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Previous Article | Next Article 
Infection and Immunity, September 2001, p. 5689-5697, Vol. 69, No. 9
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.9.5689-5697.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Opsonized Virulent Edwardsiella tarda Strains Are
Able To Adhere to and Survive and Replicate within Fish Phagocytes but
Fail To Stimulate Reactive Oxygen Intermediates
Putanae S. Srinivasa
Rao,1
Tit Meng
Lim,1 and
Ka Yin
Leung1,2,*
Department of Biological Sciences, Faculty of
Science,1 and Tropical Marine Science
Institute,2 National University of
Singapore, Singapore 119260
Received 2 January 2001/Returned for modification 12 March
2001/Accepted 7 June 2001
 |
ABSTRACT |
Edwardsiella tarda is responsible for hemorrhagic
septicemia (edwardsiellosis) in fish and also causes diseases in higher vertebrates such as birds, reptiles, and mammals, including humans. Interactions of E. tarda with blue gourami phagocytes
were studied by light microscopy as well as by adherence, intracellular
replication, and superoxide anion assays. Both nonopsonized virulent
(PPD130/91 and AL9379) and avirulent (PPD125/87 and PPD76/87) bacteria
could adhere to and survive and replicate within phagocytes, while only opsonized virulent strains replicated within the phagocytes.
Furthermore, only avirulent E. tarda elicited a higher
rate of production of reactive oxygen intermediates (ROIs) by
phagocytes, indicating that they were unable to avoid and/or
resist reactive oxygen radical-based killing by the fish phagocytes.
TnphoA transposon mutagenesis was used to construct a
library of 200 alkaline phosphatase (PhoA+) fusion mutants
from a total of 182,000 transconjugants derived from E.
tarda PPD130/91. Five of these mutants induced more ROI production in phagocytes than the wild-type strain. Two mutants had
lower replication ability inside phagocytes and moderately higher 50%
lethal dose values than the wild-type strain. Sequence analysis
revealed that three of these mutants had insertions at sequences having
homology to PhoS, dipeptidase, and a surface polymer ligase of lipid A
core proteins of other pathogens. These three independent mutations
might have changed the cell surface characteristics of the bacteria,
which in turn induced phagocytes to produce increased ROIs. Sequences
from two other mutants had no homology to known genes, indicating that
they may be novel genes for antiphagocytic killing. The present study
showed that there are differences in the interactions of virulent and
avirulent E. tarda organisms with fish phagocytes and
PhoA+ fusion mutants that could be used successfully to
identify virulence genes. The information elucidated here would help in
the development of suitable strategies to combat the disease caused by
E. tarda.
| |
INTRODUCTION |
Edwardsiella tarda, the
causative agent of edwardsiellosis in fish, is responsible for
extensive losses in both freshwater and marine aquaculture. E. tarda infection of many commercially important cultured and wild
fish has been reported, namely, channel catfish, eels, mullet, Chinook
salmon, flounder, carp, tilapia, and striped bass (46). It
has a wide host range, thus causing infection in higher vertebrates
such as birds, reptiles (51), and mammals
(49), including humans (37). In fish, it
causes septicemia with extensive skin lesions, affecting
internal organs such as the liver, kidney and spleen and muscle. These
bacteria systemically avoid host defense mechanisms, thereby rapidly
proliferating within the host and causing death.
Pathogenesis of E. tarda is multifactorial, and many
potential virulent factors have been suggested, namely
dermatotoxins (47), antiphagocyte killing
(1), hemolysins (19), serum resistance,
and the ability to invade epithelial cells (21, 28).
Although both virulent and avirulent strains were able to invade
cultured cells in vitro, only the virulent strain could enter fish in
large numbers via mucus, gills, and the gastrointestinal tract
(27) and multiply inside various internal organs, causing death. Janda and coworkers (21) also found that
pathogenicity of E. tarda did not correlate with plasmid
content, chemotactic motility, serum resistance, and expression of
selected enzyme activities. However, very little is known about the
roles of these factors in disease occurrence.
Serum- and phagocyte-mediated killing represents the two major
defense mechanisms of nonspecific immunity in fish (7,
11). Resistance to these mechanisms by pathogens leads to
infection. Most virulent fish pathogens such as Aeromonas
hydrophila (25, 26) and Renibacterium
salmoninarum (4) are resistant to both serum-
and phagocyte-mediated killing. Bacterial pathogens use different
strategies for subversion of phagocyte defenses. For example,
Salmonella spp. are known to withstand low-pH conditions within phagolysosomes and to resist oxidative stress, nutrient limitations, and antimicrobial peptides such as defensins
(15). Mycobacterium and Leishmania
produce oxygen radical scavengers to resist oxidative burst and also
prevent phagolysosomal fusion (22), while Listeria
monocytogenes survives by escaping from the phagosome into the
cytoplasm (44). The reactive oxygen intermediate (ROI)
pathway is one of the oxygen-dependent pathways used by phagocytes to fight against microbial infection (33).
Virulent bacteria may avoid or resist ROIs to overcome this type of killing.
The present study was carried out to investigate the interaction of
E. tarda with fish phagocytes, their ability to adhere and
survive and replicate within phagocytes and to resist and/or avoid ROIs
produced by phagocytes. We have also used TnphoA transposon tagging to study the genes responsible for resisting phagocyte-mediated killing. Proper understanding of these mechanisms can help in the
development of suitable strategies to overcome disease caused by
E. tarda.
| |
MATERIALS AND METHODS |
Bacterial strains and media.
Two virulent (PPD130/91 and
AL9379) and two avirulent (PPD125/87 and PPD76/87) E. tarda
strains were chosen for this study; their characteristics were reported
previously (28). The 50% lethal dose
(LD50) values of E. tarda PPD130/91,
AL9379, PPD76/87, and PPD125/87 were 105.2,
105.9, >107.4, and
>107.4, respectively. All these strains except
PPD76/87 were serum resistant. Cultures were routinely grown at 25°C
in tryptic soy agar (TSA) (Difco) or tryptic soy broth (TSB)
(Difco). Stock cultures were maintained at 
80°C as a suspension in
supplemented TSB containing 25% (vol/vol) glycerol. When required, the
antibiotics ampicillin (AMP), neomycin (NEO), and colistin (COL) (all
from Sigma) were added at the final concentrations of 50, 50, and 12.5 µg/ml, respectively.
Phagocyte isolation.
Healthy blue gourami
(Trichogaster trichopterus Pallas) were obtained from a
commercial fish farm and maintained in well-aerated, dechlorinated
water at 25 ± 2°C. Phagocytes were isolated from the head
kidney of naïve gourami and purified following the procedure of
Secombs (42). Purified phagocytic cells (1 × 106 to 2 × 106
cells/well) were allowed to adhere to 24-, 48-, or 98-well tissue culture plates (Falcon; Becton Dickinson Labware) in fetal calf serum-
supplemented L-15 medium (Leibovitz; Sigma). After 2 h of
incubation at 25°C in a 5% (vol/vol) CO2
atmosphere, cells were washed twice using Hanks balanced salt solution
(HBSS) (Sigma) to remove unattached cells. The remaining monolayer
consisted of phagocytes (4 × 105 to 5 × 105 cells/well) and was infected with E. tarda at a multiplicity of infection of 1:1 in all the experiments.
Adherence-plus-internalization assay using counts of viable
bacteria.
The adherence-plus-internalization assays using counts
of viable bacteria were performed as described before (13,
50). This assay quantifies the total number of live bacteria
bound to the outside of and internalized by the phagocytes, as well as
the bacteria nonspecifically bound to the culture dish wells. The
adherence rates were calculated from the mean number of bacteria in two
wells in triplicate experiments. For opsonization of bacteria prior to
the adherence assays, washed E. tarda cells were resuspended in 50% fresh gourami serum in HBSS, incubated for 30 min at 25°C, then washed once in HBSS, and added to the phagocytic cells as described above.
Microscopic count of adherent-plus-internalized bacteria using
Giemsa stain.
Glass coverslips were placed into each well of the
24-well tissue culture plate, and the wells were seeded with blue
gourami phagocytes and incubated for 2 h at 25°C in a 5%
(vol/vol) CO2 atmosphere as described above.
Thirty minutes after infection, the phagocytes were washed three
times with HBSS and later stained with Giemsa stain (Merck) for 30 min.
After being washed three times with phosphate-buffered saline (PBS)
(137 mM NaCl, 2.7 mM KCl, 4.3 mM
Na2HPO4, and 1.4 mM
KH2PO4 at pH 7.2), the
stained samples were then examined under an Axiovert 25 CFL inverted
microscope (Carl-Zeiss) at 100× magnification. Photographs were taken
with Kodak color ISO200 film. The adherence rate was expressed as the number of adhering bacteria per 100 phagocytes after 200 phagocytes per
coverslip were counted. The adherence rate was calculated from the mean
number of phagocytes from two coverslips in triplicate experiments.
This assay quantifies the total number of bacteria (both live and dead)
bound to the outside of and internalized by the phagocytes.
Intracellular replication assay.
The intracellular
replication assay was performed as described by Leung and Finlay
(24) with the following modifications. Thirty minutes
after infection, phagocytes were washed once with HBSS and then
incubated for 1.5 h in fetal calf serum-supplemented fresh L-15
medium with 100 µg of gentamicin/ml. This treatment killed
extracellular bacteria but did not affect the viability of
intracellular organisms. Infected phagocytes were then washed three
times in HBSS and incubated with L-15 medium. The intracellular population of bacteria was assayed at 2, 3.5, 5, and 6.5 h. The supernatant was removed, and 0.1 ml of 1% (vol/vol) Triton X-100 solution was added to the infected phagocyte monolayer. This was followed by a 1-min incubation, which released intracellular bacteria, and the bacteria were assayed as described for the adherence assay. The
relative bacterial population was calculated by dividing the intracellular population of E. tarda at 3.5, 5.0, and
6.5 h by the population at 2.0 h. Values were calculated from
the mean of the bacterial population of two wells in triplicate experiments.
Superoxide anion assay.
Thirty minutes after infection of
phagocytes with bacteria in a 96-well tissue culture plate, 100 µl of
nitroblue tetrazolium (1 mg/ml) (Sigma) was added to each well, and the
monolayers were further incubated at 25°C for 30 min in a 5%
(vol/vol) CO2 atmosphere. The reaction was
arrested with 100% methanol, followed by two washes with 70%
methanol. After the plate was dried for 1 min, 120 µl of 2 M
potassium hydroxide and 140 µl of dimethyl sulfoxide were added.
Optical density was measured with a microplate reader (Bio-Tek
Instruments) at 630 nm, and the values were represented as the
mean ± the standard error of the mean (SEM) of the counts of
quadruple wells. The production of ROIs was from one set of representative results taken from one of the three independent experiments.
Transposon mutagenesis.
E. tarda PPD130/91
(recipient; Colr) and Escherichia coli
SM10
pir(pJM703.1::TnphoA) (donor;
Ampr Neor) cultures were
statically grown in TSB at 25 and 37°C, respectively. Conjugative
transfer of the suicide plasmid pJM703.1::TnphoA
was performed by plate mating. The bacterial cell ratio of E. coli to E. tarda was adjusted to 4:1, with a total of
about 107 CFU of both donor and recipient during
mating. After 24 h of mating on TSA plates at 25°C, the cells
were harvested and resuspended in 3 ml of PBS. Appropriate dilutions
were plated on TSA supplemented with NEO, COL, and
5-bromo-3-chloro-indolyl phosphate (Sigma) (40 µg
ml
1) (TSANCX) to select for transconjugants of
E. tarda. Blue PhoA+ fusion clones
were purified by streaking on TSANCX plates.
Characterization of transposon mutants.
TnphoA
mutants were characterized by standard procedures for their ability to
grow in TSA, TSB, and phosphate-limiting medium (PLM); production of
superoxide anions, hemolysin, and catalase; replication within
phagocytes; ability to withstand low-pH conditions; survival in serum;
and adherence and internalization into fish epithelial cells.
Briefly, growth of mutants in TSB and TSA was recorded after 24 h
of incubation. Growth under phosphate-limiting conditions was examined
by culturing the bacterial cells in a modified defined minimal medium
(8) with the phosphate salts replaced by 3 µM
Na2HPO4 and the pH adjusted
to 7.0 with 30 mM HEPES. Hemolysin production was determined by
inoculating bacteria onto TSA with 5% (vol/vol) heparinized gourami
whole blood. A clear zone around a bacterial colony indicates hemolysin
production. Catalase production was assayed by the hydrogen peroxide
inhibition zone test as described previously (53). Zones
of inhibition were visualized after bacteria were placed on sterile
Whatman 3MM disks (0.6 cm in diameter) containing 10 µl of 2, 20, and 200 mM H2O2 and incubated
overnight at 25°C. The pH sensitivity of mutants was characterized by
estimating their ability to grow in low-pH conditions
(16). Overnight bacterial cultures were inoculated into
TSB, grown for 3 h to obtain 108 CFU/ml, and
inoculated into TSB at pH 5.8 ± 0.1. Afterward, bacterial growth
was monitored over a period of 24 h. Survival of the mutants in
serum was calculated by dividing the number of viable bacteria after
serum treatment by the initial number of bacteria before serum
treatment. Washed bacteria (108 CFU/ml) were
incubated in 50% (vol/vol) of fresh gourami serum for 1 h. A
value of >1 was scored serum resistant; a value of <1 was considered
serum sensitive (50). Determination of the adherence and
internalization of mutants to carp epithelial cells (epithelial
papillosum of carp Cyprinus carpio [EPC]) was performed following the protocol of Wang and coworkers (50).
DNA manipulations and Southern hybridization.
Bacterial
genomic DNA was extracted according to the Genome DNA kit manual (BIO
101). Plasmid DNA was extracted using QIAprep mini columns (Qiagen).
Restriction endonuclease digestion was accomplished by standard methods
(41). Southern blotting was performed to characterize the
transposon mutants with the BluGene Non-Radioactive Nucleic Acid
Detection system (Gibco-BRL). Transfer of the DNA to nylon membranes
(GeneScreen; NEM Research Products) and hybridization conditions were
in accordance with standard methods (41). Genomic DNA from
E. tarda PPD130/91 and its mutants were digested with
EcoRV, hybridized with a HindIII-digested
14-dATP-biotinylated (Bio-Nick Labeling System; Gibco-BRL) pJM703.1
plasmid probe, and then visualized with streptaviridin-alkaline
phosphate conjugate (BluGene Nonradioactive Nucleic Acid Detection
System; Gibco-BRL).
Cloning chromosomal segments flanking TnphoA
insertions, genome walking, and DNA sequencing.
BamHI
fragments of mutant genomic DNA flanking the transposon were cloned
into pBluescript SK(+) (Ampr) vector and
transformed into E. coli Top10F'-competent cells (Clontech).
Transformants, bearing TnphoA and flanking E. tarda chromosomal sequences, were selected by their ability to
grow on Luria-Bertani (LB) agar containing AMP and NEO. Later
these clones were sequenced. To obtain full-length sequences of all the
mutants, a genome walker library of wild-type E. tarda
PPD130/91digested with EcoRV and StuI was
constructed according to the procedure described in the Universal
Genome Walker kit (Clontech). PCR amplification was performed with
primers specific to known upstream nucleotide sequences of mutants 153, 348, 387, and 392 were synthesized by GENSET (Singapore Biotech), and
the adapter primer 1 (AP1) was used as the second primer. PCR was
carried out with Advantage Tth Polymerase Mix (Clontech), and
the cycling parameters were as follows: 7 cycles of 10 s at
94°C, 30 s at 59°C, and 3 min at 67°C; and 37 cycles of
10 s at 94°C, 30 s at 56°C, and 3 min at 67°C. The
amplified fragments were gel eluted with the Qiaquick gel extraction
kit (Qiagen), cloned into the pGEMT Easy vector system (Promega),
transformed into E. coli Top 10F'-competent cells, and
sequenced using AP1- and mutant-specific primers.
DNA sequencing was carried out with an Applied Biosystems PRISM 377 automated DNA sequencer by the dye termination method. The ABI PRISM
BigDye Terminator Cycle Sequencing Ready Reaction kit was used (Applied
BioSystems). Sequence assembly and further editing were done with
DNASIS DNA analysis software (Hitachi Software). BLASTN, BLASTX, and
FASTA sequence homology analyses were performed by using the National
Center for Biotechnology Information BLAST network service.
LD50 studies.
Naive blue gourami of
approximately 14 g each were obtained from commercial fish farms
and acclimatized for more than 1 month. Three groups of 10 fish each
were injected intramuscularly with 0.1 ml of PBS-washed bacterial cells
adjusted to the required concentrations. Fish were monitored for
mortality for 7 days, and LD50 values were calculated by
the method of Reed and Muench (39).
Statistical analysis.
All data were expressed as means ± SEM. The data were analyzed by one-way analysis of variance and a
Duncan multiple-range test (SAS software; SAS Institute). Values of
P < 0.05 were considered significant.
| |
RESULTS |
Adherence and replication kinetics of E. tarda
inside fish phagocytes.
Phagocyte-mediated killing is one of the
major nonspecific defense barriers in fish. The abilities of E. tarda to adhere to and survive and multiply inside the fish
phagocytes were investigated. The adherence-plus-internalization
ability of the E. tarda strains was estimated by direct
microscopic counts and counts of viable bacteria (Table
1). All the virulent (PPD130/91 and
AL9379) and avirulent (PPD125/87 and PPD76/87) strains adhered to
and were ingested by the phagocytes. Under nonopsonized conditions,
both direct microscopic counts and counts of viable bacteria showed the
highest percentage of adherence to phagocytes by PPD125/87, followed by
AL9379, PPD76/87, and PPD130/91. Light microscopic observation of
Giemsa-stained phagocytes revealed that PPD125/87 had the highest
number of bacteria adhering to the phagocytes after 30 min of
infection, while PPD130/91 had the lowest (Fig. 1A and B).
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FIG. 1.
Giemsa-stained bright-field micrographs of blue gourami
phagocytes infected with nonopsonized E. tarda
PPD130/91 (A) and PPD125/87 (B) and opsonized PPD130/91 (C)
and PPD125/87 (D) after 30 min of infection. Bar, 10 µm.
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When E. tarda strains were opsonized with naive gourami
serum, adherence to phagocytes increased significantly
(P < 0.05) for all the strains except PPD130/91,
as observed under light microscopy (Fig. 1C and D; Table 1). However,
the percentage adherence by estimated count of viable bacteria
decreased for the opsonized avirulent strains (PPD125/87 and PPD76/87),
whereas it increased in the case of the opsonized virulent strain
AL9379, but not for PPD130/91. For the adherence assay using counts
of viable bacteria, controls were included for bacteria binding
directly to culture plates. The rate of nonspecific binding ranged from 5.7 to 10% of the counts of viable bacteria and was insignificant compared to the rates of adherence-plus-internalization to phagocytes.
Both virulent and avirulent strains of E. tarda were able to
survive and replicate within fish phagocytes, but at varying rates
(Fig. 2). Nonopsonized E. tarda PPD130/91, AL9379, and PPD125/87 replicated faster than
PPD76/87 until 5 h of incubation; after 6.5 h of incubation,
nonopsonized virulent strains (PPD130/91 and AL9379) multiplied 1.5 to 2.5 times faster (Fig. 2A) than the avirulent ones (PPD125/87 and
PPD76/87). However, when opsonized, only virulent strains could
multiply within phagocytes (Fig. 2B). Opsonized virulent strains could
multiply significantly faster (P < 0.05) than the
nonopsonized virulent strains (Fig. 2). As infection time increased,
the bacterial count of the opsonized avirulent strains was reduced,
indicating that the bacteria were killed within the phagocytes.
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FIG. 2.
Kinetics of intracellular multiplication of E.
tarda in blue gourami phagocytes. Nonopsonized (A) and
opsonized (B) E. tarda strains (PPD130/91 ( ),
PPD125/87 ( ), AL9379 ( ), PPD76/87 ( ), P1 ( ), and
348 ( ) were used. P1 and 348 are TnphoA mutants of
E. tarda PPD130/91. The ratio of intracellular
bacteria at various times was normalized to the number of bacteria at
2 h. Values represent the mean ± SEM of the bacteria counted
in two wells in triplicate experiments.
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Effect of E. tarda on ROI production.
ROI
production is one of the several strategies used by phagocytes to kill
microorganisms. Therefore, it was of interest to examine whether
E. tarda could overcome or resist respiratory burst
activity. Figure 3 shows that gourami
phagocytes produced significantly (P < 0.05) fewer
ROIs when they were infected with virulent strains (PPD130/91 and
AL9379) than with avirulent ones (PPD125/87 and PPD76/87).
Opsonization did not change the ROI values for E. tarda
PPD125/87, PPD76/87, and PPD130/91. However, opsonized
E. tarda AL9379 produced fewer ROIs than nonopsonized strains.
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FIG. 3.
ROIs produced by blue gourami phagocytes after being
infected with various nonopsonized ( ) or opsonized ( ) E.
tarda strains. Control, the basal level of ROI production by
phagocytes that are not infected with the bacteria. Results were
expressed as the mean ± SEM from quadruplicate
experiments. Data represented by bars with asterisks differ
significantly from results obtained with E. tarda
PPD130/91 (P < 0.05).
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Since virulent E. tarda PPD130/91 could not induce a
high rate of ROI production, we were interested in knowing whether
this organism was actively suppressing oxidative responses or simply failing to stimulate phagocyte respiratory burst activity. To examine
this, we infected the fish phagocytes with live and heat-killed (100°C for 5 min) PPD130/91 and PPD125/87 and monitored the
ROI production. Our results indicate that the heat-killed virulent PPD130/91 (Fig. 4) could induce
significantly higher numbers of ROIs than live virulent PPD130/91
(Fig. 3), but there was no difference for killed and live avirulent
strain PPD125/87 (Fig. 3 and 4).
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FIG. 4.
ROIs produced by blue gourami phagocytes infected with
various strains of E. tarda. Results were expressed as
the mean ± SEM from quadruplicate experiments. Data represented
by bars with asterisks differ significantly from results obtained with
live E. tarda PPD130/91 (P < 0.05). L, live
bacteria; D, heat-killed bacteria; Control, without any
bacteria. P1, 153, 348, 387, and 392 are TnphoA mutants
of E. tarda PPD130/91.
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Isolation and characterization of TnphoA
mutants.
We have obtained a library of 200 alkaline phosphatase
(PhoA+) fusion mutants from a total of 182,000 transconjugants derived from E. tarda PPD130/91. These
NEO- and COL-resistant transconjugants were obtained at a frequency of
7.0 × 103 from several matings, with a
spontaneous mutation frequency of <4.0
×108 and <5.5 ×107
for E. tarda PPD130/91 and E. coli
SM10pir(pJM 703.1::TnphoA), respectively. TnphoA mutagenesis was carried out to target
the secreted and surface proteins of E. tarda, which may
influence the ROI production by the phagocytes upon infection. Two
hundred PhoA+ fusion mutants were screened, and 5 (mutants P1, 153, 348, 387, and 392) were found to significantly
increase ROI production compared to the wild type (E. tarda
PPD130/91) (Fig. 4). All these mutants were ampicillin sensitive,
suggesting that there was no suicide plasmid retention and integration.
These five isolates were further characterized by several different
assays, such as growth on TSA and in TSB and PLM, intracellular replication within phagocytes, adherence to and internalization into
EPC, production of catalase and hemolysin, and serum survival assay
(Table 2). Growth of all the mutants
except P1 was comparable to that of the wild-type strain in both TSB
and PLM. Mutant P1 formed smaller colonies on TSA than the other
mutants and the wild-type strain, indicating growth deficiency. Two of
the mutants (P1 and 348) were found to have a decreased ability
to replicate within phagocytes (Fig. 2B) compared to the wild-type
strain and were also sensitive to low-pH conditions. All five
mutants could produce catalase and hemolysin and had the ability
to survive in naïve gourami serum, similar to the wild type.
The ability of these mutants to adhere to and internalize into EPC
cells was assayed. Although all the mutants could adhere to the EPC
cells at rates similar to that of the wild type, their ability to
internalize the cells was slightly reduced (Table 2).
The virulence of the mutants was determined by
LD50 values for blue gourami injected
intramuscularly with different concentrations of bacteria. It was found
that all the mutants had relatively higher LD50
levels than the wild type (Table 2). Of the five different mutants, P1
and 387 were less virulent than the wild-type strain, with
LD50 values of 106.0 and
106.2, respectively. Southern blotting was also
carried out to confirm the presence of TnphoA insertions in
the genomic DNA of all the mutants. All five mutants had a single
transposon insertion in their genomic DNA (data not shown). The
hybridized fragments of all the mutants had a size of more than 8.0 kb.
No band was found for the wild-type (PPD130/91) genomic DNA.
Sequence analysis.
Genes interrupted by the TnphoA
transposon insertion in the mutants were sequenced (Table
3). Analysis of the gene sequences obtained showed that all the mutants had insertions at different loci.
Predicted open reading frames of those sequences were used to search
the National Center for Biotechnology Information database for
sequences showing homology. Sequence data from mutant P1 showed an 86%
similarity to the PhoS of S. enterica serovar Typhimurium (expectation value [E] = 2e37) over a
stretch of 88 amino acids. It also had high similarity (85%) to the
periplasmic phosphate binding protein, PstS, of E. coli
(9e3). Transposon insertion in mutant 153 occurred in
sequences having 30% identity to putative lipid A core-surface polymer
ligase WaaL of Klebsiella pneumoniae. The sequence-flanking
transposon in genomic DNA of mutant 392 had 48% homology to that of
the dipeptidase of S. enterica serovar Dublin
(E = 7e93) over a stretch of 499 amino
acids. All the above mutants had insertions at the amino acid positions
89, 195, and 211, respectively. Two other mutants, 348 and 387, did not have any significant homology to known genes in the GenBank.
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TABLE 3.
Sequence analysis of the potential virulence genes
interrupted by TnphoA in various transposon mutants of
E. tarda PPD130/91
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DISCUSSION |
Interactions of E. tarda with phagocytes.
Adherence, invasion and intracellular replication in host cells such as
phagocytes are important for pathogenesis by intracellular pathogens
(14). In the present study, we looked into the interaction between E. tarda and fish phagocytes. Adherence count by
microscopy, which estimates the total number of viable and dead
bacteria adhering to phagocytes, showed large numbers of nonopsonized
avirulent E. tarda (PPD125/87 and PPD76/87)
organisms binding to and ingested by the phagocytes compared to
virulent strain PPD130/91 (Table 1; Fig. 1A and B). Virulent strain
AL9379 had significantly higher binding and/or ingestion by phagocytes
than PPD130/91, indicating that these two virulent strains interact
with phagocytes in different ways. Ling and coworkers (28)
also reported a significantly decreased ability of PPD130/91 to
adhere to EPC cells than of other three isolates.
Adherence and phagocytosis are influenced by opsonization and cell
surface structures of the pathogen (2). Serum has
complement proteins, which coat the bacteria, thereby making them
easily recognizable by the receptors present on the phagocytes
leading to phagocytosis (55). Opsonization will enhance
uptake as well as killing by the phagocytes and will simulate the
actual bacterium-phagocyte interactions, for better understanding of
bacterial pathogenesis. Many researchers have proved the role of the
C3-dependent complement mechanism present in fish serum for
phagocytosis of pathogens by fish macrophages (31, 35,
40). A similar complement system may be present in gourami
serum, enabling phagocytes to recognize E. tarda.
Direct microscopic observations showed a significantly higher number of opsonized E. tarda organisms adhering
to and also within the phagocytes than the nonopsonized strains, except for PPD130/91 (Fig. 1C and D; Table 1). Interestingly, the
adherence assessment carried out by a count of viable bacteria, which
provides only a count of live bacteria adhering to/or ingested by
phagocytes, showed that only the opsonized virulent strain AL9379 had
increased adherence compared to nonopsonized bacteria, while both
opsonized avirulent strains PPD125/87 and PPD76/87 had
lower percentages of adherence (Table 1). This indicates that the
phagocytes may be killing the opsonized avirulent strains. Moreover,
PPD76/87 is also serum sensitive (28), contributing to
a considerably lower levels of viable bacteria.
The above variation in the number of viable bacteria, after a 30-min
infection for adherence to and/or ingestion by phagocytes, led us to
study the ability of these bacterial isolates to survive and multiply
within fish phagocytes. An intracellular replication assay of
nonopsonized virulent and avirulent E. tarda organisms revealed that they could enter, survive, and replicate in phagocytes (Fig. 2A). Similar results were also obtained by Leung and coworkers (26) when phagocytes isolated from tilapia were infected
with virulent and avirulent A. hydrophila. The ability
of these E. tarda strains to multiply within phagocytes
clearly suggests that E. tarda is an intracellular
pathogen. Ling and coworkers (28) also demonstrated the
ability of these strains to effectively multiply within EPC
cells. However, opsonized avirulent E. tarda (PPD125/87 and PPD76/87) lacked the ability to multiply within the phagocytes, while the opsonized virulent strains (PPD130/91 and
AL9379) could successfully proliferate (Fig. 2B). Gordon and coworkers
(17) have also reported significantly increased binding, intracellular trafficking, and killing of Streptococcus
pneumoniae by human alveolar macrophages after opsonization of the
bacteria with serum.
Bacterial pathogens may abuse phagocytes to invade and spread within
the host system. Therefore, an enhanced uptake by opsonization can
actually become harmful to the host if the bacterium is virulent and
has special mechanisms to subvert the host macrophage
defenses (22, 44). In the present study, only
opsonized virulent E. tarda strains (PPD130/91 and
AL9379) were able to replicate intracellularly, indicating that they
were able to overcome the defense barrier and cause infection. Another
fish pathogen, R. salmoninarum, also had the ability to
proliferate intracellularly within rainbow trout macrophages upon
opsonization (4). Our earlier studies of infection
kinetics of E. tarda in vivo with a fish model also showed that only virulent PPD130/91 had a sequential increase in
its numbers inside the hematopoietic organs such as the kidney, liver,
and spleen, whereas the avirulent PPD125/87 population decreased in
the postinfection period within these organs (27). The
present in vitro experiments carried out with phagocytes also showed a
similar trend when the bacteria were opsonized.
ROI production by phagocytes.
The microbicidal mechanisms
within the phagocyte can be broadly classified as oxygen dependent and
independent (2, 12, 55). Very little is known about
the different mechanisms used by fish phagocytes. However, the
oxygen-dependent mechanism has been demonstrated in many different
fish, namely tilapia, catfish, blue gourami, rainbow trout, and salmon
(3, 4, 26, 56). In the present study, virulent E. tarda strains induced lower rates of ROI production than avirulent
strains (Fig. 3), indicating that they have the ability to circumvent
the formidable array of antibacterial defenses by failing to trigger
the respiratory burst and thereby surviving and replicating inside the
phagocyte. Some bacteria such as S. enterica serovar Typhi
(32), Brucella abortus (23),
Haemophilus somnus (9), Mycobacterium
leprae (20), Erysipelothrix rhusiopathiae
(43), and R. salmoninarum (3) also
failed to trigger the oxidative burst, resulting in successful
intracellular survival. In contrast, virulent strains of A. hydrophila increased the chemiluminiscence production (measure of
respiratory burst activity) compared to that of avirulent strains (26), showing that they might be using a different
strategy to subvert the defense mechanisms of fish.
Several studies have suggested that intracellular pathogens have
evolved effective mechanisms for resisting or avoiding phagocytic microbicidal activity, either by inhibiting or neutralizing the production of oxygen metabolites or by preventing interaction with
these substances (34, 36, 52). Experiments carried out
here revealed that only live E. tarda PPD130/91
could reduce ROI production, compared to heat-killed
PPD130/91, while live and heat-killed PPD125/87 did not
induce any significant changes in ROI production (Fig. 4). These
results indicate that live E. tarda PPD130/91 may simply
have failed to induce ROI production by being unrecognizable. The
phagocytes, on the other hand, recognize heat-killed PPD130/91, since
heat killing may have damaged the cellular characteristics of the
bacteria. A higher induction of ROIs by PPD125/87 infection may
occur because of the lack of special cell surface characteristics that
help to avoid respiratory burst activities. The other possibility may
be that virulent E. tarda produces enzymes such as
superoxide dismutase (SOD) which quench the reactive oxygen
metabolites. Yamada and Wakabayashi (54) have shown that
both virulent and avirulent E. tarda strains can produce the
SOD enzyme; phylogenetic analysis based on sequences of SOD genes
reveals that virulent and avirulent E. tarda
strains belong to two separate classes. Other fish pathogens
such as Aeromonas salmonicida, R. salmoninarum,
and Photobacterium damselae subsp. piscicida are
known to resist oxidative killing by producing SOD (5, 6),
thereby withstanding the harsh phagocytic environment. Further
investigation using isogenic mutants of SOD is required to clarify the
role of SOD in pathogenesis.
Transposon mutagenesis and characterization of mutants.
To
further understand the genetic mechanism involved, 200 PhoA+ mutants of
PPD130/91(Neor Colr)
were generated by transposon mutagenesis. TnphoA mutants of E. tarda PPD130/91 were screened for their ability to
induce higher ROI production by phagocytes than the wild-type
PPD130/91. Five of the mutants (P1, 153, 348, 387, and 392) had the
ability to induce a higher level of ROIs than the wild-type strain
(Fig. 4). Mutants P1 and 348 were pleiotrophic in nature, having a
lower replication ability inside phagocytes and also a sensitivity
to lower pH (Table 2). The other three mutants were comparable to the
wild-type strain with respect to all the characteristics except for ROI
production and internalization in EPC cells.
Mutant P1 had transposon insertion in the gene homologous to the
phoS (pstS) gene of S. enterica
serovar Typhimurium, which is shown to be a macrophage-inducible gene
(48). Mutant P1 showed a significant increase in ROI
production by phagocytes compared to the wild type. Daigle and
coworkers (10) found that insertion of TnphoA
in the pstC gene of E. coli could cause changes
in the production of surface polysaccharides of the bacteria. Since the pstC gene is present in the downstream of pstS
gene as part of the pstSCAB-phoU operon, insertion of
transposon in the pstS gene causes changes in the production
of surface polysaccharides and enables the phagocytes to recognize
mutant P1 and trigger a higher production of ROI. In the present study,
we also noticed that mutant P1 was growth deficient on TSA, in TSB, and
also in PLM (Table 2), indicating that Pi
uptake and assimilation is an important process for its growth.
Furthermore, a lower Pi inside the phagocytes would have reduced mutant P1's ability to multiply efficiently within
them. Lucas and coworkers (30) also suggested that
low-Pi conditions could directly or indirectly
repress the functions of some invasion genes in S. enterica
serovar Typhimurium. Mutant P1 also showed significantly lower
internalization into EPC cells than the wild type. Since the
pstSCAB-phoU operon in other bacteria such as E. coli is a member of the Pho regulon, which is involved in
phosphate uptake and assimilation, it may control various functions rendering mutant P1 pleiotrophic. This may also control the expression of some important factors that are involved in the degradation of ROI,
thus causing an increase in ROI production when phagocytes were
infected with this mutant.
Mutant 153 had an insertion in the gene having homology to the
putative lipid A core-surface polymer ligase WaaL of K. pneumoniae. This gene is known to play a major role in the
biosynthesis of lipopolysaccharide (LPS); any mutation in this gene may
disrupt LPS synthesis, thereby changing the bacterial cell surface
structure. A sequence analysis of mutant 392 showed high similarity to
dipeptidase homolog of the S. enterica serovar Dublin. The
dipeptidase gene localizes in the periplasmic space and plays a role in
peptidoglycan metabolism in Salmonella (18).
Outer membrane proteins, peptidoglycan, and LPSs are on the bacterial
cell surface and often aid in enhancement or prevention of host immune
system activation. Several cell surface factors such as the outer
membrane protein (porin) of Neisseria gonorrhoeae
(29), capsule-deficient mutants of E. rhusiopathiae (43), aggregation substance of
Enterococcus faecalis (45), melanin
pigment of Burkholderia cepacia (57),
and LPS and lipid A of B. abortus (38) have
failed to either induce or suppress oxidative bursts of phagocytes.
In conclusion, insertions of transposons in the phoS (mutant
P1), lipid A (mutant 153) and didpeptidase (mutant 392) genes would
have altered the cell surface properties of E. tarda or the
biosynthesis of a second substance that degraded the ROIs. These
changes could have made these mutants readily recognizable to the
phagocytes, thus increasing ROI production. Sequence analyses of
mutants 348 and 387 did not yield any homology to known genes in
GenBank. These may be novel genes controlling some of the important functions of E. tarda in overcoming phagocyte-mediated
killing. The present study clearly demonstrated the ability of virulent E. tarda to adhere to and survive and replicate within the
blue gourami phagocytes. Virulent E. tarda failed to induce
oxidative bursts, indicating that this may be one of the
mechanisms used by them to overcome phagocytic killing. We have also
showed that TnphoA transposon tagging can be effectively
used to "fish out" genes responsible for virulence in
E. tarda. The information elucidated here will help in the
development of suitable strategies to combat the disease caused by
E. tarda.
| |
ACKNOWLEDGMENTS |
We are grateful to National University of Singapore for providing
the research grant for this work.
We are thankful to John Grizzle from Auburn University for providing us
with E. tarda AL9379 and T. Ngiam and H. Loh from Agri-food and the Veterinary Authority of Singapore for providing us with the rest of the E. tarda isolates. We also
acknowledge J. A. Matthew, who carried out the mutagenesis of
E. tarda PPD130/91.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biological Sciences, Faculty of Science, The National University of
Singapore, Science Drive 4, Singapore 117543, Singapore. Phone: (65)
874 7835. Fax: (65) 779 2486. E-mail: dbslky{at}nus.edu.sg.
Editor:
R. N. Moore
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Infection and Immunity, September 2001, p. 5689-5697, Vol. 69, No. 9
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.9.5689-5697.2001
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Abstract
Introduction
