Response Regulator DegU of Listeria monocytogenes Controls Temperature-Responsive Flagellar Gene Expression in Its Unphosphorylated State

doi:10.1128/JB.00258-08

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Journal of Bacteriology, July 2008, p. 4777-4781, Vol. 190, No. 13
0021-9193/08/$08.00+0 doi:10.1128/JB.00258-08
Copyright © 2008, American Society for Microbiology. All Rights Reserved.

Response Regulator DegU of Listeria monocytogenes Controls Temperature-Responsive Flagellar Gene Expression in Its Unphosphorylated State

Norman Mauder ,^, Tatjana Williams,^,# Frederike Fritsch, Michael Kuhn, and Dagmar Beier^*

Theodor-Boveri-Institut für Biowissenschaften, Lehrstuhl für Mikrobiologie, Universität Würzburg, Am Hubland, D-97074 Würzburg, Germany

Received 20 February 2008/ Accepted 11 April 2008

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We demonstrate that in Listeria monocytogenes, temperature-responsivetranscriptional control of flagellar genes does not rely onthe phosphorylation of the conserved phosphorylation site (D55)in the receiver domain of response regulator DegU. Furthermore,proper control of DegU-regulated genes involved in ethanol toleranceand virulence is independent of receiver phosphorylation.

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In Listeria monocytogenes, a facultative intracellular bacterium,the expression of flagellum-based motility is regulated in responseto the growth temperature (7, 13), with the permissive temperaturebeing 30°C and below. Temperature-dependent transcriptionalregulation of flagellar genes in L. monocytogenes relies onthree regulatory proteins: the repressor protein MogR, the responseregulator DegU, and GmaR, an antirepressor of MogR (3, 4, 9,10, 13). The MogR protein was shown to bind directly to multipleTTTT-N5-AAAA recognition sites within the promoter regions ofthe motility genes, thus preventing their transcription at thenonpermissive temperature (3, 9). Response regulator DegU isrequired to relieve MogR-mediated repression by enabling expressionof GmaR at low temperatures. In vitro DNA-binding experimentsdemonstrated that GmaR is able to both interfere with the bindingof MogR to flagellar gene promoters by protein-protein interactionand disrupt preformed repressor-DNA complexes (10). Apparently,DegU is also involved in the regulation of flagellin expressionon the posttranscriptional level, since compared to the wildtype, a mogR- and degU-negative mutant of L. monocytogenes producedreduced amounts of the FlaA protein, albeit increased transcriptionof flaA (9). Since transcription of degU is not responsive totemperature and the DegU protein could be detected at elevatedand low temperatures (9, 13), it is expected that the activitystate of the transcriptional activator DegU is modulated inresponse to temperature. Usually the activity of a responseregulator is controlled by receiver phosphorylation via a cognatehistidine kinase which autophosphorylates in response to theappropriate environmental stimulus (6). However, DegU of L.monocytogenes is an orphan response regulator which apparentlylacks a cognate histidine kinase (2, 12). Since interactionof a noncognate histidine kinase with DegU is conceivable, weanalyzed the contribution of receiver phosphorylation to thetranscriptional control of DegU-regulated target genes by complementinga nonmotile in-frame degU deletion mutant of L. monocytogenesEGD (12) with a mutated degU allele carrying a substitutionof the putative phosphate-accepting aspartic acid residue (D55)for asparagine. D55 in L. monocytogenes DegU corresponds toD56 in the orthologous response regulator protein of Bacillussubtilis, which was shown to be the target of phosphorylationby the cognate histidine kinase DegS (1). In fact, recombinantHis₆-tagged DegU of L. monocytogenes was phosphorylated by DegSof B. subtilis in vitro, while phosphoryl group transfer tothe mutated response regulator protein DegU(D55N) was not observed(data not shown).

The mutated degU allele was integrated into the chromosome ofthe L. monocytogenes ${Delta}$ degU strain by homologous recombinationvia DNA fragments flanking the degU gene by using a two-steppLSV1-based integration-excision procedure described earlier(12). To construct the degU(D55N) allele with 5' and 3' flankingsequences, recombinant PCR was performed by amplification ofa 428-bp fragment by using primer pair degU-u5/degU(D55N)1 anda 729-bp fragment by using primer pair degU(D55N)2/degU-d3 andby annealing of the purified PCR products, followed by PCR-basedfilling-in reactions. After digestion with EcoRI and BamHI,the recombinant PCR fragment was ligated into the mutagenesisplasmid pLSV1 (14), yielding knockout plasmid pLSV-degU(D55N).A control construct, pLSV-degU, was obtained by PCR amplificationof the wild-type degU gene and its flanking sequences with primerpair degU-u5/degU-d3 and by ligation of the resulting 1,155-bpEcoRI-BamHI fragment into pLSV1 vector DNA. Electrotransformationof the L. monocytogenes ${Delta}$ degU strain with pLSV-degU(D55N) andpLSV-degU, respectively, followed by appropriate selection procedures,yielded the L. monocytogenes degU(D55N) and L. monocytogenes ${Delta}$ degU* strains. These strains were tested for swimming motilityby stabbing the bacteria into semisolid brain heart infusion(BHI) agar (0.25% agar; Difco) and by measurement of the diametersof the swimming halos which were formed around the inoculationpoint after 48 h of incubation at 24°C. In three independentexperiments, the diameters of at least 12 swimming halos weredetermined, and the diameters obtained were normalized to themean diameter of halos formed by the wild-type strain EGD. Incontrast to the completely nonmotile L. monocytogenes ${Delta}$ degU parentstrain, the ${Delta}$ degU* strain exhibited swimming motility which wasnot significantly different from that of wild-type L. monocytogenesEGD (Student's t test; P > 0.05). Swimming motility was alsoobserved for the L. monocytogenes degU(D55N) strain; however,the swimming halos produced by this mutant showed 31%-reduceddiameters compared to those of L. monocytogenes EGD (P <0.001) (Fig. 1A). In agreement with this result, in electronmicroscopical images, fewer flagella per cell were observed,on average, in cases of the L. monocytogenes degU(D55N) strainthan in cases of the wild-type strain EGD (Fig. 1B).

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FIG. 1. (A) Swimming motility of the L. monocytogenes EGD, ${Delta}$ degU, ${Delta}$ degU*, and degU(D55N) strains. Bacteria from single colonies of the respective strains were stabbed into BHI soft agar, and the plates were incubated for 48 h at 24°C. Swimming halos obtained in a representative experiment are shown. The diameter of halos produced by the L. monocytogenes ${Delta}$ degU* and degU(D55N) strains averaged 106% ± 18% and 69% ± 8%, respectively, of the mean diameter of the wild-type strain EGD. (B) Electron micrographs of the L. monocytogenes EGD and degU(D55N) strains. Bacteria were grown without shaking in BHI broth at 24°C and were then examined under a transmission electron microscope (TEM 100; Zeiss) after negative staining with 0.5% uranyl acetate for 1 min. The number of flagella of 50 bacteria were counted per strain. On average, L. monocytogenes EGD exhibited seven flagella per cell, while 4.5 flagella were counted in the case of the degU(D55N) strain. The flagella are indicated by arrowheads. Original magnification, x20,000.

In order to analyze the transcript amounts of flagellum-specificgenes, RNA was prepared from the L. monocytogenes EGD, ${Delta}$ degU,and degU(D55N) strains grown at 24°C in BHI broth to anoptical density of 1.0 at 600 nm (13). RNA slot blot analysiswas performed according to the protocol of Pflock et al. (8)by using a flaA-specific hybridization probe that was PCR amplifiedwith primer pair flaA-S5/flaA-S3. While no flaA-specific transcriptcould be detected in the L. monocytogenes ${Delta}$ degU strain, the complementeddegU(D55N) strain produced flaA-specific mRNA; however, theamount of transcript was reduced to about 50% of that of thewild-type strain L. monocytogenes EGD (Fig. 2A). In addition,transcription of the flagellar genes flaA (lmo0690), flgK (lmo0705),fliF (lmo0713), fliN (lmo0675), and fliI (lmo0716) and the chemotaxisgenes cheY (lmo0691), cheR (lmo0683), and mcp (lmo0723) wasmonitored by quantitative real-time PCR (qRT-PCR), which wasperformed essentially as described by Mertins et al. (5). Inaccordance with previous results (13), transcription of theflagellar and chemotaxis genes was almost abolished in the L.monocytogenes ${Delta}$ degU strain, while the amounts of the flaA-, flgK-,fliF-, fliN-, fliI-, cheY-, cheR-, and mcp-specific transcriptswere found to be modestly reduced in the L. monocytogenes degU(D55N)strain (Fig. 2B; Table 1). Transcription was affected most prominentlyin cases of mcp (65% of wild-type efficiency), cheR (75% ofwild-type efficiency), and flaA (75% of wild-type efficiency).Transcription of the motility genes in the L. monocytogenesEGD and degU(D55N) strains grown at 37°C was also assessedby qRT-PCR, and equal amounts of transcript were observed (datanot shown). Moreover, supernatant proteins were isolated fromL. monocytogenes cultures grown at 24°C, as described previously(13), and were subjected to immunoblot analysis with a polyclonalrabbit antiserum (H-AB; Denka Seiken UK Ltd.) directed againstthe flagella of L. monocytogenes serotype 1/2a. In accordancewith reduced transcription of flaA (Fig. 2A and B), the amountof flagellin expressed in the L. monocytogenes degU(D55N) strainwas decreased to about 55% of the expression level of FlaA inwild-type strain EGD (Fig. 2C). As observed previously (9, 13),no FlaA protein could be detected in the L. monocytogenes ${Delta}$ degUstrain (Fig. 2C). These results demonstrate that the phosphorylationof DegU at the conserved receiver phosphorylation site is nota prerequisite for its function as a temperature-responsiveactivator of expression of the antirepressor protein GmaR. However,reduced transcription of flaA in the L. monocytogenes degU(D55N)strain indicates that the DegU(D55N) protein is less efficaciousas a transcriptional activator, which might be due to a conformationaldistortion caused by the receiver mutation.

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FIG. 2. Expression analysis of motility genes in the L. monocytogenes EGD, ${Delta}$ degU, and degU(D55N) strains. (A) Slot blot hybridization carried out with equal amounts of RNA extracted from the L. monocytogenes EGD (lane 2), ${Delta}$ degU (lane 1), and degU(D55N) (lane 3) strains. Hybridization was performed with flaA- and 16S rRNA-specific probes on RNA from three independent preparations. The 16S rRNA-specific hybridization probe was PCR amplified with primer pair 16S-S5/16S-S3. The results of a representative experiment are shown. (B) The relative changes in transcription of flaA, fliN, fliI, fliF, flgK, cheY, cheR, and mcp in the L. monocytogenes ${Delta}$ degU and degU(D55N) mutant strains, compared to the wild-type strain EGD (WT), were assessed by qRT-PCR. The ratios of the transcript amount detected in the respective mutant to that of the wild type (ratio, mutant/WT) are depicted. The indicated ratios represent the means of results of three qRT-PCR experiments performed in duplicate with cDNA which was reverse transcribed from independent RNA preparations extracted from bacteria grown at 24°C. The relative transcription of the genes under study was normalized to that of the housekeeping gene rpoB, as described by Mertins et al. (5). The primer pairs generating the respective amplicons are listed in Table 1. Error bars indicate the standard deviations from the means. (C) Western blot analysis was performed with equal amounts of supernatant proteins prepared from liquid cultures of the L. monocytogenes EGD (lane 2), ${Delta}$ degU (lane 1), and degU(D55N) (lane 3) strains grown at 24°C using a polyclonal rabbit antiserum directed against flagella of L. monocytogenes serotype 1/2a. FlaA is indicated by an arrow. The results of one of three independent experiments are shown.

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TABLE 1. Oligonucleotides used in this study

In addition to the lack of flagellar gene expression, the L.monocytogenes ${Delta}$ degU strain exhibited increased sensitivity towardethanol and reduced virulence in mice after intravenous infection(12). Attenuation of virulence cannot be attributed to the nonmotilephenotype of the degU-deficient mutant, since the virulenceof L. monocytogenes 10403S, an aflagellate mutant lacking flaA,was not affected when the bacteria were administered orogastricallyor intravenously to mice (11). The DegU-regulated genes responsiblefor both mutant phenotypes have not been identified yet. TheL. monocytogenes EGD, ${Delta}$ degU, and degU(D55N) strains were grownat 37°C in BHI broth supplemented with 5% ethanol. Whilethe L. monocytogenes ${Delta}$ degU strain is unable to grow in the presenceof 5% ethanol (12), no significant difference was observed ingrowth of wild-type and L. monocytogenes degU(D55N) mutant bacteria,suggesting that the D55N substitution in the response regulatorDegU does not affect the expression of genes involved in ethanoltolerance (Fig. 3). To investigate whether receiver phosphorylationof DegU is a prerequisite for the proper regulation of virulence-relevantgenes, BALB/c mice were intravenously infected with the L. monocytogenesdegU(D55N) strain according to standard protocols (12). Theexperiment was performed three times, independently, with groupsof five animals. At day 3 of infection, no significant differencesin the bacterial loads in the livers and spleens of mice infectedwith the L. monocytogenes degU(D55N) strain were observed comparedto the loads in the respective organs of animals to which thewild-type strain L. monocytogenes EGD had been administered.As a control, the degU gene was PCR amplified from chromosomalDNA of the L. monocytogenes degU(D55N) strain reisolated frommice, and the presence of the D55N mutation was confirmed bysequence analysis. Therefore, we reason that the D55N mutationin the receiver sequence of DegU does not interfere with theexpression control of virulence-relevant genes.

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FIG. 3. Growth of the L. monocytogenes EGD, ${Delta}$ degU, and degU(D55N) strains at 37°C in BHI broth in the presence of 5% ethanol. Overnight cultures of the respective strains were diluted 1:50 in BHI broth supplemented with 5% ethanol. The optical densities (in Klett units) were determined at the indicated time points. The growth curve represents the means of results of four independent experiments. Error bars indicate the standard deviations from the means.

In conclusion, we have shown that phosphorylation of responseregulator DegU at the conserved phosphorylation site is notcrucial for the control of target genes whose differential expressionis responsible for the complex phenotype of the L. monocytogenesstrain lacking DegU. The mechanism of temperature-responsive,DegU-dependent regulation of GmaR expression, which might requirean additional regulatory protein acting in concert with DegU,remains to be elucidated.

ACKNOWLEDGMENTS

This work was supported by grants from the Deutsche Forschungsgemeinschaft(BE 1543/5-1) and ERA-NET PathoGenoMics, project SPATELIS (0313939C).

FOOTNOTES

* Corresponding author. Mailing address: Theodor-Boveri-Institut für Biowissenschaften, Lehrstuhl für Mikrobiologie, Universität Würzburg, Am Hubland, 97074 Würzburg, Germany. Phone: 49-931-8884421. Fax: 49-931-8884402. E-mail: d.beier{at}biozentrum.uni-wuerzburg.de

Published ahead of print on 25 April 2008.

Both authors contributed equally to the present study.

Present address: Julius-von-Sachs-Institut für Biowissenschaften,Lehrstuhl für Botanik II, Universität Würzburg,Julius-von-Sachs-Platz 3, 97082 Würzburg, Germany.

^# Present address: Medizinische Klinik I, Molekulare Kardiologie,Universitätsklinikum Würzburg, Josef-Schneider-Str.2, 97080 Würzburg, Germany.

Present address: Dekanat der Medizinischen Fakultät, UniversitätsklinikumWürzburg, Josef-Schneider-Str. 2, 97080 Würzburg,Germany.

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