Intracellular growth of Legionella pneumophila within Acanthamoeba castellanii Neff

Acanthamoeba castellanii Neff supports the intracellular growth of Legionella pneumophila. When acanthamoebae were exposed to L. pneumophila for 1 h and then washed free of unassociated bacteria and placed in liquid culture, levels of viable amoeba-associated legionellae and legionellae free in the culture medium increased by three to four orders of magnitude in 48 to 72 h. However, most of the legionellae remained amoeba-associated and could be cultured only after disruption of the amoebae. Furthermore, legionella viability declined rapidly in amoeba culture medium alone or when bacteria and amoebae were separated by a microporous membrane. Therefore, direct amoeba-legionella contact is required for this growth. Infected acanthamoebae treated with cold acetone to permeabilize them to fluorescent-labeled anti-L. pneumophila antibody appeared to contain far more legionellae than amoebae fixed with glutaraldehyde so as to prevent antibody penetration. Electron micrographs of infected A. castellanii showed numerous bacteria, including some dividing forms, within vacuoles in the cytoplasm. These results together show that A. castellanii is able to provide an intracellular niche for the growth of L. pneumophila.     

Growth of Legionella pneumophila in Acanthamoeba castellanii enhances invasion.

Legionella pneumophila is considered to be a facultative intracellular parasite. Therefore, the ability of these bacteria to enter, i.e., invade, eukaryotic cells is expected to be a key pathogenic determinant. We compared the invasive ability of bacteria grown under standard laboratory conditions with that of bacteria grown in Acanthamoeba castellanii, one of the protozoan species that serves as a natural host for L. pneumophila in the environment. Amoeba-grown L. pneumophila cells were found to be at least 100-fold more invasive for epithelial cells and 10-fold more invasive for macrophages and A. castellanii than were L. pneumophila cells grown on agar. Comparison of agar- and amoeba-grown L. pneumophila cells by light and electron microscopy demonstrated dramatic differences in the morphology and structure of the bacteria. Analyses of protein expression in the two strains of bacteria suggest that these phenotypic differences may be due to the expression of new proteins in amoeba-grown L. pneumophila cells. In addition, the amoeba-grown bacteria were found to enter macrophages via coiling phagocytosis at a higher frequency than agar-grown bacteria did. Replication of L. pneumophila in protozoans present in domestic water supplies may be necessary to produce bacteria that are competent to enter mammalian cells and produce human disease.     

Reduced expression of the global regulator protein CsrA in Legionella pneumophila affects virulence-associated regulators and growth in Acanthamoeba castellanii

Legionella bacteria have a developmental cycle in which they go from existing in the aquatic environment to replicating inside eukaryotic host cells. The adaptation to the new environment requires an efficient regulatory system. Overexpression of CsrA, a global regulatory protein found in a variety of gram-negative bacteria has been shown to suppress virulence-associated traits in Legionella pneumophila. Since evidence resulting only from overproduction may not be sufficient to validate the role of a regulatory protein, a csrA mutant strain, CsrA(-), with a drastically reduced production of CsrA, was created. Using RNA slot blots and Western blotting it was shown that fliA and flaA, genes which contribute to flagellation, were expressed early in the mutant. Additionally, in CsrA(-) the levels of the stationary-phase sigma factor, RpoS, and a recently described regulator of virulence traits, LetE, were increased. Growth curves of CsrA(-) bacteria were delayed with pigment production occurring at the same OD578 but at reduced levels in the mutant. Replication ability of the CsrA(-) mutant in amoebae was also affected. Based on these results, we could show that CsrA is involved in the regulation of the bacterial switch from the replicative to the transmissible form.     

Intracellular Growth in Acanthamoeba castellanii Affects Monocyte Entry Mechanisms and Enhances Virulence of Legionella pneumophila

Since Legionella pneumophila is an intracellular pathogen, entry into and replication within host cells are thought to be critical to its ability to cause disease. L. pneumophila grown in one of its environmental hosts, Acanthamoeba castellanii, is phenotypically different from L. pneumophila grown on standard laboratory medium (BCYE agar). Although amoeba-grown L. pneumophila displays enhanced entry into monocytes compared to BCYE-grown bacteria, the mechanisms of entry used and the effects on virulence have not been examined. To explore whether amoeba-grown L. pneumophila differs from BCYE-grown L. pneumophila in these characteristics, we examined entry into monocytes, replication in activated macrophages, and virulence in mice. Entry of amoeba-grown L. pneumophila into monocytes occurred more frequently by coiling phagocytosis, was less affected by complement opsonization, and was less sensitive to microtubule and microfilament inhibitors than was entry of BCYE-grown bacteria. In addition, amoeba-grown L. pneumophila displays increased replication in monocytes and is more virulent in A/J, C57BL/6 Beige, and C57BL/6 mice. These data demonstrate for the first time that the intra-amoebal growth environment affects the entry mechanisms and virulence of L. pneumophila.     

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.     

Interaction of Legionella pneumophila with Acanthamoeba castellanii: uptake by coiling phagocytosis and inhibition of phagosome-lysosome fusion.

Legionella pneumophila is a facultative intracellular parasite able to survive within both human monocytes and amoebae. We have demonstrated that processing of L. pneumophila by the free-living amoeba Acanthamoeba castellanii shows many similarities to the processing of L. pneumophila by monocytes. These similarities include uptake of L. pneumophila by coiling phagocytosis and the subsequent confinement of L. pneumophila in a ribosome-studded phagosome. In addition, as in monocytes, inhibition of lysosomal fusion with phagosomes containing L. pneumophila was detected in amoebae. With all clinical isolates, inhibition of phagosomes-lysosome fusion correlated with virulence. However, with one of the environmental isolates tested, no significant difference in phagosome-lysosome fusion was observed between the virulent and avirulent forms. These results indicate that the avirulent form of this isolate differed from the virulent form in some other respect critical to intracellular survival. Therefore, intracellular multiplication of L. pneumophila within A. castellanii may not be solely dependent upon the inhibition of lysosomal fusion.     

Association of flagellum expression and intracellular growth of Legionella pneumophila.

We examined the role of the flagella of Legionella pneumophila in the infection of amoebae and human monocyte-like cells. Insertional mutants were constructed with mini-Tn10. Ten mutants (F-) which did not react with polyclonal L. pneumophila antiflagellar antisera were identified. Ten randomly selected mutants (F+) that did react with the polyclonal antiflagellar antiserum were also identified. The infectivity of these 20 mutants in Hartmannella vermiformis and human U937 cells was characterized. Seven of the 10 F- mutants were attenuated in their ability to multiply in the amoebae during the first 3 days of coincubation and failed to multiply in U937 cells. Three of the 10 F- mutants multiplied as well as the wild-type parent strain did in amoebae and to a limited degree in U937 cells. None of the 10 F+ mutants were attenuated in either the amoebae or U937 cells. While the flagellar structure is not essential for virulence, the ability of L. pneumophila to infect amoebae and human phagocytic cells appears to be linked to flagellar expression. We believe that the attenuated F- mutants contain insertions in genes critical to both flagellum expression and the infection process.     

The Legionella pneumophila GacA homolog (LetA) is involved in the regulation of icm virulence genes and is required for intracellular multiplication in Acanthamoeba castellanii

Legionella pneumophila, the causative agent of legionnaires' disease, is a broad-host-range facultative intracellular pathogen. Thus far, 24 genes (icm/dot genes) required for L. pneumophila intracellular growth, have been discovered. In this study, a deletion substitution was constructed in the L. pneumophila homolog of the gacA response regulator (letA) and its involvement in L. pneumophila pathogenicity and icm/dot gene expression was characterized. The letA mutant constructed had no intracellular growth defect when analyzed in HL-60 derived human macrophages, but it was found to be severely attenuated for intracellular growth in the protozoan host Acanthamoeba castellanii. The growth defect in amoebae was fully complemented by introducing the L. pneumophila letA gene on a plasmid. In addition, the LetA regulator was found to be involved in the expression of three icm genes (icmT, icmP and icmR). The level of expression of the icmT::lacZ and icmR::lacZ fusions was found to be higher, while the level of expression of the icmP::lacZ fusion was found to be lower when analyzed in the letA mutant strain, in comparison to the wild-type strain. We concluded that LetA has a moderate effect on icm/dot gene expression, but it probably plays a major role in the expression of L. pneumophila genes required for intracellular growth in protozoan hosts. A similar host specific phenotype was previously described for the RpoS sigma factor and the type II general secretion system of L. pneumophila.     

De novo synthesis of Legionella pneumophila antigens during intracellular growth in phagocytic cells.

Legionella pneumophilia is a gram-negative rod which is able to multiply within phagocytic cells. The process of phagocytosis leads to a rapid environmental change that might require a coordinate regulation of gene expression to ensure intracellular survival. Since there is little information on up- and downregulation of genes during the early phases of phagocytosis, we radiolabeled intracellular L. pneumophila at different times after phagocytosis by macrophages of the Mono Mac 6 cell line and immunoprecipitated antigens with antilegionella sera or monoclonal antibodies. We could identify two antigens which were upregulated, one of which was the Mip protein, three antigens which were downregulated, and three antigens which were not detectable in extracellularly grown L. pneumophila. The Mip protein was stained most intensively 4 to 8 h after intracellular infection, suggesting that it is needed during intracellular multiplication rather than initiation of infection. A 44-kDa antigen which was not detectable during extracellular growth was most prominent from 2 to 4 h postinfection when Mono Mac 6 cells were used as phagocytic cells. The 44-kDa antigen was also expressed during growth with Acanthamoeba castelanii, MRC-5, and U937 cells but with different kinetics. Synthesis of this antigen was not dependent on protein synthesis of the host cell. Since the 44-kDa antigen could be precipitated by an antiserum produced against a recombinant Escherichia coli harboring a plasmid with an L. pneumophila insert which also codes for the mip gene, we believe that the corresponding gene is within the vicinity of the mip gene. We named this protein legionella intracellular growth antigen (LIGA), since it could be found exclusively in intracellularly grown L. pneumophila.     

Liquid medium for growth of Legionella pneumophila.

The medium described is a simple yeast extract broth capable of growing large number of Legionella neumophila, the causative organism of Legionnaires disease. Filtration was chosen as a means of sterilization, since medium that was autoclaved did not support growth without the presence of Norite A. The filtered medium gave rapid cell growth and maintained the initial antigen production. The observed generation time was 99 min with a maximum cell population of 2 X 10(2) COLONY-FORMING UNITS PER ML IN APPROXIMATELY 40 H.     

A plasmid in Legionella pneumophila.

Sixteen strains from the six serogroups of Legionella pneumophila were examined for the presence of extrachromosomal genetic elements by a modified cleared lysate procedure, dye-buoyant centrifugation, and agarose gel electrophoresis. Two strains, Atlanta-1 and Atlanta-2 from serogroup II, each contained a plasmid of cryptic function with a molecular weight of ca. 30 megadaltons.     

Chemically defined medium for Legionella pneumophila growth.

A chemically defined medium containing 18 amino acids, inorganic salts, rhamnose, choline, and ferric pyrophosphate has been developed. The final concentrations of salts and amino acids were modeled after yeast extract. This medium supported the growth of four serogroups of Legionella pneumophila. Growth in shake cultures at 37 degrees C produced a lag time of approximately 5 h and a generation time of 4 h with a maximum growth yield of 10 9 colony-forming units per ml. A soluble brown pigment was observed in the stationary phase of growth. The optimal pH was 6.3. Rhamnose and choline were stimulatory; arginine, serine, threonine, cysteine, valine, and methionine were essential. Supplemental iron was not required to attain maximum growth, but iron deprivation caused an extended lag phase.     

Amino acid requirements for Legionella pneumophila growth.

The amino acids L-arginine, L-isoleucine, L-leucine, L-methionine, L-serine, L-threonine, and L-valine were essential for the growth of Legionella pneumophila in a chemically defined medium. A partial requirement for L-cysteine (or L-cystine) was also observed. A minimal medium containing only the eight required amino acids supported the growth of this bacterium only if the medium was supplemented with L-glutamic acid. This latter compound was the only amino acid capable of stimulating growth in the eight-amino acid medium.     

Differences in protein synthesis between wild type and intracellular growth-deficient strains of Legionella pneumophila in U937 and Acanthamoeba polyphaga

An important aspect of Legionnaires' disease is the growth of the causative agent, Legionella pneumophila, within infected host cells. Many proteins including stress proteins of L. pneumophila were strongly induced in a wild type strain that had been used to infect U937 human macrophage-like cells. In contrast, the expression of the proteins was much weaker within a protozoan host, Acanthamoeba polyphaga. The results suggested that active bacterial protein synthesis is required more within macrophages than within protozoa for adaptation of L. pneumophila to intracellular environments. The synthesis of these proteins was not observed in intracellular growth-deficient strains after infection in either type of host cells. The inability of protein synthesis in these strains is correlated with their inability of intracellular growth. Furthermore, on U937 infection, the synthesis of beta-galactosidase encoded in an inducible reporter construct immediately ceased in the in intracellular growth-deficient strains after infection, while the wild type strain was able to synthesize it during the course of infection. These results suggested that the intracellular growth of Legionella pneumophila within macrophages requires active protein synthesis from an earlier stage of bacterial infection.     

Cryptococcus neoformans var. gattii can exploit Acanthamoeba castellanii for growth.

It has recently been proposed that the origin and maintenance of virulence in certain environmental fungi is influenced by their interactions with non-vertebrate hosts such as amoebae and nematodes. In prior studies we have shown that the interactions of the soil amoebae Acanthamoeba castellanii with Cryptococcus neoformans varieties neoformans and grubii resemble those with macrophages. Here we extend those studies to C. neoformans variety gattii and describe quantitative differences in the type and outcome of the interactions observed relative to the other varieties. C. neoformans var. gattii proliferated in the presence of A. castellanii but the interaction was primarily extracellular with a paucity of phagocytic events. Experiments with acapsular cells coated with polysaccharide suggest that differences in the capsule structure may be responsible for the different interactions between cells of varieties neoformans, grubii, and gattii with amoebae. The ability of C. neoformans var. gattii to exploit amoebae indicates that despite major biological differences between C. neoformans varieties, all retain the ability to be pathogenic for A. castellanii.     

Comparison of liquid growth media for Legionella pneumophila.

Ten liquid media were compared under standard conditions for their ability to support the growth of Legionella pneumophila. Modified gonococcal-ferric cysteine broth (without sodium chloride) supplemented with 1% yeast extract yielded the best overall growth of the one strain of L. pneumophila examined. Growth rates were independent of pH changes which occurred during incubation. The growth rates of 10 different strains of L.pneumophila were compared in this medium. There appeared to be little difference in the growth rates of strains passaged frequently or infrequently, or between environmental and clinical isolates. Moderate aeration resulted in a faster growth rate and in approximately a 1 log10 higher final cell concentration as compared to a static broth culture. These experiments demonstrate that there are moderate to marked differences among the various media described in the literature and that no liquid medium yet developed supports rapid growth of L. pneumophila incubated without shaking.     

A hemidominant Naip5 allele in mouse strain MOLF/Ei-derived macrophages restricts Legionella pneumophila intracellular growth

Mouse-derived macrophages have the unique ability to restrict or permit Legionella pneumophila intracellular growth. The common inbred mouse strain C57BL/6J (B6) restricts L. pneumophila growth, whereas macrophages derived from A/J mice allow >10(3)-fold bacterial growth within three days. This phenotypic difference was mapped to the mouse Naip5 allele. The B6 restrictive Naip5 allele is dominant, and six amino acid changes in its product were predicted to control permissiveness. By using the wild-derived mouse strain MOLF/Ei, we found that MOLF/Ei-derived macrophages also restrict L. pneumophila growth, yet the Naip5 protein is identical to the A/J Naip5 at the six-amino-acid signature. The MOLF/Ei restrictive trait, unlike that of B6-derived macrophages, was not dominant over the A/J trait. In spite of this phenotypic difference, the L. pneumophila growth restriction in MOLF/Ei macrophages was mapped to the Naip5 region as well, indicating that the originally predicted change in the A/J Naip5 allele may not be critical for restriction. In the product of the A/J Naip5 permissive allele, there are four unique amino acid changes that map to a NACHT-like domain. Similar misregulating mutations have been identified in the NACHT domains of Nod-like receptor (NLR) proteins. Therefore, one of these mutations may be critical for restriction of L. pneumophila intracellular growth, and this parallels results found with human NLR variants with defects in the innate immune response.     

2-Deoxy-D-glucose inhibits intracellular multiplication and promotes intracellular killing of Legionella pneumophila in A/J mouse macrophages.

Legionella pneumophila can grow intracellularly in A/J mouse macrophages. 2-Deoxy-D-glucose (2dG) (0.1, 1, and 10 mM) inhibited intracellular multiplication and promoted intracellular killing of L. pneumophila dose dependently when it was added to the culture medium of macrophage monolayers, whereas it did not inhibit the bacterial growth in buffered yeast extract broth, which was used for an L. pneumophila culture. The effect of 2dG was reversible because the surviving bacteria resumed intracellular multiplication after the washing away of 2dG from the culture. The effect of 2dG was also competitively inhibited by high concentrations of glucose. The inhibitory effect of 2dG was not attributed to the inhibition of bacterial phagocytosis by macrophages. Furthermore, sodium fluoride (0.1 and 1 mM), cycloheximide (0.1 and 1 microgram/ml), and tunicamycin (1, 2, and 5 micrograms/ml) did not promote the killing of L. pneumophila in macrophages, implying that the inhibitory effect of 2dG cannot be attributed to the inhibition of glycolysis, protein synthesis, and protein glycosylation in macrophages. We suggest that 2dG promotes intracellular killing of L. pneumophila by activating some novel killing mechanism of macrophages.     

Heterogeneity in intracellular replication and cytopathogenicity of Legionella pneumophila and Legionella micdadei in mammalian and protozoan cells.

In contrast to Legionella pneumophila, little is known about the pathogenesis of other legionellae species that are capable of causing Legionnaires' disease. In this report, we contrast L. pneumophila and L. micdadei for their cytopathogenicity and intracellular replication within mammalian and protozoan cells. We show by transmission electron microscopy that L. micdadei replicates within an endoplasmic reticulum (RER)-free phagosome within human macrophages, alveolar epithelial cells, and within the protozoan Hartmannella vermiformis. In contrast, L. pneumophila replicates within a RER-surrounded phagosome within the same host cells. In contrast to replication of L. pneumophila within Acanthamoebae polyphaga, L. micdadei does not replicate within this protozoan host. Despite the prolific intracellular replication, L. micdadei is less cytopathogenic to all host cells than L. pneumophila. Since both species replicate intracellularly to a similar level, we have examined whether the reduced cytopathogenicity of L. micdadei is due to a reduced capacity to induce apoptosis or pore formation-mediated necrosis, both of which contribute to killing of the host cell by L. pneumophila. The data show that both species induced apoptosis-mediated killing of mammalian cells to a similar level. In contrast to L. pneumophila, expression of the pore-forming toxin by L. micdadei and its necrotic effect on macrophages and alveolar epithelial cells is undetectable. This has been further confirmed showing that L. micdadei is completely defective in contact-dependent haemolysis of RBCs, an activity mediated by the pore-forming toxin. Finally, in contrast to L. pneumophila, there was no significant intrapulmonary replication of L. micdadei in the A/J mice animal model. Our data show dramatic differences between L. pneumophila and L. micdadei in intracellular replication, cytopathogenicity, and infectivity to mammalian and protozoan cells.     

A Legionella pneumophila gene encoding a species-specific surface protein potentiates initiation of intracellular infection.

To investigate the pathogenesis of Legionnaires disease at a molecular level, we mutated by directed allelic exchange a gene encoding a Legionella pneumophila-specific 24,000-dalton (Da) surface protein. Southern hybridization and immunoblot analyses demonstrated that the predicted DNA rearrangement occurred in L. pneumophila with a specific loss of 24-kDa antigen expression. Compared with its isogenic parent, the mutant was significantly impaired in its ability to infect transformed U937 cells, a human macrophagelike cell line; i.e., the bacterial inoculum of the mutant strain that was required to initiate infection of the macrophage monolayer was ca. 80-fold greater than that of the isogenic parent strain. The mutant strain regained full infectivity on reintroduction of a cloned 24-kDa protein gene, indicating that the reduced infectivity was due specifically to the mutation in that gene. Compared with the parent strain, the mutant strain was recovered at titers that were ca. 10-fold lower shortly after infection, but it exhibited a similar intracellular growth rate over the next 40 h, indicating that the mutant was defective in its ability to initiate macrophage infection rather than in its ability to replicate intracellularly. When opsonized, the mutant strain was still significantly less infectious than the parent strain, despite equivalent macrophage association, suggesting that the mutant was not merely missing a ligand for macrophage attachment. The mutant also exhibited reduced infectivity in explanted human alveolar macrophages, demonstrating the relevance of the U937 cell model for analyzing this mutant phenotype. These results represent the first identification of a cloned L. pneumophila gene that is necessary for optimal intracellular infection; we designate this gene mip, for macrophage infectivity potentiator.