Identification of mip-like genes in the genus Legionella.

The mip gene of Legionella pneumophila serogroup 1 strain AA100 encodes a 24-kilodalton surface protein (Mip) and enhances the abilities of L. pneumophila to parasitize human macrophages and to cause pneumonia in experimental animals. To determine whether this virulence factor is conserved in the genus Legionella, a large panel of Legionella strains was examined by Southern hybridization and immunoblot analyses for the presence and expression of mip-related sequences. Strains representing all 14 serogroups of L. pneumophila contained a mip gene and expressed a 24-kilodalton Mip protein. Although the isolates of the 29 other Legionella species did not hybridize with mip DNA probes under high-stringency conditions, they did so at reduced stringency. In support of the notion that these strains possess mip-like genes, these species each expressed a protein (24 to 31 kilodaltons in size) that reacted with specific Mip antisera. Moreover, the cloned mip analog from Legionella micdadei encoded the cross-reactive protein. Thus, mip is conserved and specific to L. pneumophila, but mip-like genes are present throughout the genus, perhaps potentiating the intracellular infectivity of all Legionella species.     

Interaction of Legionella micdadei with human monocytes.

We have recently shown that Legionella micdadei is ingested, but not killed, by human neutrophils. Herein we investigate the role of human monocytes in defense against this organism. Serum and monocytes from normal donors having no detectable antibody to L. micdadei were used. Egg-passaged L. micdadei organisms multiplied inside these monocytes with a peak growth of 2 log units within 12 h. No growth occurred when monocytes were omitted or when sonicated monocytes were used. Electron microscopy 18 h after infection revealed these organisms to be intracellular in normal-appearing phagosomes. When the input multiplicity of L. micdadei was greater than 1 CFU per monocyte, no intracellular growth occurred. When egg-passaged Legionella pneumophila organisms were used, intracellular organisms were found in phagosomes studded with ribosomes at the same time period. Peak intracellular growth of L. pneumophilia occurred by 48 h. L. micdadei activated the complement system and was opsonized by C3. However the use of complement-depleted (heat-inactivated) serum as the opsonic source had no effect on the bacterium's ingestion or growth in the monocyte. Thus, L. micdadei multiples in human monocytes. This entry and growth is independent of antibody or complement. The intracellular locations of L. micdadei and L. pneumophila differ, suggesting different mechanisms for the survival of these two organisms in the monocyte.     

Monoclonal antibodies to Legionella Mip proteins recognize genus- and species-specific epitopes.

Monoclonal antibodies (MAbs) against the virulence-associated Mip protein of Legionella spp. were raised by immunizing BALB/c mice with (i) Legionella pneumophila, (ii) Legionella micdadei, and (iii) purified recombinant native Mip protein cloned from L. pneumophila Philadelphia 1. Following screening of seeded wells by immunoblot analysis with homologous antigens, eight Mip-specific MAbs were found. These MAbs were chosen to investigate the antigenic diversity of Mip proteins in the genus Legionella. Mip was detected in 82 Legionella strains representing all 34 species tested. One of these MAbs, obtained from immunization with L. micdadei, recognized an epitope common to all Legionella species tested by immunoblot analysis. Another MAb was discovered to be specific for the Mip protein of L. pneumophila. The remaining six MAbs recognized 18 to 79% of Legionella species included in this study. By making use of the MAbs introduced in this study, it could be shown that, based on Mip protein epitope expression, Legionella species can be divided into at least six antigenetically distinct groups. As demonstrated by 43 L. pneumophila strains representing all serogroups, no antigenic diversity of Mip proteins was found for this species. In addition, 18 non-Legionella species, including Chlamydia trachomatis, Neisseria meningitidis, Pseudomonas aeruginosa, and Saccharomyces cerevisiae, all of which are known to carry genes homologous to the Legionella mip genes, were reacted against all eight MAbs. No cross-reactivity was detectable in any of those strains.     

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.     

Nucleotide sequence analysis of the Legionella micdadei mip gene, encoding a 30-kilodalton analog of the Legionella pneumophila Mip protein.

After the demonstration of analogs of the Legionella pneumophila macrophage infectivity potentiator (Mip) protein in other Legionella species, the Legionella micdadei mip gene was cloned and expressed in Escherichia coli. DNA sequence analysis of the L. micdadei mip gene contained in the plasmid pBA6004 revealed a high degree of homology (71%) to the L. pneumophila mip gene, with the predicted secondary structures of the two Mip proteins following the same pattern. Southern hybridization experiments, with the plasmid pBA6004 as the probe, suggested that the mip gene of L. micdadei has extensive homology with the mip-like genes of several Legionella species. Furthermore, amino acid sequence comparisons revealed significant homology to two eukaryotic proteins with isomerase activity (FK506-binding proteins).     

Cross-reactive Legionella antigens and the antibody response during infection

In order to define cross-reactive Legionella antigens suitable for diagnostic purposes, we investigated sonicate antigens from two Legionella species, including two serogroups of L. pneumophila. The antigens were reacted with heterologous and homologous rabbit antisera in Western blot. Sera from seven patients with culture-verified L. pneumophila infection and nine patients with serologically confirmed L. micdadei infection were also investigated for reactivity with the corresponding antigens. Among the cross-reactive Legionella antigens defined, non-specific reactivity in patients' sera with the 58-kDa common antigen (CA) was noted. Specific reactions were observed with the Legionella flagellum antigen and with the macrophage infectivity potentiator (Mip) protein; with both antigens, however, the reactive sera were too few to suggest the use of a single antigen in a diagnostic test.     

Abscess and empyema caused by Legionella micdadei.

Legionella micdadei is the second most common species implicated in the occurrence of Legionella pneumonia (D. J. Bremer, Semin. Respir. Infect. 4:190-205, 1987). Although there has been a reported lung abscess caused by dual infection (L. micdadei and L. pneumophila), there are no known cases of L. micdadei as the only causative organism. We report a case of a patient with a lung abscess from which L. micdadei was the sole organism isolated.     

Ingestion of Legionella micdadei inhibits human neutrophil function.

Legionella micdadei is a human pathogen which survives within leukocytes. To determine how this organism escapes intracellular destruction, we examined its effect on human neutrophil activity. Neutrophils were allowed to ingest L. micdadei prior to evaluation of functional activity. Compared with control cells which did not ingest organisms, cells ingesting L. micdadei showed significantly depressed production of superoxide anion (24.5 +/- 9.0 nmol/10(6) cells per 15 min versus 6.9 +/- 3.2 nmol/10(6) cells per 15 min, respectively; P = 0.002), chemotaxis (43.9 +/- 0.8 mm versus 0.9 +/- 1.3 mm of directed migration, respectively; P = 0.001) and bactericidal activity against Staphylococcus aureus (97.9% versus 37.6% of ingested organisms killed, respectively; P = 0.001). Similar degrees of inhibition could not be demonstrated when either Staphylococcus aureus or Escherichia coli was ingested by cells prior to evaluation. Inhibition of neutrophil function did not occur when phagocytosis of L. micdadei was prevented. However, inhibition occurred with heat-killed as well as with viable organisms. The inhibition of neutrophil function by ingested L. micdadei may help explain the bacterium's ability to survive intracellularly and may begin to explain the pathogenesis of this disease.     

Legionella micdadei (Pittsburgh pneumonia agent): direct fluoresent-antibody examination of infected human lung tissue and characterization of clinical isolates.

Legionella micdadei (Pittsburgh pneumonia agent) was identified by direct fluorescent-antibody (DFA) examination of lung tissue in six of seven persons diagnosed previously as having L. micdadei pneumonia only by histopathology and in four persons who also had positive cultures of the organism. No cross-reactions occurred with monospecific DFA conjugates prepared against Legionella pneumophila serogroups 1 to 6, Legionella bozemanii, Legionella dumoffii, and Legionella gormanii. One person had L. pneumophila serogroup 6 identified by DFA examination of lung tissue and subsequent culture of stored pulmonary secretions. Characterization of the four strains of L. micdadei revealed specific DFA reactions, bacteriological behavior, and cellular fatty acid composition that allow identification of the organism. DFA testing appears to be a sensitive method for identifying L. micdadei prescent in human lung tissue or cultured on artificial media.     

Biochemical and functional analyses of the Mip protein: influence of the N-terminal half and of peptidylprolyl isomerase activity on the virulence of Legionella pneumophila

The virulence factor Mip (macrophage infectivity potentiator) contributes to the intracellular survival of Legionella pneumophila, the causative agent of Legionnaires' disease. The protein consists of two domains that are connected via a very long alpha-helix (A. Riboldi-Tunnicliffe et al., Nat. Struct. Biol. 8:779-783, 2001). The fold of the C-terminal domain (residues 100 to 213) is closely related to human FK506-binding protein (FKBP12), and like FKBP12, Mip exhibits peptidylprolyl cis/trans isomerase (PPIase) activity. The alpha-helical N-terminal domain is responsible for the formation of very stable Mip homodimers. In order to determine the importance of the homodimeric state of Mip for its biochemical activities and for infectivity of Legionella, a truncated, monomeric Mip variant [Mip((77-213))] was overexpressed in Escherichia coli and characterized biochemically. In vitro isomerase activity assays revealed that the altered protein exhibits full isomerase activity towards peptide substrates. However, the deletion resulted in a dramatic loss in the efficiency of refolding of reduced and carboxy-methylated RNase T(1). By cis complementation of the Mip-negative mutant strain L. pneumophila JR32-2, we constructed the strain L. pneumophila JR32-2.4, which expresses an N-terminally truncated variant of Mip. Infection studies with these strains revealed that the N-terminal part and the dimerization of Mip but not its PPIase activity are necessary for full virulence in Acanthamoeba castellanii. Infection of guinea pigs showed that strains with dimerization-deficient Mip (JR32-2.4) or a very low PPIase activity (JR32-2.2) were significantly attenuated in the animal model. These results suggest a different role of the PPIase activity and the N-terminally mediated dimeric state of Mip in monocellular systems and during the infection of guinea pigs.     

Legionella species of different human prevalence induce different rates of apoptosis in human monocytic cells

Legionella species of different human prevalence were examined with respect to induction of apoptosis in the human monocytic cell line Mono Mac 6 (MM6). L. pneumophila serogroup 1 (Pontiac), L. pneumophila serogroup 1 (Philadelphia-1), L. longbeachae serogroup 1, L. gormanii, L. micdadei and L. steigerwaltii were used to infect MM6 cells. Subsequent induction of apoptosis was investigated by enzyme-linked immunosorbent assay (ELISA), gel electrophoresis of cellular DNA extracts, and staining of cells with the DNA dye 4', 6-diamidino-2-phenylindole (DAPI). Additionally, the concomitant occurrence of infection and apoptosis was demonstrated by a combination of immunohistochemistry with nuclear DAPI counterstaining. Induction of apoptosis in MM6 cells by a given species of the genus Legionella correlates with their human prevalence rather than with their ability to multiply within this human monocytic cell line. Furthermore, we found that initiation of apoptosis of Mono Mac 6 cells was dependent on direct adherence of the pathogenic bacteria to the host cell and was triggered by extracellular bacteria.     

Comparative Analysis of Legionella pneumophila and Legionella micdadei Virulence Traits

While the majority of Legionnaire's disease has been attributed to Legionella pneumophila, Legionella micdadei can cause a similar infection in immunocompromised people. Consistent with its epidemiological profile, the growth of L. micdadei in cultured macrophages is less robust than that of L. pneumophila. To identify those features of the Legionella spp. which are correlated to efficient growth in macrophages, two approaches were taken. First, a phenotypic analysis compared four clinical isolates of L. micdadei to one well-characterized strain of L. pneumophila. Seven traits previously correlated with the virulence of L. pneumophila were evaluated: infection and replication in cultured macrophages, evasion of phagosome-lysosome fusion, contact-dependent cytotoxicity, sodium sensitivity, osmotic resistance, and conjugal DNA transfer. By nearly every measure, L. micdadei appeared less virulent than L. pneumophila. The surprising exception was L. micdadei 31B, which evaded lysosomes and replicated in macrophages as efficiently as L. pneumophila, despite lacking both contact-dependent cytopathicity and regulated sodium sensitivity. Second, in an attempt to identify virulence factors genetically, an L. pneumophila genomic library was screened for clones which conferred robust intracellular growth on L. micdadei. No such loci were isolated, consistent with the multiple phenotypic differences observed for the two species. Apparently, L. pneumophila and L. micdadei use distinct strategies to colonize alveolar macrophages, causing Legionnaire's disease.     

Acid-fast bacilli in sputum: a case of Legionella micdadei pneumonia.

Legionella micdadei has been implicated as a cause of nosocomial pneumonia. There are no reports of L. micdadei pneumonia diagnosed by acid-fast stain of expectorated sputum. We report a case of L. micdadei pneumonia in which expectorated sputum harbored acid-fast bacteria that reacted specifically with fluorescent antiserum to L. micdadei, confirmed by culture. In a patient at risk for nosocomial infection, the differential diagnosis of a positive sputum stain for acid-fast bacilli should include L. micdadei in addition to mycobacteria. Therapy for L. micdadei infection should be considered pending confirmation of the diagnosis.     

Legionella pneumophila Mip, a surface-exposed peptidylproline cis-trans-isomerase, promotes the presence of phospholipase C-like activity in culture supernatants

The type II secretion system of Legionella pneumophila promotes pathogenesis. Among the Legionella type II-dependent exoenzymes is a p-nitrophenol phosphorylcholine (p-NPPC) hydrolase whose activity is only partially explained by the PlcA phospholipase C. In a screen to identify other factors that promote secreted hydrolase activity, we isolated a mip mutant. L. pneumophila Mip is a surface-exposed, FK506-binding protein that is needed for optimal infection and has peptidylproline cis-trans-isomerase (PPIase) activity. Since the molecular target of Mip was undefined, we investigated a possible relationship between Mip and the secreted p-NPPC hydrolase activity. In the mip mutant there was a 40 to 70% reduction in secreted activity that was successfully complemented by providing mip on a plasmid. A similar phenotype was observed when we examined four other independently derived mip mutants, and in all cases the defect was complemented by reintroduction of mip. Thus, mip promotes the presence of a p-NPPC hydrolase activity in culture supernatants. We also found that the C terminus of Mip is required for this effect. When supernatants were examined by anion-exchange chromatography, the p-NPPC hydrolase activity associated with Mip proved to be type II dependent but distinct from PlcA. This conclusion was supported by the phenotype of a newly constructed mip plcA double mutant. Thus, Mip promotes the elaboration of a new type II exoprotein. These data provide both the first evidence for a target for Mip and the first indication that a surface PPIase is involved in the secretion or activation of proteins beyond the outer membrane.     

Pathogenicity of Legionella pneumophila.

The bacterium Legionella pneumophila is the principal etiologic agent of Legionnaires' disease, a form of lobar pneumonia. Ubiquitous in aquatic environments, the gram-negative Legionella organism is a facultative, intracellular parasite of protozoa. The pathogenesis of legionellosis is largely due to the ability of L. pneumophila to invade and grow within alveolar macrophages, and it is widely believed that this ability results from a prior adaptation to intracellular niches in nature. Indeed, intracellular legionellae display a remarkable capacity to avoid endosomal and lysosomal bactericidal activities and to establish a unique replicative phagosome. In recent years, much progress has been made toward identifying the bacterial factors that promote intracellular infection and virulence. Surface structures that enhance infection include LPS, flagella, type IV pili, an outer membrane porin, and the Mip propyl-proline isomerase. Both type II and type IV protein secretion systems are critical for L. pneumophila pathogenesis. Whereas the type II (Lsp) system secretes a collection of degradative enzymes, the type IV (Dot/Icm) system likely exports effector proteins that are especially critical for trafficking of the Legionella phagosome. In addition to facilitating pilus formation and type II secretion, the inner membrane prepilin peptidase (PilD) of L. pneumophila appears to mediate a third, potentially novel pathway that is operative in the mammalian host. Periplasmic and cytosolic infectivity determinants include a catalase-peroxidase and the HtrA and Hsp60 stress-response proteins. The stationary phase response and the iron acquisition functions of L. pneumophila also play key roles in pathogenesis, as do a number of other loci, including the pts, mil and enh genes.     

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.     

Identification of Legionella pneumophila-specific genes by genomic subtractive hybridization with Legionella micdadei and identification of lpnE, a gene required for efficient host cell entry

Legionella pneumophila is a ubiquitous environmental organism and a facultative intracellular pathogen of humans. To identify genes that may contribute to the virulence of L. pneumophila, we performed genomic subtractive hybridization between L. pneumophila serogroup 1 strain 02/41 and L. micdadei strain 02/42. A total of 144 L. pneumophila-specific clones were sequenced, revealing 151 genes that were absent in L. micdadei strain 02/42. Low-stringency Southern hybridization was used to determine the distribution of 41 sequences, representing 40 open reading frames (ORFs) with a range of putative functions among L. pneumophila isolates of various serogroups as well as strains of Legionella longbeachae, L. micdadei, Legionella gormanii, and Legionella jordanis. Twelve predicted ORFs were L. pneumophila specific, including the gene encoding the dot/icm effector, lepB, as well as several genes predicted to play a role in lipopolysaccharide biosynthesis and cell wall synthesis and several sequences with similarity to virulence-associated determinants. A further nine predicted ORFs were in all L. pneumophila serotypes tested and an isolate of L. gormanii. These included icmD, the 5' end of a pilMNOPQ locus, and two genes known to be upregulated during growth within macrophages, cadA2 and ceaA. Disruption of an L. pneumophila-specific gene (lpg2222 locus tag) encoding a putative protein with eight tetratricopeptide repeats resulted in reduced entry into the macrophage-like cell line, THP-1, and the type II alveolar epithelial cell line, A549. The gene was subsequently renamed lpnE, for "L. pneumophila entry." In summary, this investigation has revealed important genetic differences between L. pneumophila and other Legionella species that may contribute to the phenotypic and clinical differences observed within this genus.     

Identification of a gene that affects the efficiency of host cell infection by Legionella pneumophila in a temperature-dependent fashion

The ability to infect host cells is critical for the survival and replication of intracellular pathogens in humans. We previously found that many genes involved in the ability of Legionella pneumophila to infect macrophages are not expressed efficiently under standard laboratory growth conditions. We have developed an approach using expression of L. pneumophila genes from an exogenous constitutive promoter on a low-copy-number vector that allows identification of genes involved in host cell infection. Through the use of this strategy, we found that expression of a gene, lvhB2, enhances the efficiency of L. pneumophila infection of mammalian cells. The putative protein encoded by lvhB2 has similarity to structural pilin subunits of type IV secretion systems. We confirmed that this gene plays a role in host cell infection by the construction of an in-frame deletion in the L. pneumophila lvhB2 gene and complementation of this mutant with the wild-type gene. The lvhB2 mutant does not display a very obvious defect in interactions with host cells when the bacteria are grown at 37 degrees C, but it has an approximately 100-fold effect on entry and intracellular replication when grown at 30 degrees C. These data suggest that lvhB2 plays an important role in the efficiency of host cell infection by L. pneumophila grown at lower temperatures.     

Induction of apoptosis of human macrophages in vitro by Legionella longbeachae through activation of the caspase pathway

The cytotoxicity of the facultative intracellular bacterium, Legionella longbeachae, an important cause of legionellosis, was characterised. Apoptosis was induced in HL-60 cells, a human macrophage-like cell line, during the early stages of infection and induction of apoptosis correlated with cytotoxicity. Apoptosis was confirmed by agarose gel electrophoresis of fragmented DNA, surface exposure of phosphatidylserine and propidium iodide labelling of host cell nuclei. The involvement of macrophage infectivity potentiator (Mip) protein, a known virulence factor of L. longbeachae, was also examined. A mip mutant of L. longbeachae induced apoptosis of HL-60 cells but failed to multiply intracellularly, suggesting that intracellular replication of L. longbeachae is not essential for the induction of apoptosis of HL-60 cells. Furthermore, induction of apoptosis of L. longbeachae-infected macrophages was mediated by activation of the caspase pathway but might be independent of tumour necrosis factor-alpha- and Fas-mediated signal transduction pathways.     

Role of the alveolar macrophage in host defense and immunity to Legionella micdadei pneumonia in the guinea pig

Guinea pigs develop a lethal pneumonia after intratracheal infection with Legionella micdadei, and the lung displays pathological changes similar to those observed in humans. To investigate the role of the resident alveolar macrophage in the pathogenesis of L. micdadei pneumonia, guinea pig alveolar macrophages obtained by bronchoalveolar lavage were cultured in vitro and infected with L. micdadei. In the absence of opsonins L. micdadei was phagocytized by, and multiplied within, alveolar macrophages with greater than a 100-fold increase in cell-associated colony forming units over 20 h. L. micdadei opsonized with complement or antibody multiplied within alveolar macrophages at the same rate as unopsonized bacteria. Guinea pigs which were treated with antimicrobials after infection with L. micdadei and recovered from the pneumonia were immune to challenge with an otherwise lethal inoculum of L. micdadei. However, the growth curve of both unopsonized and opsonized L. micdadei in the alveolar macrophages from immune animals was essentially identical to that in macrophages from susceptible animals. Thus, the resident alveolar macrophage is not capable of limiting the growth of Legionella. Rather, the alveolar macrophages appear to be the primary site of Legionella multiplication within the lung. Although alveolar macrophages may participate in other aspects of pulmonary immunity to the legionellae, these data indicate that the alveolar macrophage alone does not act as an effector cell in cell-mediated immunity to Legionella.