding protein that is essential for transport activity. In addition to delivering ligand to the membrane-bound components of the system on the external face of the membrane, the interaction of the binding protein with the membrane complex initiates a signal that is transmitted to the ATP binding subunit on the cytosolic side and stimulates its hydrolytic activity. Mutations that alter the membrane complex so that it transports independently of the periplasmic binding protein also result in constitutive activation of the ATPase. Genetic analysis indicates that, in general, two mutations are required for binding protein-independent transport and constitutive ATPase. The mutations alter residues that cluster to specific regions within the membrane spanning segments of the integral membrane components MalF and MalG. Individually, the mutations perturb the ability of MBP to interact productively with the membrane complex. Genetic alteration of this signalling pathway suggests that other agents might have similar effects. These could be potentially useful for modulating the activities of ABC transporters such as P-glycoprotein or CFTR, that are implicated in disease.

Mutagenesis of Legionella pneumophila using Tn903 dlllacZ: identification of a growth-phase-regulated pigmentation gene

Study of the molecular basis for Legionella pneumophila pathogenicity would be facilitated with an efficient mutagen that can not only mark genomic mutations, but can also be used to reflect gene expression during macrophage infection. A derivative of Tn903, Tn903dlllacZ, is shown to transpose with high efficiency in L. pneumophila. Tn903dlllacZ encodes resistance to kanamycin (KmR) and carries a 5' truncated 'lacZ gene that can form translational fusions to L. pneumophila genes upon transposition. The cis-acting Tn903 transposase is supplied outside Tn903dlllacZ, and hence chromosomally integrated copies are stable. KmR LacZ+ insertion mutants of L. pneumophila were isolated and shown by DNA hybridization to carry a single Tn903dlllacZ inserted within their chromosomes at various locations. One particular KmR LacZ+ mutant, AB1156, does not produce the brown pigment (Pig-) characteristic of Legionella species. Tn903dlllacZ is responsible for this phenotype since reintroduction of the transposon-linked mutation into a wild-type background results in a Pig- phenotype. L. pneumophila pigment production is normally observed in stationary-phase growth of cells in culture, and beta-galactosidase activity measured from the pig::lacZ fusion increased during the logarithmic-phase growth and peaked at the onset of stationary phase. Interestingly, pig::lacZ expression also increased during macrophage infection. The pigment itself, however, does not appear to be required for L. pneumophila to grow within or kill host macrophages.

Tinkering with transporters: periplasmic binding protein-dependent maltose transport in E. coli

Periplasmic binding protein-dependent transport systems represent a common mechanism for nutrient and ion uptake in bacteria. As a group, these systems are related to one another and to other transporters of both prokaryotes and eukaryotes, based on sequence similarity within an ATP-binding subunit and overall structural organization. These transporters probably all use energy derived from ATP to pump substrates across membranes. Although there is considerable information about the sequences and identity of the transporters, there is little information about how they work. That is, where do ligands bind? Where do the subunits or domains interact with one another? How is the energy of nucleotide binding and/or hydrolysis converted to conformational changes? In order to address these questions we have taken a genetic approach that involves studying mutant forms of a transporter. Rather than study mutations that result in complete loss of function, the study of mutations which perturb or alter the normal function of the transporter in a defined manner has provided a limited insight into how the answers to these questions may be obtained.

Identification of Legionella pneumophila genes required for growth within and killing of human macrophages

Legionella pneumophila was mutagenized with Tn903dIIlacZ, and a collection of mutants was screened for defects in macrophage killing (Mak-). Of 4,564 independently derived mutants, 55 (1.2%) showed a reduced or complete lack in the ability to kill HL-60-derived human macrophages. Forty-nine of the Mak- mutants could be assigned to one of 16 DNA hybridization groups. Only one group (9 of the 10 members) could be complemented for macrophage killing by a DNA fragment containing icm and dot, two recently described L. pneumophila loci that are required for macrophage killing. Phenotypic analysis showed that none of the mutants were any more sensitive than the wild type to human serum, oxidants, iron chelators, or lipophilic reagents nor did they require additional nutrients for growth. The only obvious difference between the Mak-mutants and wild-type L. pneumophila was that almost all of the Mak- mutants were resistant to NaCl. The effects of LiCl paralleled the effects of NaCl but were less pronounced. Resistance to salt and the inability to kill human macrophages are linked since both phenotypes appeared when Tn903dIIlacZ mutations from two Mak- strains were transferred to wild-type backgrounds. However, salt sensitivity is not a requisite for killing macrophages since a group of Mak- mutants containing a plasmid that restored macrophage killing remained resistant to NaCl. Mak- mutants from groups I through IX associated with HL-60 cells similarly to wild-type L. pneumophila. However, like the intracellular-multiplication-defective (icm) mutant 25D, the Mak- mutants were unable to multiply within macrophages. Thus, the ability of L. pneumophila to kill macrophages seems to be determined by many genetic loci, almost all of which are associated with sensitivity to NaCl.

Characterization of the structural requirements for assembly and nucleotide binding of an ATP-binding cassette transporter. The maltose transport system of Escherichia coli

The periplasmic maltose-binding protein-dependent, maltose transport system of Escherichia coli is a well studied member of the ATP-binding cassette family of transport ATPases. In addition to the water-soluble maltose-binding protein, the system comprises three membrane proteins, MalF, MalG, and MalK, which form a heterotetrameric complex (FGK2) in the cytoplasmic membrane. The purified complex exhibits transport-associated ATPase activity. To characterize the requirements for nucleotide binding and hydrolysis by the FGK2 complex, we used plasmids to express different combinations of the individual subunits as well as mutant forms of the MalK subunit. Prior to measuring nucleotide binding, we examined membrane preparations for the presence of each subunit from strains that contained all possible permutations of the three structural genes, malF, malG, and malK. We found that when all three genes were present or when malF and malK were present together, the corresponding antigens were detected easily on Western immunoblots and were soluble in the non-ionic detergent, Triton X-100. In contrast, all other permutations resulted in decreased amounts of antigen or antigen that was Triton X-100-insoluble. We relied on photocross-linking with 8-azido-[32P]ATP and ATP hydrolysis as indicators of the ability of the transport complex to interact with purine nucleotides. 8-Azido-[32P]ATP was photocross-linked to the MalK subunit. Photolabeling of MalK was inhibited by ATP, ADP, and GTP and not by other nucleotides. Photolabeling of MalK required the presence of MalF but not MalG. Mutations in malK that affect amino acid residues thought to be directly involved in nucleotide binding did indeed abolish labeling and resulted in loss of transport activity without affecting protein stability. In general, ATP hydrolysis correlated with the photocross-linking. A notable exception is the MalK941 mutant protein which retained the ability to be labeled by 8-azido-[32P]ATP but was unable to catalyze detectable levels of ATP hydrolysis. Some, but not all, of the malK mutations were dominant to wild type. To study the mechanism of dominance we devised a means of measuring the ability of different wild-type and mutant MalK proteins to interact with the MalF and MalG subunits. This assay relies on the fact that, when a bifunctional MalK-LacZ hybrid protein is associated with the MalF and MalG subunits, it is membrane-bound. Excess MalK competed with the MalK-LacZ hybrid protein for sites in the membrane and resulted in the hybrid fractionating as a soluble protein.(ABSTRACT TRUNCATED AT 400 WORDS)

Genetic analysis of periplasmic binding protein dependent transport in Escherichia coli. Each lobe of maltose-binding protein interacts with a different subunit of the MalFGK2 membrane transport complex

Escherichia coli is able to accumulate maltose and maltodextrins by an ATP-binding cassette transporter known as the maltose transport system. This transport system is comprised of five proteins: the LamB protein in the outer membrane; the periplasmic maltose-binding protein (MBP); two integral inner membrane proteins, MalF and MalG; and MalK, which is associated with the cytoplasmic face of the inner membrane. It has been previously suggested that MBP interacts with MalF and MalG during sugar transport across the inner membrane. In two independent genetic studies, reported here, residue 210 of MBP has been identified as an important site for its interaction with MalF. In one study, allele-specific suppressors of a malF mutation, malF506, were isolated and yielded mutations which altered residue tyrosine 210 of MBP to aspartic acid. In the other study, dominant mutations in malE (the structural gene of MBP) were isolated; one of these altered the same tyrosine residue (210) to cysteine. It was shown that the Y210C MBP mutant is also an allele-specific suppressor malF506, and that of the suppressor MBP alleles also exhibited dominant-negative phenotypes. Previously it was shown that alterations at residues glycine 13 and aspartate 14 of MBP can result in suppression of a malG mutant. From these results and those described, it is possible to propose a simple model in which the amino-terminal lobe of MBP interacts with MalG and the carboxy-terminal lobe of MBP interacts with MalF. The locations of residues 13, 14 and 210 on the three-dimensional structure of MBP are in keeping with this model.

Identification of a Legionella pneumophila locus required for intracellular multiplication in human macrophages

The legionnaires' disease bacterium, Legionella pneumophila, is a facultative intracellular parasite. Its interaction with phagocytes has characteristics in common with several other intracellular parasites. Critical aspects of L. pneumophila intracellular multiplication are evasion of lysosomal host cell defenses and the presence of a nutritionally appropriate environment. Following phagocytosis, wild-type L. pneumophila multiply within a specialized phagosome which does not fuse with secondary lysosomes. Mutants which have lost the ability to grow within phagocytes no longer cause disease in animals, indicating that the capacity to multiply intracellularly is important for pathogenesis. One such mutant, 25D, has been shown to be defective in inhibiting phagosome-lysosome fusion. This phagolysosomal environment is not conducive to Legionella growth. We report the isolation of a region of the L. pneumophila genome (icm, intracellular multiplication) which restores the capacity of 25D to multiply in human macrophages. The complemented mutants also regain the capacity to interfere with phagosome-lysosome fusion and to cause lethal pneumonia in guinea pigs.

Interaction between maltose-binding protein and the membrane-associated maltose transporter complex in Escherichia coli

Active transport of maltose in Escherichia coli requires the presence of both maltose-binding protein (MBP) in the periplasm and a complex of MalF, MalG, and MalK proteins (FGK2) located in the cytoplasmic membrane. Earlier, mutants in malF or malG were isolated that are able to grow on maltose in the complete absence of MBP. When the wild-type malE+ allele, coding for MBP, was introduced into these MBP-independent mutants, they frequently lost their ability to grow on maltose. Furthermore, starting from these Mal- strains, Mal+ secondary mutants that contained suppressor mutations in malE were isolated. In this study, we examined the interaction of wild-type and mutant MBPs with wild-type and mutant FGK2 complexes by using right-side-out membrane vesicles. The vesicles from a MBP-independent mutant (malG511) transported maltose in the absence of MBP, with Km and Vmax values similar to those found in intact cells. However, addition of wild-type MBP to these mutant vesicles produced unexpected responses. Although malE+ malG511 cells could not utilize maltose, wild-type MBP at low concentrations stimulated the maltose uptake by malG511 vesicles. At higher concentrations of the wild-type MBP and maltose, however, maltose transport into malG511 vesicles became severely inhibited. This behaviour of the vesicles was also reflected in the phenotype of malE+ malG511 cells, which were found to be capable of transporting maltose from a low external concentration (1 microM), but apparently not from millimolar concentrations present in maltose minimal medium. We found that the mutant FGK2 complex, containing MalG511, had a much higher apparent affinity towards the wild-type MBP than did the wild-type FGK2 complex.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechanism of maltose transport in Escherichia coli: transmembrane signaling by periplasmic binding proteins

Maltose transport across the cytoplasmic membrane of Escherichia coli is dependent on the presence of a periplasmic maltose-binding protein (MBP), the product of the malE gene. The products of the malF, malG, and malK genes form a membrane-associated complex that catalyzes the hydrolysis of ATP to provide energy for the transport event. Previously, mutants were isolated that had gained the ability to grow on maltose in the absence of MBP. After reconstitution of the transport complex into proteoliposomes, measurement of the ATPase activity of wild-type and mutant complexes in the presence and absence of MBP revealed that the wild-type complex hydrolyzed ATP rapidly only when MBP and maltose were both present. In contrast, the mutant complexes have gained the ability to hydrolyze ATP in the absence of maltose and MBP. The basal rate of hydrolysis by the different mutant complexes was directly proportional to the growth rate of that strain on maltose, a result indicating that the constitutive ATP hydrolysis and presumably the resultant cyclic conformational changes of the complex produce maltose transport in the absence of MBP. These results also suggest that ATP hydrolysis is not directly coupled to ligand transport even in wild-type cells and that one important function of MBP is to transmit a transmembrane signal, through the membrane-spanning MalF and MalG proteins, to the MalK protein on the other side of the membrane, so that ATP hydrolysis can occur.

The malZ gene of Escherichia coli, a member of the maltose regulon, encodes a maltodextrin glucosidase

We have characterized a maltodextrin glucosidase, previously described as a maltose-inducible, cytoplasmic enzyme that cleaves p-nitrophenyl-alpha-maltoside in Escherichia coli. The gene encoding the enzyme activity, referred to as malZ, is located at 9.3 min on the chromosomal map. We cloned the gene in a high copy number vector and purified the enzyme. It is a monomer, with an apparent molecular weight of 65,000. The enzyme degrades maltodextrins, ranging from maltotriose to maltoheptaose, to shorter oligosaccharides, the final hydrolysis products being maltose and glucose. We measured the kinetic parameters, Km and Vmax, for the hydrolysis to glucose of the five different substrates. The binding of the substrate is enhanced by increasing the number of glucosyl residues in the maltodextrin. In contrast, the maximum rate of hydrolysis (Vmax) is fastest for maltotriose. To study the mode of action of the enzyme, we quantitatively measured the amount of free glucose liberated from the different maltodextrin substrates after a long incubation. More glucose is liberated from the long dextrins, as compared to the shorter ones, showing that the primary hydrolysis product was glucose, not maltose. Furthermore, [14C]maltotriose, specifically labeled at the reducing end, was hydrolyzed to [14C]glucose and unlabeled maltose. These data demonstrate that the malZ gene product is a maltodextrin glucosidase, liberating glucose from the reducing end of malto-oligosaccharides. The nucleotide sequence of malZ and the deduced amino acid sequence showed that malZ encodes a protein with a molecular weight of 68,960. Homology to glucosidases, alpha-amylases, and pullulanases were observed. Conserved regions thought to represent active sites in dextrin hydrolases were found in the MalZ protein.

The activities of the Escherichia coli MalK protein in maltose transport, regulation, and inducer exclusion can be separated by mutations

The maltose regulon consists of several genes encoding proteins involved in the uptake and utilization of maltose and maltodextrins. Five proteins make up a periplasmic binding-protein-dependent active transport system. One of these proteins, MalK, contains an ATP-binding site and is thought to couple the hydrolysis of ATP to the accumulation of substrate. Beside its function in transport, MalK has two additional roles: (i) it negatively regulates mal regulon expression and (ii) it serves as the target for regulation of transport activity by enzyme IIIGlc of the phosphotransferase system. To determine whether the three functions of MalK are separable, we have isolated and characterized three classes of malK mutations. The first type (class I) exhibited constitutive mal gene expression but still allowed normal transport of maltose; the second type (class II) lacked the ability to transport maltose but retained the ability to repress the mal genes. Class I mutations were localized in the last third of the gene, at amino acids 267 (Trp to Gly) and 346 (Gly to Ser). Mutations of class II were found at the positions 137 (Gly to Ala), 140 (delta Gln Arg), and 158 (Asp to Asn). These mutations are near or within the region of MalK that exhibits extensive homology to the B site of an ATP-binding fold. In addition, site-directed mutagenesis was used to add or remove one amino acid in the A site of the ATP-binding fold. Plasmids carrying these mutations also behaved as class II mutants. The third class of malK mutations resulted in resistance to the enzyme IIIGlc-mediated inhibitory effects of alpha-methylglucoside. These mutations did not interfere with the regulatory function of MalK. One of these mutations (exchanging a serine at position 282 for leucine) is located in a short stretch of amino acids that exhibits homology to a sequence in the Escherichia coli Lac permease in which alpha-methylglucoside-resistant mutations have been found.

An immunoprotective molecule, the major secretory protein of Legionella pneumophila, is not a virulence factor in a guinea pig model of Legionnaires' disease

We have examined whether a molecule that is capable of inducing immune protection, the major secretory protein (MSP) of Legionella pneumophila, is required for virulence in a guinea pig model of Legionnaires' disease. To do so, we have compared the virulence in guinea pigs of an isogenic pair of L. pneumophila, Philadelphia 1 strain, one of which produces MSP (MSP+) and one of which does not (MSP-). Both the MSP- strain and the MSP+ strain of L. pneumophila are highly virulent for guinea pigs, inducing similar signs and progression of illness. Both strains are lethal and have comparable LD50s and LD100s. Both strains multiply in the lungs of guinea pigs at a similar rate, and both strains produce indistinguishable pathological lesions in the lungs. Both strains maintain a stable phenotype with guinea pig passage, i.e., the MSP- strain does not regain the capacity to secrete MSP and the MSP+ strain retains its capacity to secrete MSP after lung passage. Although vaccination with MSP induces strong protective immunity in the guinea pig against lethal aerosol challenge with L. pneumophila, this protective immunogen is not required in its intact proteolytically active form for the expression of virulence by the intracellular pathogen L. pneumophila. This demonstrates that a protective immune response need not necessarily be directed against a virulence determinant and suggests that any molecule that allows the host immune system to detect and act against an intracellularly sequestered pathogen may potentially serve as a protective immunogen against such a pathogen.

The Legionella pneumophila major secretory protein, a protease, is not required for intracellular growth or cell killing

The Legionella pneumophila major secretory protein (Msp) is a Zn2+ metalloprotease whose function in pathogenesis is unknown. The structural gene for the Msp protease, mspA, was isolated from an L. pneumophila genomic library. In Escherichia coli which contain plasmids with the mspA gene, Msp protein and activity are found in the periplasmic space and the cytoplasm. Transposon mutagenesis with Tn9 of an mspA-containing plasmid in E. coli yielded mutants which no longer expressed protease activity and others with increased protease activity. These results suggested that mspA expression might be regulated. Msp was shown to be produced at a much higher level in L. pneumophila grown in rich compared to semidefined media. A Tn9 insertion which abolishes Msp expression was introduced into the L. pneumophila genome. This mspA::Tn9 L. pneumophila strain showed no detectable production of Msp by immunoblot analysis, and it had less than 0.1% of the protease activity found in the wild-type strain. This mutant was fully capable of growing within and killing human macrophages derived from the HL-60 cell line.

The HL-60 model for the interaction of human macrophages with the Legionnaires' disease bacterium

The facultative intracellular pathogen, Legionella pneumophila, multiplies within and kills human monocytes and alveolar macrophages. We show that L. pneumophila strain Philadelphia-1 infects, multiplies within and kills the promyelocyte HL-60 cell line after its differentiation into macrophage-like cells. The characteristics of the interaction between L. pneumophila and differentiated HL-60 cells closely resemble those between L. pneumophila and human peripheral blood monocytes. With both cell types, C receptors and serum C mediate attachment of L. pneumophila, which are taken up by coiling phagocytosis. The replicative phagosome is lined with ribosomes; intracellular multiplication is iron-dependent; and replicating bacteria ultimately destroy the host cell. As in human monocytes, an avirulent mutant derivative of L. pneumophila Philadelphia-1, 25D, does not replicate in and is not cytopathic for differentiated HL-60 cells. Differentiated HL-60 cells therefore provide a convenient and faithful model for the study of L. pneumophila-mononuclear phagocyte interaction.

The HL-60 model for the interaction of human macrophages with the Legionnaires' disease bacterium

The facultative intracellular pathogen, Legionella pneumophila, multiplies within and kills human monocytes and alveolar macrophages. We show that L. pneumophila strain Philadelphia-1 infects, multiplies within and kills the promyelocyte HL-60 cell line after its differentiation into macrophage-like cells. The characteristics of the interaction between L. pneumophila and differentiated HL-60 cells closely resemble those between L. pneumophila and human peripheral blood monocytes. With both cell types, C receptors and serum C mediate attachment of L. pneumophila, which are taken up by coiling phagocytosis. The replicative phagosome is lined with ribosomes; intracellular multiplication is iron-dependent; and replicating bacteria ultimately destroy the host cell. As in human monocytes, an avirulent mutant derivative of L. pneumophila Philadelphia-1, 25D, does not replicate in and is not cytopathic for differentiated HL-60 cells. Differentiated HL-60 cells therefore provide a convenient and faithful model for the study of L. pneumophila-mononuclear phagocyte interaction.

Sodium/proton antiport is required for growth of Escherichia coli at alkaline pH

Evidence is presented indicating that Escherichia coli requires the Na+/H+ antiporter and external sodium (or lithium) ion to grow at high pH. Cells were grown in plastic tubes containing medium with a very low Na+ content (5-15 microM). Normal cells grew at pH 7 or 8 with or without added Na+, but at pH 8.5 external Na was required for growth. A mutant with low antiporter activity failed to grow at pH 8.5 with or without Na+. On the other hand, another mutant with elevated antiporter activity grew at a higher pH than normal (pH 9) in the presence of added Na+ or Li+. Amiloride, an inhibitor of the antiporter, prevented cells from growing at pH 8.5 (plus Na+), although it had no effect on growth in media of lower pH values.

Isolation of a Legionella pneumophila restriction mutant with increased ability to act as a recipient in heterospecific matings

The ability of Legionella pneumophila to act as a recipient of IncP and IncQ plasmids in matings with Escherichia coli varies widely from strain to strain. We found that the low efficiency of mating of the Philadelphia-1 strain is due to a type II restriction-modification system, and we isolated and characterized a Philadelphia-1 mutant that lacks the restriction enzyme activity.

Overproduction of MalK protein prevents expression of the Escherichia coli mal regulon

The mal regulon of Escherichia coli comprises a large family of genes whose function is the metabolism of linear maltooligosaccharides. Five gene products are required for the active accumulation of maltodextrins as large as maltoheptaose. Two cytoplasmic gene products are necessary and sufficient for the intracellular catabolism of these sugars. Two newly discovered enzymes have the capacity to metabolize these sugars but are not essential for their catabolism in wild-type cells. A single regulatory protein, MalT, positively regulates the expression of all of these genes in response to intracellular inducers, one of which has been identified as maltotriose. In the course of studying the mechanism of the transport system, we have placed the structural gene for one of the transport proteins, MalK, under the control of the Ptrc promoter to produce large amounts of this protein. We found that although high-level expression of MalK was not detrimental to E. coli, the increased amount of MalK decreased the basal-level expression of the mal regulon and prevented induction of the mal system even in the presence of external maltooligosaccharides. Constitutive mutants in which MalT does not depend on the presence of the internal inducer(s) were unaffected by the increased levels of the MalK protein. These results are consistent with the idea that MalK protein somehow interferes with the activity of the MalT protein. Different models for the regulatory function of MalK are discussed.

Genetics of Legionella pneumophila

Legionella pneumophila is a facultative intracellular pathogen capable of entering and growing in a variety of phagocytic cells including free-living amoebae as well as alveolar macrophages and monocytes. A genetic analysis of L. pneumophila should facilitate the identification of bacterial factors that promote the intracellular lifestyle of this organism.

Allele-specific malE mutations that restore interactions between maltose-binding protein and the inner-membrane components of the maltose transport system

Active accumulation of maltose and maltodextrins by Escherichia coli depends on an outer-membrane protein. LamB, a periplasmic maltose-binding protein (MalE, MBP) and three inner-membrane proteins, MalF, MalG and MalK. MalF and MalG are integral transmembrane proteins, while MalK is associated with the inner aspect of the cytoplasmic membrane via an interaction with MalG. Previously we have shown that MBP is essential for movement of maltose across the inner membrane. We have taken advantage of malF and malG mutants in which MBP interacts improperly with the membrane proteins. We describe the properties of malE mutations in which a proper interaction between MBP and defective MalF and MalG proteins has been restored. We found that these malE suppressor mutations are able to restore transport activity in an allele-specific manner. That is, a given malE mutation restores transport activity to different extents in different malF and malG mutants. Since both malF and malG mutations could be suppressed by allele-specific malE suppressors, we propose that, in wild-type bacteria, MBP interacts with sites on both MalF and MalG during active transport. The locations of different malE suppressor mutations indicate specific regions on MBP that are important for interacting with MalF and MalG.

Isolation and characterization of auxotrophic mutants of Legionella pneumophila that fail to multiply in human monocytes

Attempts to isolate auxotrophic mutants of Legionella pneumophila have been hampered by the complex nutritional composition of the media used to cultivate this organism. We developed a semidefined medium, designated CAA, to facilitate the isolation and characterization of Legionella auxotrophs. Unlike previously described chemically defined media for this organism, L. pneumophila formed colonies on CAA agar. Using this medium, we isolated several independent tryptophan auxotrophs of strain Philadelphia-1 after ethyl methanesulfonate mutagenesis and penicillin enrichment. Trimethoprim selection was used to isolate several independent thymidine-requiring mutants of the same strain. The thymidine auxotrophs exhibited a marked decrease in viability when they were deprived of thymidine. The results of monocyte infection experiments with both the tryptophan and thymidine auxotrophs indicated that the thymidine auxotrophs were incapable of intracellular survival or multiplication. In contrast, the tryptophan auxotrophs grew well in monocyte cultures. The isolation of additional auxotrophic mutants will facilitate the study of the nutritional requirements of L. pneumophila for growth in human mononuclear phagocytes.