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Journal of Bacteriology, January 2006, p. 556-568, Vol. 188, No. 2
0021-9193/06/$08.00+0     doi:10.1128/JB.188.2.556-568.2006
Copyright © 2006, American Society for Microbiology. All Rights Reserved.

Identification of Listeria monocytogenes Genes Contributing to Intracellular Replication by Expression Profiling and Mutant Screening

Biju Joseph,^1, Karin Przybilla,^1,, Claudia Stühler,¹ Kristina Schauer,² Jörg Slaghuis,¹ Thilo M. Fuchs,² and Werner Goebel^1*

Theodor-Boveri-Institut (Biozentrum), Lehrstuhl für Mikrobiologie, Universität Würzburg, D-97074 Würzburg, Germany,¹ Zentralinstitut für Ernährungs- und Lebensmittelforschung (ZIEL), Abteilung Mikrobiologie, Technische Universität München, D-85350 Freising, Germany²

Received 16 June 2005/ Accepted 16 October 2005

	ABSTRACT

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A successful transition of Listeria monocytogenes from the extracellular to the intracellular environment requires a precise adaptation response to conditions encountered in the host milieu. Although many key steps in the intracellular lifestyle of this gram-positive pathogen are well characterized, our knowledge about the factors required for cytosolic proliferation is still rather limited. We used DNA microarray and real-time reverse transcriptase PCR analyses to investigate the transcriptional profile of intracellular L. monocytogenes following epithelial cell infection. Approximately 19% of the genes were differentially expressed by at least 1.6-fold relative to their level of transcription when grown in brain heart infusion medium, including genes encoding transporter proteins essential for the uptake of carbon and nitrogen sources, factors involved in anabolic pathways, stress proteins, transcriptional regulators, and proteins of unknown function. To validate the biological relevance of the intracellular gene expression profile, a random mutant library of L. monocytogenes was constructed by insertion-duplication mutagenesis and screened for intracellular-growth-deficient strains. By interfacing the results of both approaches, we provide evidence that L. monocytogenes can use alternative carbon sources like phosphorylated glucose and glycerol and nitrogen sources like ethanolamine during replication in epithelial cells and that the pentose phosphate cycle, but not glycolysis, is the predominant pathway of sugar metabolism in the host environment. Additionally, we show that the synthesis of arginine, isoleucine, leucine, and valine, as well as a species-specific phosphoenolpyruvate-dependent phosphotransferase system, play a major role in the intracellular growth of L. monocytogenes.

	INTRODUCTION

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Listeria monocytogenes is a gram-positive, food-borne bacterium that is widely distributed in nature and can cause serious infection in susceptible individuals (9). The infection pathogenesis of this facultative intracellular pathogen includes phases where the bacteria successfully proliferate in the challenging environment in a variety of mammalian cell types like epithelial cells, endothelial cells, hepatocytes, dendritic cells, and macrophages. While invading the host cells, L. monocytogenes is confronted with suboptimal growth conditions, such as a rapid pH drop within the phagosome (1). Following early escape from the primary phagosome by membrane lysis, the pathogen is released into the cytosol where it encounters conditions of nutrient and iron starvation. The genes essential for the internalization of L. monocytogenes by the mammalian host cells (inlA and inlB), phagosomal escape (hly, plcA, and plcB), and intra- and intercellular motility (actA) have been extensively studied in the past years (45). All these virulence genes are controlled by PrfA, a central transcription regulator, which activates gene transcription by binding to a specific site termed the PrfA box and recruiting RNA polymerase to the PrfA-dependent promoters (6). Using a microinjection technique, we observed a prfA mutant of L. monocytogenes to replicate much less efficiently than the wild-type strain. However, none of the known virulence genes was shown to be responsible for this reduced intracellular replication (17). Likewise, a Listeria innocua strain equipped with the prfA and hly genes encoding listeriolysin for phagosomal escape into the host cell's cytosol also showed a substantially lower cytosolic replication efficiency than that of L. monocytogenes (39).

While it is evident that the products of the virulence gene cluster and their regulator, PrfA, are indispensable for L. monocytogenes to reach the cytoplasm of mammalian cells, the specific set of genes necessary for cytosolic proliferation still lacks detailed description despite several approaches to characterize the genes and proteins involved in intracellular replication: the selective induction of 32 proteins was shown by two-dimensional electrophoresis when L. monocytogenes EGD was grown in J774 macrophages, but the nature of the proteins is unknown (19). By screening a library of Tn917-lac insertion mutants, the specific induction of genes for purine and pyrimidine biosynthesis as well as for arginine uptake in J774 cells was observed (21). Furthermore, the results of analysis of some L. monocytogenes mutants auxotrophic for amino acids and nucleobases indicated that synthesis of all three aromatic amino acids and adenine was essential for efficient cytosolic replication in J774 cells (27). Reduced proliferation in the cytosol of these mammalian host cells was also observed for a mutant defective in oppA encoding an oligopeptide-binding protein (2), a result that suggests that efficient uptake of oligopeptides may favor intracellular growth of L. monocytogenes in macrophages.

Recently, a transporter for phosphorylated hexoses, encoded by hpt, was identified in L. monocytogenes with high homology to the UhpT transporter of Escherichia coli. Expression of hpt proved to be strictly PrfA dependent, and an hpt mutant exhibited significantly reduced efficiency in cytosolic replication (8). However, complementation of L. innocua with the L. monocytogenes hpt gene did not substantially improve the replication capacity of this strain in the host cell's cytosol, suggesting further requirements of L. monocytogenes for efficient growth in this cellular compartment. Interestingly, an L. monocytogenes mutant lacking the lipoate protein ligase LplA1 was also found to be defective for growth specifically in the host cell cytosol. Further analysis suggested that abortive growth was due to loss of pyruvate dehydrogenase function whose E2 subunit is a major target for LplA1 (32). Specific metabolic requirements for replication in macrophages and epithelial cells have also been reported for Salmonella enterica serovar Typhimurium (22), Mycobacterium tuberculosis (43), and Shigella flexneri (26). These intracellular bacteria, however, replicate in specialized phagosomal compartments, and the growth requirements in these compartments are likely to be different from the requirements in the host cell's cytosol where L. monocytogenes multiplies.

To obtain a more comprehensive overview of genes deployed by L. monocytogenes to efficiently proliferate in mammalian cells, we determined the complete expression profile of L. monocytogenes replicating in the cytosol of mammalian cells. For that purpose, we compared the overall transcriptional activity of L. monocytogenes grown in the cytosol of epithelial cells to that of the same strain cultured extracellularly in rich medium by using whole-genome microarrays. This approach allowed the identification of 279 genes exhibiting increased mRNA levels and 272 genes with reduced mRNA levels under in vivo conditions. In parallel, we established a listerial mutant library by insertion duplication mutagenesis that represents approximately 13% of the genes of L. monocytogenes and screened it for strains with impaired replication capacity in Caco-2 cells, but not in brain heart infusion (BHI) medium. Seventeen percent of the listerial genome is devoted to carbon and nitrogen metabolism and transport proteins involved therein (16); of these genes, in this study we found an up-regulation of 65 genes intracellularly, and one of these genes, encoding a putative phosphoenolpyruvate-dependent phosphotransferase system (PTS) enzyme, is present in L. monocytogenes, but not in the nonpathogenic species L. innocua. This study shows for the first time a genome-wide analysis of gene regulation in intracellularly replicating L. monocytogenes. By combining two different approaches, microarray analysis and mutant screening, we partially expose the biological relevance of the observed adaptations of the listerial transcriptome to the intracellular environment.

	MATERIALS AND METHODS

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Bacterial strains, growth conditions, and cell lines. Strains used in this study are listed in Table 1. Escherichia coli strains XL2-Blue (Stratagene, La Jolla, CA) and DH5 were cultivated in Luria-Bertani (LB) medium at 37°C. L. monocytogenes EGD (serovar 1/2a) was grown in brain heart infusion (BHI) at 37°C or at 30°C and 42°C. When necessary, media were supplemented with erythromycin (Sigma, St. Louis, MO) to final concentrations of 300 µg/ml for E. coli or 5 µg/ml for L. monocytogenes. For solid media, 1.5% agar (wt/vol) was added. Human colon epithelial cells (Caco-2 cells) were received from the American Type Culture Collection (ATCC HTB-37) and were cultured at 37°C and 5% CO₂ in RPMI 1640 (Gibco, Eggenstein, Germany) supplemented with 10% heat-inactivated fetal calf serum (FCS) (Biochrom KG, Berlin, Germany). In order to monitor the in vitro growth of L. monocytogenes cells, 100 µl of an overnight culture were diluted into 10 ml prewarmed BHI medium and shaken at 190 rpm. The optical density of the cultures was measured every hour in a Klett-Summerson colorimeter (Klett Manufacturing Co., Inc., New York, NY). For storage at –80°C, strains were grown to an optical density at 550 nm of 0.6, and glycerol (final concentration, 15%) was added to yield 1-ml samples.

Construction of an insertion mutant library of L. monocytogenes. A random, mutagenic fragment library of L. monocytogenes strain Pkp1 was constructed in the temperature-sensitive shuttle vector pLSV101 that is a shortened version of pLSV1 (46). The methylase gene from pLSV1 was amplified with primer pair MSLmethylase1 and MSLmethylase2, generating a 1,322-bp HindIII-HindIII DNA fragment which was cloned into a 4,170-bp fragment derived from HindIII treatment of pLSV1, resulting in plasmid pLSV101 (5,491 bp). This vector replicates in Listeria at 30°C, while it is lost after several cell divisions at 42°C due to two transition mutations in the repF gene. DNA fragments of L. monocytogenes EGD were randomly generated by sonication by the protocol of Lee et al. (24) with the following modifications. Chromosomal DNA (100 µg) was prepared as described previously (10). DNA was suspended in 1 ml of sonication buffer and sonicated for 120 s with repeated interruptions for cooling on ice. After ethanol precipitation, the DNA fragments were redissolved, and an aliquot of 1 µg was analyzed by agarose gel electrophoresis (2% agarose) to confirm the generation of short DNA fragments. The fractionated DNA was digested with 1 U MboI (= Sau3A) per µg DNA and separated as described above. Gel slices containing unirradiated DNA fragments from 200 to 400 bp were isolated from the gel using dialysis bags, purified, and redissolved by standard procedures (37). In parallel, the pLSV101 vector was restricted with the MboI-compatible restriction endonuclease BamHI. Aliquots of 100 ng vector DNA were treated with shrimp alkaline phosphatase (Boehringer, Mannheim, Germany) as recommended by the supplier and ligated with 250 ng fragment DNA. Ligation samples were transformed into E. coli strain XL2-Blue, and E. coli transformants were selected at 37°C on LB agar containing erythromycin. Colonies were pooled in sets of 60 to 380 clones, and 300 ng DNA isolated from each pool was transformed into L. monocytogenes EGD. The L. monocytogenes EGD fragment library clones were selected at 30°C in the presence of erythromycin. The clones were streaked out at 30°C, and single colonies were suspended in 200 µl BHI in a 96-well microtiter plate. Twenty microliters of each suspension was dropped with a multichannel pipette into wells on prewarmed BHI agar plates containing erythromycin and incubated at 42°C for 2 days. Selected insertion mutants of L. monocytogenes EGD were isolated in 96-well microtiter plates in BHI and regrown overnight at 42°C in the presence of erythromycin. To determine the site of insertion-duplication mutagenesis, the respective strain of the mutagenic library was used as a template to amplify the cloned fragment with the primer pair LSV3 and LSV-4380rev. To recover wild-type strains that had lost the plasmid, mutants were streaked out on BHI agar plates without erythromycin and grown overnight at a permissive temperature. This step was reiterated at least four times, and complete curing of integrated plasmid was confirmed by growing single colonies on BHI agar plates with erythromycin at 30°C.

Construction of deletion mutants. In-frame deletions of glpD (lmo1293), lmo1538, and a species-specific region spanning from lmo1968 to lmo1974 (lmo1968-1974) were performed in parental strains Sv1/2a, EGD, and EGD-e, respectively, as described previously (42). To construct EGDglpD, two fragments of 518 bp and 529 bp were amplified using the oligonucleotide pairs glpDa/glpDb2 and glpDc2/glpDd and ligated via the introduced BglII sites. Following nested PCR using the oligonucleotides glpD-nested1 and glpD-nested3 and the ligation mixture as a template, the resulting fragment was cloned into pLSV1 via BamHI and EcoRI, giving rise to pLSVglpD. pLSVglpD was transformed into L. monocytogenes EGD by electroporation, and erythromycin-resistant bacteria growing at 43°C harboring the chromosomally integrated plasmid were selected. Cointegrates were resolved as described above, and erythromycin-sensitive clones were screened by PCR to identify a mutant in which the second recombination step resulted in a deletion of glpD (lmo1293). For the deletion of the lmo1968-1974 gene cluster, a 906-bp downstream fragment of lmo1968 was amplified by using the oligonucleotides CAH1 and CAH2, and a second, 861-bp fragment, which is localized upstream of lmo1974, was amplified with oligonucleotides CAH3 and CAH4 from chromosomal DNA derived from strain EGD-e. The fragments were cut with BamHI-XhoI and XhoI-EcoRI, respectively, and cloned in one ligation step into pLSV1 via BamHI and EcoRI. The deletion mutant EGD-e1968-1974 was then generated as described above. A similar strategy was chosen to delete lmo1538 using the oligonucleotides gkA to gkD. The resulting fragments were cut with BamHI and SalI, respectively, and cloned into pLSV101 in two steps. The correct orientation of the fragments was confirmed by PCR. glpD (lmo1293) was also deleted in mutant EGD1538 using pLSVglpD as described above, resulting in mutant EGD1538glpD. The gene deletions in all four mutants were confirmed by PCR analysis and sequencing.

Epithelial cell infection assays. A total of 2.5 x 10⁵ Caco-2 cells per well were seeded in a 24-well culture plate and cultivated until infection. Cells were washed twice with phosphate-buffered saline (PBS) supplemented with Mg²⁺ Ca²⁺ (PBS-Mg²⁺Ca²⁺) and covered for 1 hour with 500 µl RPMI 1640 containing 1.5 µl of a bacterial culture grown overnight. The average multiplicity of infection (MOI) was calculated to range from 6 to 14. To test deletion mutants, glycerol stocks were thawed, and the bacteria were sedimented and washed twice with PBS and resuspended in 1 ml PBS. After the Caco-2 cells were washed once with PBS-Mg²⁺Ca²⁺, extracellular bacteria were removed by adding 0.5 ml RPMI 1640 containing 10 µg/ml gentamicin. After 7 hours of incubation, the infected Caco-2 cells were washed again with PBS-Mg²⁺Ca²⁺ and then lysed in 1 ml cold Triton X-100 (0.1%). Intracellular replication behavior of the mutants and the wild type was quantified by plating dilutions of the lysed cells on BHI agar plates that were incubated at 42°C for 1 day. If appropriate, the plates contained 5 µg/ml erythromycin. To examine adhesion properties of bacterial strains, the infection time was reduced to 35 min, and before lysis, cells were washed four times with PBS-Mg²⁺Ca²⁺. The capability of bacterial cells to invade Caco-2 cells was investigated as described above, but lysis of the epithelial cells was performed after 1 hour, and a higher gentamicin concentration of 50 µg/ml was used.

RNA isolation. Since the two samples to be compared in this study were not homogeneous, they were treated as follows to make them comparable. (i) Eight 250-ml tissue culture flasks with confluent Caco-2 cells were infected with L. monocytogenes at an MOI of 20. Caco-2 cell infection assays were performed as described above. Cells were lysed 6 h postinfection with cold distilled water. Mammalian cell debris was removed by centrifugation at 1,000 x g for 10 min at 4°C, leaving only the bacteria in the supernatant. Bacterial numbers were determined by plating dilutions on BHI agar plates. Bacteria were pelleted at 6,000 x g for 10 min at 4°C, shock frozen in liquid nitrogen, and stored at –70°C for RNA isolation. (ii) L. monocytogenes bacteria were grown in BHI to an optical density at 600 nm of 1.0 corresponding to the late logarithmic phase. To normalize the background resulting from Caco-2 cell debris, eight 250-ml flasks of confluent Caco-2 cells were lysed with cold distilled water. After the addition of an appropriate number of cells corresponding to that of the infected pellets, the suspension was treated in the same way as described above. RNA from these two samples was extracted using the RNeasy mini kit (QIAGEN, Hilden, Germany) according to the manufacturer's protocol with some modifications to lyse the bacteria. Cell pellets were suspended in lysis buffer and placed in a 2-ml BLUE tube, filled with silica-sand (Bio 101 Inc., La Jolla, CA). The tube was shaken three times for 45 s each time with a 1-minute interval on ice between each shaking at a speed setting of 6.5 in a bead beater FP120 FastPrep cell disrupter (Savant Instruments, Inc., Farmingdale, NY). Residual DNA was removed on a column with QIAGEN RNase-free DNase (QIAGEN, Hilden, Germany).

Microarray hybridization and data analysis. Transcriptome analyses were performed using whole-genome DNA microarrays that contained synthetic 70-mer oligodeoxyribonucleotides covering all open reading frames of the L. monocytogenes genome. The oligonucleotides (Operon Co.) were spotted on epoxy-coated glass slides from Quantifoil according to the manufacturer's instructions by T. Chakraborty (Institut für Medizinische Mikrobiologie, Giessen, Germany). Each oligonucleotide was spotted twice on a slide to generate two replicates for each oligonucleotide on a slide. A total of six RNA samples were prepared for cDNA labeling and hybridization. Briefly, equal amounts (40 µg) of the RNAs were used to synthesize cDNA differentially labeled with Cy3-dCTP and Cy5-dCTP (Amersham Pharmacia, Freiburg, Germany) during a first-strand reverse transcription reaction with Superscript II RNase H^– reverse transcriptase and 9 µg random primers (Life Technologies, Karlsruhe, Germany). Dye swap was performed as follows. Three intracellular listerial cDNA samples were generated using Cy3-dCTP, and the other three were generated using Cy5-dCTP. The two cDNA samples were combined, diluted with 3x SSC (1x SSC is 0.15 M NaCl plus 0.015 M sodium citrate) and 0.1% (wt/vol) sodium dodecyl sulfate, hybridized to the microarray, and incubated at 50°C for 16 h. After the slides were washed, they were scanned using ScanArray HT and analyzed using the ScanArray express software (Perkin-Elmer, Boston, MA). Spots were flagged and eliminated from analysis when the signal-to-noise ratio was less than three or in obvious instances of high background or stray fluorescent signals. The LOWESS method of normalization (47) was performed on the background-corrected median intensity of the spots. The normalized ratios were analyzed further with Microsoft Excel (Microsoft, Redmond, WA) and SAM (significance analysis of microarrays) software for statistical significance (44) (see Table S2 in the supplemental material). The value was adjusted to 2.1, which results in false significant median of 0.29 (see Table S3 in the supplemental material). To determine the significance of differential expression, RNA was isolated from L. monocytogenes grown in BHI, and 30 to 40 µg of this RNA was labeled either with Cy3-dCTP or with Cy5-dCTP. The two cDNA probes generated were hybridized onto the same slide, and the data were analyzed as mentioned above. Since the values spread from 0.6 to 1.6, we considered values >1.6 and <0.6 to be significant in our experiments. To exclude the possibility of cross hybridization to host cell RNA, one slide was hybridized with Cy3-dCTP-labeled cDNA derived from Caco-2 cell RNA and with Cy5-dCTP-labeled cDNA obtained from L. monocytogenes grown in BHI, and the other slide was hybridized with the same cDNA but with the dyes swapped. No significant signal intensity was detected using the cDNA from Caco-2 cells (data not shown).

Real-time RT-PCR. Real-time reverse transcriptase PCR (RT-PCR) was conducted on total RNA isolated independently from that used for transcriptome analysis experiments. Before real-time RT-PCR was performed, the absence of DNA from RNA samples was verified by PCR amplification of the genes to be assayed with 1 µg RNA as the template. cDNA synthesis was performed as described above from 5 µg total RNA. Instead of the labeled nucleotides, equal amounts (20 mM) of dATP, dCTP, dGTP, and dTTP were used. Real-time RT-PCR in a final volume of 20 µl was carried out in a MJ Research PTC-200 cycler according to the manufacturer's protocol of the qPCRCore kit for SYBR green-I (Eurogentec, Liege, Belgium). The primers used for real-time RT-PCR are listed in Table S1 in the supplemental material.

Statistical analysis for overrepresentation of genes identified by microarray analysis and insertion-duplication mutagenesis. The average knockout fraction (F) of the mutant library was determined to be 16% using the general features of the L. monocytogenes genome (16) and the formulas of Lee and coworkers (24) [q = (G – I)/L and F (%) = 1 – (1 – q)ⁿ, where G is the average size of a gene (918 bp), I is the insert size (244 bp), L is the genome size of L. monocytogenes (2,944,528 bp), F is given as a percentage, and n is the size of the library (760 mutants)]. We extrapolated the 16 overlapping genes to a library saturation of 100%, resulting in an estimated number of 100 attenuating mutant genes in the group of up-regulated genes. Seventy-two mutant genes out of 456 genes (16% saturation) extrapolated to 450 mutants out of 2,853 genes (100% saturation), and 279 up-regulated genes from 2,853 genes gives a probability of 0.0153 [(450/2,853) x (279/2,853) = 0.158 x 0.097] of genes which overlap between the two techniques by chance (2,853 x 0.0153 = 43.6). To the expected number of 43.6 genes and the observed number of 100 overlapping genes (extrapolated), we applied the test for binominal distribution and the chi-square test, and both tests rejected the null hypothesis (P < 0.01), i.e., the overrepresentation is significant.

	RESULTS

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Global transcriptional profile of L. monocytogenes in epithelial cells. We compared the expression profile of L. monocytogenes grown in BHI (RNA_BHI) with that of L. monocytogenes grown in the cytosol of Caco-2 cells (RNA_Caco). RNA was isolated and purified from L. monocytogenes EGD either grown in vitro or intracellularly, and the differentially labeled RNAs (RNA_Caco/RNA_BHI) were then hybridized against whole-genome microarrays containing oligonucleotides of all genes identified in the genome sequence of L. monocytogenes EGD-e (16). We chose to isolate RNA 6 hours after infection, a time point that reflects active intracellular replication as shown previously (14). In total, the statistical analysis using SAM software (44) identified 541 genes with transcriptional alterations during intracellular growth of L. monocytogenes. We observed 259 listerial genes whose expression is down-regulated in intracellular L. monocytogenes compared to those cultivated in BHI. Most noticeable is the strong repression of genes involved in glycolysis, namely, eno (3.3-fold), lmo2460 (3.3-fold), pfk (2.5-fold), pgk (2.5-fold), pgm (2-fold), pykA (2.5-fold), and tpi (2.5-fold), while the other repressed genes mainly encode functions involved in DNA replication, recombination, transcription, protein biosynthesis, cell wall synthesis, and energy metabolism. The down-regulation of these listerial genes most likely reflects the slower growth of L. monocytogenes in Caco-2 cells (generation time about 40 min) compared to that in BHI (25 min) (34). The differentially up-regulated genes were grouped into several categories according to their cellular functions, such as virulence, carbon and nitrogen metabolism, stress response, regulation, and those with unknown functions (Table 2 and Fig. 1).

View larger version (14K): [in this window] [in a new window]   FIG. 1. Changes in expression of genes belonging to functional groups. The bars show the percentages of listerial genes in each group that exhibit altered expression inside epithelial cells. The white bars indicate the proportion of genes that are down-regulated, and the black bars represent the proportion of up-regulated genes for each functional group. The total number of genes per functional category is shown in parentheses and is equivalent to 100%.

View larger version (17K): [in this window] [in a new window]   FIG. 2. Correlation of microarray and real-time RT-PCR analyses of selected genes. The changes in intracellular gene expression compared to that in BHI (RNACaco/RNABHI) were log transformed. The relative expression of the genes studied was normalized to the expression of the housekeeping gene rpoB as described elsewhere (28, 41). The genes studied included lmo1517 (1517), lmo1974 (1974), and lmo1971 (1971). Six independent real-time RT-PCR experiments were performed.

View larger version (19K): [in this window] [in a new window]   FIG. 3. Effects of insertional knockouts on the intracellular replication of L. monocytogenes. Caco-2 cells were infected with either the wild-type strain or insertional mutants as described in Materials and Methods. Mutated genes are in the same order as in Table 2, and putative functions are indicated in parentheses. The number of CFU recovered after 7 hours was determined, and reduced survival of the mutants was calculated as a percentage compared to the control group. The control group comprised 107 insertional mutants whose intracellular growth was not significantly affected. Error bars represent the standard deviations from the mean (n 3 for insertional mutants; n = 13 for the wild type). The significance level was 0.02 according to Student's t test. lmo2434 encodes a glutamate decarboxylase (glutamate decarb.).

View larger version (17K): [in this window] [in a new window]   FIG. 4. Real-time RT-PCR to study the effects of pLSV101 insertion on the transcription of genes located downstream. cDNAs obtained from wild-type strain EGD (Wt Egd) and mutant EGD-lmo1971::pLSV101 (lmo 1971 :: pLSV 101) were used as a template for real-time RT-PCR with oligonucleotides specific for lmo1968. The quantity of lmo1968-specific cDNA was normalized to the quantity of rpoB cDNA, indicating that the concentration of lmo1968-specific cDNA and thus mRNA is not reduced in the mutant strain.

View larger version (19K): [in this window] [in a new window]   FIG. 5. Effects of nonpolar deletions of glpD (lmo1293), lmo1538, and lmo1968-1974 on the intracellular replication of L. monocytogenes. Caco-2 cells were infected with either the wild-type strain (EGD) or the mutants to an MOI of 6 to 14, and the numbers of bacteria recovered after 7 hours of infection were determined. Mutant strains with deletions of lmo1538 (1538), glpD (glpD), lmo1538 and glpD (1538/glpD), and lmo1968-1974 (1968-1974) were studied. Eleven independent infections were performed for each strain. Error bars represent the standard deviations from the means. The application of the Student t test and the use of pair differences revealed significant differences in the replication efficiencies of the tested mutants from that of the wild-type strain.

	DISCUSSION

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Previous in vitro studies (28) have shown that PrfA especially in its constitutively active PrfA* form (33) can induce, in addition to the PrfA-dependent virulence genes, transcription of a large number of other (mainly SigB-dependent) genes. It is interesting to note that induction of many of these genes was not observed in the intracellular milieu, indicating that the bacterium adapts to this environment in a different manner.

Genes responsible for uptake and utilization of carbon sources. We identified several up-regulated genes coding for ABC transporters and enzymes of the PTS and other transport systems that are required for the uptake and utilization of carbon sources (Table 2). The importance of these genes for intracellular replication of L. monocytogenes inside the host cell's cytosol is further shown by the fact that mutations in some of these genes reduce the efficiency of listerial growth in epithelial cells. Some of these genes seem to be under carbon catabolite repression (CCR) control, since their up-regulation is also observed in ccpA and hprK mutants (S. Mertins, unpublished data). The presence of catabolite-responsive elements (cre) in the promoter regions of two genes identified in this study, namely, lmo0783 and lmo2762, encoding mannose-specific and cellobiose-specific PTS enzymes, indicates that part of the listerial metabolism is released of CCR control when the bacteria replicate in the host cell cytosol (Table 2). Together with the down-regulation of the glycolysis genes (Fig. 1) and the up-regulation of hpt, this observation strengthens the assumption that the level of free glucose is low and glucose is not a predominant carbon source for listeria inside host cells. This is in line with our observation that the use of glucose, in addition to weakening the host cell's own carbon supply, would lead to the counterproductive inactivation of PrfA (Mertins, unpublished), and it is also possible that listeria uses this low concentration of glucose as a signal to induce the PrfA regulon. Among the differentially regulated genes involved in C metabolism are remarkably many that are involved in the pentose phosphate cycle (Table 2). Their up-regulation provides evidence that the pentose phosphate cycle is the major catabolic pathway for the generation of necessary intermediates and for gluconeogenesis when carbon sources other than glucose or phosphorylated glucose are utilized. The induced transcription of the genes encoding glycerol kinases (lmo1034 and lmo1538) suggests that glycerol may also play a role as a carbon source for listerial growth in the cytosol of the host cells. The reduced growth of strains with insertion and deletion mutations of lmo1538 and glpD (lmo1293) seems to confirm this hypothesis (Fig. 5). This assumption is further strengthened by the strong up-regulation of plcB (9.8-fold) encoding a broad-spectrum phospholipase which could provide glycerol from host-derived phospholipids (Fig. 6A). The gene encoding a putative -keto-deoxygluconate aldolase (lmo1969) known to be involved in the Entner-Doudoroff pathway is part of a gene operon specific for L. monocytogenes to which the genes lmo1973-1971 encoding a putative pentitol-specific PTS also belong. Their intracellular up-regulation, together with the finding that the EGD-lmo1971:pLSV101 and EGD-e1968-1974 mutants showed significantly attenuated growth in Caco-2 cells (Table 2 and Fig. 2 to 4), demonstrate that the species-specific gene cluster lmo1968-1974 is required for wild-type-like intracellular replication of L. monocytogenes.

View larger version (18K): [in this window] [in a new window]   FIG. 6. (A) Proposed model for the interaction of phospholipases with eut genes to provide alternative C and N sources to intracellular L. monocytogenes. Phosphatidylethanolamine derived from phospholipids of host cell membranes could be broken down by the listerial phospholipase PlcB (which is highly active intracellularly) into glycerol and ethanolamine which then provides additional C or N sources by the action of the EutBC (ethanolamine ammonia-lyase). Acetyl-CoA, acetyl coenzyme A. (B) Proposed model for the regulation and fine tuning of nitrogen metabolism by L. monocytogenes for intracellular proliferation. TCA-cycle, tricarboxylic acid cycle.

Genes involved in anabolic pathways. Among the differentially regulated genes involved in anabolic pathways, we primarily observed up-regulation of genes involved in the synthesis of amino acids that L. monocytogenes bacteria, but not the host cells, are able to biosynthesize, notably tryptophan, isoleucine, leucine, valine, and arginine. The importance of isoleucine and valine biosyntheses for intracellular growth was confirmed by a threefold attenuation of an insertional ilvD mutant (Fig. 3). Recently, it was shown that CcpA regulates the expression of branched-chain amino acids in Bacillus subtilis (38, 42). The presence of a cre box in the promoter region of ilvD leads to the assumption that the synthesis of branched-chain amino acids might be regulated by CcpA. Although serine and glutamine as nonessential amino acids could be provided by the host cell, the up-regulation of key genes such as glnA for their biosynthesis in cytosolically grown L. monocytogenes suggests that the intracellular level of these amino acids is low and that cytosolically replicating listeriae depend on their biosynthesis for efficient intracellular growth (see below). Synthesis of arginine revealed another significant adaptation of listeriae to the host cell cytosol. The gene cluster argCJBDF of which two genes, argC and argD, were found to be intracellularly up-regulated by a factor of 3 and 1.9, respectively, is involved in the conversion of glutamate to ornithine, and an insertional mutation of argD led to a reduced replication rate in Caco-2 cells (Fig. 3).

Up-regulated genes required for nitrogen metabolism. L. monocytogenes lacks the genes for nitrate reduction (16) and is therefore entirely dependent on reduced nitrogen sources, such as amino acids or ammonia, for its nitrogen supply. Within the host cell cytosol, the amount of ammonia is low, as excess ammonia is lethal to mammalian cells. Therefore, it was not surprising to see the up-regulation of genes involved in the glutamine-glutamate synthesis pathway, such as glnA (lmo1299) and gltAB (lmo1733-lmo1734). The amino group of glutamate is the nitrogen donor for the biosynthesis of approximately 85% of the cell's nitrogenous compounds in the low-GC-containing bacterium B. subtilis (11), a fact that strengthens the assumption that high-level expression of GS is essential for L. monocytogenes to proliferate in the intracellular environment. The importance of GS in the pathogenicity of M. tuberculosis (43) and S. enterica serovar Typhimurium (22) has been previously studied, and it was shown that deletion of GS resulted in reduced replication of these bacteria in human macrophages and guinea pigs. In this context, it is interesting to note that L. monocytogenes has an interrupted citrate cycle due to the absence of the gene for 2-oxoglutarate dehydrogenase (W. Eisenreich, personal communication), and accumulated 2-oxoglutarate could be channelled into the glutamate metabolic pathway (Fig. 6B).

Little is known about the regulation of nitrogen metabolism in L. monocytogenes. Nitrogen metabolism in gram-positive bacteria is regulated by the availability of rapidly metabolizable nitrogen sources, but not by any mechanism analogous to the two-component system NtrBC found in enteric bacteria (11). Of the three B. subtilis regulators involved in nitrogen metabolism, namely, TnrA, GlnR, and NrgB, homologues of only the latter two are present in L. monocytogenes and are encoded by glnR and lmo1517. The regulatory function of the homologue of lmo1517 (GlnK) in nitrogen metabolism of Corynebacterium glutamicum has been recently established (5). We propose that the product of lmo1517 has a similar function in regulation of nitrogen metabolism in L. monocytogenes along with GlnR and GltC (Fig. 6B). Thus, increased glutamine-glutamate synthesis regulated by GlnR, GltC, and the product of lmo1517 seems to be an adaptation by intracellular L. monocytogenes to proliferate in the cytosolic milieu.

Genes involved in stress response and gene regulation. The transcription of a number of listerial genes, such as dnaK, groEL, lmo1138, and grpE, genes that are known to be essential for overcoming bacterial stress, was found to be induced during intracellular growth like (Table 2). Their up-regulation suggests that their products help the bacteria to adapt to the harsh intracellular conditions. Of particular interest is the fourfold up-regulation of clpB encoding a subunit of the ATP-dependent Clp protease. This proteolytic enzyme in bacterial cells has been shown previously to be an important factor for efficient intracellular growth of L. monocytogenes (7, 30, 31, 36). By degradation of unnecessary proteins, Clp may provide amino acids, which could also serve as C and/or N sources for intracellularly growing L. monocytogenes. As expected, a large number of listerial genes encoding transcriptional regulators were found to be up- or down-regulated inside the host cells, reflecting the altered gene regulation during adaptation of L. monocytogenes to the intracellular environment. The induction of five of these genes is probably due to the release of CCR control. It is also worth mentioning that a substantial number of listerial genes of entirely unknown function were highly up-regulated in the intracellularly growing listeriae. The insertional knockout of one of these genes, lmo0759, resulted in a threefold-reduced intracellular proliferation with respect to the control group (Fig. 3). Four up-regulated genes, lmo0748-lmo0751, are part of a gene cluster specific for L. monocytogenes. The contribution of these genes to intracellular listerial replication deserves further investigation.

Concluding remarks. Despite extensive studies concerning the key steps in the life cycles of facultative intracellular pathogens, knowledge of the specific set of genes required for replication within the cytosolic environment is still rather limited. The up-regulation of all genes of the major virulence gene cluster, including hly, plcA, mpl, actA, plcB as well as the other known PrfA-regulated genes, inlA, inlB, inlC, and hpt, is obviously the most prominent response of L. monocytogenes to the growth conditions of the host cell's cytosol. While most of these genes determine special functions essential for reaching the final destination in the infected cells (9, 45), the latter gene encodes a hexose phosphate transporter and was the first indication that specific physiological adaptation mechanisms may be essential for the successful colonization of the host cells by this intracellular pathogen (8).

Apart from the previously reported metabolic requirements for the growth of S. enterica serovar Typhimurium and M. tuberculosis in macrophages, this study identified differentially regulated genes in intracellular L. monocytogenes that belong to other functional categories. This is not too surprising, considering the entirely different compartments of the host cells in which these microorganisms multiply, namely, the cytosol versus specifically modified phagosomes. The present study provides the first, still rather incomplete view of the metabolism of an intracellularly growing bacterial pathogen. On the basis of these results, we would like to conclude that intracellular bacteria that are able to efficiently replicate inside host cells avoid competing with the host cell for its major carbon and nitrogen sources but rather take advantage of alternative carbon and nitrogen products of the host cells, such as phosphorylated glucose deriving from the host cell's glycogen (M. Beck, unpublished data) and ethanolamine derived from phospholipids. This strategy probably allows a longer survival of the host cell, in which the invading bacterium could survive and replicate for a longer period. In addition to the discussed metabolic adaptations of the bacteria by the host cell's cytosolic milieu, it should be considered that these bacteria will probably also induce functions during cytosolic growth which may modify host cell activities to favor their multiplication.

	ACKNOWLEDGMENTS

 
We are grateful to Michael Kuhn for valuable suggestions and critical reading of the manuscript, Aleksey Min for help with the statistical analysis, and Anja Schramm for help with the microarray experiments.

B.J. was a recipient of a postdoctoral fellowship from the "Europäisches Graduiertenkolleg 587/2." This work was supported by the Fonds der Chemischen Industrie of Germany and by the Competence Center PathoGenoMik funded by the Federal Ministry of Education and Research (BMBF) of Germany.

	FOOTNOTES

 
* Corresponding author. Mailing address: Theodor-Boveri-Institut (Biozentrum), Lehrstuhl für Mikrobiologie, Universität Würzburg, Am Hubland, D-97074 Würzburg, Germany. Phone: 49-931-8884400. Fax: 49-931-8884402. E-mail: goebel{at}biozentrum.uni-wuerzburg.de.

Supplemental material for this article may be found at http://jb.asm.org/.

These two authors contributed equally to this work.

Present address: Merckle GmbH, Ludwig-Merckle-Str. 3, 89143 Blaubeuren-Weiler, Germany.

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