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Infection and Immunity, September 1999, p. 4886-4894, Vol. 67, No. 9
0019-9567/99/$04.00+0
Activation of Caspase 3 during Legionella
pneumophila-Induced Apoptosis
Lian-Yong
Gao and
Yousef
Abu Kwaik*
Department of Microbiology and Immunology,
University of Kentucky Chandler Medical Center, Lexington, Kentucky
40536-0084
Received 3 May 1999/Returned for modification 10 June 1999/Accepted 21 June 1999
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ABSTRACT |
The hallmark of Legionnaires' disease is replication of
Legionella pneumophila within cells in the alveolar spaces.
The mechanisms by which L. pneumophila replicates
intracellularly and kills the host cell are largely not understood. We
have recently shown that within 3 h of initiation of the infection
and prior to intracellular replication, L. pneumophila
induces apoptosis in macrophages, alveolar epithelial cells, and
peripheral blood monocytes, which correlates with cytopathogenicity
(L.-Y. Gao and Y. Abu Kwaik, Infect. Immun. 67:862-870, 1999). In this
report, we show that the ability of L. pneumophila to
induce apoptosis is, largely, not growth phase regulated. We
demonstrate that the induction of apoptosis by L. pneumophila in macrophages is mediated through the activation of
caspase 3. The enzymatic activity of caspase 3 to cleave a specific
synthetic substrate in vitro is detected in L. pneumophila-infected macrophages at 2 h after infection and
is maximal at 3 h, with over 900% increase in activity. The activity of caspase 3 to cleave a specific substrate [poly(ADP-ribose) polymerase, or PARP] in vivo is also detected at 2 h and is
maximal at 3 h postinfection. The activity of caspase 3 to cleave
the synthetic substrate in vitro and PARP in vivo is blocked by a specific inhibitor of caspase 3. The kinetics of caspase 3 activation correlates with that of L. pneumophila-induced nuclear
apoptosis. Inhibition of caspase 3 activity blocks L. pneumophila-induced nuclear apoptosis and cytopathogenicity
during early stages of the infection. Consistent with the ability to
induce apoptosis, extracellular L. pneumophila also
activates caspase 3. Three dotA/icmWXYZ mutants of L. pneumophila that are defective in inducing apoptosis do not
induce caspase 3 activation, suggesting that expression and/or export
of the apoptosis-inducing factor(s) is regulated by the
dot/icm virulence system. This is the first description of
the role of caspase 3 activation in induction of nuclear apoptosis in
the host cell infected by a bacterial pathogen.
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INTRODUCTION |
Apoptosis is a strictly regulated
genetic and biochemical suicide program that plays critical roles
during development and tissue homeostasis and in modulating
pathogenesis of a variety of diseases (54). The expanding
family of cysteine proteases (caspases) that specifically cleave
proteins next to aspartate (Asp) residues has been demonstrated to
include crucial components of the apoptotic pathways
(9). A cascade mechanism for transmission of diverse
apoptotic signals into a common apoptotic effector pathway by networks
of caspases has been well demonstrated (36, 38, 48).
Among the 11 caspases that have been identified so far,
caspase 3 plays a central role in driving the apoptotic effector pathway (36, 37). Activated caspase 3 cleaves and
inactivates the inhibitor for caspase-activated DNase (ICAD), allowing
CAD to enter the nucleus and degrade chromosomal DNA (17,
47). Activation of caspase 3 has been observed in various
types of cells undergoing apoptosis induced by a variety of
stimuli. In immune system-responsive cells, such as macrophages,
neutrophils, and lymphocytes, activation of caspase 3 has been shown to
be required for apoptosis induced by Fas-FasL or tumor necrosis factor alpha (TNF-
)-TNF receptor (TNFR) interactions (42).
A number of bacterial pathogens are capable of manipulating host cell
apoptotic pathways, although whether these manipulations are to the
advantage of the host or of the bacteria may vary among pathogens. The
obligate intracellular pathogens, such as Chlamydia trachomatis and Rickettsia rickettsii, inhibit host
cell apoptosis, which may allow these organisms to grow and persist
intracellularly (15, 19). Many facultative intracellular
bacteria, such as Mycobacterium avium (21),
Shigella flexneri (61), Salmonella typhimurium (39), Legionella pneumophila
(22, 40), and Yersinia pseudotuberculosis
(45), have been shown to induce apoptosis in the host cell.
Salmonella- and Shigella-induced apoptosis
in macrophages is mediated through direct binding and activation of ICE
(caspase 1) (14, 29, 31, 60). Although caspase 3 plays a
central role in driving the apoptotic pathways triggered by a variety
of stimuli, its role in apoptosis induced by bacterial pathogens is not known.
L. pneumophila is a parasite of protozoa in the environment
and is the causative agent of Legionnaires' disease, a potentially fatal pneumonia (1, 7). The ability of L. pneumophila to cause pneumonia is dependent on its capacity to
invade and replicate within alveolar macrophages, monocytes, and
potentially alveolar epithelial cells (1, 23). Initial
bacterial attachment to the host cells is mediated, at least in part,
by type IV pili (52), the heat shock protein Hsp60
(26), and the major outer membrane protein opsonized by
complement (59). Following entry into the host cell,
L. pneumophila replicates within a phagosome that does not
fuse to lysosomes (see references 1 and
7 for recent reviews). This alteration in endocytic
trafficking has been recently shown to be mediated by L. pneumophila proteins encoded by the pmi,
mil, dot, and icm loci (24, 25,
49, 57). During the intracellular infection, the bacteria exhibit dramatic alterations in gene expression, which are thought to play
major roles in bacterial adaptation to the intracellular microenvironment (2-4, 6, 8, 20) and possibly in killing the host cell upon termination of intracellular replication (13, 22).
Induction of necrosis and apoptosis plays roles in killing of the host
cell by L. pneumophila. Necrosis in L. pneumophila-infected macrophages occurs within 20 to 60 min of
infection at a high multiplicity of infection (MOI), 500 (32,
34). The induction of necrosis is mediated by a cell-associated
pore-forming toxin, and evidence for this mediation has been recently
provided (34). Interestingly, L. pneumophila is
not cytotoxic to host cells during the exponential phase of growth but
becomes cytotoxic upon entering the postexponential phase
(13), indicating that expression of the pore-forming toxin
is growth phase regulated. We have recently shown that L. pneumophila induces apoptosis in U937 human macrophages, human
peripheral blood monocytes, and alveolar epithelial cells within 2 to
3 h postinfection in a dose-dependent manner and that the
induction of apoptosis correlates with cytopathogenicity
(22). We proposed a biphasic model by which L. pneumophila kills the host cell. The first phase is mediated by
induction of apoptosis during early stages of the infection
(22), and it is followed by rapid necrosis upon termination
of intracellular bacterial replication concomitant with the phenotypic
transition of the bacteria into the cytotoxic phenotype
(13).
In this investigation, we continued our studies on characterization of
the mechanisms by which L. pneumophila induces apoptosis (22). Our data clearly demonstrate that L. pneumophila-induced apoptosis in macrophages is mediated through
the activation of caspase 3.
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MATERIALS AND METHODS |
Bacterial strains and growth media.
The virulent strain
AA100 of L. pneumophila has been described previously
(5). Isolation and characterization of the pmi mutants and the mil mutants of L. pneumophila
have been described previously (24, 25). L. pneumophila strains were grown on buffered charcoal yeast extract
agar plates or, for the mutant strains, in buffered yeast extract (BYE)
broth supplemented with 50 µg of kanamycin/ml.
Cytopathogenicity of L. pneumophila to U937
macrophages.
The human macrophage-like cell line U937 was
maintained and differentiated into macrophage-like cells by phorbol
12-myristate 13-acetate (Sigma, St. Louis, Mo.), as previously
described (24). Infection was performed, in triplicate, in
96-well plates containing 105 cells/well at an MOI of 5 or
50 for 1 h at 37°C, followed by three washes with the culture
medium to remove unattached extracellular bacteria and subsequent
incubation at 37°C. Cytopathogenicity (loss of cell viability) was
determined by Alamar blue assay and expressed as we described
previously (22). To examine the effect of caspase inhibitor
on the cytopathogenicity of L. pneumophila to the host cell,
macrophages were pretreated for 90 min with 50 µmol of the caspase
3-specific inhibitor Z-DEVD-FMK (Oncogene Research Products, Cambridge,
Mass.) (18). The monolayers were then infected by strain
AA100 for 1 h in the presence of the inhibitor, followed by washes
to remove unattached bacteria and subsequent incubation in the presence
of the inhibitor. An additional 50 µmol of Z-DEVD-FMK was added to
the monolayers at 12 h postinfection to replenish any inhibitor
potentially degraded during this period.
DNA fragmentation analysis.
Differentiated U937 cells were
plated in six-well plates (2 × 106 cells/well) and
were infected with strains of L. pneumophila at an MOI of
50, as described above. At several intervals after the 1-h infection
period, the cells in each well were lysed with 500 µl of lysis buffer
(22), and the DNA was extracted, electrophoresed in 1.8%
agarose gel, and stained with ethidium bromide, exactly as we described
previously (22). To examine inhibition of DNA fragmentation
by the caspase 3-specific inhibitor, U937 macrophages were preincubated
with or without the inhibitor, infected by strain AA100, and incubated
in the presence or absence of the inhibitor. The monolayers were lysed
at 3 h after the 1-h infection period, and the DNA samples were
processed exactly as described above.
TUNEL assays.
Differentiated U937 macrophages on glass
coverslips were infected by strain AA100 at an MOI of 5 or 50, exactly
as described above. Terminal deoxynucleotidyltransferase-mediated
dUTP-biotin nick end labeling (TUNEL) assays were performed as we
described previously (22). Briefly, at 2 and 3 h after
the 1-h infection period, the monolayers were fixed, permeabilized, and
blocked with 2% bovine serum albumin. For labeling of L. pneumophila, the monolayers were incubated with a rabbit
polyclonal antiserum raised against strain AA100 (22),
followed by a goat anti-rabbit immunoglobulin G secondary antibody
conjugated to Alexa Red (Molecular Probes, Inc., Eugene, Oreg.).
Apoptotic nuclei were labeled with a cell death detection kit based on
TUNEL, according to the instructions of the manufacturer (Boehringer
Mannheim Corporation, Indianapolis, Ind.). To examine inhibition of
nuclear apoptosis in the presence of the caspase 3-specific inhibitor,
the monolayers were preincubated with or without the inhibitor,
infected by strain AA100 at an MOI of 50, and incubated in the presence
or absence of the inhibitor. The monolayers were fixed at 8 h
after the 1-h infection period and labeled, exactly as described above.
To demonstrate changes in plasma membrane permeability during
inhibition of nuclear apoptosis by the caspase 3-specific inhibitor,
cells in the monolayers at 8 h postinfection were stained with the
nuclear dye propidium iodide (PI) (molecular mass, 668 Da)
(22), which does not penetrate intact plasma membranes.
Labeled cells were examined with a Leica model TCS NT confocal laser
scanning microscope, and a minimum of 100 cells per sample were
counted. Apoptosis or necrosis was quantitated as the percentage of
TUNEL-positive or PI-positive cells, respectively, in the total number
of cells examined.
Assays for caspase 3 enzymatic activities.
U937 macrophages
in six-well plates (2 × 106 cells per well) were
infected with strains of L. pneumophila or the DH5 strain of E. coli at an MOI of 50, exactly as described above. At
several intervals after the 1-h infection period, the cells in each
well were lysed with 300 µl of lysis buffer (5 mM EDTA [pH 8.0], 2 mM dithiothreitol, 20 mM Tris-HCl [pH 7.5], 2 µg of aprotinin/ml, and 2 µg of leupeptin/ml) for 30 min at 4°C. Cell lysates were centrifuged for 5 min at 15,000 × g and 4°C to
remove insoluble cellular contents. Supernatants equivalent to 2 × 105 cells were diluted in reaction buffer (100 mM
Tris-HCl [pH 7.5], 10 mM dithiothreitol, 0.1% CHAPS, 2 µg of
aprotinin/ml, and 2 µg of leupeptin/ml) to a total suspension volume
of 100 µl. For detection of caspase 3 activity, the suspensions were
incubated in the presence or absence of 50 µmol of a fluorogenic
substrate, Z-DEVD-AMC (Oncogene Research Products), which is specific
for caspase 3 (43). For detection of the inhibition of
caspase 3 activity, the suspensions were treated with or without 1 µmol of the caspase 3-specific inhibitor prior to addition of the
fluorogenic substrate. Release of AMC from Z-DEVD-AMC by the activity
of caspase 3 was measured on an LS50B luminescence spectrometer (Perkin
Elmer, Norwalk, Conn.) at excitation and emission wavelengths of 380 and 460 nm, respectively.
To examine the activation of caspase 3 in macrophages by extracellular
L. pneumophila, infection was carried out in the presence of
1 µg of cytochalasin D (CytD) per ml, as we described previously (22, 25). Inhibition of bacterial uptake was confirmed by complete sterilization of the infected monolayers with 50 µg of gentamicin/ml after the infection period, as we described previously (22, 25). To examine whether a factor secreted to the
culture supernatant of L. pneumophila induces apoptosis,
caspase 3 activity was examined in U937 macrophages that had been
incubated for 4 h in tissue culture medium containing 5%
bacterial culture supernatant, which is equivalent to the ratio of
bacterial suspension added during inoculation at an MOI of 50. The
bacterial culture supernatant was prepared from stationary-phase
cultures (optical density at 550 nm [OD550], 2.3) that
were filter sterilized through a 0.2-µm-pore-size low-protein-binding
filter (Millipore, Bedford, Mass.). Incubation of control monolayers
with 10 µM actinomycin D (ActD) was used as a positive control for
induction of caspase 3 activation.
Immunoblot analyses.
U937 cells (5 × 106)
uninfected or infected by strain AA100 at an MOI of 50 in the presence
or absence of the caspase 3-specific inhibitor were resuspended, at
several intervals after the 1-h infection period, in cold
phosphate-buffered saline containing protease inhibitors (2 µg of
leupeptin/ml and 2 µg of aprotinin/ml) and phosphatase inhibitors (5 mM NaF and 1 mM Na3VO4) (56). Cells
were pelleted by low-speed centrifugation at 1,000 × g
for 2 min and lysed in 50 µl of cold lysis buffer (56).
Equivalent amounts of proteins were resolved on sodium dodecyl sulfate
(SDS)-10% polyacrylamide gel electrotransferred onto Immobilon-P
(Millipore) membranes that were probed with a rabbit polyclonal
anti-poly(ADP-ribose) polymerase (PARP) antiserum according to the
recommendations of the manufacturer (Upstate Biotechnology, Lake
Placid, N.Y.). The blots were subsequently stripped in 62.5 mM Tris-HCl
[pH 6.8]-2% SDS-100 mM 
-mercaptoethanol for 45 min at 65°C
and reprobed with a mouse monoclonal antiactin antibody clone AC-15
(Sigma Co.), as we described previously (55).
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RESULTS |
L. pneumophila-induced apoptosis is not growth phase
regulated.
L. pneumophila exhibits rapid cytotoxicity to the
host cells only upon entry into the postexponential growth phase, which seems to be due to necrosis mediated by a potent cell-associated pore-forming toxin (13, 32, 34). We have recently shown that
L. pneumophila induces a dose- and time-dependent apoptosis in U937 macrophages, peripheral blood monocytes, and alveolar epithelial cells during early stages of infection (22).
Therefore, we first examined whether, similar to necrosis, L. pneumophila-induced apoptosis was growth phase regulated.
L. pneumophila grown in BYE broth to different growth phases
was pelleted, washed with tissue culture medium, and then used
to
infect U937 macrophages at an MOI of 5 or 50 for 1 h. TUNEL
assays
were performed at 2 and 3 h after the 1-h infection period,
and
the percent apoptotic cells was determined (see the Materials
and
Method section). The data showed that, at all the growth phases
examined,
L. pneumophila induced apoptosis (Fig.
1 and
2).
However,
there was a slight trend towards a gradual increase in the
induction
of apoptosis by the bacteria from the early exponential
(OD
550 = 0.3) to mid-exponential
(OD
550 = 1.5) and postexponential
(OD
550 = 2.2) growth phases, at either MOI and either
time point examined
(Fig.
1 and
2). However, compared to the enhanced
gradual increase
in the induction of apoptosis by
L. pneumophila at different growth
phases, the induction of necrosis
is strictly growth phase regulated
and is not detectable during the
exponential phase but is detectable
only upon entry into the
postexponential phase (
13). Bacteria
grown to late
stationary phase (OD
550 > 2.3, 24 h after
termination
of replication) exhibited a slight reduction in the ability
to
induce apoptosis, which correlated with the reduction of bacterial
viability by threefold (Fig.
1 and data not shown). Heat-killed
bacteria did not induce apoptosis (data not shown).
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FIG. 1.
Induction of apoptosis in macrophages by L. pneumophila grown to different growth phases. (A) Growth kinetics
of L. pneumophila in BYE broth. The arrows are accompanied
by OD550 values and indicate bacterial cultures used for
infection of U937 macrophages at MOI of 5 and 50. (B and C)
Quantitation of apoptosis (examined by TUNEL assays) in macrophages
infected at MOI of 5 and 50 at 2 h (panel B) and 3 h (panel
C) postinfection. OD550 was the OD of the bacterial
cultures used in the infections. At least 100 cells were examined for
each sample. Error bars represent standard deviations, some of which
are too small to be presented. Representative images of the infection
at an MOI of 50 are shown in Fig. 2.
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FIG. 2.
Representative confocal laser scanning microscopy images
of L. pneumophila-infected macrophages. Apoptosis was
examined by TUNEL assays at 3 h after the 1-h period of infection
at an MOI of 50. The apoptotic nuclei appear in green. L. pneumophila was labeled by an L. pneumophila-specific
polyclonal antiserum followed by an Alexa Red conjugate, which is shown
in red. Panels B, D, F, and H are images of cells infected by bacterial
cultures at the indicated values of OD550, and for
comparison noninfected cells (NI) are shown in panel J. The panels on
the top are the phase-contrast images corresponding to the ones on the
bottom.
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Since
L. pneumophila grown to the postexponential phase is
highly cytotoxic (
13), it is possible that some of the cells
infected by the bacteria at this growth stage may have detached
from
the monolayers, which may have resulted in underestimation
of the
actual percent apoptotic cells. Therefore, we examined
detachment of
cells from the monolayers that were infected, at
different MOI, by
strain AA100 grown to the postexponential phase
(OD
550 = 2.2). Although about 30% of the cells
detached at 3 h
postinfection from the monolayers infected at an
MOI of 50, loss
of cells from the monolayers infected at an MOI of 5 was minimal
(8%). The gradual increase in the induction of apoptosis
by bacteria
grown to the postexponential phase may be due to the
dramatic
increase in invasiveness of the bacteria at this growth stage
(
13). This is supported by our recent findings that although
extracellular
L. pneumophila can induce apoptosis,
bacterial invasion
enhances this process (
22). Therefore,
L. pneumophila is capable
of induction of apoptosis at all
growth phases, with an approximately
twofold increase upon exiting the
exponential phase. This is in
contrast to the growth phase-regulated
induction of necrosis,
which is not detectable during exponential
growth and is exhibited
only upon entry into the postexponential
phase.
Inhibition of caspase 3 activation blocks L. pneumophila-induced nuclear apoptosis.
Caspase 3 activation
is essential for DNA fragmentation to occur in apoptosis induced by a
variety of stimuli (9, 47, 58). The synthetic tetrapeptide
derivative Z-DEVD-FMK has been extensively used as a specific inhibitor
of caspase 3 (18). As shown in Fig.
3A, this inhibitor completely blocked DNA
fragmentation in U937 macrophages induced by L. pneumophila
(Fig. 3A, lane 3). Complete inhibition of nuclear apoptosis in L. pneumophila-infected macrophages by this inhibitor was further
confirmed by TUNEL assays performed at 3 h postinfection (data not
shown) and 8 h postinfection (Fig. 3B through E).
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FIG. 3.
Inhibition of caspase 3 activation blocks L. pneumophila-induced nuclear apoptosis. (A) Agarose gel
electrophoresis of U937 macrophage DNA prepared at 3 h after the
1 h period of infection at an MOI of 50. The monolayers were
infected in the presence (AA100 + DEVD) (lane 3) or absence
(AA100) (lane 2) of the caspase 3-specific inhibitor, Z-DEVD-FMK, or
were neither infected nor treated (NI) (lane 1). M indicates the 100-bp
molecular size markers. (B) Quantitation of TUNEL-positive and
PI-positive cells. U937 macrophages were infected, at an MOI of 50, by
strain AA100 in the presence (AA100+C3i) or absence (AA100) of the
caspase 3-specific inhibitor (C3i). At 8 h after the 1-h infection
period, one portion of the monolayers was fixed and labeled by TUNEL.
The other portion of the monolayers was labeled, in parallel to TUNEL,
with PI without fixation. As negative controls, noninfected monolayers
were treated with (NI+C3i) or without (NI) the inhibitor. At least 100 cells were counted for each sample. Error bars represent standard
deviations, some of which are too small to be presented. (C through H)
Representative confocal laser scanning microscopy images of U937
macrophages infected in the presence or absence of the caspase
3-specific inhibitor and examined by TUNEL (upper panels) or PI
staining (lower panels). For TUNEL assay, the apoptotic nuclei are
shown in green, and the L. pneumophila cells are shown in
red (see legend to Fig. 2). For PI staining, the nuclei of the cells
with changes in plasma membrane permeability are shown in red. The
images of TUNEL and PI staining of noninfected monolayers treated with
the inhibitor, as negative controls, are shown in panels E and H,
respectively.
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Activity of caspase 3 in L. pneumophila-infected cells
to cleave a synthetic substrate in vitro.
To further confirm that
caspase 3 was enzymatically active in L. pneumophila-infected macrophages, cell lysates were incubated with
the fluorogenic substrate specific for caspase 3 (Z-DEVD-AMC) (43). Compared to the noninfected cells, a 380% increase in fluorescence was detected in the lysate of infected cells at 2 h
postinfection, and the increase culminated at 3 h postinfection, when there was a 900% increase in fluorescence (Fig.
4B). ActD, which was used as a positive
control for induction of apoptosis in U937 macrophages (22),
induced caspase 3 activation (Fig. 4B). Heat-killed L. pneumophila or E. coli cells, used as negative controls, did not induce activation of caspase 3 (see Fig. 7). Importantly, the kinetics of caspase 3 activation in L. pneumophila-infected macrophages correlated with the kinetics of
nuclear apoptosis (Fig. 4A).
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FIG. 4.
Kinetics of caspase 3 activity in L. pneumophila-infected U937 macrophages to cleave a synthetic
substrate and its correlation with nuclear apoptosis. (A) Kinetics of
nuclear apoptosis in macrophages examined by DNA fragmentation at
several intervals after the 1-h period of infection at an MOI of 50 and, for comparison, in noninfected cells (NI). M indicates the 100-bp
molecular size markers. (B) Kinetics of caspase 3 enzymatic activity to
cleave the fluorogenic substrate, Z-DEVD-AMC, which is specific for
caspase 3. Some of the monolayers were infected in the presence
(AA100+CytD) or absence (AA100) of 1 µg of CytD/ml. ActD indicates
incubation of the noninfected macrophages with 10 µg of ActD/ml.
C3i-AA100 indicates infection in the presence of the caspase 3 inhibitor (C3i), Z-DEVD-FMK. NI and NT indicate noninfected and
nontreated cells, respectively. Cell lysates were prepared at the
indicated time points after the 1-h period of infection at an MOI of
50. The caspase 3-specific inhibitor was added to the lysates of the
infected (AA100+C3i) or ActD-treated (ActD+C3i) cells to demonstrate
the specificity of the enzymatic activity of caspase 3. Relative
enzymatic activity of caspase 3 was calculated as the percent increase
in fluorescence compared to that for NI+NT and expressed as percent
control fluorescence. Error bars represent standard deviations, some of
which are too small to be presented.
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Cleavage of Z-DEVD-AMC was specifically due to the activity of caspase
3, since the reaction was completely blocked, in the
lysates of both
L. pneumophila-infected and ActD-treated cells,
by the
caspase 3-specific inhibitor, Z-DEVD-FMK (Fig.
4B). Furthermore,
L. pneumophila-induced caspase 3 activation in macrophages
was
completely abolished, up to 12 h postinfection, by the caspase
3-specific inhibitor (Fig.
4B). Pretreatment of the bacteria with
the
caspase 3 inhibitor did not affect the ability to induce apoptosis
in
nontreated macrophages (data not shown), indicating that inhibition
of
apoptosis by this inhibitor was indeed due to inhibition of
caspase 3 activity in the host cells but not that of the bacterial
apoptotic
factor.
Activity of caspase 3 in L. pneumophila-infected cells
to cleave a natural substrate in vivo.
To further demonstrate
caspase 3 activity in vivo, we examined the kinetics of cleavage of one
of its natural substrates, PARP, by immunoblot analysis of cell lysates
(Fig. 5). Cleavage of PARP p116 into the signature fragment p85 in
L. pneumophila-infected macrophages was not detected at
1 h postinfection (data not shown), was very prominent at 2 h, and was complete at 3 to 4 h. Reduction in the amount of p85 at
5 and 8 h postinfection may be due to partial degradation.
Importantly, cleavage of PARP was completely blocked in cells infected
in the presence of the caspase 3-specific inhibitor for at least 8 h postinfection, confirming that cleavage of PARP was specifically due
to the activation of caspase 3 (Fig. 5). Interestingly, although the caspase
3 inhibitor blocked L. pneumophila-induced nuclear
apoptosis in U937 macrophages, it failed to block the surface
exposure of phosphatidylserine induced by the bacteria (reference
22 and data not shown), which indicates that these
two events in the apoptotic pathway are independent. This finding is
consistent with previous observations of apoptosis in macrophages
induced by Yersinia spp. (45).
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FIG. 5.
Caspase 3 activity in L. pneumophila-infected
U937 macrophages to cleave the natural specific substrate (PARP) for
caspase 3 in vivo. The in vivo caspase 3 activity in L. pneumophila-infected macrophages was detected by cleavage of PARP
in immunoblots of cell lysates prepared at the indicated time points
after the 1-h period of infection at an MOI of 50 and probed with a
rabbit polyclonal anti-PARP antibody. The blots were stripped and
reprobed with a mouse anti-actin monoclonal antibody. Caspase 3 activity is demonstrated by cleavage of p116 PARP to its signature
fragment p85.
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Role of caspase 3 in L. pneumophila-mediated
cytopathogenicity.
Inhibition of caspase 3 activity by Z-DEVD-FMK
significantly reduced cytopathogenicity of L. pneumophila to
U937 macrophages during the first 3 h after the 1-h infection
period (Fig. 6). After 12 h
postinfection, inhibition of caspase 3 activity was no longer
sufficient to protect the cells from L. pneumophila-induced cytopathogenicity (Fig. 6), although caspase 3 activity was completely blocked during these periods (Fig. 4B and 5).
Pretreatment of the bacteria with the caspase 3 inhibitor did not have
any detectable effect on their cytopathogenic capacities (data not
shown). The data indicated that inhibition of caspase 3 activity
delayed but did not completely block the L. pneumophila-induced cell death. This may not be surprising since
inhibition of nuclear apoptosis by the caspase 3 inhibitor may not
block all of the apoptotic pathways induced by L. pneumophila. Our data may also suggest that at later times of the
infection necrotic cell death could have occurred due to the presence
of a large number of post-exponential-phase cytotoxic bacteria
(13). To test this possibility, cells were stained with PI,
in parallel with TUNEL, to examine whether cytopathogenicity at later
time points in the presence of the caspase 3 inhibitor was due to
necrotic damage. The data showed that the plasma membrane of
macrophages infected at an MOI of 50 in the presence of the caspase
3 inhibitor became permeable to PI at 8 h postinfection, although nuclear apoptosis was completely blocked by this
inhibitor during this period (Fig. 3B through H). This
increased permeability in the plasma membrane could be due to apoptotic
pathways independent of nuclear apoptosis or to a direct action of the
pore-forming toxin expressed by a small proportion of bacteria that
have already entered the postexponential phase.
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FIG. 6.
Inhibition of the activity of caspase 3 blocks
cytopathogenicity of L. pneumophila to U937 macrophages
during early stages of the infection. Macrophages were infected at an
MOI of 50 in the presence or absence of the caspase 3-specific
inhibitor (C3i), Z-DEVD-FMK, and cytopathogenicity was determined at
the indicated time points by Alamar blue assay and compared to that for
noninfected cells (NI). Error bars represent standard deviations, some
of which are too small to be presented.
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Viable extracellular L. pneumophila induces caspase 3 activation in macrophages.
We have recently shown that
extracellular L. pneumophila induces nuclear apoptosis
in U937 macrophages, but bacterial invasion enhances the apoptotic
process (22). In this study, we examined the activation
of caspase 3 by extracellular bacteria. U937 macrophages were
preincubated with CytD for 30 min and infected by strain AA100 for 30 min in the presence of CytD, extracellular bacteria were killed with
gentamicin, and U937 macrophages were further incubated in the presence
of CytD. We confirmed complete blockage of bacterial uptake by
CytD-treated macrophages by sterilization of the infected monolayers
following gentamicin treatment. Cell lysates were prepared at different
time points to examine caspase 3 activity in cleaving the synthetic
substrate. As shown in Fig. 4B, caspase 3 was activated by
extracellular L. pneumophila: the activity increased by
approximately 460 and 710% at 3 and 6 h postinfection,
respectively. CytD by itself did not have any detectable effect on
caspase 3 activation during this period. Activation of caspase 3 by
extracellular bacteria correlated with the induction of nuclear
apoptosis (22), indicating that the activation of caspase 3 is associated with induction of nuclear apoptosis by extracellular
L. pneumophila. The reduced level of caspase 3 activity induced by extracellular bacteria is consistent with our finding that
bacterial invasion enhances apoptosis (22). A live L. pneumophila macrophage contact was required for the induction of
apoptosis in macrophages, since neither the heat-killed bacteria nor
the bacterial culture supernatant induced activation of caspase 3 (Fig.
7). E. coli, which was used as
a negative control, had no detectable effect on caspase 3 activation
(Fig. 7). We have recently shown that three dotA/icmWXYZ
mutants (GG105, GL10, and GS95) (24) are defective in
inducing nuclear apoptosis, indicating that the apoptosis-inducing
factor is regulated and/or exported by the Dot/Icm type V-like
secretion apparatus (22, 49, 57). Since DotA is a
cytoplasmic membrane protein, it is most likely that these three
mutants are defective in export but not in expression of the
apoptosis-inducing factor. We further confirmed the dependence of
L. pneumophila-induced apoptosis on the Dot/Icm potential
secretion apparatus by demonstrating that the three
dotA/icmWXYZ mutants were also defective in inducing caspase
3 activation in infected macrophages (Fig. 7 and data not shown)
(22).
View larger version (15K):
[in this window]
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|
FIG. 7.
Dependence of caspase 3 activation in macrophages on
live L. pneumophila macrophage contact. Caspase 3 activity
to cleave Z-DEVD-AMC was determined for cells infected by live (AA100)
or heat-killed (H.K-AA100) strain AA100, live dot/icm mutant
bacteria (only data for GL10 are shown), and E. coli. C.S
and BYE indicate cells treated with cell-free bacterial culture
supernatant of strain AA100 and BYE broth, respectively. Relative
enzymatic activity of caspase 3 was determined at 3 h after the
1-h period of infection or 4 h after the initiation of the
treatment with C.S or BYE and was expressed as percent control
fluorescence (percent compared to the fluorescence of noninfected cells
[NI]). Error bars represent standard deviations, some of which are
too small to be presented.
|
|
| |
DISCUSSION |
We have previously shown that L. pneumophila induces
apoptosis in macrophages, alveolar epithelial cells, and peripheral
blood monocytes during the first few hours of the infection
(22). In addition, we have also shown that the induction of
apoptosis is dose dependent and is detectable at 3 h after
infection at an MOI of 0.5 (22). Therefore, it is very clear
that the induction of apoptosis occurs very early in the interaction
between L. pneumophila and mammalian cells. We have proposed
a biphasic model by which L. pneumophila kills the host cell
(22). Killing is mediated through the induction of apoptosis
during the early stages of the infection (22, 40) followed
by an independent and rapid induction of necrosis upon entry into the
postexponential phase (13).
In this study, we have used an MOI of 50 to ensure maximal activation
of the apoptotic pathway to examine the activity of caspase 3 during
L. pneumophila-induced apoptosis. We have demonstrated that
activation of caspase 3 in macrophages by L. pneumophila is
essential for nuclear apoptosis. To our knowledge, this is the first
report demonstrating an involvement of caspase 3 activity in induction
of apoptosis by a bacterial pathogen. Yersinia spp.-induced nuclear apoptosis in macrophages has been shown to require the activity
of the family of caspases, since it is blocked by a broad-spectrum caspase inhibitor, Z-VAD-FMK (45); this finding is similar
to our previous findings in L. pneumophila-induced apoptosis
in macrophages (22). However, which caspase(s) is activated
in Yersinia spp.-induced apoptosis has not been reported. On
the other hand, S. typhimurium and S. flexneri
are the only two bacterial species known to activate a particular
member of the caspase family, i.e., caspase 1/ICE (14, 29,
60). Inhibition of caspase 1 activity by a specific inhibitor
blocks S. typhimurium- and S. flexneri-induced
apoptosis in macrophages and prevents cell death induced by the
bacteria (29, 30). Furthermore, it has recently been shown
that caspase 3 is not required for S. flexneri-induced
apoptosis in macrophages (31), which indicates that the
caspase 1- and caspase 3-mediated apoptotic pathways are distinct. In
contrast to the distinct caspase activation-mediated nuclear apoptosis
by L. pneumophila and Shigella, host cell DNA
fragmentation by Mycoplasma penetrans is mediated through a
bacterial endonuclease (10). These differences add to the
diversity of mechanisms utilized by bacterial pathogens to induce
nuclear apoptosis in the host cell.
The primary function of caspase 1 is generally believed to be
proinflammatory, whereas the function of caspase 3 and most other
caspases is mostly proapoptotic (27, 28, 48). Activation of
caspase 1 in S. flexneri-infected macrophages leads to
cleavage of the precursor interleukin (IL) 1 into mature IL-1 that
may subsequently initiate an intense host inflammatory response, which is evident in infected patients (30, 62). Therefore,
it has been proposed that activation of caspase 1 in
S. flexneri-infected macrophages converts a
proapoptotic event into a proinflammatory one (62). Release
of proinflammatory cytokines, such as IL-1 and TNF-, by L. pneumophila-infected macrophages has been reported (12,
53). However, our preliminary data suggest that caspase 1 is not
activated in L. pneumophila-infected macrophages
(unpublished data), which is consistent with other observations that
caspase 1- and caspase 3-mediated apoptotic pathways are distinct
(31). Therefore, in contrast to S. flexneri-induced apoptosis in macrophages, which is primarily
proinflammatory, apoptosis induced by L. pneumophila in
macrophages may be primarily proapoptotic.
Although cytopathogenicity of L. pneumophila to macrophages
has been well documented, the mechanisms of cell death are not well
understood. We have recently shown that L. pneumophila
induces a dose- and time-dependent apoptosis during early stages of
infection (22). We have also provided genetic and
biochemical evidence that apoptosis plays an important role in
cytopathogenicity of L. pneumophila to the host cells
(22). Here we further demonstrate that inhibition of nuclear
apoptosis in macrophages by a caspase 3-specific inhibitor reduces
cytopathogenicity of L. pneumophila to these cells during
early stages of the infection. Our data do not exclude the possibility
that changes in plasma membrane permeability at later stages of the
infection may have occurred due to the presence of a large number of
post-exponential-phase cytotoxic bacteria (13).
Nevertheless, our data show that caspase 3-mediated apoptosis plays an
important role in cytopathogenicity of L. pneumophila to the
host cell during early stages of the infection.
Extracellular L. pneumophila induces caspase 3-mediated
apoptosis. However, entry of the bacteria into the host cell enhances but is not required for the activation of caspase 3. In contrast, entry
of S. flexneri into macrophages and subsequent bacterial escape into the cytoplasm are essential for S. flexneri to
induce caspase 1-mediated apoptosis (14, 30). Similarly,
S. typhimurium entry into macrophages is required for
activation of the apoptotic pathway (39). Thus, L. pneumophila is the first documented example of an intracellular
pathogen that induces caspase 3-mediated apoptosis in macrophages upon
contact and prior to entry.
Our data demonstrate that the Dot/Icm type V-like secretion apparatus
is required for the induction of apoptosis. We propose three
possibilities for how extracellular L. pneumophila activates the caspase cascade. First, upon contact with the host cell, L. pneumophila translocates, through the Dot/Icm secretion machinery, the apoptotic factor(s) into the host cell cytosol, which results in
activation of caspase 3 either directly or by activation of caspases
upstream of caspase 3. Second, upon contact with the host cell,
L. pneumophila secretes, through the Dot/Icm secretion machinery, the apoptotic factor(s) in close proximity of attachment, which binds to a death receptor on the host cell surface. This receptor
may be Fas (35, 46), TNFR (42), or other death receptors. Third, L. pneumophila translocates the apoptotic
factor(s), through the Dot/Icm secretion machinery, to the bacterial
surface, which may then mediate bacterial binding to a death receptor
on the host cell surface. It is also possible that more than one of
these proposed strategies are exploited by L. pneumophila. Nevertheless, our preliminary data show that caspase 8, which is the
most upstream caspase that interacts with the cytoplasmic domains of
many death receptors (11, 41), is activated in L. pneumophila-infected macrophages, suggesting that the apoptotic signal is generated upon binding to a death receptor. Therefore, it
should be of great interest to investigate whether L. pneumophila binds a known or a novel death receptor to induce apoptosis.
Why does L. pneumophila induce apoptosis from an
extracellular location at such an early stage of the infection of the
macrophages and alveolar epithelial cells (22) that
subsequently support intracellular replication of the bacteria? First,
it is possible that extracellular L. pneumophila, upon
contact with the cells, induces host cell apoptotic pathways to
facilitate alteration of trafficking of the bacterium-containing
phagosome to block its fusion to endocytic vesicles that allow
phagosomal maturation through the endosomal-lysosomal pathway (1,
44). It has been shown that induction of apoptosis results in
blockage of endocytic fusion, due to cleavage of Rabaptin 5 by the
caspase cascade (16). Rabaptin 5 stabilizes the Rab5-GTP
complex (50), which stimulates endocytic fusion, and thus
cleavage of Rabaptin-5 is thought to result in a Rab5-GDP complex that
blocks endocytic fusion (16, 51). Interestingly, the three
dotA/icmwxyz mutants that are defective in induction of
apoptosis are also targeted into a phagosome that is trafficked through
the endosomal-lysosomal pathway, which culminates in fusion to the
lysosomes (reference 44 and our unpublished data).
Second, since L. pneumophila has been shown to suppress the
oxidative burst in monocytes (33), induction of apoptosis
may down-regulate the bacteriocidal activity of these cells to enable
the bacteria to survive in what is otherwise considered a harsh
environment for microorganisms. Third, induction of apoptosis may play
an important role in killing the host cells for subsequent release of
the intracellular bacteria from the host cell. Fourth, host cell death
by apoptosis may reduce inflammation at the foci of infection (compared
to that resulting from necrosis), which would enhance bacterial
proliferation at the sites of infection. During this study we observed
that apoptotic macrophages harboring L. pneumophila are
taken up by other, uninfected macrophages (unpublished data). It would
be intriguing to examine whether this process results in elimination of
the bacteria through lysosomal degradation of the engulfed infected
macrophage or whether the bacteria are able to escape this fatal fate
and replicate in the new host cell.
| |
ACKNOWLEDGMENTS |
We thank Charles E. Snow, Vivek Rangnekar, and members of Abu
Kwaik laboratory for their helpful suggestions and comments.
Y.A.K. is supported by Public Health Service Award R29AI-38410.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, University of Kentucky Chandler Medical Center, Lexington, KY 40536-0084. Phone: (606) 323-3873. Fax: (606)
257-8994. E-mail: yabukw{at}pop.uky.edu.
Editor:
J. T. Barbieri
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Abstract
Introduction
