Modulation of Gonococcal Piliation by Regulatable Transcription of pilE

doi:10.1128/JB.183.5.1600-1609.2001

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Journal of Bacteriology, March 2001, p. 1600-1609, Vol. 183, No. 5
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.5.1600-1609.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Modulation of Gonococcal Piliation by Regulatable Transcription of pilE

Cynthia D. Long,¹^, Stanley F. Hayes,² Jos P. M. van Putten,³^, Hillery A. Harvey,⁴ Michael A. Apicella,⁴ and H. Steven Seifert¹^,^*

Department of Microbiology-Immunology, Northwestern University Medical School, Chicago, Illinois 60611¹; Microscopy Branch² and Laboratory for Microbial Structure and Function,³ Rocky Mountain Laboratories, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Hamilton, Montana 59840; and Department of Microbiology, University of Iowa, Iowa City, Iowa 52242⁴

Received 29 August 2000/Accepted 6 December 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The gonococcal pilus, a member of the type IV family of pili, is composed of numerous monomers of the pilin protein and playsan important role in the initiation of disease by providing theprimary attachment of the bacterial cell to human mucosal tissues.Piliation also correlates with efficient DNA transformation. Toinvestigate the relationships between these pilus-related functions,the piliation state, and the availability of pilin, we constructeda derivative of MS11-C9 ( $Delta$ pilE1) in which the lacIOP regulatorysequences control pilE transcription. In this strain, MS11-C9.10,the steady-state levels of pilin mRNA and protein directly correlatewith the concentration of IPTG (isopropyl- $beta$ -D-thiogalactopyranoside)in the growth medium and can reach near-wild-type levels of expression.Transmission electron microscopy (TEM) demonstrated that the numberof pili per cell correlated with the steady-state expression levels:at a low level of transcription, single long pili were observed;at a moderate expression level, many singular and bundled piliwere expressed; and upon full gene expression, increased lateralassociation between pili was observed. Analysis of pilus assemblyby TEM and epithelial cell adherence over a time course of inductiondemonstrated that pili were expressed as early as 1 h postinduction.Analysis at different steady-state levels of transcription demonstratedthat DNA transformation efficiency and adherence of MS11-C9.10to transformed and primary epithelial cells also correlated withthe level of piliation. These data show that modulation of thelevel of pilE transcription, without a change in pilE sequence,can alter the number of pili expressed per cell, pilus bundling,DNA transformation competence, and epithelial cell adherence ofthegonococcus.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Neisseria gonorrhoeae is a gram-negative diplococcus and the causative agent of the sexually transmitted disease gonorrhea.Pili are long, filamentous appendages composed primarily of theprotein subunit pilin (48). The pilin protein undergoes antigenicvariation at a high frequency (21, 42), allowing escape fromthe host immune response (53, 60) and alteration of adherenceproperties (22, 23, 36, 52). Pilin sequence changes occurpredominantly by nonreciprocal recombination events (14). Variantsequences from silent copies of potential pilin coding sequences(pilS) transfer to the pilin expression gene (pilE) (13, 39)in a RecA (21)-, RecO-, and RecQ (26)-dependentfashion.

The gonococcal pilus is a member of the type IV family of pili, which are found on a variety of gram-negative bacteria includingNeisseria meningitidis, Pseudomonas aeruginosa, Vibrio cholerae,Escherichia coli, and Myxococcus spp. (56). Many type IV pilusassembly genes are homologous to genes involved in the generalsecretion pathway as well as genes implicated in DNA binding anduptake in Bacillus subtilis and Haemophilus influenzae (46).Pili are required for full natural DNA transformation efficiencyof N. gonorrhoeae (43). Gonococci (Gc) that do not express pilin(41, 61) or are nonpiliated due to a mutation in a pilus assemblygene (5, 9, 49) are greatly reduced in competence. Thepresence of the PilC protein, which copurifies with pili (18),has also been shown to be required for efficient DNA transformation(34). Some pilus phase variants demonstrate intermediate levelsof transformation competence (10, 23). A 10-bp transformationuptake sequence is essential for efficient gonococcal transformation(6, 11), although uptake sequence-independent transformationcan occur at a low frequency (4, 44).

Pilus-mediated adherence of Gc has been studied extensively in vitro. Piliation has been shown to enhance adherence to epithelialcells both in tissue culture (31, 51) and in organ culture(25). Cell culture systems using primary cells derived fromthe human urogenital tract have recently been developed to aidin further investigation of gonococcal adherence and invasionmechanisms (15, 28). Studies with cultured cells and tissuesections have shown that antigenic variation of the pilin proteincan alter the adherence properties of the pilus and may confertissue tropism (17, 36). Antigenic variation may also subsequentlymodify gonococcal adherence by causing a change in the numberand aggregation properties of the pili expressed by the bacterialcell (23). The gonococcal PilC protein is also important forpilus-mediated adherence (33, 58); PilC has been proposedas the pilus tip-located adhesin (35) and has been localizedat the bacterial cell surface (32). Human membrane cofactorprotein (MCP or CD46) has been shown to be a cellular gonococcalpilus receptor (19).

To investigate how altering the availability of pilin would affect pilus biogenesis and pilus-related functions, we createda derivative of gonococcal strain MS11 in which the expressedpilin gene is under the control of lacIOP regulatory sequences.In this strain, MS11-C9.10, the steady-state levels of pilin mRNAand pilin protein correlate directly with the levels of IPTG (isopropyl- $beta$ -D-thiogalactopyranoside)in the growth medium. This allowed examination of the relationshipsbetween pilE transcription and piliation phenotype, DNA transformationcompetence, and adherence to epithelial cells. Furthermore, thelac-regulatable pilE gene allowed study of the kinetics of pilusgrowth and expression upon addition of IPTG to the growthmedium.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains and growth conditions. E. coli DH10B (FmcrA mcrB mrr recA endA) (Gibco-BRL) was grown at 37°C on Luria-Bertani medium (Difco) and selected for antibioticresistance at 40 µg of kanamycin (KAN) and 200 µg of erythromycin(ERM) (Sigma) per ml. Gc strains MS11-A, MS11-B2, MS11-C9 (38),and their derivatives were grown on Gc Medium Base (Difco) plusKellogg Supplements (20) (GCB) at 37°C in 5% CO₂, with or withoutup to 5 mM IPTG (Diagnostic Chemicals Ltd.). Gc were selectedfor antibiotic resistance at 10 µg of ERM perml.

Construction of the regulatable pilE strain C9.10. All enzymes used were supplied by New England Biolabs unless otherwise noted and were used under conditions recommended bythe supplier. pNG3049 (41) was linearized with Bsu36I, whichcuts between the pilE2 promoter and the pilE2 coding region inthe 5' untranslated portion (Fig. 1). pHSX-ermC-lacIOP (40)was digested with NotI to release a 3.1-kb fragment containingermC, lacI^q, and the tandem lac operator promoter sequences, tacOP and UV5OP.The ends of the pNG3049 and pHSX-ermC-lacIOP fragments were filledwith the Klenow fragment of polymerase I, the blunt ends wereligated, and the ligation was used to transform E. coli DH10B.Clones were selected for ERM and KAN resistance. A resultant clonedplasmid DNA of the correct size and orientation was linearizedwith PstI and used to transform Gc strain MS11-A. Gc chromosomalDNA was isolated from transformants as described by Boyle-Vavraand Seifert (3) and analyzed by Southern blotting as describedby Sambrook et al. (37) using a pilE gene probe. DNA from oneGc transformant which had incorporated the construct into thecorrect location was used to transform Gc strain MS11-C9 ( $Delta$ pilE1),and transformants were selected on ERM. Transformants were analyzedby Southern blotting, and one transformant that had incorporatedthe construct into the pilE2 locus, C9.10, was used throughoutthe remainder of thisstudy.

Construction of MS11-C9.11 recA6. To generate an MS11 derivative with a wild-type pilE promoter and the pilE coding sequence of C9.10, C9.10 was first transformedwith pVD300recA6 DNA to introduce the IPTG-regulated recA6 allele(40) to aid in the maintenance of the C9.10 pilE coding sequence.C9.10 recA6 was then transformed in the presence of IPTG withpNG3049 DNA, which was originally used to create C9.10 and containsthe C9.10 pilE coding sequence under the control of a wild-typepilE promoter. Gc from the transformation mix were plated on GCBmedium in the absence of antibiotics and IPTG and then screenedfor a piliated morphology. If the regulatable pilE construct wasmaintained, Gc would have a nonpiliated morphology, but if thewild-type promoter from pNG3049 had recombined into the chromosome,transformed Gc would display a piliated morphology in the absenceof IPTG. The pilE sequence of piliated colonies were determined,and transformants that had the C9.10 pilE sequence and were ERMsensitive were subjected to Southern analysis to confirm properrecombination into the chromosome and loss of ermC. This strain,MS11-C9.11 recA6, was used in the time courseexperiments.

RNA purification and analysis. Gc were grown in 10 ml of GC Liquid (GCL) medium (1.5% Proteose Peptone no. 3 [Difco], 0.4% K₂HPO₄, 0.1% KH₂PO₄, 0.1% NaCl)with Kellogg Supplements, 0.042% sodium bicarbonate, and 0, 0.005,0.01, 0.02, 0.05, 0.1, 0.5, or 1.0 mM IPTG at 37°C for 4 to 6h with shaking. Cells were sedimented at 5,000 × g for 15 min,and the total RNA was purified using the TRIzol reagent (Gibco-BRL)according to the manufacturer'sprotocol.

Equal amounts of each RNA sample were analyzed by Northern blot as described by Sambrook et al. (37). Membranes were fixedby UV cross-linking and drying. Prehybridization took place for2 h at 50°C in 50% formamide, as described previously (37).A pilE gene probe was isolated from plasmid pNG3100 (41) afterdigestion with EcoRI and HindIII and separation on a 1.0% agaroseTAE gel. The ~1-kb fragment containing pilE was random primerlabeled with [ $alpha$ ³²P]dCTP (Amersham) (7), hybridized overnight, washed three timesfor 5 min each time at room temperature with 2× SSC (1× SSC is0.15 M NaCl plus 0.015 M sodium citrate), and twice for 15 mineach time at 65°C with 0.1× SSC-0.5% sodium dodecyl sulfate (SDS),and exposed to X-Omat-AR film (Kodak) with an intensifying screen.Densitometric analysis was performed using the AlphaImager 2000(Alpha Innotech Corp.).

Analysis of pilin and PilC production. To analyze pilin production, Gc were grown as described for RNA purification. Cells were sedimented at 5,000 × g for 15 minand resuspended in 5× protein sample buffer (2). Equal amountsof the cell lysates were separated on SDS-15% polyacrylamide gelelectrophoresis (PAGE) gels and transferred to a nitrocellulosemembrane (Micron Separations, Inc.) using a Trans-Blot Cell (Bio-Rad).The membranes were blocked with MegaBlocI (CEL Associates) asrecommended by the manufacturer and probed with the T36 anti-pilinpolyclonal antiserum, which was raised against a pilin peptidespanning amino acids 37 to 56 (CILAEGQKSAVTEYYLNNGK) (a gift fromM. So) (8) at a dilution of 1:1,000. Alkaline phosphatase-conjugatedgoat anti-rabbit immunoglobulin G secondary antibody (Promega)was used at a dilution of 1:7,500, and the immunoblots were developedcolorimetrically as described previously (23).

Analysis of PilC production was performed as described for pilin analysis, except that cell lysates were separated on SDS-7.5%PAGE gels, and membranes were probed with preabsorbed polyclonalPilC antiserum (a gift from J. Pfeifer and S.Normark).

Electron microscopy. To analyze piliation at steady-state levels of induction, Gc were grown with 0, 0.005, 0.01, 0.02, 0.05, 0.5, or 5.0 mM IPTGfor 18 to 20 h on plates, and poly-L-lysine-treated (1 µg ml¹) Formvar-coated grids (Ladd Research Industries, Inc.) were usedto lift cells from colonies. The grids were then fixed and negativelystained as described previously (23).

To perform the time course of piliation induction with C9.10 and C9.11 recA6, Gc were grown overnight on GCB medium in theabsence of IPTG and were suspended in 8 ml of HEPES-buffered medium(10 mM HEPES [pH 7.4], 145 mM NaCl, 5 mM KCl, 5 mM glucose, 1mM CaCl₂, 1 mM MgCl₂, 1.5% Proteose Peptone no. 3, 1% Iso VitaleX)at an optical density at 550 nm of approximately 0.1. Gc weregrown with continuous rotation in the presence of 1 mM IPTG orwithout IPTG. At regular intervals over a 16-h period, aliquotswere transferred to Parlodion-coated 300-mesh copper grids. Sampleswere allowed to adsorb for 1 h, and then the supernatant was removed.Grids were washed thrice with double-distilled H₂O for 5 min toremove the residual medium and salts. Grids were then air driedand negatively stained with 1% ammonium molybdate for 30 s. Excessstain was removed, and grids were air dried under vacuum priorto examination and photography in a Hitachi Hu11-E-1 electronmicroscope at 75 kV and with SO-163 electron image film(Kodak).

Determination of gonococcal transformation efficiency. Gc were grown in the absence of IPTG on plates for 16 to 18 h, collected with Dacron swabs, and suspended to a density of10⁸ CFU per ml in GCL. Then, 20 µl of cells was added to 200 µl ofGCL containing 0 to 1 mM IPTG, 5 mM MgSO₄ (41), and 100 ng ofpSY6 DNA (44), which, when recombined into the Gc chromosome,confers resistance to nalidixic acid (NAL) (Sigma). After 15 minat 37°C, the transformation mixes were diluted into 2 ml of GCLplus Kellogg Supplements and the same IPTG concentration as previouslyand then incubated at 37°C in 5% CO₂ for 5 h. The transformationmixes were diluted and plated on GCB medium with 2 µg of NAL perml to select transformants and on GCB medium to determineCFU.

Cell culture conditions and adherence assays. Opa Gc were used for all adherence assays. The Opa status of each strain was determined by Western analysis as previouslydescribed (23), except that membranes were probed with the 4B12anti-Opa monoclonal antibody (a gift from M. Blake) (1).

Primary cultures of human corneal epithelial cells were established as described previously (50). For use in adherence assays,epithelial cells were grown on 12-mm circular Thermanox coverslipsin 1 ml of MCDB 153 medium. Before the start of the infection,the medium was replaced with 1 ml of RPMI supplemented with 5%fetal calf serum and 0.1% Iso VitaleX. Gc, grown on Gc agar platesin the presence of the appropriate antibiotics (37°C, 5% CO₂),were added to the cells at a multiplicity of infection of 100.When appropriate, 0.5 mM IPTG was present during the assay. At0 to 2 h of incubation (37°C, 5% CO₂), the infection was stoppedby rinsing the cells three times with 1 ml of Dulbecco phosphate-bufferedsaline (PBS) to remove unbound bacteria, followed by fixationin 0.1% glutaraldehyde-1% paraformaldehyde in Dulbecco PBS. Specimenswere stained with crystal violet (0.007% in distilled water),and the bacterial adherence was scored with an Olympus (New HydePark, N.Y.) BH-2microscope.

The Chang conjunctival cell line (ATCC CCL 20.2) was maintained, and adherence assays were performed as previously described(23). The data presented in Fig. 7 were calculated by dividingthe number of adherent CFU of each strain by the number of adherentCFU of the nonpiliated strain MS11-B2.

The primary urethral epithelial cells were collected and maintained as described by Harvey et al. (15). Five days priorto the adherence assay, 2 × 10⁴ viable primary urethral epithelial cells were plated per wellin 24-well culture dishes containing collagen-coated coverslipsin hormonally defined growth medium (Clonetics). At the time ofthe assay, each well contained ~3.3 × 10⁴ viable cells in a confluent monolayer. The adherence assay wasperformed as described for the Changcells.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Construction and characterization of the regulatable pilE strain C9.10. We constructed a Gc strain in which the wild-type pilE promoter was displaced with lac regulatory sequences to investigatethe relationships between pilE transcription, pilus assembly,and pilus function. The first step in constructing a regulatablepilE strain was to insert an ERM resistance cassette and lacIOPregulatory sequences upstream of the pilE coding sequence in the5' untranslated region. The plasmid pHSX-ermC-lacIOP (40) containstwo tandem lac promoter-operator sequences (tac-UV5), which areregulated more effectively by lacI^Q than single operator promoter regions (27). The ermC and lacI^Q genes are transcribed in the opposite orientation of the lacpromoter-operator sequences and therefore do not influence transcriptionof genes downstream of these sequences. The lac promoter-operatorsequences, the lacI^Q gene, and the ermC gene were inserted into pilE2, just upstreamof the pilE2 ribosomal binding site and downstream of pilE2 promotersequences, in pNG3049 (41) (Fig. 1). This construct was transformedinto MS11-C9, which carries the pilE2 gene, and nonpiliated (P) ERM-resistant Gc transformants were grown with 0.5 M IPTG onsolid medium to identify transformants that exhibited a piliated(P⁺) colony morphology. These transformants were analyzed by Southernblot to ensure that the construct was in the pilE2 locus and thatno other pilin loci had changed (data not shown). One transformant(MS11-C9.10, or C9.10) was chosen for further analysis.

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FIG. 1. Schematic of the regulatable pilE gene of C9.10. Shaded boxes indicate genes and are drawn to scale. Arrows extended from the gene names indicate the direction of transcription. Thick arrows indicate the operators and promoters. P, pilE2 promoter. Restriction sites are abbreviated in capital letters as follows: B, Bsu36I; C, ClaI, H, HpaI, N, NotI, S, SmaI. Crossed-out restriction sites were destroyed during construction.

The regulatable pilE strain C9.10 was characterized by Northern and Western analysis to determine the relative levels of pilinmRNA and protein produced with respect to the parental strainMS11-C9. C9.10 was grown in liquid medium for 4 to 6 h withoutIPTG or grown in media containing IPTG at 0.005 to 1.0 mM. TotalRNA was isolated and probed with a pilE gene probe. Pilin mRNAwas not detectable when C9.10 was grown without IPTG, and pilinmRNA levels gradually increased when cells were grown with increasingconcentrations of IPTG in the growth medium, ultimately reachingan expression level of 86.8% compared to the wild type (Fig. 2A).Whole-cell lysates were prepared from the same bacterial culturesas the RNA samples and were probed with a pilin anti-peptide antiserumthat binds to a conserved pilin epitope (see Materials and Methods)(8). No detectable pilin was produced when C9.10 was grownwithout IPTG (Fig. 2B). The level of pilin protein steadily increasedas the IPTG in the growth medium increased to 0.05 mM, and thenpilin expression leveled off despite further increases in pilEmRNA expression. We have previously shown that monoclonal antibodiesthat bind to conserved epitopes on pilin react with differentaffinities to some pilin variants (23), and therefore the levelsof C9.10 variant pilin expression cannot be directly comparedto the C9 pilin variant. These Northern and Western analyses demonstratedthat in C9.10, the regulatable pilE gene allows for control ofpilE transcription and pilin production by altering the concentrationof IPTG.

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FIG. 2. Northern and Western analyses of C9.10. The concentration of IPTG used for induction is indicated above each lane. (A) Pilin mRNA was detected with a pilE gene probe. (B) Pilin protein was detected with the T36 anti-pilin polyclonal antiserum. The mobilities of molecular mass markers are indicated to the left of the blot (in kilodaltons).

Pilus expression by C9.10. We have previously shown that changes in the pilin amino acid sequence due to antigenic variation alter the level of pilinproduced, the number of pili per cell, the extent of pilus bundling,and the percentage of cells expressing pili in a given population(23). We used C9.10 to determine how varying the expressionlevel of a given variant pilin protein affected pilus assemblyand pilus bundling. Transmission electron microscopy (TEM) wasused to determine the piliation phenotype of C9.10 when grownin the presence of 0, 0.005, 0.01, 0.02, 0.05, 0.5, or 5.0 mMIPTG for 18 to 20 h on solid media. No pili were detected on negativelystained cells when IPTG was not added to the growth medium (Fig.3A). At the lowest level of induction (0.005 mM IPTG), most cellsdid not express detectable pili, but 5 to 10% of cells expressedone or two long pili (Fig. 3B). At 0.01 and 0.02 mM IPTG, a numberof singular pili were present on most cells (Fig. 3C and D). Manysingular pili, as well as small bundles and networks of pili,were observed at 0.05 mM IPTG (Fig. 3E). At 0.5 and 5.0 mM IPTG,single pili and pili in larger bundles and networks were detected(Fig. 3F and G).

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FIG. 3. TEM images of negatively stained C9.10. (A) C9.10 in the absence of IPTG. (B) IPTG at 0.005 mM. (C) IPTG at 0.01 mM. (D) IPTG at 0.02 mM. (E) IPTG at 0.05 mM. (F) IPTG at 0.5 mM. (G) IPTG at 5.0 mM. A typical cell from the grid is shown for each level of induction except for panel B, which represents a minority of the population. Scale bars in panels A and F represent 0.5 µm; panel B to E and panel G images were obtained at the same magnification as for panel A. The arrow in panel B points to a pilus.

In addition to determining the steady-state pilus expression at different levels of IPTG, we analyzed the dynamics of pilusexpression over a period of 16 h of growth in liquid medium, withpilE induction beginning at t₀. Gc were grown overnight on solidmedium in the absence of IPTG. Gc were then inoculated into liquidmedium containing no or 1 mM IPTG; samples were taken at 2, 4,8, 12, and 16 h and processed for analysis of piliation by TEM.Pili were never observed when C9.10 was not induced with IPTG(Fig. 4A). After 2 h of growth in the presence of IPTG, 60% ofthe C9.10 cells expressed a few long pili per cell (Fig. 4B).After 4 h of growth in IPTG, 5 to 10 pili per organism were detectedon greater than 95% of the cells (Fig. 4C). The piliation of C9.10after 8 h of induction was similar to that at 4 h, with approximately10 pili per cell on the majority of cells in the population (datanot shown). After 12 and 16 h of growth, a substantial portionof the cells in the culture was dead (presumably due to autolysis),and a few pili were detectable on the intact cells. This analysisdemonstrates that pilus production is rapidly induced upon exposureof C9.10 to IPTG and that a threshold level of pilus expressionis achieved after 4 h of IPTG induction. Interestingly, C9.10is significantly less piliated when grown in liquid medium comparedto growth on solid medium (compare with Fig. 3F). This reductionin piliation is not due to the heterologous promoter since, wehave also observed decreased piliation during liquid growth fora wild-type pilE variant (data not shown).

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FIG. 4. TEM images of negatively stained C9.10 and C9.11 over a time course of pilus induction. (A) C9.10 after 4 h of growth without IPTG. (B) C9.10 after 2 h of growth with 0.5 mM IPTG. (C) C9.10 after 4 h of growth with 1.0 mM IPTG. (D) C9.11 after 2 h of growth without IPTG. (E) C9.11 after 4 h of growth without IPTG. A typical cell from the grid is shown in each panel. The bar represents 0.5 µm in panels A, B, D, and E and 0.25 µm in panel C.

The kinetics of pilus expression was also examined by assaying the adherence of C9.10 to primary corneal epithelial cells.Primary corneal cells were inoculated with Gc upon induction with0.5 mM IPTG at t₀. At 0, 15, 30, 60, 90, and 120 min postinoculation,the primary cells were washed to remove nonadherent Gc and observedto determine the adherence. No adherent Gc were observed duringthe first 30 min of IPTG induction (Fig. 5A to C) or when theprimary cells were inoculated with a nonpiliated control (datanot shown). Gc began to adhere to the primary corneal cells after60 min of IPTG induction (Fig. 5D), and the number of Gc per cellincreased after 90 and 120 min of IPTG induction (Fig. 5E andF). These results corroborate the TEM data (Fig. 4B) and indicatethat functional pili are expressed as early as 1 h post-IPTG induction.

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FIG. 5. Adherence of C9.10 to primary corneal cells over a time course of pilus induction. Gc were grown overnight in the absence of IPTG. Gc were incubated with 0.5 mM IPTG and the cultured cells as indicated in each panel. Monolayers were then washed, fixed, stained with crystal violet, and viewed with a light microscope.

For accurate comparison between C9.10 and a strain with a wild-type pilE promoter, a strain which has a wild-type pilE promoterand expresses the same pilE sequence as C9.10 was generated (seeMaterials and Methods). This strain (MS11-C9.11 recA6) was thenanalyzed for piliation over a 16-h time course in liquid medium.During the first 8 h of growth, MS11-C9.11 recA6 expressed numerouspili per cell that were aggregated into bundles (Fig. 4D and E).At the 12- and 16-h time points, similar to what was seen withthe regulatable pilE strain, a significant reduction in viabilitywas observed, but many pili were still present. The number ofpili expressed per cell and the extent of pilus bundling by C9.10did not reach that expressed by MS11-C9.11 recA6.

DNA transformation efficiency of C9.10. Gc readily take up their own DNA, and piliated organisms possess much higher transformation efficiencies than their nonpiliatedcounterparts (43). Studies with pilus biogenesis mutants haveshown that the mere presence of pilin protein that cannot be assembledinto pili is not sufficient to maintain a high level of transformationcompetence (5, 9, 49). However, Gc that express a fewpili have been shown to exhibit transformation efficiencies betweenthat of piliated and nonpiliated ( $Delta$ pilE) variants (10, 23).We therefore utilized the regulatable pilE strain to investigatethe relationship between pilin expression levels and DNA transformationefficiency.

Gc strains C9.10, C9.11 recA6, and MS11-B2 ( $Delta$ pilE1 $Delta$ pilE2) (38) were grown in the absence of IPTG overnight on solid medium.Gc were suspended in liquid medium containing 0, 0.005, 0.01,0.02, 0.05, 0.5, or 1.0 mM IPTG and pSY6 plasmid DNA that, whenrecombined into the chromosome, confers resistance to NAL (44).After 5 h of incubation, Gc were selected on NAL to assess thetransformation efficiency. As shown in Fig. 6, the transformationefficiency of C9.10 directly correlated with the number of singlelong pili up to an intermediate level of pilE transcription (0.05mM IPTG). The point at which the transformation competence ofC9.10 reached a plateau was similar to the competence level ofC9.11 recA6, which expresses the same pilin sequence under thecontrol of the wild-type pilE promoter, showing that full transformationcompetence is reached at a pilin expression level that is ca.50% that of the wild type.

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FIG. 6. DNA transformation competence of C9.10, C9.11 recA6, and MS11-B2. Strains were incubated in the absence or presence of IPTG as indicated for 5 h with plasmid pSY6, which confers resistance to NAL (Nal^R) when recombined into the chromosome. The transformation efficiency was expressed as the number of NAL-resistant transformants per CFU. A representative of three identical experiments is shown.

Adherence of C9.10 to epithelial cells. Gonococcal pili have been suggested to play a crucial role in the initiation of disease by providing the primary attachmentof the bacterial cell to human mucosal tissues (47). Previousinvestigations into how the level of piliation affects adherencedemonstrated that both the number of pili per cell and the extentof pilus bundling influence gonococcal adherence to epithelialcells (23). To study the relationship between the level of piliationand adherence, we used two different types of epithelial cells.The transformed cell line that we chose was the Chang conjunctivalepithelial cell line, which has been used in numerous studiesof gonococcal adherence (17, 36, 54). A second type of epithelialcell culture that we used was the primary urethral epithelialcell system established by Harvey et al. (15).

Gc were grown in the presence of 0, 0.005, 0.05, or 0.5 mM IPTG for 18 to 20 h on solid medium. Gc were incubated with nearlyconfluent monolayers of Chang cells or primary urethral epithelialcells at a ratio of 100 Gc to 1 cultured cell for 2.5 h. WhenC9.10 was not induced or was induced with a low level of IPTG(0.005 mM), its adherence was not significantly different fromthat of the nonpiliated control MS11-B2 (Fig. 7). However, atintermediate (0.05 mM IPTG) and high (0.5 mM IPTG) induction levels,adherence of C9.10 to both epithelial cell types increased significantlyover that of uninduced C9.10. Adherence of C9.10 to Chang cells,even when induced at 0.5 mM IPTG, never reached the adherencelevel of the positive control C9.11 recA6 (Fig. 7A). Furthermore,C9.10 exhibited an approximately threefold-greater adherence toChang cells than primary urethral cells relative to the P control strain (Fig. 7). These data indicate that, unlike DNAtransformation competence, a low level of pilus expression doesnot promote a significant level of adherence over that of a nonpiliatedstrain and that an intermediate level of piliation is necessaryto significantly increase adherence to cultured epithelial cells.

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FIG. 7. Adherence of C9.10 and C9.11 recA6 to epithelial cells. For 18 h prior to the assay, Gc were induced with IPTG as indicated below the x axis. Gc were incubated with the cultured cells for 2.5 h. Monolayers were washed, disrupted, and plated to allow the counting of cell-associated CFU. The number of cell-associated CFU for each strain was divided by the number of cell-associated CFU of nonpiliated control strain MS11-B2 to yield the relative adherence. Values represent the mean and standard error of at least three identical experiments. (A) Adherence to Chang conjunctival epithelial cells. (B) Adherence to primary urethral epithelial cells.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

We used the lac regulatory system to modulate Gc pilin expression in N. gonorrhoeae. By altering the steady-state level ofpilin transcription with different levels of IPTG, the relationshipsbetween pilin expression, pilus expression, and pilus-relatedfunctions (DNA transformation and epithelial cell adherence) wereexamined. Importantly, this was accomplished without the complicationsbrought about when pilin sequence changes pilus expression throughthe process of antigenic variation. Moreover, by adjusting pilinexpression through transcription, new insights into pilus assemblyprocesses were obtained. Finally, a time course of pilus expressionallowed the determination of the time required for pilus expressionand the development of pilus-mediated celladherence.

The regulatable pilE strain C9.10 is the first reported strain in which a change in pilus bundling has been observed withouta change in pilin amino acid sequence. At low to intermediatelevels of IPTG, strain C9.10 expresses singular pili, and thenumber of pili per cell increases as the IPTG concentration increases.At 0.05 mM IPTG pili begin to associate into loose networks, andat 0.5 and 5 mM IPTG pili are aggregated into substantial bundlesas well as remaining singular. A change in pilus expression fromsingular pili to bundled pili upon the increase of pilin expressionindicates that the extent of pilus bundling is at least partiallydetermined by the concentration of pili and not solely by theprimary pilin amino acid sequence. Our previous study of a panelof strain FA1090 pilin variants (23), as well as numerous otherstudies (24, 55), showed that a change in the pilin aminoacid sequence is often associated with a change in the extentof pilus bundling. Together, these studies indicate that boththe level of pilin expression and the primary pilin amino acidsequence influence the aggregation of gonococcal pili. It hasnot been determined whether the individual pili within a pilusbundle all originate from the same gonococcal cell or whetherthey contain pili from multiplecells.

One of the most striking observations made with the regulatable pilE strain was its piliation phenotype when induced at lowlevels of IPTG. Most Gc were nonpiliated at the lowest inductionlevel (0.005 mM IPTG), but a minority of the cells expressed oneor two detectable pili of approximately wild-type length. Thisexpression phenotype was unexpected and in contrast to the phenotypeof an E. coli strain containing an IPTG-inducible type I pilussystem. When a lacUV5-regulated fim operon was maximally inducedfor 30 min, the majority of cells expressed a few short pili;the number of pili per cell increased over the following 1.5 h,but the pili never reached wild-type length (59). In contrast,we observed that long pili were expressed after 2 h of induction,and the number of long pili increased over the next 2 h. One significantdifference between these two bacterial species is that E. coliexpresses a lactose permease (lacY), whereas the Gc do not carryany of the lac operon genes. Another inherent difference betweenthese two systems is that many of the type I pilus biogenesisgenes are encoded in an operon with the main pilus subunit, whereasthe gonococcal pilus biogenesis genes are not. In the type I pilussystem, the number of pili assembled per cell is directly correlatedwith the level of FimD, an outer membrane protein required forpilus assembly (reviewed in reference 16). Therefore, it seemsthat during type I pilus assembly, all "centers" equally competefor pilin and assemble pilin into pili at similar rates. However,when pilin is rate limiting in the Gc type IV pilus system, thepilin that is available is assembled into a pilus of wild-typelength at only one or two sites, if at all. Perhaps a thresholdlevel of pilin must accumulate, conceivably in the inner membrane(57), prior to assembly of a pilus. Another possibility is thatwhen the level of pilin is low, the level of one or more additionalpilus biogenesis genes is also low, allowing for only a limitednumber of pilus assembly sites, as seen in the type I pilus system.This does not seem to be the case with the pilus biogenesis proteinsPilQ and PilC, which are amply expressed in nonpiliated strains(18, 29). Our favored hypothesis is that Gc pilin is targetedto the inner membrane, and only one pilus assembly site has accessto this pilin pool. If a localized threshold level of pilin accumulates,a single pilus is assembled. When there is a greater amount ofpilin available, the threshold level of pilin can be accessibleto additional sites of pilus assembly throughout the membrane,and the number of pili per cell consequently increases. This impliesthat the apparatus through which a pilus is assembled is regulated,since pilus assembly only occurs when enough pilin has accumulatedto form a pilus of wild-typelength.

The DNA transformation experiments with the regulatable pilE strain revealed that only a small amount of pilin is necessaryto significantly increase the transformation competence of theGc over that of a nonpiliated strain. Even when the regulatablepilE strain was not induced, its transformation efficiency was10-fold higher than that of the nonpiliated strain, MS11-B2, whichhas deletions of pilE1 and pilE2 (38). One explanation for thisphenomenon could be that in a small proportion of cells, the lacpromoter is transiently or genetically derepressed. This wouldcause the small proportion of cells to produce enough pilin tosignificantly increase the competence of the population, but notenough pilin to be easily detected. Alternatively, we have foundthat the regulatable pilE construct is minimally transcribed whenuninduced (40). However, we have never detected pili when C9.10was not induced with IPTG. This suggests that small amounts ofpilin may play a role in DNA transformation even when not incorporatedinto a detectable pilus. Additionally, small increases in pilEtranscriptional activity correlated with relatively large increasesin transformation competence. Comparable results were seen withanother gonococcal inducible pilin strain (34). In this induciblepilin strain (N456), pilE was under control of a less tightlyregulated lac regulatory construct than that used for C9.10. TheDNA transformation efficiency of N456 increased significantlyafter 1 and 12 h of IPTG induction compared to the same strainwhen uninduced, even though very little pilin was produced (34).By studying a panel of different regulatable pilE variants andpilus assembly mutants in strain FA1090, we propose that piliare not required for transformation competence but that a pilin-dependentchange of the pilus assembly apparatus into a transport competentstate is required for DNA internalization (C. D. Long and H. S.Seifert, unpublishedresults).

The maximal transformation efficiency of C9.10, which was equal to that of the wild-type control C9.11 recA6, was attainedat the intermediate induction level of 0.05 mM IPTG. As mentionedabove, it is at this level of induction that the pili of C9.10began to aggregate and, at higher levels of induction, the extentof pilus bundling increased. The increase in transformation competencedirectly correlated with the number of single pili present butnot with the total number of pili. This suggests that single,unbundled pili may be important in the process of DNA uptake.This hypothesis is further supported by the observation that otherminimally piliated gonococcal strains exhibit intermediate DNAtransformation efficiencies (10, 23).

One interesting observation from the adherence experiments is that piliated Gc exhibited greater adherence to the immortalizedChang cell line than the primary urethral epithelial cells relativeto the adherence of a nonpiliated control. The different adherenceprofiles between the Chang and primary urethral cells indicatethat Chang cells may have altered the expression of CD46 or otherputative downstream effector molecules involved in gonococcaladherence, express CD46 in a more accessible manner, or alteredthe expression of different receptors or coreceptors for pilus-mediatedadherence. Alternatively, although the conjunctiva and urethraare both primary sites of gonococcal infection, perhaps the distributionof pilus receptor(s) is different at eachsite.

The data from the adherence experiments also lend insight into the level of piliation required by Gc for sufficient adherenceto epithelial cells. A significant increase in the adherence ofthe regulatable pilE strain to both Chang conjunctival and primaryurethral epithelial cells was seen when steady-state inductionof pilE was increased from 0.005 to 0.05 mM IPTG and a greaternumber of singular pili, as well as loose "networks" of pili,were present. However, there was no significant increase in adherencewhen IPTG was increased from 0.05 to 0.5 mM and pili became morebundled. A related phenomenon has been observed with a panel ofmeningococcus (Mc) carrier and disease isolates of various serogroups(12). A majority of the Mc isolates expressing aggregated piliexhibited low adherence to human buccal epithelial cells, andmost isolates expressing unaggregated pili exhibited medium tohigh levels of adherence (12). Interestingly, these data contrastthe report from Marceau et al., who found that the adherence ofencapsulated Mc to an epithelial cell line is strongly promotedby bundled pili and that variants which express singular piliexhibit a low level of adherence (24). However, the classificationof all Mc into "aggregated" and "unaggregated" categories maynot accurately reflect the true piliation state of a particularpilin variant. In the present study, and in our previous studyof a panel of gonococcal pilE variants (23), TEM revealed thatboth aggregated and singular pili can be expressed by a givenvariant. The number of pili per cell and the percentage of cellsexpressing pili can also differ between pilE variants (23).It is possible that singular pili may be expressed by the "aggregated"Mc variants, but the pili may be difficult to detect due to pilusfragility and shearing during electron microscopy sample preparation.Conversely, the presence of capsule, differential glycosylation(45), and/or the decreased number of possible pilin variantsavailable to the Mc (due to fewer pilS copies in its genome [30])may limit the overall piliation state to only a few phenotypes.Further investigation into the relationships between pilin sequence,piliation state, and pilus-mediated adherence in Gc and Mc isclearly needed in order to draw conclusions regarding the effectof pilus bundling onadherence.

In this study, the effects of a wide range of pilin production and piliation levels on gonococcal pilus-related functionswere examined without changing the pilE sequence. The DNA transformationand adherence data generated through use of the regulatable pilEstrain mirror our previous observations using a panel of pilEvariants which express various levels of singular and aggregatedpili (23). The expression of a few singular pili correlateswith an intermediate level of DNA transformation efficiency. Furthermore,variants that expressed the greatest number of singular pili percell exhibited the highest levels of adherence to Chang cells,whereas the adherence of a variant expressing highly bundled piliwas significantly decreased (23). By taking into account thefindings of both studies, we conclude that it is the piliationstate and not the pilE sequence per se which directly affectsthe pilus-related functions of adherence and DNAtransformation.

	ACKNOWLEDGMENTS

We thank M. So for the T36 anti-pilin antiserum, J. Pfeifer and S. Normark for the PilC antiserum, and M. Blake for the 4B12anti-Opa monoclonal antibody. Finally, we thank Eric Skaar andEric Sechman for critical reading of themanuscript.

This work was supported by PHS grants AI31494 and AI33493 to H.S.S. and grants AI18384 and AI38515 to M.A.A. C.D.L. was partiallysupported by PHS grant T32GM08061.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology-Immunology, Northwestern University Medical School, 303E. Chicago Ave. S213, Chicago, IL 60611. Phone: (312) 503-9788.Fax: (312) 503-1339. E-mail: h-seifert{at}northwestern.edu.

Present address: Molecular Diagnostics, Abbott Diagnostic Division, Abbott Laboratories, Abbott Park, IL60064.

Present address: Institute of Infectious Diseases and Immunology, Department of Bacteriology, Utrecht University, NL-3584CL Utrecht, TheNetherlands.

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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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Citing Articles

1.	Blake, M. S., C. M. Blake, M. A. Apicella, and R. E. Mandrell. 1995. Gonococcal opacity: lectin-like interactions between Opa proteins and lipooligosaccharide. Infect. Immun. 63:1434-1439[Abstract].
2.	Bollag, D. M., and S. J. Edelstein. 1991. Protein methods. John Wiley & Sons, Inc., New York, N.Y.
3.	Boyle-Vavra, S., and H. S. Seifert. 1993. Shuttle mutagenesis: two mini-transposons for gene mapping and for lacZ transcriptional fusions in Neisseria gonorrhoeae. Gene 129:51-57[CrossRef][Medline].
4.	Boyle-Vavra, S., and H. S. Seifert. 1996. Uptake-sequence-independent DNA transformation exists in Neisseria gonorrhoeae. Microbiology 142:2839-2845[Abstract].
5.	Drake, S. L., and M. Koomey. 1995. The product of the pilQ gene is essential for the biogenesis of type IV pili in Neisseria gonorrhoeae. Mol. Microbiol. 18:975-986[CrossRef][Medline].
6.	Elkins, C., C. E. Thomas, H. S. Seifert, and P. F. Sparling. 1991. Species-specific uptake of DNA by gonococci is mediated by a 10-base-pair sequence. J. Bacteriol. 173:3911-3913[Abstract/Free Full Text].
7.	Feinberg, A. P., and B. Vogelstein. 1983. A technique for radiolabeling DNA restriction endonuclease fragments to high specific activity. Anal. Biochem. 132:6-13[CrossRef][Medline].
8.	Forest, K. T., S. L. Bernstein, E. D. Getzoff, M. So, G. Tribbick, H. M. X. Geysen, C. D. Deal, and J. A. Tainer. 1996. Assembly and antigenicity of the Neisseria gonorrhoeae pilus mapped with antibodies. Infect. Immun. 64:644-652[Abstract].
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