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Infection and Immunity, November 1999, p. 5972-5978, Vol. 67, No. 11
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Bordetella bronchiseptica-Mediated
Cytotoxicity to Macrophages Is Dependent on bvg-Regulated
Factors, Including Pertactin
Catrina B.
Forde,1
Xiaoju
Shi,1,
Jingli
Li,2 and
Mark
Roberts1,*
Department of Veterinary Pathology,
University of Glasgow Veterinary School, Garscube Estate, Glasgow G61
1QH, Scotland,1 and Vaccine Research
Unit, Department of Biochemistry, Imperial College of Science,
Technology and Medicine, London SW7 2AZ,
England2
Received 12 April 1999/Returned for modification 26 May
1999/Accepted 30 August 1999
 |
ABSTRACT |
The effect of Bordetella bronchiseptica infection on
the viability of murine macrophage-like cells and on primary porcine alveolar macrophages was investigated. The bacterium was shown to be
cytotoxic for both cell types, particularly where tight cell-to-cell
contacts were established. In addition, bvg mutants were
poorly cytotoxic for the eukaryotic cells, while a prn
mutant was significantly less toxic than wild-type bacteria. B. bronchiseptica-mediated cytotoxicity was inhibited in the
presence of cytochalasin D or cycloheximide, an inhibitor of
microfilament-dependent phagocytosis or de novo eukaryotic protein
synthesis, respectively. The mechanism of eukaryotic cell death was
examined, and cell death was found to occur primarily through a
necrotic pathway, although a small proportion of the population
underwent apoptosis.
| |
INTRODUCTION |
Bordetella bronchiseptica
is a pathogen of both domestic and farm animals and an opportunistic
pathogen in immunocompromised humans (17). The bacterium
colonizes the respiratory tract and is thought to preferentially adhere
to ciliated epithelial cells and possibly to alveolar macrophages
(39). Like its close relative Bordetella
pertussis, the causative agent of whooping cough, B. bronchiseptica produces an array of virulence factors whose
expression, in both species, is in general controlled by the
bvgAS operon in response to environmental stimuli
(1). These factors include toxins such as adenylate cyclase
toxin (ACT) and dermonecrotic toxin and adhesins such as fimbriae,
filamentous hemagglutinin (FHA), and pertactin. The latter is an
immunogenic surface protein with apparent molecular masses of 68 and 69 kDa in B. bronchiseptica and B. pertussis,
respectively (5, 30). P69/pertactin has been shown to be a
protective antigen against B. pertussis infections in mice
and is a component of acellular vaccines against whooping cough
(16, 36), and P68/pertactin protects against B. bronchiseptica-mediated atrophic rhinitis in animals (37,
38). While P69/pertactin is known to promote adhesion of B. pertussis to eukaryotic cells, possibly via an RGD tripeptide
sequence (9, 28, 29), the role of P68/pertactin in adhesion
of B. bronchiseptica to eukaryotic cells remains to be characterized.
Until relatively recently, B. bronchiseptica was considered
to be an exclusively extracellular pathogen, but a number of studies have now demonstrated intracellular invasion or intracellular persistence of the bacterium in a wide variety of eukaryotic cells, including professional phagocytes (3, 14, 21, 23, 41, 42).
It has been suggested that this is a bvg-independent
process, as bvg mutants survived in equal numbers to or
greater numbers than their wild-type parent (3, 21, 42). Few
of the factors involved in these processes have been identified,
although mutants deficient in urease or acid phosphatase synthesis
(6, 30, 32) or motility (47) are less able to
survive intracellularly and mutants deficient in bvg adhere
less efficiently (21). B. pertussis has also been
recovered from the intracellular milieu in a number of studies, but
this appears to require a Bvg+ phenotype with the bacteria
unable to persist for extended periods (11, 15, 27, 40).
Recently, a cytotoxic effect, dependent on environmental modulation of
B. bronchiseptica gene expression, has been reported for an
epithelial cell line infected with the bacterium (45). In
addition, B. pertussis-mediated apoptosis of macrophages has
been demonstrated in vitro and in vivo and is mediated by ACT (19,
24, 25). In this study, we have examined the interaction of
B. bronchiseptica with a murine macrophage-like cell line
and with porcine alveolar macrophages (PAM) and have determined that
the bacterium is cytotoxic for mononuclear phagocytic cells.
Furthermore, we show that cell death occurs both by necrosis and by
apoptosis but that a significant proportion of the population remains
viable after infection. Cytotoxicity was also found to be
bvg dependent and to involve pertactin.
| |
MATERIALS AND METHODS |
Bacterial strains, plasmids, and tissue culture.
B.
bronchiseptica strains were grown on Bordet-Gengou agar plates
supplemented with 12% (vol/vol) sheep blood and streptomycin and/or
chloramphenicol, as appropriate. BBC17 was isolated in this laboratory
and is a spontaneous streptomycin-resistant mutant of CN7531, which was
isolated from a pig with atrophic rhinitis (30). CN7531 is
also the strain from which the prn gene was cloned and
sequenced (30). BRD866 and GVB39 are prn and
bvgAS strains, respectively, of BBC17. BRD866 was
constructed as follows. A 1.8-kb PstI internal fragment of
the B. bronchiseptica prn gene was excised from the cosmid
pBD844 (30) and cloned into pUC18 to give pBD865. This was
then digested with ClaI, and, after end filling with Klenow
fragment, it was ligated alongside a blunt-ended 0.7-kb cat
(Cmr) cassette. The
prn::cat cassette was recovered from
the resulting plasmid, pBD866, by digestion with BamHI and
HindIII and cloned into the similarly digested suicide
vector pRTP1 (44) to generate pBD878. The suicide plasmid
used to generate GVB39 was constructed by a similar strategy. A 2.7-kb
EcoRI fragment of B. pertussis chromosomal DNA
encoding all of bvgA and about half of bvgS was cloned into pUC18. This construct was digested with StuI
(which cuts in the 5' end of bvgS), and the ends were filled
with Klenow fragment and ligated to the cat cassette,
described above, to give plasmid pBD805. The inactivated bvg
locus was recovered by digestion with BamHI and
HindIII and ligated into identically digested pRTP1 to
yield pBD901. Both pBD878 and pBD901 were conjugated independently into
BBC17 by using Escherichia coli SM10
pir, and strains in which allelic exchange had taken place were selected by
plating on medium containing chloramphenicol and streptomycin. Southern
blot analysis was carried out to confirm that allelic replacement had
occurred (data not shown). BB7866 (33) is a spontaneous
bvgS strain of a human wild-type isolate, BB7865
(33), and GVB184 is BB7866 carrying
PtacP68/pertactin on pBBR1MCS (26).
Expression of P68/pertactin and FHA in whole-cell lysates of all
strains was analyzed by Western blotting with the pertactin-specific monoclonal antibody BB05 (34) and rabbit polyclonal
anti-B. pertussis FHA, respectively. P68/pertactin was
expressed in BBC17, BB7865, and GVB184 (at 60% of that of wild-type
B. bronchiseptica) and was absent in BRD866
(prn), GVB39 (bvg), and BB7866 (bvg) (data not shown). FHA was expressed in BBC17, BRD866 (prn),
and BB7865 and was not expressed in GVB39 (bvg), BB7866
(bvg), and GVB184 (data not shown). ACT activity was assayed
in all strains and was produced at around the same levels in BBC17,
BRD866 (prn), and BB7865 and was not expressed in GVB39
(bvg), BB7866 (bvg), and GVB184 (19a).
The murine macrophage-like cell line RAW264.7 and PAM were maintained
in Dulbecco modified Eagle medium (DMEM; Gibco BRL Life Sciences,
Paisley, United Kingdom) supplemented with 10% Myoclone Super Plus
fetal calf serum and 2 mM glutamine in 5% CO2 at 37°C.
PAM were collected by lavaging pig lungs with 200 ml of room
temperature (RT) DMEM three times. The pooled cells were washed twice
with DMEM and pelleted by centrifugation for 5 min at 110 × g. They were then resuspended in 500 ml of ACK erythrocyte lysis
buffer and incubated for 10 min at RT. After harvesting by
centrifugation for 5 min at 110 × g, the cells were counted by trypan blue exclusion and were seeded at a concentration of
106 cells/ml in DMEM supplemented with 10 µg of
gentamicin per ml.
LDH assay.
The CytoTox nonradioactive cytotoxicity assay
(Promega, Southampton, United Kingdom) was used to quantitate cytosolic
lactate dehydrogenase (LDH) release as an indicator of cell viability, as recommended by the manufacturer. Briefly, RAW264.7 cells were seeded
in 96-well trays at a concentration of 106 cells/ml 24 h prior to use. Where appropriate, cells were incubated with
cytochalasin D (CD) (0.5 µg/ml) or cycloheximide (CH) (100 µg/ml)
for 1 h prior to infection. CD and CH were kept in the medium
throughout infections. Suspensions of bacteria prepared from 18-h-old
Bordet-Gengou lawns were prepared in prewarmed (37°C) DMEM. The cells
were infected at a multiplicity of infection (MOI) of 500:1 or 100:1,
and where appropriate, trays were centrifuged at 400 × g for 5 min after infection. Following an incubation period of 1, 2, or 4 h at 37°C in 5% CO2, the plates were
centrifuged at 400 × g for 5 min, 50-µl aliquots of
medium were transferred to a fresh tray, and 50 µl of substrate mix
was added to each well. After a 30-min incubation at RT in the dark, 50 µl of stop solution was added to each well and the absorbance was
recorded at 490 nm. Positive controls in each assay were represented by wells in which cells were lysed by the addition of Triton X-100 (0.8%). Each assay was carried out at least twice in triplicate. Results were analyzed by a one-way analysis of variance.
Nucleosome ELISA.
A Nucleosome enzyme-linked immunosorbent
assay (ELISA) kit (Calbiochem, Nottingham, United Kingdom), which
employs DNA affinity-mediated capture of free nucleosomes, was used to
quantitate apoptotic cells in vitro. Briefly, RAW264.7 cells or freshly
harvested PAM were seeded in 96-well trays at a concentration of
106 cells/ml 24 h prior to use. Positive control cells
were pretreated with 0.5 µg of actinomycin D (AD) per ml for 4 or
18 h to induce apoptosis. The cells were infected at an MOI of
100:1 with suspensions of bacteria as described above, and where
appropriate, plates were centrifuged at 400 × g for 5 min after infection. After an incubation period of 2 h at 37°C
in 5% CO2, the plates were centrifuged at 400 × g for 5 min. The medium was removed, and the cells were resuspended in 100 µl of lysis buffer per well and were disrupted by
vigorous pipetting. The plate was incubated on ice for 30 min before
being centrifuged at 1,000 × g for 10 min at 4°C,
and the lysis buffer was removed to a fresh 96-well tray. After at
least 18 h at 
20°C, the lysates were thawed at RT and
transferred into wells of the Nucleosome ELISA microtiter plate
supplied by the manufacturer. Following incubation for 3 h at RT,
the wells were washed three times with 1× wash buffer and 100 µl of
detector antibody was added to each well. After incubation for 1 h
at RT, the wells were again washed three times with 1× wash buffer.
One hundred microliters of freshly filtered 1× streptavidin conjugate (streptavidin-linked horseradish peroxidase conjugate) was added to
each well, and the plate was incubated for 30 min at RT. Wells were
washed twice with 1× wash buffer and flooded once with distilled H2O, and 100 µl of RT substrate solution was added to
each well. After 30 min of incubation at RT in the dark, 100 µl of
stop solution was added to each well. The absorbance was read with a
spectrophotometric plate reader at 450 nm. Each assay was carried out
at least twice in triplicate.
Fluorescence-activated cell sorting (FACS) analysis of infected
cells.
RAW264.7 cells were seeded in 24-well trays at a
concentration of 106 cells/ml 24 h prior to use. The
cells were infected at an MOI of 100:1 with suspensions of bacteria
prepared as described above. Where appropriate, cells were treated with
CD or AD as described above. After an incubation period of 2 h at
37°C in 5% CO2, the cells were washed three times with
cold phosphate-buffered saline (PBS) and resuspended in 1 ml of cold
1× Hanks balanced salt solution supplemented with 2.5 mM
CaCl2. Cells (100 µl) were stained with 10 µl of
fluorescein-conjugated annexin V (AV-fluorescein isothiocyanate [FITC]) (R&D Diagnostics, Abingdon, United Kingdom) at a
concentration of 10 µg/ml. AV is a phospholipid binding protein with
a selective affinity for negatively charged phospholipids and a
specificity for phosphotidylserine (46). The latter is
exposed on the outer leaflet of the cytoplasmic membrane of apoptotic
cells as a consequence of loss of cell membrane phospholipid asymmetry
and thus acts as a marker of early-phase apoptosis. After incubation at
RT for 15 min in the dark, 400 µl of 1× Hanks balanced salt solution supplemented with 2.5 mM CaCl2 was added and analysis was
carried out within 1 h on an EPICS-XL flow cytometer (Coulter).
Seven thousand events were acquired.
Fluorescence microscopy.
RAW264.7 cells were seeded in
four-well plastic chamber slides (Lab-Tek, Leicester, United Kingdom)
at a concentration of 106 cells/ml 24 h prior to use
in phenol red-free DMEM. The cells were infected at an MOI of 100:1
with suspensions of bacteria as described above, and after a 1-h
incubation, infected cells were washed three times with PBS. Staining
with fluorochromes was carried out in 1 ml of phenol red-free DMEM.
Cells were stained with propidium iodide (PI) (20 mM) and AV-FITC or PI
and SYTO-9 (3.34 µM) (Molecular Probes Europe BV, Leiden, The
Netherlands) for 15 min at RT in the dark. AV-FITC, as discussed above,
stains the membranes of apoptotic cells, while PI is taken up by
necrotic cells. Thus, apoptotic and necrotic cells can be
distinguished. SYTO-9 is a green fluorochrome which, in the presence of
PI, stains cells with intact membranes, and therefore, these two
fluorochromes can be used to distinguish between viable and nonviable
cells. Slides were washed twice with PBS before being imaged on a Leica DMLB fluorescence microscope with a standard long pass fluorescein filter set and LabSpectrum software (Vysis, London, United Kingdom).
| |
RESULTS |
B. bronchiseptica is cytotoxic for macrophages, and
toxicity is mediated by pertactin and other bvg-regulated
factors.
RAW264.7 cells were infected with different B. bronchiseptica strains at an MOI of 100:1 and were incubated for
1, 2, or 4 h. As is evident from Fig.
1a, wild-type strains BBC17 and BB7865 exerted a significant cytotoxic effect which increased with time. In
contrast, the bvg mutants GVB39 and BB7865 caused very
little cell damage, even with extended incubation. The prn
mutant BRD866 behaved similarly to the bvg mutants at the 1- and 2-h points, but at 4 h, it had induced LDH release
considerably greater than that of GVB39 (bvg) but still
significantly less than that of BBC17 at this time point. The amount of
cytotoxicity (assessed by LDH release) by BRD866 at 4 h was
similar to that of the wild-type strain at 1 h. Expression of
pertactin in a bvg strain (GVB184) did not enhance its
cytotoxicity. The difference in the cytotoxicity of the different
strains is not due to differences in their growth rate in DMEM (data
not shown). The effect of close cell-to-cell contacts was examined by
centrifuging the bacteria onto the monolayer directly after infection.
Figure 1b shows that the two wild-type strains and the pertactin mutant
were all highly cytotoxic for the cell line in these circumstances,
regardless of the length of incubation, although BRD866
(prn) was significantly less cytotoxic than its wild-type
parent (BBC17) at 1 and 2 h. As before, the bvg mutants
were mildly cytotoxic and the presence of pertactin in a
bvg-negative background was not sufficient to induce
cytotoxicity. RAW264.7 cells were also infected at MOI of 1:1, 10:1,
and 500:1 with all strains used previously. At an MOI of 500:1, levels
of toxicity increased, while at MOI of 1:1 and 10:1, levels of toxicity decreased in comparison to those observed at an MOI of 100:1. However,
the same patterns of cytotoxicity were observed as when the cells were
infected at an MOI of 100:1 (data not shown). In another experiment,
freshly harvested PAM were infected with B. bronchiseptica
for 2 h, and as can be seen in Fig. 1c, these cells appeared to be
generally more sensitive to infection, as both BRD866 (prn)
and GVB39 (bvg) induced around fourfold-higher levels of LDH
release than those which occurred in the RAW264.7 cells at 2 h
postinfection. Also, levels of LDH release were around the same
regardless of whether the bacteria were centrifuged onto the monolayer.
This may suggest that cells recovered from the in vivo milieu are more
susceptible to B. bronchiseptica infection.
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FIG. 1.
Cytotoxic effects of B. bronchiseptica on
macrophages. Macrophages were infected at an MOI of 100:1, and LDH
assays were carried out at 1, 2, or 4 h postinfection with
RAW264.7 cells (a); 1, 2, or 4 h postinfection with RAW264.7 cells
which were centrifuged for 5 min at 400 × g
immediately after infection (b); and 2 h postinfection with PAM
and without () or with (+) centrifugation (c). The bars represent the
mean percent release of LDH from three wells in comparison with the
positive control wells, and the error bars represent the standard
deviations. Statistical significance of strain-dependent cytotoxicity
is shown as P < 0.001 (***), P < 0.01 (**), and P < 0.05 (*). BRD866 and
GVB39 were compared to BBC17 at each time point, and BB7866 and GVB184
were compared to BB7865 at each time point.
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CD and CH inhibit B. bronchiseptica-induced
cytotoxicity.
B. bronchiseptica can enter both phagocytic
and nonphagocytic cells by a microfilament-dependent process (14,
20), and therefore, levels of cytotoxicity were characterized in
RAW264.7 cells which were pretreated with CD before infection. Figure
2a shows that cytoxicity was
significantly reduced at 1 h postinfection, and the LDH release
fell by ~90% in cells infected with BBC17, BB7865, and BRD866
(prn). At 4 h postinfection (Fig. 2b), addition of CD
did not result in a significant decrease in cytotoxicity of strain
BBC17. LDH release from cells infected with BB7865 and BRD866
(prn) remained lower in CD-treated cells than in untreated cells. The effect of pretreatment with CH was also examined, as it has
been shown to inhibit pertactin-mediated adhesion (9). As
seen with CD treatment, CH reduced B. bronchiseptica-mediated cytotoxicity at the 1- and 4-h points
(this was not significant for BBC17 at 4 h). The same effects as
those described above, in the presence of CD and CH, were observed when
bacteria were centrifuged onto monolayers or at a higher MOI of 500:1
(data not shown).
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FIG. 2.
Inhibition of cytotoxicity by CD and CH. RAW264.7 cells
were infected at an MOI of 100:1, and LDH assays were carried out at 1 (a) and 4 (b) h postinfection in the presence and absence of CD and CH.
The bars represent the mean percent release of LDH from three wells in
comparison with the positive control wells, and the error bars
represent the standard deviations. Statistical significance of
inhibition of cytotoxicity in each strain is shown as P < 0.001 (***), P < 0.01 (**), and
P < 0.05 (*). BRD866 and GVB39 were compared to
BBC17 at each time point, and BB7866 and GVB184 were compared to BB7865
at each time point.
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B. bronchiseptica induces apoptosis in
macrophages.
As B. bronchiseptica was clearly cytotoxic
for macrophages, the effect was further characterized to define if
toxicity was due to programmed cell death. After infection, RAW264.7
cells were labelled with AV-FITC and analyzed by FACS. A clear shift in
the proportion of apoptotic cells in the population was evident in the
presence of BBC17 (Fig. 3c), as
opposed to uninfected cells (Fig. 3a), and to around
the same degree as cells treated with AD for 18 h (Fig. 3b). This
could be inhibited in cells pretreated with CD (Fig. 3d). BRD866
(prn) was also able to increase the proportion of apoptotic
cells (Fig. 3e) but not to the same extent as seen with the wild-type
infection, while GVB39 (bvg) had little effect (Fig. 3f).
The effect of CD on uninfected cells was minimal, as a barely
discernible shift was observed in its presence (data not shown).
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FIG. 3.
FACS analysis of B. bronchiseptica-induced apoptosis. RAW264.7 cells were stained with
AV-FITC and analyzed on an EPICS-XL flow cytometer. (a and b) Profiles
of uninfected cells in the absence (a) and presence (b) of AD. (c to f)
Profiles of cells which were infected with B. bronchiseptica
for 2 h at an MOI of 100:1: BBC17 in the absence of CD (c), BBC17
in the presence of CD (d), BRD866 (e), and GVB39 (f). The cursors
represent populations of differing fluorescent intensities.
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To confirm that B. bronchiseptica induces apoptosis in
macrophages, infected RAW264.7 cells and PAM were assayed for release of free nucleosomes, a phenomenon associated with DNA laddering and
late-stage apoptosis. In the case of the RAW264.7 cells, only BBC17
gave rise to a significant positive result (6 nucleosome units/ml) in
comparison to uninfected cells (0.2 nucleosome units/ml) and only where
bacteria were centrifuged onto the monolayer (data not shown). When PAM
were infected, both BBC17 and BRD866 (prn) caused
nucleosomes to be released (Fig. 4). In
the presence of GVB39 (bvg), centrifugation was required
before a significant positive result was obtained.
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FIG. 4.
Nucleosome release by B. bronchiseptica-infected macrophages. PAM were infected at an MOI
of 100:1, and Nucleosome ELISAs were carried out at 2 h
postinfection without () or with (+) centrifugation. Nucleosome
release in uninfected cells treated with AD for 4 or 18 h was also
examined. The bars represent the mean counts from three wells, and the
error bars represent the standard deviations. Statistical significance
of strain-dependent nucleosome release is shown as P < 0.001 (***), P < 0.01 (**), and
P < 0.05 (*). BRD866 and GVB39 were compared to
BBC17.
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The major proportion of the cell population remains viable after
infection with B. bronchiseptica.
While B. bronchiseptica clearly induced apoptosis in macrophages, it was
not known which proportion of the total eukaryotic cell population
underwent programmed cell death or if any of the population died via a
necrotic pathway. RAW264.7 cells, which had been infected for 1 h,
were therefore stained with PI and AV-FITC or with PI and SYTO-9, which
enable viable, necrotic, and apoptotic populations of cells to be
distinguished and quantified. Examination of the cells by fluorescence
microscopy showed that, after infection with BBC17, the major
proportion of cells in the population remained viable. Those cells
which were stained with PI and SYTO-9 but which had taken up PI
constituted only around 10 to 20% of the population (Fig.
5a). This is generally in agreement with
the results obtained from LDH assays carried out with RAW264.7 cells
infected with BBC17 for 1 h (Fig. 1a and b), where around 20 to
40% cytotoxicity was observed. Of those cells which were stained with
PI and AV-FITC, around 1% of cells stained with AV-FITC (Fig. 5b).
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FIG. 5.
Quantification of live, necrotic, and apoptotic cells by
fluorescence microscopy. RAW264.7 cells were infected with BBC17 at an
MOI of 100:1. At 1 h postinfection, they were stained with PI and
SYTO-9 (a) or PI and AV-FITC (b) and were imaged with a Leica DMLB
fluorescence microscope at a magnification of ×200. Grey-scale
representative images of a red-green exposure (a) and a green exposure
(b) are shown. The highly fluorescent cells are in cells stained with
PI (a) and cells stained with AV-FITC (b).
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DISCUSSION |
B. bronchiseptica has been shown to adhere to, invade,
or persist intracellularly in eukaryotic cell lines in a variety of in
vitro studies. In contrast, B. pertussis appears unable to survive intracellularly for prolonged periods, and the bacterium is
known to induce apoptosis in macrophages both in vitro and in vivo
(19, 24, 25). Cell death in this instance is mediated by
ACT, and neither pertussis toxin nor pertactin/P69 is a prerequisite (24). There is little data detailing B. bronchiseptica-mediated eukaryotic cell death, although a
cytotoxic effect in epithelial cells has been described elsewhere
(45), and it has been suggested that viability of
macrophages decreases on extended exposure to these bacteria
(3).
As B. bronchiseptica is known to persist within cultured and
primary phagocytes, and as its close relative B. pertussis
is toxic for these cells, we investigated the capacity of the former to
promote cell death in macrophages. By using plasma membrane integrity
as a marker of macrophage viability, it was apparent that both human
and porcine wild-type isolates of B. bronchiseptica were
toxic for these cells (Fig. 1a and 2a). This effect was exacerbated by
centrifuging the bacteria onto the cells (Fig. 1b), suggesting that the
process enhanced the number of contacts between B. bronchiseptica and the eukaryotic cells. Also, the fact that
centrifugation overcame the reduced cytotoxicity of the
prn-negative mutant suggests that the role of pertactin is
to promote stable adhesion of B. bronchiseptica or to bring
it into close apposition to the macrophages. Therefore, one would
expect that pertactin would not be cytotoxic itself, and this is
supported by the finding that expression of pertactin does not augment
the cytotoxicity of a bvg mutant strain, even when
centrifugation is employed. Also, pertactin has been used as a
component of acellular pertussis vaccines in humans without recorded
side effects. Levels of cytotoxicity increased with time possibly
because there was an increase in bacterial numbers or because there was
an increase in synthesis of a cytotoxic factor(s). However, little
bacterial-mediated cytotoxicity, as assayed by LDH release, occurred in
the presence of bvg mutants which do not produce dedicated
virulence factors, including toxins and adhesins. This is in agreement
with the morphological effects described by van den Akker
(45), who showed that Bvg
phase variants of
B. bronchiseptica are nontoxic for epithelial cells, and
with the data showing that bvg mutants of B. pertussis and B. bronchiseptica are nontoxic for
macrophages (3, 23). It should be noted, though, that the
bvg mutants are not completely nontoxic for macrophages, as
they were able to induce nuclesome release in PAM when centrifuged onto
the monolayer. Also, BRD866, a mutant deficient in the production of
P68/pertactin, induced low levels of cytotoxicity in the short term (1 to 2 h) but levels at around that induced by wild type in the
longer term (4 h) (Fig. 1a). This is reminiscent of the finding that no
significant difference was found in levels of cytotoxicity induced by
wild type or a pertactin mutant of B. pertussis at 4 h
postinfection (24). However, a strain also used in that
study, which was deficient in both prn and fha,
was less efficient at promoting DNA fragmentation in macrophages but
had less ACT activity than its parent. This may suggest that other
adhesins, such as FHA, are able to promote binding of the bacteria to
macrophages in a compensatory time-dependent manner in the absence of
pertactin, which, in turn, leads to increased cytotoxicity.
Alternatively, P68/pertactin may act as a chaperon for correct FHA
function in B. bronchiseptica, as has been suggested by
Arico et al. (2) for P69/pertactin in B. pertussis. In that study, adhesion of B. pertussis to
CHO cells was found to be time dependent, to absolutely require FHA,
and to be influenced significantly by P69/pertactin. FHA has also been
recently shown to be required and sufficient for mediating adherence of
B. bronchiseptica to rat lung epithelial cells, but while
required, it is not sufficient for tracheal colonization
(8). As GVB184, a bvg mutant complemented only
with P68/pertactin, behaves in a similar manner as noncomplemented bvg mutants, this may again suggest that cytotoxic activity
is dependent on effective binding of the bacteria via multiple
adhesins. The same effect was reported for bvg mutant
B. pertussis (9). The viability of PAM was more
affected by B. bronchiseptica (Fig. 1c) than was that of
RAW264.7 cells, possibly because they are mature macrophages or because
they are alveolar macrophages per se. However, again prn and
bvg mutants were clearly less toxic than their wild-type
parent. Our results and those for other bacteria that are intracellular
pathogens but which can also cause apoptosis, such as
Salmonella spp., are somewhat contradictory. That is, why do
intracellular pathogens kill their host cell? It may be that they kill
more mature, and potentially more bactericidal, macrophages
preferentially, which increases their chances of entering a more
friendly environment. This appears to be the case in our studies where
PAM were more readily killed than RAW264.7 cells. Alternatively,
B. bronchiseptica may invade macrophages merely to more
efficiently kill them. However, this is in conflict with reports that
B. bronchiseptica can persist for days inside cells. It is
possible that the bacteria that persist within cells have adapted to
live within cells by down regulating the expression of cytotoxic
factors and possibly up regulating other genes. These hypotheses
require further experiments before they can be confirmed or refuted.
CD inhibits internalization of B. bronchiseptica and
Bordetella parapertussis by eukaryotic cells (10, 14,
20), presumably by blocking phagocytosis, but has been reported
to have no effect on adherence of B. pertussis to CHO cells
(35). Also, in a study examining the effects of B. pertussis-mediated apoptosis, while the kinetics of toxicity were
slightly slower in the presence of CD, the bacteria were able to induce
complete lysis of the macrophage population at 8 h postinfection
(25). In this study, CD significantly inhibited the ability
of B. bronchiseptica wild types and the prn
mutant to induce cytotoxicity at 1 h postinfection (Fig. 2a). At
4 h postinfection, there was no significant difference in LDH
release between CD-treated cells and untreated cells infected with the
porcine isolate BBC17. However, it is possible that bacterial replication could have occurred by the 4-h point of the assay, causing
toxic effects to be enhanced even in the presence of CD. In the
presence of the human isolate BB7865 and the prn mutant BRD866, cytotoxic effects remained significantly lower than those induced in cells not treated with CD, although levels had increased from those observed at 1 h postinfection (Fig. 2b). Thus, it would appear that internalization of B. bronchiseptica profoundly
enhances its ability to effect eukaryotic cell death but is not
essential. The effects of CH treatment on cytotoxicity mirrored those
seen with CD treatment, and as CH also inhibits P69/pertactin-mediated adhesion (9), it is possible that pertactin, which contains an RGD integrin-recognition motif, acts as a signalling molecule, resulting in the upregulation of receptors on the phagocytic cell surface. However, a recent report by Buckley et al. (4) has shown that RGD-containing peptides enter cells and directly induce activity of caspase-3, a proapoptotic protein. It would appear then
that efficient adhesion, internalization, and production of a cytotoxic
factor(s), possibly ACT, are the maximal conditions for B. bronchiseptica-mediated cell death. However, a recent paper has
reported that a cyaA mutant of B. bronchiseptica
is as cytotoxic for J774 macrophages as is its wild-type parent
(22), but a cyaA mutant in which the type III
secretion system was knocked out by a mutation in the bscN
gene was significantly less toxic. Tracheal cytotoxin (7)
and lipooligosaccharide (43) have also been described as
having a toxic effect on polymorphonuclear leukocytes and thus may
account for the degree of cytotoxicity of Bvg B. bronchiseptica.
As a variety of pathogens have now been described as inducers of
apoptosis, including B. pertussis, the ability of B. bronchiseptica to do so was examined by using markers for both
early-stage and late-stage apoptosis. FACS analysis and ELISA-based
histone detection (Fig. 3 and 4) clearly showed that B. bronchiseptica does induce apoptosis in murine macrophages, and as
demonstrated in the LDH assays, cell death is reduced when macrophages
are exposed to bacteria with a bvg- or
prn-negative background. Quantification of the proportion of
cells which had died via apoptosis was carried out by fluorescence
microscopy, in order that the necrotic population, if any, could also
be determined. Figure 5 shows that, while a small proportion of
macrophages stained with the apoptotic marker AV-FITC, the majority of
nonviable cells had taken up PI. Therefore, it would appear that
B. bronchiseptica is able to trigger cell death by more than
one mechanism. This phenomenon has also been described for
Escherichia coli (enteroaggregative E. coli
strains) (12) and for Shigella flexneri
(13), but in these instances, the type of cell death appears
to be dependent on the macrophage derivation. It has also been recently
suggested that Salmonella typhimurium, which survives within
macrophages and can cause them to apoptose, also induces a
necrotic-type death (31). As discussed by Fernandez-Prada et
al. (13) and Gordon et al. (18), there are
extensive heterogeneity and diversity within the macrophage population,
and one could presume that this would influence the route of
bacterium-mediated cell death. Further study will be required to define
the extent of B. bronchiseptica-mediated cytotoxicity in
vivo and to identify the mechanisms and factors involved.
| |
ACKNOWLEDGMENTS |
We thank Nicole Guiso for carrying out ACT assays and Linda
Andrews for assistance with FACS analysis.
This work received financial support from the Wellcome Trust, research
grant no. 045078.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Veterinary Pathology, University of Glasgow Veterinary School, Garscube Estate, Bearsden Rd., Glasgow G61 1QH, Scotland. Phone: 141 330 5780. Fax: 141 330 5602. E-mail:
m.roberts{at}vet.gla.ac.uk.
Present address: Department of Immunology, St. Bartholomew's and
The Royal London School of Medicine and Dentistry, London EC1A 7BE, England.
Editor:
R. N. Moore
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Top
Abstract
Introduction
