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Previous Article | Next Article 
Journal of Bacteriology, August 1999, p. 4896-4904, Vol. 181, No. 16
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
High-Frequency RecA-Dependent and -Independent
Mechanisms of Congo Red Binding Mutations in Yersinia
pestis
Janelle M.
Hare1 and
Kathleen A.
McDonough1,2,*
Department of Biomedical Sciences, University
at Albany, State University of New York,1 and
David Axelrod Institute, Wadsworth Center, New York State
Department of Health,2 Albany, New York 12201
Received 15 March 1999/Accepted 9 June 1999
 |
ABSTRACT |
Yersinia pestis, which causes bubonic and pneumonic
plague, forms pigmented red colonies on Congo red (CR) dye agar. The
hmsHFRS genes required for CR binding (Crb+)
are genetically linked to virulence-associated genes encoding a
siderophore uptake system. These genes are contained in a 102-kb chromosomal pgm locus that is lost in a high-frequency
deletion event, resulting in loss of the Crb+ phenotype. We
constructed a recA mutant strain of Y. pestis
KIM10+ (YPRA) to test whether the high frequency Crb mutants result
from a RecA-mediated deletion of the IS100-flanked
pgm locus. Two Pgm-associated phenotypes (Crb+
and pesticin sensitivity [Psts]) were used as markers for
the presence of the pgm locus in the RecA+
KIM10+ and RecA
YPRA strains. In KIM10+, both phenotypes
were lost at a very high (2 × 103) frequency, due
to the deletion of the entire pgm locus. In YPRA, the
Crb+ phenotype was still lost at a high frequency (4.5 × 105), although the loss of the Psts
phenotype occurred at spontaneous antibiotic resistance mutation frequencies (2 × 107). These RecA-independent
Crb mutants were caused by mutations in both the
hmsHFRS locus and in a newly identified gene,
hmsT. Nonpigmented Yersinia pseudotuberculosis and Escherichia coli strains transformed with both
hmsT and hmsHFRS became Crb+. This
study demonstrates that in a laboratory culture, the Crb+
phenotype is unstable, independent of the pgm locus
deletion. We propose that a lack of selection for the CR-binding
ability of Y. pestis in vitro may contribute to the
mutation frequencies observed at the hmsHFRS and
hmsT loci.
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INTRODUCTION |
Yersinia pestis, the
bacterium that causes bubonic and pneumonic plague, possesses a variety
of plasmid- and chromosome-encoded virulence genes. Wild-type Y. pestis strains bind Congo red (CR) dye in agar media and form
pigmented (Crb+) colonies at 26°C (but not at 37°C)
(21). This phenotype has been historically used as an
indicator for the presence of a group of virulence traits related to
iron uptake. This correlation between Crb+ and virulence is
due to the genetic linkage between the hmsHFRS locus
required for the Crb+ phenotype (29) and
virulence-associated genes that encode a siderophore-based iron uptake
system (1). The combined presence of these traits is
referred to as the pigmentation (Pgm+) phenotype, which is
spontaneously lost from Y. pestis at a high frequency
(2).
The loss of the Pgm+ phenotype results in the loss of a
variety of iron-regulated proteins and has pleiotropic effects.
Pgm bacteria are avirulent in a mouse model unless
infection occurs by an intravenous route or in the presence of
exogenously supplied iron (5, 38). Pgm
bacteria cannot grow at 37°C under iron-poor conditions (10, 31,
32) and are resistant to the bacteriocin pesticin, because of the
loss of the pesticin receptor, which functions as a receptor for both a
siderophore and the bacteriocin pesticin (10). Pesticin is
produced by Y. pestis and is active against bacteria that
possess the pesticin receptor but lack the pesticin production and
immunity plasmid pPst (33).
Fetherston et al. showed that the spontaneous loss of the
Pgm+ phenotype was due to the deletion of a large (102-kbp)
chromosomal pgm locus (12), which had been
previously observed (25). The pgm locus contains
the hmsHFRS genes that are required for the Crb+
phenotype (29) and transmission of Y. pestis by
its flea vector (19), as well as the virulence-associated
siderophore genes, which are part of the Y. pestis
high-pathogenicity island (YP-HPI) (3, 17).
Single, directly repeated copies of IS100 bound the
pgm locus (Fig. 1)
(11), but only one copy of IS100 remains when the pgm locus is deleted (12). This led to the
hypothesis that the pgm locus deletion is caused by a
recombination event between these IS100 copies (11,
20). However, one survey of a collection of 43 Y. pestis strains isolated throughout the world found that 27% of
the 26 Crb strains exhibited only a partial loss of
Pgm-associated phenotypes (20). These isolates were
Crb but hybridized to a DNA probe derived from the
irp2 gene, which is present at the opposite end of the
pgm locus (Fig. 1). However, no
irp2 and Crb+ bacteria were
identified. These strains' Crb phenotypes were traced to
deletions encompassing the hmsHFRS genes, as well as
mutations in both the hmsHFRS genes and in another, unknown
gene(s) (4).
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FIG. 1.
The 102-kb pgm locus of Y. pestis
KIM10+, showing the hmsHFRS and psn gene
locations and the IS100 copies bounding the locus. The inset
map of the hmsHFRS genes shows the locations of the PCR
primers HMS1, HMS2, HMS5, and HMS6, depicted as arrowheads 1, 2, 5, and
6. The arrow indicates the location and direction of the promoter
region of hmsHFRS. The DNA sequences contained in the
plasmids pSDR7, pSDR3, and pSDR13 are designated by horizontal lines.
The irp2, psn, and other genes at the right end
of the pgm locus encode the virulence-associated siderophore
production and uptake system (1, 14) encoded in the YP-HPI
(3, 17).
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These studies indicated that Crb colonies of Y. pestis bacteria can result from events other than a deletion of
the entire pgm locus. The Crb phenotype could
result from deletions at the hmsHFRS end of the pgm locus caused by homologous recombination between
appropriately located IS100 copies or other repeated
sequences. Alternately, these Crb mutants could be caused
by transposition of IS100 or other insertion sequences into
the hmsHFRS locus or may result from point mutations. Our
goals in this study were to determine the mechanisms and the relative
frequencies of these various deletions and mutations and to identify
any other gene(s) required for the Crb+ phenotype.
We investigated the role of RecA-mediated events in causing the
high-frequency loss of the Crb+ phenotype in Y. pestis by evaluating the frequency of the loss of two
Pgm-associated phenotypes in a recA mutant. We show that at
least two separate mechanisms produce the high-frequency
Crb phenotype in Y. pestis and that mutation
frequencies at different sites within the pgm locus may
vary. RecA-mediated deletion of the entire pgm locus caused
the majority of Crb mutants in RecA+ cells.
However, the use of a recA mutant strain, which could not
carry out the RecA-mediated pgm locus deletion event, showed that RecA-independent, Crb mutants occurred at a
frequency 100-fold higher than the frequency of spontaneous mutation to
drug resistance. These Crb recA mutants
carried mutations in either the previously defined hmsHFRS
genes or in a newly identified gene (hmsT), which is located outside the pgm locus. This study defines CR binding as an
unstable phenotype of Y. pestis, independent of the
high-frequency pgm locus deletion.
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MATERIALS AND METHODS |
Bacterial strains.
Y. pestis KIM10+ is a pigmented,
attenuated strain that was derived from a virulent prototype called KIM
(38). KIM10+ is a derivative of KIM6+ (the strain in which
the pgm locus and its deletion were initially characterized
[12]), which lacks the pesticin production and
immunity plasmid (29), making it sensitive to the effects of
pesticin. KIM10+ also lacks the 70-kbp calcium dependence plasmid but
contains the 100-kbp plasmid and the pgm locus (as denoted
by the "+" symbol) (29). Y. pestis and
Yersinia pseudotuberculosis strains were grown at 28°C on
brain heart infusion (BHI; Difco, Detroit, Mich.) agar or in BHI broth.
The Y. pseudotuberculosis strains used in this study were
cured of the calcium dependence plasmid to render them avirulent by
growth on sodium oxalate plates at 37°C (15). Y. pseudotuberculosis PTB50, PTB51, PTB52, and PTB56 are serotype IB
and possess the yersiniabactin siderophore system encoded by the YP-HPI
(17). Y. pseudotuberculosis PTB53, PTB54, and
PTB55 are serotypes IB, III, and III, respectively, and do not possess
the yersiniabactin siderophore system. The KIM10+ recA
mutant was named YPRA and is described below. Transforming the cloned,
native recA gene back into YPRA generated the
RecA+ strain YPRA(pBSrecA).
KIM10+ recA mutant construction.
The Y. pestis recA GenBank entry (accession no. X75336) was used to
design PCR primers (forward,
5'-TTAAGTCGACGGTACGTGAAATGGCATTGGG-3'; reverse,
5'-ATTAGGATCCGCAGTTCAGATTCACTTTGG-3'; annealing temperature, 59°C) that would amplify a RecA-expressing cassette. Genomic DNA from
Y. pestis 195/P (27) was the DNA template for
PCRs (DNA thermal cycler model 480; Perkin-Elmer Cetus, Norwalk,
Conn.). The 1.65-kbp Y. pestis recA PCR product was cloned
into pBluescript SK(+) (Stratagene, La Jolla, Calif.) and maintained in
Escherichia coli JM109 by ampicillin (100 µg/ml).
The cloned recA gene was mutated by cloning a 955-bp
kanamycin resistance cassette (aph3') from Tn903
(8) into unique ClaI and EcoRV sites
within the recA gene. This replaced approximately the middle
third of the recA coding sequence. This marked
recA clone (pBS
recA::kan) was maintained in
JM109 by kanamycin (50 µg/ml). The deleted 390-bp
ClaI-EcoRV recA fragment was cloned into pBluescript SK(+) to form pmidrecA. A 2.2-kbp
SacI-SalI fragment of pBSrecA::kan
containing the marked recA::kan region was
subcloned into the suicide vector pCVD442 to form
pCVDrecA::kan. pCVD442 has a pir-dependent
origin of replication from the plasmid R6K and was maintained in
E. coli (
pir) (9). pCVD442
contains the Bacillus subtilis counterselectable marker
sacB, which encodes levan sucrase, an enzyme that is toxic
to gram-negative bacteria in the presence of sucrose (13).
pCVDrecA::kan was electroporated into Crb+
KIM10+ cells, which were plated on BHI agar containing ampicillin (50 µg/ml) and kanamycin (50 µg/ml) to select for merodiploids
possessing the suicide vector construct integrated into native
recA. Plasmid absence was verified by performing a plasmid
DNA preparation on merodiploid candidates. Direct selection for a
second crossover to replace the native recA gene was
obtained by plating an overnight culture grown in the absence of drug
selection on BHI agar plus 5% sucrose and kanamycin.
Genetic and phenotypic verification of the recA
mutant YPRA.
Southern analyses were carried out on the PCR
amplification product of the recA genes from the chromosome
of the KIM10+ and YPRA strains. Three probes were used: the KIM10+
native recA gene, the kanamycin resistance cassette, and the
390-bp fragment of recA that was replaced in YPRA.
Western blot analyses were carried out by using an anti-E.
coli RecA antibody donated by the Charles Radding laboratory.
Total cell lysates were obtained by boiling an overnight culture of cells in a standard 1× sodium dodecyl sulfate gel loading buffer (30) for 3 min and were run on a sodium dodecyl
sulfate-12.5% polyacrylamide gel. The gel was blotted onto a
Zeta-Probe membrane with a TransBlot SD system (both from Bio-Rad
Laboratories, Hercules, Calif.). The blot was blocked overnight in
Tris-buffered saline (TBS)-0.1% Tween-20-5% nonfat dry milk, washed
in TBS-0.1% bovine serum albumin, and incubated with a rabbit
anti-E. coli RecA antibody diluted 1:1,000 in TBS-bovine
serum albumin-Tween. The blot was then washed and incubated with an
alkaline phosphatase-conjugated goat anti-rabbit immunoglobulin G
antibody (Jackson ImmunoResearch, West Grove, Pa.). Alkaline
phosphatase activity was observed by rinsing the blot in the detection
reagents BCIP (5-bromo-4-chloro-3-indolylphosphate) and nitroblue
tetrazolium for 4 min, after which the reaction was stopped by rinsing
the blot with deionized water.
A UV sensitivity test was carried out by irradiating uncovered BHI
plates spread with KIM10+ and YPRA cultures (optical density at 600 nm,
0.2) with 5,000 mJ of UV light per cm2 for 12 s
in a UV Stratalinker 1800 (Stratagene) apparatus. These dilutions were
also plated on BHI agar plates containing 0.5 µg of mitomycin C
(Sigma, St. Louis, Mo.) per ml. Control plates spread with these
dilutions were not exposed to UV light or mitomycin C. After 3 days of
incubation in the dark at 28°C, viable counts in the presence and
absence of UV exposure or mitomycin C were calculated. Colonies were
photographed under dark-field conditions on an Olympus SZH10 research
stereoscope equipped with an Olympus PM-10ADS automatic photomicrograph
system and an Olympus C-335AD-4 camera. Diameters of KIM10+ and YPRA
colonies were measured from stereomicrographs at a magnification of
×7.
Phenotype assays.
Pesticin plates were prepared by plating
0.2 ml of an overnight culture of the pesticin-producing Y. pestis strain EV76-x(pKYP1) on BHI agar. After 2 days of
incubation at 28°C, 5 ml of molten BHI agar was overlaid on the
plates, which were then stored at 4°C for 2 days. CR plates contained
heart infusion agar (Difco) plus 0.2% galactose and 0.01% CR dye
(Sigma) (36). Surgalla CR plates contained 1% heart
infusion broth plus 2% agar, 0.2% galactose, and 0.01% CR dye
(36). A single colony of each test strain was inoculated
into 3 ml of BHI broth and grown for 24 h at 28°C. The culture
was then plated on pesticin and CR plates and incubated at 37°C
(pesticin plates) or 28°C (CR plates) for 2 days. The frequency of
pesticin resistance was calculated by dividing the CFU per ml for
pesticin-resistant colonies by the total CFU per ml for the culture as
determined by growth on control BHI agar plates. The Crb
frequency was calculated by dividing the number of Crb
(white) colonies by the total number of colonies observed on the CR
plates. Growth at 28°C on BHI plates containing streptomycin (25 µg/ml) or rifampin (20 µg/ml) was used to assay antibiotic resistance mutation frequencies.
Plasmids.
The library and cloning vector pBRtet was
constructed by removing a 156-bp
EcoRV-HindIII fragment of pBR322 to abolish
the activity of the tetracycline resistance gene. pHFRS, which
expresses the hemin storage proteins HmsHFRS, was constructed by
subcloning a 9.65-kbp HindIII-SalI fragment
of the plasmid pHMS1 (29) into pBRtet. Derivatives of
pHFRS were constructed that express a subset of the hemin storage
proteins. pFRS is a 9.4-kbp HindIII-SmaI collapse of pHFRS that expresses HmsF, HmsR, and HmsS. pRS is a 7.5-kbp
BamHI collapse of pHFRS that expresses HmsR and HmsS. Plasmids are described in Table 1. All
plasmids were transformed by electroporation in 0.2-cm gap cuvettes on
a Gene Pulser (both from Bio-Rad), set at 2.5 kV, 200 
, and 25 µF,
and grown for 1 h at 37°C before being plated to the appropriate
media.
KIM10+ library construction and screening.
A genomic library
of KIM10+ was constructed by ligating partially
Sau3AI-digested KIM10+ genomic DNA into the BamHI
site of vector pBRtet. We screened the library and identified a
complementing clone, pHMSX, which was then digested with
EcoRI to yield two DNA fragments suitable for subcloning. A
6.5-kbp EcoRI fragment consisting of both the vector and
approximately half of the insert was self-ligated to form pHMSXB, which
contained open reading frame B (ORFB). The other, 2.8-kbp
EcoRI fragment of pHMSX was ligated into pBRtet to form
pHMSXA, which contained ORFA.
PCR analyses.
To amplify within hmsH, primers
HMS1 (5'-TTCATTGTATCGTAGCC-3') and HMS2
(5'-CATCAGTCAGTAACTCC-3') were used (annealing temperature, 44°C). Primers HMS5 (5'-CCCTGAAGTAAGACAGCG-3') and HMS6
(5'-GATAATGTCAATCCAGCG-3') were used to amplify part of
hmsF, hmsR, and the beginning of hmsS
(annealing temperature, 48°C). Primers topgmL
(5'-GTCACACCGAATTCAGC-3') and topgmR
(5'-CGCTACCACTGAAATCC-3') flanking the pgm locus
were used to amplify the pgm deletion junction (annealing
temperature, 48°C). The pgm deletion junction-containing
plasmid pFUS43 (12) was used as a positive control for
deletion of the pgm locus.
Southern and colony blot analyses.
Genomic DNA was purified
via the Puregene kit (Gentra Systems, Inc., Minneapolis, Minn.).
Southern blots were prepared by electrophoresing DNA on a 0.9% agarose
gel (Bio-Rad) in 0.5× Tris-borate-EDTA buffer (30) and
blotting DNA by capillary action onto a Zeta-Probe nylon membrane
(Bio-Rad). The DNA was cross-linked to the membrane by UV light in a UV
Stratalinker 1800 (Stratagene). Colony blot preparation, probe
preparation, and hybridizations were carried out as previously
described (17). All probes were radioactively labeled by
random primer labeling (17). The recA probe
consisted of the PCR product amplified with the recA forward
and reverse primers. A probe for the hmsHFRS locus genes
consisted of both a 6-kbp BamHI fragment of pHMS1 containing
hmsH and part of hmsF and a PCR product derived
from amplification with HMS5 and HMS6 that contained hmsRS.
The probe for the ORFA and ORFB region was the purified plasmid pHMSX.
Nucleotide sequence accession number.
The DNA sequence of
hmsT is listed in the GenBank database under accession no.
AF132982.
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RESULTS |
Determination of the Crb mutation frequency in Y. pestis KIM10+.
We assayed the RecA+ KIM10+
strain to establish the frequency of the loss of two Pgm-associated
phenotypes located at opposite ends of the 102-kbp pgm
locus: CR binding and pesticin sensitivity (Psts) (Fig. 1).
Loss of the Crb+ phenotype was screened by growing colonies
on CR agar; red colonies were Crb+, and white colonies were
Crb. Red colonies with white sectors were occasionally
observed but were not used to calculate the Crb mutation frequency, so
that only mutations occurring during the initial 24-h growth period were represented in the mutation frequency. The frequency of
Crb+ loss was calculated by dividing the number of
Crb colonies by the total number of colonies screened.
Loss of Psts was selected by growth on pesticin-containing
plates. The frequency of Psts loss was calculated by
dividing the CFU per ml of pesticin-resistant (Pstr)
colonies by the CFU per ml of cells plated on BHI medium lacking pesticin.
KIM10+ lost both the Psts and Crb+ phenotypes
at high frequencies (2.7 × 103 and 2.0 × 103, respectively) (Fig.
2). We tested some of each type of mutant (Pstr or Crb) for the other phenotype,
because the deletion of the entire pgm locus would result in
a simultaneous loss of both markers. All 32 Pstr KIM10+
mutants that we tested were also Crb, and all of the 20 Crb KIM10+ colonies that we tested were Pstr,
suggesting that these mutants had indeed lost the entire pgm locus.
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FIG. 2.
Comparison of the frequencies of loss of various
phenotypes in the KIM10+ versus the YPRA strains. The values in the
graph are the means ± standard deviations (error bars) for
multiple independent experiments. Asterisks indicate that the frequency
of resistance to antibiotics was not evaluated in YPRA(pBSrecA).
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The deletion of the pgm locus in the Crb
mutants was confirmed by three additional tests. None of the 20 Crb Pstr mutants hybridized to a
hmsHFRS gene probe in colony blot analyses (data not shown).
In addition, a 2-kb product was amplified by PCR with primers flanking
the pgm locus from all of the five strains that we tested.
Finally, DNA sequence analysis of the PCR product from one of these
five mutants demonstrated that a single copy of the 2-kb
IS100 element remained in place of the pgm locus
(data not shown). Transformation of the hmsHFRS-containing
plasmid pHMS1 into these Pgm mutants restored the
Crb+ phenotype, as expected and observed previously
(30).
The two Pgm-associated phenotypes are lost at different frequencies
in YPRA.
We made a Y. pestis KIM10+ recA
mutant strain (YPRA) to test the hypothesis that the high-frequency
Crb phenotypes arising in Y. pestis are caused
by RecA-mediated deletions, either of the entire
IS100-flanked pgm locus or smaller, insertion element-flanked regions. The frequency of spontaneous resistance to two
drugs (streptomycin and rifampin) was measured in KIM10+ and YPRA to
establish and compare the background mutation frequencies in these
strains. Mutation frequencies were similar for each drug in KIM10+ and
YPRA (Fig. 2), indicating that YPRA is not a mutator strain
(6) that is prone to higher mutation frequencies.
Frequencies of loss of the Crb+ and Psts
phenotypes were measured in YPRA to determine whether the
high-frequency loss of the Crb+ phenotype occurred by a
RecA-dependent process (such as a deletion of the entire 102-kb
pgm locus). We reasoned that the high-frequency loss of the
Pgm-associated phenotypes would be greatly reduced in YPRA if the
pgm locus deletion were RecA mediated. In YPRA, the
frequency of Pstr mutants decreased 10,000-fold from
RecA+ KIM10+ levels to spontaneous mutation levels (Fig.
2). In contrast, the loss of the Crb+ phenotype was reduced
only moderately (40-fold) relative to KIM10+ and remained at a
frequency 100- to 1,000-fold higher than the spontaneous mutation
frequency measured by resistance to streptomycin and rifampin (Fig. 2).
The RecA+ YPRA(pBSrecA) strain lost both the
Crb+ and Psts phenotypes at the same high
frequency as KIM10+ (Fig. 2), confirming the role of RecA in this
process. Twelve Crb RecA+ YPRA(pBSrecA)
mutants were analyzed by PCR and found to have deletions of the entire
pgm locus that were indistinguishable from the deletion
events observed in the Crb RecA+ KIM10+ mutants.
In contrast to KIM10+, only 13% of the Pstr YPRA mutants
(6 of 46) were also Crb. Similarly, only 1 of the 18 Crb YPRA mutants (YPRA11; see below) was also
Pstr. These results indicated that in the absence of RecA,
the altered phenotypes of most of these YPRA mutants were due to events
other than a deletion of the entire pgm locus.
Mutations in the hmsHFRS locus comprise one class of
Crb recA mutants.
In contrast to the
loss of Psts, the Crb+ phenotype was lost at a
relatively high frequency in YPRA. Eighteen YPRA Crb
mutants were further characterized to learn if the relatively high-frequency loss of this phenotype was due to a common
RecA-independent mechanism. The pgm locus was present in
nearly all (17 of 18) of these mutants. These mutants remained
Psts and contained the hmsHFRS locus as
determined by colony blot and PCR analyses of two different regions
within the hms locus (data not shown). Southern analysis
indicated no obvious insertions, deletions, or rearrangements in the
hmsHFRS loci of these strains (Fig.
3, lanes 1 to 9). The remaining mutant
(YPRA11) lost the entire pgm locus by a deletion, as
indicated by the PCR amplification of a 2-kbp product with primers
flanking the pgm locus. This mutant was also
Pstr and did not possess DNA from the
hmsHFRS locus as measured by the above-mentioned colony,
PCR, and Southern analyses (data not shown).
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FIG. 3.
Southern blot analyses of Y. pestis and
Y. pseudotuberculosis strains, showing lack of gross
chromosomal rearrangements in the hmsHFRS and
hmsT regions. Genomic DNA from these strains was digested
with EcoRV and probed with the hmsHFRS genes
(left panel) and pHMSX (right panel). Lane 1, Y. pestis
KIM10+; lane 2, YPRA17; lane 3, YPRA18; lane 4, YPRA19; lane 5, YPRA21;
lane 6, YPRA22; lane 7, YPRA23; lane 8, YPRA24; lane 9, YPRA25; lane
10, KIM10+; lane 11, YPRA; lane 12, Y. pseudotuberculosis
PTB56; lane 13, PTB52; lane 14, PTB53; lane 15, PTB54; lane 16, Y. pestis YPRA17; lane 17, YPRA18; lane 18, YPRA11; lane 19, YPRA7; lane 20, YPRA22; lane 21, YPRA24. Positions of molecular size
markers (in kilobase pairs) for both panels are shown to the left. The
sizes of the bands hybridizing to the hmsHFRS genes are as
follows: hmsH, 6.5 and 1.2 kb; hmsF, 2.1 kb;
hmsRS, 2.7 kb. The 2.0-, 1.3-, and 1.1-kb bands in lanes 10 to 21 hybridize to hmsT DNA sequences.
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Plasmid complementation experiments were conducted to identify the
mutated gene loci in the YPRA Crb mutants. Successful
complementation was defined as the restoration of red colony growth
upon plasmid transformation. Eleven of the 18 mutants were complemented
by pHFRS, which encodes the hmsHFRS genes (Table
2). These 11 mutants were further tested
with derivatives of pHFRS that expressed only some of the hemin storage
proteins to determine which particular hms gene was mutated.
Four mutations were localized to hmsH, one mutant was
defective in hmsF, five mutants had defects in either
hmsR or hmsS, and one mutant (YPRA11) was missing
the hmsHFRS genes entirely (Table 2), indicating that these
mutants did not carry a common mutation. The control RecA-expressing
plasmid pBSrecA did not complement these mutants' Crb
phenotype.
A new gene, hmsT, restores the Crb+
phenotype to a second class of Crb mutants.
The
inability of pHFRS to restore the Crb+ phenotype to 7 of
the 18 YPRA Crb mutants is consistent with previous
observations suggesting that a second locus was required for the
Crb+ phenotype (22, 28). In addition, a recent
report suggested that a putative gene needed for the Crb+
phenotype was located in the region of the pgm locus
surrounding, but not including, the hmsHFRS genes
(4). However, none of the seven YPRA Crb
mutants was complemented with the plasmids pSDR13, pSDR3, and pSDR7,
all of which contain DNA from this region of the pgm locus (Fig. 1).
We then screened a Sau3AI library of KIM10+ chromosomal DNA
in two of these seven YPRA Crb mutants (YPRA7 and YPRA22)
to identify library clones that would restore the Crb+
phenotype to these mutants. Twelve red colonies derived from four
independent library transformation experiments possessed library clones
that contained an identical 4.75-kb DNA insert. This library clone
(designated pHMSX) complemented the Crb phenotype in six
of the seven YPRA Crb mutants that were not successfully
complemented with pHFRS. The seventh mutant, YPRA24, was not
complemented by pHFRS, pHMSX, or both plasmids, and thus the cause of
its Crb phenotype remains unclear. It is possible that
this lesion marks another unidentified genetic locus that is involved
in the expression of the Crb+ phenotype.
The arrangement of restriction enzyme sites and a partial DNA sequence
obtained from pHMSX matched a DNA sequence in the partially completed
Y. pestis genome Sanger database (40). The
corresponding 4.75-kb DNA sequence in the Y. pestis database
contained two ORFs, ORFA (1,440 bp) and ORFB (1,170 bp) (Fig.
4). The predicted protein sequence of
ORFA was 67% identical to a hypothetical protein of E. coli
(accession no. P39406). The predicted protein sequence of ORFB had a
region of 172 amino acids at its C terminus that was 39% identical to
a Synechocystis sp. PleD protein of unknown function
(accession no. D64005). A PleD homolog in Caulobacter crescentus is a response regulator that is part of a signal
transduction pathway involved in motility regulation (7,
18). ORFB's C-terminal region of homology to PleD contains a
162-amino-acid protein domain of unknown function (DUF9), contained in
the Pfam (protein family) database (34). This domain is
present in bacterial proteins containing signaling domains
(34).
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FIG. 4.
Map of pHMSX. The narrow bar represents library vector
pBRtet sequences, and the thick bar represents Y. pestis
insert DNA containing ORFA and ORFB. The location of a domain of
unknown function (DUF9) is shown below ORFB. The Y. pestis
insert DNA fragments contained in pHMSXA and pHMSXB are shown as bars
below pHMSX. B/Sa indicates the site of Sau3AI-cut Y. pestis DNA ligation into the BamHI site of pBRtet.
B, BamHI; C, ClaI; EI, EcoRI; EV,
EcoRV; H, HindIII; S, SalI.
|
|
pHMSX was subcloned to test the abilities of each of the two ORFs to
complement the Crb phenotype of the YPRA
Crb mutants (Fig. 4). pHMSXB (orfB), but not
pHMSXA (orfA), restored the Crb+ phenotype to
YPRA22 (Fig. 5A). The DNA sequence of
ORFB from pHMSX was identical to the ORFB DNA sequence present in the
Y. pestis database that was recently described as
hmsT (22).
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FIG. 5.
CR binding phenotypes of Y. pestis, E. coli, and Y. pseudotuberculosis strains. (A) Y. pestis KIM10+ (Pgm+) and KIM10 (Pgm),
showing Crb+ and Crb phenotypes,
respectively. The YPRA22 strain (Crb) is shown
complemented with the library subclones pHMSXA (Crb) and
pHMSXB (Crb+). (B) E. coli and Y. pseudotuberculosis strains transformed with hmsT and
hmsHFRS. Strains were transformed with either pHMS1, pHMSXB,
or both plasmids. Only colonies transformed with both plasmids appear
red and have a small, wrinkled colony morphology (are
Crb+). A partially reddish phenotype is seen in PTB54 and
PTB55 on CR agar. (C) An experiment similar to that shown in panel B
was done, but cells were plated on slightly different CR agar plates
(Surgalla). The PTB55 but not PTB50 Y. pseudotuberculosis
strain shows a partially reddish phenotype, to a greater extent than on
CR agar. Magnification, ×4. The Crb colonies appear
yellowish in these photos but are whiter when viewed directly on the CR
agar plates.
|
|
pHMSX was used as a probe in Southern analyses to analyze the YPRA
Crb (hmsT-based) mutants. Wild-type KIM10+,
YPRA, and the Crb (hmsHFRS-based) strains were
used as controls. The hmsT-hybridizing DNA bands from both
the control and Crb (hmsT) strains were
identical in size (Fig. 3, lanes 10 to 21). This result suggested that
no large insertions, deletions, or other rearrangements were present in
this region of the chromosome and that point mutations or small lesions
might be responsible for the hmsT defects in these strains.
The Crb YPRA11 isolate that lacked the entire
pgm locus possessed bands that hybridized to both ORFA and
ORFB (hmsT) sequences (Fig. 3, lane 18), indicating that
hmsT lies outside the pgm locus.
Y. pseudotuberculosis and E. coli strains
transformed with hmsT and hmsHFRS are
Crb+.
We transformed Y. pseudotuberculosis
PTB55, PTB50, PTB51, and PTB54 and E. coli DH5
with
pHMSXB and pHMS1 to determine whether hmsT and/or the
hmsHFRS genes could produce a Crb+ phenotype in
these normally nonpigmented species (28, 36). Neither pHMSXB
nor pHMS1 conferred a Crb+ phenotype on these strains when
used alone (Fig. 5B). However, when these strains were transformed with
both of these plasmids, they were Crb+ at both 28 and
37°C and acquired a small, wrinkled colony morphology similar to that
of Y. pestis (Fig. 5B). This phenotype was apparent when
colonies appeared at 20 h of growth.
The presence of both plasmids in these strains also resulted in an
unusual, stalactite-like growth in broth. This pattern of broth growth,
which is typical of Y. pestis (16), is
characterized by reduced turbidity in culture, with cells growing in
clumps at the bottom and sides of the tube (Fig.
6). Others have noted a correlation
between autoaggregation of Y. pestis cells and pigmentation status consistent with changes in cell surface hydrophobicity upon
binding CR or hemin (19, 21). The DH5, PTB50, and PTB51 strains, all containing both pHMS1 and pHMSXB, repeatedly grew in this
stalactite-like fashion after 2 days at 28°C; Y. pseudotuberculosis PTB55 and PTB54 showed fewer of these
characteristics (Fig. 6 and data not shown).
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FIG. 6.
Broth growth appearance of E. coli and
Y. pseudotuberculosis strains transformed with either pHMS1,
pHMSXB, or both plasmids. After transformation and growth on CR plates,
colonies were cultured in BHI broth for 2 days at 28°C. In the
presence of both plasmids, E. coli and Y. pseudotuberculosis PTB51 have a growth pattern similar to that of
Y. pestis, with flecks of bacterial growth on the walls and
bottom of the tube but little turbidity. PTB55 shows only a few of
these growth characteristics. This experiment was repeated three times
with similar results.
|
|
To determine whether the particular CR agar recipe used affected the
requirement for both the hmsT and hmsHFRS genes,
we repeated these experiments with the original CR agar recipe
developed by Surgalla and Beesley (36). On our CR plates and
to a greater extent on Surgalla CR plates, we observed that two of the
four Y. pseudotuberculosis strains (PTB55 and PTB54) were
pigmented slightly red when transformed with pHMS1 alone (Fig. 5C).
However, this partial, reddish phenotype, which developed only after
>24 h of growth, was lighter than the dark red Crb+
phenotype that we observed when both pHMS1 and pHMSXB were used. Additionally, neither the wrinkled colony appearance nor the altered broth growth seen in the Crb+ Y. pseudotuberculosis colonies resulted from the transformation of
pHMS1 alone. Y. pseudotuberculosis PTB50 and PTB51 did not show this partial phenotype on either type of CR agar.
| |
DISCUSSION |
The Pgm+ phenotype is comprised of both the
Crb+ phenotype and a group of virulence traits that allow
Y. pestis to acquire iron from its mammalian hosts. The
original measurement of Pgm+ loss used the Pstr
mutation rate as an indicator for the loss of all of the traits that
make up the Pgm+ phenotype (2). Another study
investigating the effects of a Y. pestis fur mutant found
that Crb colonies were dramatically increased in a
fur mutant in the presence of excess iron (35).
In this study, we analyzed the variety and frequency of events causing
Crb mutants separately from other Pgm-associated
phenotypes. We determined that the instability of the Crb+
phenotype is due to both RecA-mediated deletions and high-frequency RecA-independent mutations.
High-frequency RecA-dependent and -independent mechanisms found for
Crb mutants.
This study contains the first description of a
recA mutant strain of Y. pestis, which we
constructed by replacing the native recA gene of KIM10+ with
a mutated, marked recA allele. We used this recA
mutant (YPRA) to test whether RecA-mediated homologous recombination
caused the deletion of the pgm locus, as others have
proposed (12, 20). Three types of events accounted for the
high frequency Crb phenotype we observed in Y. pestis. These included (i) the RecA-dependent deletion of the
pgm locus, (ii) mutations in several of the
hmsHFRS genes, and (iii) mutations in a previously
uncharacterized gene, hmsT.
All Crb (or Pstr) mutants of the
RecA+ KIM10+ strain appeared to result from a
pgm locus deletion, similar to previous observations (35). These data confirmed the original observation linking the phenotypes of colony pigmentation and pesticin sensitivity (2) and indicated that a RecA-mediated deletion of the
pgm locus is the main source of Crb mutants in
RecA+ strains of Y. pestis. Point mutations or
small lesions in hmsHFRS and hmsT probably also
occur in RecA+ strains, and hmsHFRS mutations
have been observed by others (4, 24). However, the
RecA-independent mutations we observed occurred 40-fold less frequently
than the pgm locus deletions in the RecA+ KIM10+
strain and would be readily masked by the presence of the
high-frequency pgm locus deletions.
While a RecA-dependent deletion of the pgm locus was
expected to be the predominant mechanism of generating
Crb mutants, we observed that RecA-independent mutations
in the hmsHFRS and hmsT loci also occurred at
higher frequencies than spontaneous mutation frequencies to antibiotic
resistance. Another study also observed losses of the Crb+
phenotype independent of a pgm locus deletion in a
collection of Y. pestis strains (20). However,
most of these Crb mutants in the previous study had
deletions of the hmsHFRS locus, probably mediated by
homologous recombination (4). Furthermore, these mutants
were from different isolates in a Y. pestis strain collection and thus represent a range of possible Crb
mutants that can occur and become fixed over time in different Y. pestis populations (4). In contrast, our data were
gathered from the events occurring in a particular RecA+ or
RecA Crb+ strain over a 24-h growth period
and so directly measure the frequency of Crb mutants
arising in one homogenous population.
The high number of Crb mutants arising in YPRA was
unexpected, given that the levels of spontaneous mutation to
Pstr dropped to background antibiotic resistance mutation
levels in this strain. The reasons for the higher loss of the
Crb phenotype are not clear. The mutation targets of the
hmsHFRS and hmsT loci (8.1 kbp)
(reference 24 and this study) are larger than those
of the psn gene (2.1 kbp) (10) and could
contribute to the unequal mutation frequencies we observed. However,
the fourfold difference in the sizes of mutation targets is probably not sufficient to result in a 100-fold increase in the
Crb mutant frequency over background drug resistance levels.
An alternate explanation for this result is the differing amounts of
selective pressures that are present when the mutation frequencies of
specific genes are measured. The antibiotic resistance assays typically
used to calculate spontaneous mutation rates use gene targets that are
under selective pressure in the bacterial cell (39). The
assays we used, which tested resistance to streptomycin and rifampin,
require an altered but functional ribosome structure and RNA polymerase
subunit, respectively (39). Therefore, only a limited
number of mutations can be tolerated by these genes and still result in
a functional protein. In contrast, genes whose functions are not
required for the growth conditions of the assay have fewer restrictions
on the types and numbers of mutations they may maintain and may behave
as unselected DNA sequences (37).
Mutation frequencies observed for the hmsHFRS and
hmsT genes are similar to those reported for E. coli genes in the absence of selective pressure
(105) (37). The hmsHFRS genes are
required for blockage of Y. pestis' flea vector
(19) but not for the pathogenesis of bubonic plague in
mammals (23). We observed no difference in the viabilities of Crb+ Y. pestis when grown on CR agar compared
to BHI agar (data not shown). Similarly, the apparent size difference
in Crb+ versus Crb colonies was likely due to
a difference in colony morphology (Crb+ colonies are
wrinkled and domed, while Crb colonies are flat), rather
than the growth inhibition of Crb+ colonies on CR agar.
Taken together, these observations suggest that these genes are
selected neither for nor against under laboratory growth conditions.
Therefore, the seemingly high Crb mutation frequency in
hmsT and hmsHFRS would be predicted by the
"selective pressure" argument.
In contrast, the frequency of mutations to Pstr was similar
to what we observed with antibiotic resistance markers that are under
selective pressure. This result is more difficult to explain in the
absence of a known selection for Psn under standard laboratory conditions. Iron acquisition is not likely to be the cause of the
selection, as iron is not limiting under laboratory conditions. It is
possible that another, unknown function of Psn could limit the
accumulation of mutations in psn in the presence of an
intact pgm locus.
Role of IS100 in pgm locus deletions.
A deletion of the entire pgm locus likely results from
frequent RecA-mediated homologous recombination occurring between the two directly repeated IS100 copies flanking the
pgm locus, as predicted from earlier observations
(12). The observation that the IS100 sequence
formed the exact endpoints of the deletion and the RecA dependence of
this deletion process support this conclusion. Previous reports of
multiple Y. pestis strains having the same, approximately
102-kbp chromosomal deletion event (12) suggest that the
IS100-flanked structure of the pgm locus is
highly conserved in Y. pestis strains (4, 12).
Other homologous recombination-mediated deletions and inversions may
also be occurring elsewhere in the genome at similar frequencies but
may not be evident without the loss of an easily observed phenotype
such as CR binding.
One YPRA mutant (YPRA11) lacked the entire pgm locus. As
RecA is thought to be required for all recombination pathways
(26) it is unlikely that this deletion resulted from
recombination. An alternate explanation is that this deletion was
caused by a transposon-mediated intramolecular deletion event.
A survey of Y. pestis strains collected from clinical cases
worldwide found that some Crb strains had undergone
partial deletions of the pgm locus (4, 20), which
were either flanked by additional copies of IS100 within the
pgm locus or due to undefined causes (4). In
contrast, we found no partial deletions of the pgm locus
involving the hmsHFRS genes. Presumably this reflects the
presence of additional copies of repetitive elements within the
pgm locus in these different strains. KIM10+ possesses no
additional copies of IS100 within its pgm locus
(12).
A second locus is required for the Crb+ phenotype.
By investigating the location of RecA-independent mutations resulting
in the Crb phenotype, we identified a gene
(hmsT [22]) that restored the Crb+ phenotype to one class of Y. pestis
Crb mutants. The combined presence of
hmsT and the hmsHFRS genes was both
necessary and sufficient to confer the Crb+ phenotype upon
the normally nonpigmented E. coli and Y. pseudotuberculosis strains (Fig. 6). These results suggest that
both of these gene loci are nonfunctional or absent in these species
and are consistent with a previous report that E. coli does
not become Crb+ when transformed with the
hmsHFRS genes alone (28). The changes in colony
morphology and growth in liquid culture that occurred in the
Crb+ E. coli and Y. pseudotuberculosis strains suggest that the hmsHFRS and
hmsT genes contribute to the similar wrinkled colony
morphology on plates and stalactite-like growth in liquid culture that
is seen in Y. pestis (17, 21). However, unlike in
Y. pestis, the Crb+ phenotype in E. coli and Y. pseudotuberculosis was temperature independent. This suggests that another gene, which is present in
Y. pestis but absent or nonfunctional in E. coli
and Y. pseudotuberculosis, provides the temperature
dependence of the Crb+ phenotype. Alternately, it is
possible that the temperature-dependent expression of the
Crb+ phenotype in Y. pestis could be due to a
masking of the heme receptor on the cell surface at 37°C. Both
hypotheses are consistent with the observation that the
Crb+ phenotype of Pgm Y. pestis
cells remains temperature dependent in the presence of multiple copies
of hmsT and hmsHFRS on the plasmids pHMSXB and
pHMS1, respectively (data not shown), excluding a simple multicopy effect.
The Crb Y. pseudotuberculosis strains that we
examined contained DNA sequences that hybridized with DNA probes
derived from hmsT and hmsHFRS. However, these
strains showed no evidence of rearrangements, insertions, or deletions
in these loci (Fig. 3 and data not shown), suggesting that the
Crb phenotype of this species may be due to an
accumulation of point mutations or small lesions in these genes. As a
flea vector does not transmit Y. pseudotuberculosis, these
genes may not be selected in this species and may behave as noncoding
DNA sequences.
The specific contribution of the hmsT gene product to the
Crb+ phenotype and the function of its DUF9 domain, which
has been found in bacterial response regulator proteins, are not yet
known. The requirement for hmsT in the Crb+
phenotype may indicate a role for it in the flea transmission stage of
plague, as is the case for the hmsHFRS genes
(19). hmsT is present in the Pgm
strain YPRA11, indicating that it lies outside the pgm
locus, and thus is separated from the hmsHFRS genes by
at least 15 kbp (11).
In summary, we demonstrated that both RecA-dependent and -independent
mechanisms cause the high-frequency loss of the Crb+
phenotype that occurs in Y. pestis. A RecA-mediated deletion of the pgm locus caused the majority of these mutants.
However, the RecA-independent mutations in the hmsHFRS and
hmsT genes occurred at a frequency 100-fold higher than
similar mutations in psn. We propose that this lack of
uniformity in mutation frequencies at distinct but genetically
linked loci may reflect a smaller amount of selection for the
hms genes relative to psn under in vitro
conditions. Future studies with additional genes may help clarify the
extent to which mutation frequencies can predict gene function under
different environmental conditions.
| |
ACKNOWLEDGMENTS |
This work was supported by New Investigator Funds to K.A.M. from
the Wadsworth Center and National Science Foundation predoctoral fellowship GER9353931 to J.M.H.
We thank the Charles Radding laboratory, for providing us with the
anti-E. coli RecA antibody and alkaline phosphatase Western blotting procedure, and the Ontario Ministry of Health Department, for
serotyping the Y. pseudotuberculosis isolates. We also thank the Wadsworth Center Molecular Genetics Core Facility, for the synthesis of oligonucleotides and DNA sequencing services, and the
photography and illustration units of the Wadsworth Center, for support
services. We are also grateful to Keith Derbyshire, Richard Lease, and
Dilip Nag for their helpful comments on this manuscript and to Robert
Perry for helpful discussions and for sharing unpublished information.
Sequence data from the Sanger Y. pestis genome database were
produced by the Yersinia pestis Sequencing Group at the
Sanger Centre (40).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: David Axelrod
Institute, Wadsworth Center, NYSDOH, 120 New Scotland Ave., P.O. Box 22002, Albany, NY 12201-2002. Phone: (518) 486-4253. Fax: (518) 474-3181. E-mail: mcdonoug{at}wadsworth.org.
| |
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Abstract
Introduction
