Department of Molecular Biology, University of Gdansk, Kadki 24, 80-822 Gdansk, Poland1
Division of Genomic Medicine, University of Sheffield Medical School, Beech Hill Road, Sheffield S10 2RX, UK2
Institute of Oceanology, Polish Academy of Sciences, w. Wojciecha 5, 81-347 Gdynia, Poland3
Author for correspondence: Mark S. Thomas. Tel: +44 114 271 2834. Fax: +44 114 273 9926. e-mail: m.s.thomas{at}shef.ac.uk
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ABSTRACT |
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Keywords: bacteriophage infection, MacConkey agar, antigen 43, RNA polymerase subunit, phase switching
Abbreviations: DOC, deoxycholate; PVP, polyvinylpyrrolidone; WSS Wytwórnia Surowic I Szczepionek
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INTRODUCTION |
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Antigen 43 (Ag43) is the major phase-variable protein in the outer membrane of E. coli and is present in excess of 5x104 molecules per cell (Owen, 1992 ). Ag43 is composed of two subunits,
and ß, which are encoded by a single gene, agn43 (formerly called flu) in E. coli K-12, and maturation requires removal of the N-terminal signal peptide and proteolytic cleavage of the remaining polypeptide (Caffrey & Owen, 1989
; Henderson et al., 1997
). The 43 kDa
subunit is surface-expressed and is attached to the cell through an interaction between its C-terminal domain and the 43 kDa ß subunit, an integral outer-membrane protein (Caffrey & Owen, 1989
; Owen et al., 1987
). Presentation of Ag43 on the cell surface is responsible for the so-called frizzy or form 1 phenotype (Diderichsen, 1980
; Henderson et al., 1997
; Warne et al., 1990
). This protein has also been reported to be a factor required for autoaggregation of E. coli cells (Henderson et al., 1997
; Hasman et al., 1999
, 2000
), interspecies cell aggregation (Kjaergaard et al., 2000a
, b
) and cell-to-cell interactions within E. coli biofilms (Danese et al., 2000
).
In this work we examined phage development in the presence of bile salt concentrations resembling those found in the intestinal tract (Pope et al., 1995 and references therein). Our results show that in the presence of carbohydrates, bile salts can strongly inhibit the ability of phage
and other coliphages to infect E. coli. This inhibition can be suppressed by the presence of Ag43 on the host cell surface, suggesting a potentially important role for this protein in interactions between E. coli and its phages in their natural environment.
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METHODS |
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Culture media.
LuriaBertani (LB) medium and LB agar were as described by Sambrook et al. (1989) . Various compounds were added to the LB medium as indicated. Growth rates of all tested strains varied only slightly (
15%) in the presence of these compounds at the concentrations used (data not shown). Different sources of MacConkey agar were used: Difco Bacto MacConkey Agar Base, Oxoid MacConkey Agar and MacConkey Agar from WSS (Wytwórnia Surowic i Szczepionek). The compositions of these broths are broadly similar, but they differ in certain respects, most importantly in the nature of the included bile salts (for details see legend to Table 1
).
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One-step growth experiments.
Lytic development of bacteriophage in E. coli cells was investigated by one-step growth experiments as described by Szalewska et al. (1994)
.
Measurement of the efficiency of phage adsorption.
Bacteriophages were added to E. coli cells suspended in the appropriate medium to a m.o.i. of 0·1 and the mixture was incubated at 30 °C (experiments performed at 37 °C gave similar results although the kinetics of adsorption were different). Samples were withdrawn at the times indicated, centrifuged for 1 min in a microcentrifuge and the supernatant was titrated on the E. coli wild-type strain MG1655. The titre obtained at time zero (a sample withdrawn immediately after addition of bacteriophages to the cell suspension) was considered to correspond to 100% unadsorbed phages and other values were calculated relative to this value.
Bacterial autoaggregation assay.
Autoaggregation of bacterial cells was tested according to Hasman et al. (1999) . Briefly, overnight cultures of tested strains were adjusted to approximately the same OD575 (about 1·2) by dilution with the same medium and 15 ml each culture was placed in a sterile 20 ml tube and vigorously agitated for 10 s. 1 ml samples were withdrawn from approximately 1 cm below the meniscus at the indicated times and the OD575 was measured.
Isolation and analysis of membrane proteins.
Cell and protein fractionation by sucrose density gradient ultracentrifugation was performed as described by Kucharczyk et al. (1991) and K
dzierska et al. (1999)
. The fractions of outer- and inner membrane proteins were collected separately and subjected to SDS-PAGE.
Protein sequencing.
After transfer of the material from selected protein bands obtained after SDS-PAGE to an Immobilon P membrane (Bio-Rad), automatic microsequencing was performed at the Institute of Molecular Biology, BioCenter, Jagiellonian University (Cracow, Poland).
Measurement of ß-galactosidase activity.
Activity of ß-galactosidase in cells harbouring a fusion of the agn43 promoter to the lacZ gene was measured according to Miller (1972) .
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RESULTS |
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To determine whether this phenomenon was dependent only on the presence of DOC and lactose, we added the individual MacConkey components separately and in various combinations to LB agar, and titrated bacteriophage on E. coli lawns grown on each composite medium. In no case was formation of plaques inhibited when components of MacConkey agar were tested singly, although addition of lactose or DOC resulted in the production of smaller plaques. Only when lactose was present together with DOC was
plaque formation abolished. The nature of the carbohydrate (whether pentose or hexose, or mono- or disaccharide) present in the medium in combination with DOC does not appear to be important for the inhibition of phage
development. Furthermore, metabolism of the carbohydrate does not play a role in the inhibitory process, as plaque formation on a lac- tester strain, WAM106, was also found to be inhibited by the presence of DOC and lactose together (data not shown). To determine whether the inhibitory effect is specific for carbohydrates or also occurs in the presence of other related carbon sources, we tested the effects of the polyalcohols glycerol and mannitol in combination with DOC on plaque formation by phage
. We observed only a slight reduction in plaque size in the presence of these components relative to the plaque size formed in the presence of DOC alone (data not shown). Pyruvate together with DOC caused some reduction in plaque size but not as much as pentoses, hexoses and disaccharides (data not shown). Thus, it seems that the strong inhibitory effect on plaque formation is specific to carbohydrates.
We tested whether other bile salts and bile acids, acting alone or together with carbohydrates, are able to inhibit phage development in LB medium. Addition of unconjugated bile salts containing one, two or three hydroxyl groups (lithocholate, chenodeoxycholate and cholate, respectively) had similar effects to those exerted by DOC (two hydoxyl groups), whereas cholanic acid, a bile acid metabolite devoid of hydroxyl groups, was only slightly inhibitory for plaque formation (Table 2). The conjugated forms of cholate and DOC also had little effect on
plaque formation (Table 2
). We also examined the effect of the structurally related (i.e. steroidal) detergent CHAPS and the non-detergent bile salt precursor cholesterol, as well as other unrelated detergents, both ionic (Sarkosyl, SDS) and non-ionic (Brij 58, Triton X-100), on plaque formation. While addition of all these compounds to LB medium did result in a reduction in plaque size in the presence of added carbohydrate (particularly Sarkosyl and Triton X-100) none of them completely inhibited plaque formation (Table 2
). Other compounds that increase the viscosity of the medium, such as PEG and PVP (polyvinylpyrrolidone), only exerted slight inhibitory effects on plaque formation in the presence of carbohydrate (Table 2
).
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Bile salts in combination with carbohydrates impair phage adsorption
To identify the step that is inhibited by the combined presence of bile salts and carbohydrates, phage growth was monitored in one-step growth experiments where the phage and E. coli host were exposed to DOC and lactose either before or following phage adsorption. No significant influence of these compounds on phage growth (as judged by measurement of phage burst size) was observed when added after phage adsorption (data not shown). When we tested the efficiency of adsorption in the presence of DOC or lactose we found that phage adsorption was somewhat less effective in the presence of either of these components (
60% and 30% of phages remained unadsorbed in the presence of DOC or lactose alone, respectively, in comparison to less than 10% phages remaining unadsorbed in the absence of these compounds). However, adsorption was severely impaired by the combined presence of DOC and lactose (
90% phages remained unadsorbed) (Fig. 1a
). Other carbohydrates in combination with DOC gave rise to similar results (data not shown). Thus, we conclude that the inhibition of phage
development by the combined action of bile salts and carbohydrates is mainly due to impairment of phage adsorption on the host cells.
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The rpoA341 mutation suppresses the inhibition of phage adsorption and plaque formation in the presence of bile salts and carbohydrates
The rpoA gene encodes the subunit of RNA polymerase. This subunit plays a role in activator- and UP element-dependent transcription at many promoters. We found that phage
forms normal plaques on lawns of a strain (WAM105) harbouring a mutant rpoA allele, rpoA341, in the presence of DOC and lactose, whereas an otherwise isogenic rpoA+ strain (WAM106) behaved in an identical fashion to the wild-type E. coli strain MG1655 (Table 3
). Indeed, with all the combinations of bile salts/detergents and carbohydrates described above, the ability of the WAM106 strain (rpoA+) to support plaque formation was the same as that of MG1655, whereas
formed normal plaques on lawns of the rpoA341 mutant in the presence of all of the combinations tested (data not shown). We also found that whereas phage
adsorbs with low efficiency to the rpoA+ host (WAM106) in the presence of DOC and lactose, these agents have little inhibitory effect on
adsorption to the rpoA341 mutant (Fig. 1b
, c
).
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Activity of the agn43 promoter is stimulated by the rpoA341 mutation
To test whether the increased abundance of Ag43 in the rpoA341 mutant was due to an increase in the efficiency of transcription of the gene encoding this protein, agn43 (formerly known as flu), we constructed a transcriptional fusion consisting of the agn43 promoter and the lacZ reporter gene. We found that the agn43 promoter is active in the rpoA+ strain under all conditions tested, although it is depressed by about 40% in the presence of lactose alone, DOC alone, or lactose and DOC together (Table 4). However, the ß-galactosidase activity in the rpoA341 mutant harbouring this fusion is 23-fold higher than that in the rpoA+ strain, and is less strongly affected by the presence of DOC and/or lactose in the medium (Table 4
). As the fusion was present on a plasmid, we measured the plasmid copy number in both strains and found no significant difference (data not shown). Therefore, the increased abundance of Ag43 in the rpoA341 mutant is due, at least in part, to increased transcription of agn43.
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The rpoA341 mutation increases the sensitivity of E. coli to hydrogen peroxide
As OxyR is a negative regulator of agn43 expression, the rpoA341 mutation could exert its stimulatory effect on agn43 transcription indirectly, through impairing expression of oxyR. As oxyR mutants are sensitive to hydrogen peroxide, we tested the possibility that strains bearing the mutant RNA polymerase are sensitive to hydrogen peroxide. Bacteria containing either the rpoA341 allele or both the rpoA341 and oxyR::kan alleles together were found to be at least as sensitive to hydrogen peroxide as the
oxyR::kan mutant (data not shown). This observation is consistent with the possibility that the rpoA341 mutation results in impairment of oxyR expression.
Ag43 suppresses the inhibitory effect of bile salts and carbohydrates on adsorption and plaque formation by phage
To test whether the ability of phage to efficiently adsorb to a strain carrying the rpoA341 mutation in the presence of bile salts and carbohydrate is specifically due to the increased production of Ag43 in this strain, we constructed an rpoA341 agn43::cat double mutant. This strain was found to be unable to support phage adsorption and the formation of normal plaques by
in the presence of DOC and lactose (Table 5
). Therefore, we investigated the effect of Ag43 overproduction on the efficiency of phage
adsorption to the rpoA+ strain. As expected, we found that in WAM106 bacteria in which Ag43 production was directed from a multicopy plasmid (pAG43g) the cells autoaggregated efficiently. Moreover, phage
adsorption on this strain was efficient irrespective of the presence of DOC and/or lactose (Fig. 1d
, e
). The improved adsorption of phage
on Ag43-overproducing rpoA+ cells in the presence of DOC and lactose also resulted in restoration of the ability of this strain to support normal plaque formation under these conditions (Table 3
). Similarly, we found that in the presence of DOC and lactose,
forms normal plaques on the reference agn43+ host (ZK2686), but not on the agn43::cat mutant (ZK2692). The inability of phage
to form plaques on ZK2692 was suppressed by expression of agn43 from a plasmid (Table 5
). These results strongly suggest that the ability of the rpoA341 host to support phage development in the presence of bile salts and carbohydrates is due to a specific stimulatory effect of this mutation on agn43 gene expression.
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The inhibitory effect of carbohydrates and bile salts on phage growth is not restricted to bacteriophage
To examine whether the combined action of bile salts and carbohydrates on phage infection is specific only for we examined plaque formation by phages P1 and T4 in the presence of lactose and DOC. We found that the presence of these compounds affects plaque formation by both phages in a similar manner to that observed for
, i.e. plaque formation by P1 and T4 was inhibited by the presence of lactose and DOC (Table 3
). Moreover, in both cases phage adsorption was shown to be impaired by the presence of lactose and DOC (data not shown). Furthermore, this inhibition was abolished by either the presence of the rpoA341 mutation or expression of the agn43 gene from a multicopy plasmid, although the stimulatory effects of agn43 expression on plaque formation by phage P1 were less pronounced than for
and T4 (Table 3
). Since plaque formation by
, P1 and T4 phages in the presence of DOC and lactose was restored by the same genetic factors, yet their target receptors differ, it seems that the inhibition of phage development is due to a general physical or chemical effect on phage adsorption rather than directed at a specific phage receptor.
Bile salts together with carbohydrates may sequester divalent cations and prevent effective phage adsorption but can be compensated for by the presence of Ag43 on the cell surface
Many phages require the presence of divalent cations for stability and to neutralize the negative charge of the bacterial cell surface to allow efficient adsorption to their hosts (Casjens & Hendrix, 1988 ; Hancock, 1997
). Under conditions of relatively low cation concentration (we do not supplement LB media with divalent cations) any sequestration of cations, or exclusion of cations from the bacterial cell surface, by the combined action of bile salts and carbohydrates could explain the observed inhibition of phage adsorption. In support of this idea, we found that the inhibitory effect of bile salts and carbohydrates on plaque formation by phages
and T4 on MG1655 or WAM106 can be suppressed by addition of Mg2+ (20 mM) to the medium, whereas addition of Ca2+ (20 mM) is required to suppress the effect on plaque formation by P1 (data not shown).
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DISCUSSION |
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Few conclusions can be drawn regarding the structural requirements of the inhibitory detergents. Like all bile acids, the inhibitory bile acids (cholate, DOC, chenodeoxycholate and lithocholate) are steroid-based molecules, possessing between one and three hydroxyl groups in addition to the alkyl side chain carboxyl group. The hydroxyl groups attached to the steroid moiety mean that the molecule has polar and non-polar faces. Although dihydroxy bile salts (DOC, chenodeoxycholate) are more effective than trihydroxy bile salts (cholate) in membrane solubilization and dissociation of proteinprotein interactions, we observed no relationship between this property and their effect on plaque formation. Cholanic acid, which is not inhibitory for plaque formation, is identical to these bile acids except that it does not possess hydroxyl groups. On the other hand, the bile acid precursor cholesterol, which is also not inhibitory for plaque formation, does possess a hydroxyl group attached to the steroid moiety but the aliphatic side chain is larger and lacks a carboxyl group. Interestingly, amidation of the single carboxyl group of cholic acid or DOC with an amino acid, despite resulting in replacement of the original bile acid carboxyl group with an alternative free carboxyl or sulfonyl group (e.g. glycodeoxycholate, taurodeoxycholate or CHAPS), diminishes the potency of these compounds.
As infection of E. coli by other phages that employ different receptors for attachment to the host bacterial cell surface are similarly prone to interference by bile salts and carbohydrates, the mechanism of inhibition of phage adsorption is unlikely to involve specific effects on their receptors. The possibility of a direct effect of bile salts and carbohydrates on the phages themselves is also unlikely because we found that overproduction of a bacterial protein, Ag43, serves to restore efficient phage adsorption and plaque formation in the presence of bile salts and carbohydrates. Our results suggest that bile salts together with carbohydrates may sequester cations or deplete them from the cell surface and thereby prevent effective phage adsorption. This inhibition can be circumvented by the presence of Ag43 on the cell surface. Since the subunit of Ag43 extends beyond the LPS O antigen (Henderson et al., 1997
) and can function as an adhesin mediating autoaggregation and biofilm formation (Diderichsen, 1980
; Danese et al., 2000
), this protein could serve as an alternative initial site of interaction of the phage with the host under limiting concentrations of divalent cations. The possibility that phage adsorption is somehow facilitated by Ag43-mediated aggregation of bacteria, rather than due to an interaction with Ag43 is unlikely, as Ag43-induced suppression also occurs in solid medium.
Role of the RNA polymerase subunit in regulation of agn43 expression
Phase variation of Ag43 is regulated at the transcriptional level and requires the Dam methylase and the regulatory protein OxyR (Henderson & Owen, 1999 ). It was proposed that OxyR represses transcription by binding to a site located 19 bp downstream from the putative start point for agn43 transcription (Hasman et al., 1999
). Three GATC sites, which are targets for methylation by the Dam methylase, are located in the regulatory region of the agn43 gene (Henderson & Owen, 1999
; Hasman et al., 1999
). These sequences are not protected from methylation in an oxyR background and methylation of these sequences abrogates binding by OxyR (Haagmans & van der Woude, 2000
). Thus, the Dam methylase promotes the ON phase, while binding by OxyR has the opposite effect. The oxyR gene, in turn, is regulated by catabolite repression: mutations in crp (encoding cAMP receptor protein, the global regulator of catabolite-repressible genes) or cya (encoding adenylate cyclase) prevent the induction of oxyR expression that occurs in early exponential phase (Gonzalez-Flecha & Demple, 1997
).
We found that introduction of the rpoA341 mutation into cells predominantly in the OFF phase for agn43 expression results in switching of the population to the ON phase as judged by the presence of increased synthesis of Ag43 and an increased efficiency of autoaggregation. Gene fusion analysis suggested that this was due, at least in part, to an increase in transcription of agn43. The rpoA341 mutation results in a single amino acid change (K271E) in the C-terminal domain of the subunit of RNA polymerase (Thomas & Glass, 1991
). It was previously demonstrated that the stimulation of a number of promoters by different transcriptional activators, including two promoters which require the CRPcAMP complex, is impaired in the rpoA341 mutant (Giffard & Booth, 1988
; W
grzyn et al., 1992
; Szalewska-Pa
asz et al., 1996
; Obuchowski et al., 1997
; Gabig et al., 1998
), most probably due to a defective interaction between these activators and RNA polymerase. Since efficient expression of oxyR requires the CRPcAMP complex, one possible reason for the increased transcription of agn43 in the rpoA341 mutant may be a decrease in OxyR synthesis due to a defective interaction between the CRPcAMP complex and RNA polymerase at the oxyR promoter. In support of this, bacteria harbouring the rpoA341 allele were found to be sensitive to hydrogen peroxide.
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ACKNOWLEDGEMENTS |
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Received 26 July 2001;
revised 22 October 2001;
accepted 7 January 2002.