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Previous Article | Next Article 
Infection and Immunity, June 2000, p. 3758-3762, Vol. 68, No. 6
0019-9567/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Constitutive Mutations of the Salmonella enterica
Serovar Typhimurium Transcriptional Virulence Regulator
phoP
John S.
Gunn,1,*
Robert K.
Ernst,2
Andrea J.
McCoy,1 and
Samuel I.
Miller2
Department of Microbiology, University of
Texas Health Science Center at San Antonio, San Antonio, Texas
78229-3900,1 and Departments of Medicine
and Microbiology, University of Washington, Seattle, Washington
981952
Received 13 December 1999/Returned for modification 17 February
2000/Accepted 22 March 2000
 |
ABSTRACT |
The PhoP-PhoQ two-component system is necessary for the virulence
of Salmonella spp. and is responsible for regulating
several modifications of the lipopolysaccharide (LPS). Mutagenesis of the transcriptional regulator phoP resulted in the
identification of a mutant able to activate transcription of regulated
genes ~100-fold in the absence of PhoQ. Sequence analysis showed
two single-base alterations resulting in amino acid changes at
positions 93 (S93N) and 203 (Q203R). These mutations were individually
created, and although each resulted in a constitutive phenotype,
the double mutant displayed a synergistic effect both in the induction
of PhoP-activated gene expression and in resistance to
antimicrobial peptides. The constitutive phoP gene was
placed under the control of an arabinose-inducible promoter to examine
the kinetics of PhoP-activated gene induction and the resultant
modifications of LPS. Gene induction and 2-hydroxymyristate
modification of the lipid A were shown to occur within minutes of the
addition of arabinose and to peak at 4 h. As the first
constitutive mutant of phoP identified, this allele will be
invaluable to future genetic and biochemical studies of this and likely
other regulatory systems.
| |
TEXT |
The PhoP-PhoQ two-component
regulatory system controls the expression of genes necessary for
virulence and survival of salmonellae within host macrophages (7,
18, 23). Within the macrophage phagosome, PhoP-PhoQ is
activated to induce gene transcription (1). The
regulated genes include those necessary for modification of
lipopolysaccharide (LPS) and resistance to the action of antimicrobial peptides, which likely increase bacterial survival within
macrophages (10, 13). Additionally, PhoP-PhoQ is
involved in the regulation of magnesium transport (9),
resistance to the action of bile (32), and secretion of
proteins by a type III mechanism (27).
PhoQ is a predicted transmembrane protein with a single periplasmic
domain encompassing amino acids 44 to 191 (11). Evidence suggests that this periplasmic domain binds environmental factors such
as Mg2+ (33, 34). PhoQ is a kinase that, upon
sensing environmental signals, activates the DNA binding function of
PhoP through a phosphorylation event (11) leading to
PhoP-regulated gene activation.
Constitutive activation of two-component regulators has been reported
for several systems in a variety of bacterial species (16, 17, 19,
28). Previously, a Salmonella enterica serovar Typhimurium phoP locus mutant (pho24) was
isolated that constitutively expressed PhoP-activated genes
(pag) and repressed PhoP-repressed genes (prg)
(21, 24). This mutation mapped to the gene encoding the
membrane-bound kinase PhoQ (change from Thr to Ile at position 48), and
not that encoding the DNA binding protein PhoP (11). The
pho24 allele has a pleiotropic affect on S. enterica serovar Typhimurium virulence, including the
attenuation of mouse virulence and survival within cultured
macrophages, which suggested a temporal importance in the shift to
PhoP-PhoQ activation during infection. This study describes the
identification and characterization of a constitutive mutant of this
regulatory system located in PhoP. The identification of this mutant
will aid current and future studies of the signal transduction process
and the interaction of PhoP with regulated gene promoters.
Identification and characterization of constitutive
phoP mutants.
To generate mutations in the
phoP gene, the following protocol was used. PCR primers were
designed to bind to the 5' and 3' ends of the phoP gene,
such that the 3' primer contained a PstI site at its
terminus and the 5' primer contained a BamHI site at
its terminus (JG31 and JG39, respectively). The 5' primer contained the
native ATG start codon with the BamHI site directly upstream of this translational start site. Upon amplification by PCR, the phoP gene was cloned into M13mp18 via the BamHI
and PstI sites. Single-stranded DNA (ssDNA) was purified
from M13 phage. Approximately 10 µg of ssDNA was incubated in a
25-µl final volume with hydrazine (2 and 3.36 M final concentrations)
or formic acid (3.7 and 6 M final concentrations) for 10 min at room
temperature or sodium nitrite (1.2 M final concentration) for 60 min at
room temperature. After chemical treatment, DNAs were diluted to 200 µl, precipitated, and resuspended in 20 µl of water. A 4-µl
aliquot of each mutagenized DNA was then PCR amplified with primers at
the 3' end (JG31) and 5' end (JG45) of the DNA. JG45 is similar to
JG39, except it contains an XbaI site and the native
ribosome binding site at its 5' terminus in place of the
BamHI site. The PCR products were digested with XbaI and PstI and cloned into the low-copy vector
pWSK29 (8), in which the phoP gene is transcribed
from the lac promoter of the vector. A portion of each
ligation was electroporated into Escherichia coli DH5
.
Following growth of cells in the entire ligation mix overnight in the
presence of ampicillin, plasmid DNA was isolated. As a first screen,
strain SIM547, which is a derivative of LB5010 (R-M+
galE recA phoP::Tn10d), was transformed
with the isolated DNA. The S. enterica serovar Typhimurium
phoN gene encodes a nonspecific acid phosphatase and
controls the blue color phenotype of cells on agar plates containing
the chromogenic substrate XP (5-bromo-4-chloro-3-indolylphosphate) (21). phoN is transcriptionally activated by
PhoP-PhoQ, and because SIM547 is PhoP-PhoQ null, this strain is white
on plates containing XP. Upon transformation of SIM547 with each of the mutagenized pools, several blue colonies (n = 35) were
observed (2 M hydrazine, 11.5% blue; 3.36 M hydrazine, 33% blue; 3.7 M formic acid, 2.8% blue; 6 M formic acid, 11% blue; and 1.2 M sodium nitrite, 9.3% blue). The plasmid DNA of all 35 blue colonies
identified was isolated and transformed into two strains: JSG465, which
is PhoP-PhoQ null and carries a transposon-generated fusion to a gene
whose transcription is increased when PhoP-PhoQ is activated (pagB::MudJ); and JSG225, which
contains a TnphoA insertion in pagD and is
phenotypically PhoP-PhoQ null (PhoP
) and
PhoN (phoN2
zxx::6251dTn10-CAM [85% linked to
phoN]). Of the 35 plasmids, only one (plasmid pPC3-2 from
the 2 M hydrazine pool) resulted in considerable activation of the
fusion protein in both JSG465 and JSG225. Several possibilities exist
for the lack of activation of the other plasmids identified in the
first screen. For example, phoN may require smaller amounts
of active PhoP than pagB or pagD for activation,
or, alternatively, the pool of SIM547 cells used for the transformation
may have contained those with a phoN mutation, allowing
expression in the absence of PhoP. The latter is less likely because
the percentage of blue isolates increased with increasing
concentrations of hydrazine or formic acid used with the DNA. Table
1 shows the 
-galactosidase or alkaline
phosphatase activities of the pho24 strain with each of the
reporter fusions examined, as well as those of various strains
containing either pPC3-2 or a wild-type (control) phoP
plasmid (pWSK200). These data show that pPC3-2 results in 94- and
63-fold activations of pagD and pagB,
respectively. In addition, slightly higher levels of PhoP-activated
gene transcription were observed with pPC3-2 than with the
pho24 (PhoQ constitutive) mutation. Therefore, this represents the first mutant of the virulence regulatory protein PhoP
that is able to activate genes of the PhoP regulon in the absence of
PhoQ signaling.
Analysis of the pPC3-2-mediated PhoP-constitutive phenotype.
S. enterica serovar Typhimurium strains containing the
pho24 allele activate and repress the production of a number
of proteins (Pag and Prg) that are obvious by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis. In
addition, activation of the regulon results in a variety of
distinguishing phenotypes, including increased resistance to certain
antimicrobial peptides (10, 12, 25), which are potent
antibacterial factors that are ubiquitous in the animal and plant
kingdoms (2, 36). Therefore, strains carrying the pPC3-2
plasmid were examined by SDS-PAGE for alteration of protein expression
and for altered resistance to antimicrobial peptides. Whole-cell
lysates of the PhoP and PhoPc
(pho24) strains and of PhoP strain with pPC3-2
were prepared from overnight cultures as previously described
(11) and electrophoresed on a 10% polyacrylamide gel. As
seen in Fig. 1, PhoPc
(pho24) and PhoP with pPC3-2 lysates look
similar, and both are different from PhoP lysate at
several locations (the most obvious of which are marked by an arrow).
Therefore, the protein pattern imparted by the pPC3-2 plasmid appears
to be the "constitutive pattern" and is accomplished in the absence
of PhoQ. In addition to the similarities in protein profiles of the
pPC3-2-containing strain and the PhoQ-Ile48 mutant strain, there exist
some protein differences between these strains, including differences
in intensity between some common activated species. This may be due to
slight differences in promoter affinity between the mutant and the
wild-type phoP alleles.
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FIG. 1.
Analysis of protein expression patterns by SDS-PAGE.
Whole-cell proteins of the PhoP (lane 1) strain, the
PhoP strain with plasmid pPC3-2 (lane 2), and the
PhoQ-constitutive (pho24) (lane 3) strain were separated on
a 10% polyacrylamide gel. The expression pattern of lane 2 containing
proteins of the PhoP strain with plasmid pPC3-2 is
similar to that of lane 3 containing proteins of the PhoQ-constitutive
(pho24) strain and dissimilar from that of lane 1, further
demonstrating the constitutive phenotype imparted by the pPC3-2
constitutive phoP allele. Arrows point to the most obvious
protein differences between those with the PhoP-constitutive pattern
(lanes 2 and 3) and the PhoP pattern (lane 1). Lane M
contains the molecular mass standards, the sizes of which are given to
the left in daltons.
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|
To examine the antimicrobial peptide resistance phenotype, MIC assays
were conducted with the PhoP strain carrying pPC3-2 or
the control plasmid pWSK200. The results showed that the
PhoP strain with pPC3-2 had an eightfold increase in
resistance to PG-1, an 18-amino-acid peptide with a -sheet structure
isolated from porcine neutrophils (data not shown). Therefore, the
presence of the pPC3-2 plasmid resulted in increased resistance to
antimicrobial peptides, which was previously known to depend upon the
level of activated PhoP in the cell.
DNA sequencing and site-directed mutagenesis determine the genetic
basis of the pPC3-2-mediated PhoP-constitutive phenotype.
To
determine the genetic basis of the constitutive phenotype associated
with plasmid pPC3-2, the phoP gene was sequenced. Sequence
analysis showed two mutations: a G
A at base position 418, resulting
in an SN alteration at amino acid 93; and an AG at base position
748, resulting in a QR alteration at amino acid 203 (base positions
correspond to those defined by Miller et al. [23];
GenBank accession no. M24424). These residues flank consensus regions
near the amino and carboxy termini and are novel among OmpR family
regulatory protein constitutive mutations that have been identified
(Fig. 2). Interestingly, OmpR, PmrA, and VirG constitutive mutations that have been identified also frequently flank or are located within consensus regions (3, 16, 17, 19, 20,
26, 28, 29, 31). To determine if one or both of these mutations
was sufficient for the observed constitutive phenotype, each mutation
was constructed by site-directed mutagenesis. Primers JG68 and JG69
were made to contain the mutations at bases 418 and 748, respectively.
Mutagenesis was accomplished with the Muta-Gene phagemid kit (Bio-Rad)
and confirmed by DNA sequence analysis. The resulting plasmids,
pPSK200-691 (containing the 784 AG mutation) and pPSK200-7974
(containing the 418 GA mutation), were transformed into strain
JSG225. Upon analysis of alkaline phosphatase activity, it was shown
that both mutations resulted in activation of the
pagD::TnphoA fusion, with PhoP S93N resulting in 65-fold activation and PhoP Q203R resulting in 15-fold activation. These activities, though, were less than that of both mutations together (94-fold activation). As further verification of the constitutive phenotype imparted by the PhoP S93N and PhoP Q203R single
mutations, strains carrying the mutant plasmids were examined in the
peptide resistance assay. Both single mutations resulted in a MIC
requirement that was intermediate between that of the negative control
and that of the strain carrying both mutations together (data not
shown). This further suggests that these mutations act synergistically
to result in the observed high-level PhoP activation.
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FIG. 2.
Protein alignment of OmpR-type regulators with known
constitutive mutations. The protein sequences aligned include those of
PhoP (GenBank accession no. M24424), PmrA (accession no. L13395), OmpR
(accession no. J01656), and VirG (29). Circled residues with
arrows denote those changes that have been shown to result in a
constitutive phenotype. Highly conserved consensus regions located near
these sites, including the aspartic acid residue (D) predicted to be a
site of phosphorylation, are boxed.
|
|
Use of the constitutive phoP gene to determine the
kinetics of pag activation and LPS modification.
It
has been shown by Garcia-Vescovi et al. (9) that upon
chelation of Mg2+ in the media, activation of a
PhoP-regulated locus, psiD, occurs rapidly and peaks by
5 h. We placed the constitutive phoP gene under the
control of an arabinose-inducible promoter and used this to determine
the kinetics of activation of several pag genes as well as
the modification of lipid A with 2-hydroxymyristate, which can be added
as a result of activation of an unknown PhoP-activated gene(s). To
construct an arabinose-inducible phoP-constitutive gene, the
phoP gene was PCR amplified from pPC3-2 with primers JG225
and JG45, digested with enzymes HindIII and
XbaI (whose sites were incorporated into the 5' end of
primers JG225 and JG45, respectively), and ligated into vector
pBAD18 (15). Following transformation of E. coli
DH5, the correct plasmid was identified (pPCBAD3-2). Upon
transformation of the clone into various S. enterica serovar
Typhimurium strains, cells were grown to mid-log phase, and arabinose
was added to a concentration of 0.05 or 0.2% (both concentrations have
been shown to maximally induce the pBAD promoter). Cells were harvested
at time points before and after arabinose addition and examined for
pag gene activation by -galactosidase or alkaline
phosphatase assays or for LPS modifications as described below. Upon
induction of the mutant phoP with arabinose in a
PhoP background, activation of pagD was
observed within minutes and peaked at 4 h (Fig.
3). Nearly identical kinetics were
observed with other PhoP-activated genes tested (data not shown).
Because these kinetics are similar to those reported by Garcia-Vescovi et al. (9), this finding suggests that Mg2+
signaling, which is sensed by PhoQ and communicated to PhoP via a
phosphotransfer event, is as efficient as altering the presence or
absence of an "activated" PhoP protein.
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FIG. 3.
Activation of pagD transcription by
arabinose-inducible PhoP production. PhoP strains
carrying a pagD::TnphoA reporter and the
pPCBAD3-2 plasmid were grown to log phase and then not supplemented or
supplemented with arabinose. Alkaline phosphatase activity was
monitored over time. Lines with squares are results from cultures with
arabinose added at time zero, and those with diamonds are results from
cultures without arabinose added.
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|
Numerous modifications of S. enterica serovar Typhimurium
LPS are controlled by PhoP (12-14), including modification
of the lipid A with 2-hydroxymyristate. PhoP-mediated modification of LPS within macrophage phagosomes is thought both to aid in resistance of the bacterium to resident antimicrobial peptides and to alter immune
recognition and cytokine response (13, 35). For modification of LPS to be effective, it must occur rapidly upon PhoP activation. To
examine the kinetics of LPS modification, lipid A was isolated at
various time points after activation of the mutant phoP
allele with arabinose. LPS was isolated by the Mg2+-ethanol
precipitation procedure as described by Darveau and Hancock (6). Lipid A was isolated from LPS by hydrolysis in 1% SDS at pH 4.5 (4), and the fatty acids were analyzed as methyl esters by capillary gas chromotography GC with flame ionization detection as described previously (5, 30). The identities of
the individual fatty acid chains were confirmed by capillary GC with
electron impact mass spectrometry. These experiments showed that, upon
activation of phoP, the amount of 2-hydroxymyristate present
in lipid A isolated from induced phoP mutant bacteria was
two- to threefold higher than the amount present in lipid A isolated
from noninduced phoP mutant bacteria. Upon induction, the
amount of 2-hydroxymyristate increased rapidly, with greater than 15%
of the lipid A containing this modification within 4 h, and was
maintained throughout the course of the assay (Fig. 4). Similar to the induced
phoP mutant strain, the phoQ-constitutive strain
(pho24) demonstrated an increase in the amount of
2-hydroxymyristate with more than 25% of the lipid A containing this
modification within 4 h (data not shown). Finally, a
phoP-null strain gave amounts of 2-hydroxymyristate similar
to those of the noninduced phoP mutant (data not shown).
These results demonstrate that pag activation and
modification of lipid A with 2-hydroxymyristate occur with similar
kinetics, confirming the assumption that, upon PhoP-activation,
pag gene transcription, Pag enzymatic activity, and LPS
modification and turnover all occur fairly rapidly. Rapid modification
of the LPS is likely necessary for Salmonella's
intracellular survival by providing resistance to the host's innate
immune system and by altering immune system recognition of this
pathogen.
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FIG. 4.
Activation of 2-hydroxymyristate lipid A (2-OH C14:0)
modification by arabinose-inducible PhoP production. A
PhoP strain carrying the pPCBAD1 plasmid was grown to log
phase and then not supplemented or supplemented with arabinose (0.2%).
The percentage of 2-hydroxymyristate lipid A modification was monitored
over time by GC analysis. Solid circles represent a culture with
arabinose added at time zero, and solid squares represent a culture
without arabinose added. The experiment presented was representative of
three separate experiments.
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|
The identified constitutive phoP allele will be invaluable
in future work defining the PhoP-PhoQ regulon. This phoP
mutant will aid in the definition of the unknown molecular events of PhoP interaction with both activated and repressed gene promoters. Furthermore, this mutant will be used to test the induction kinetics of
other PhoP-PhoQ-mediated phenotypes, such as antimicrobial peptide and
bile resistance, and type III-mediated secretion of proteins involved
in eukaryotic cell invasion.
| |
ACKNOWLEDGMENTS |
We thank IntraBiotics Pharmaceuticals, Inc., for providing
protegrin (PG-1) and Jennifer Van Velkinburgh for her technical assistance.
This work was supported by grants AI30479 (S.I.M.) and AI43521 (J.S.G.)
from the National Institutes of Health.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology, Mail code 7758, University of Texas Health Science Center at San Antonio, 7703 Floyd Curl Dr., San Antonio, TX 78229-3900. Phone:
(210) 567-3973. Fax: (210) 567-3795. E-mail:
gunnj{at}uthscsa.edu.
Editor:
J. T. Barbieri
| |
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Infection and Immunity, June 2000, p. 3758-3762, Vol. 68, No. 6
0019-9567/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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