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J Biol Chem, Vol. 274, Issue 43, 30651-30656, October 22, 1999
§,
From the Division of Cellular Immunology, La Jolla Institute for
Allergy and Immunology, San Diego, California 92121 and the
Department of Internal Medicine, University of
California, San Diego, California 92103
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Caspase-3 initiates apoptotic DNA fragmentation
by proteolytically inactivating DFF45 (DNA fragmentation
factor-45)/ICAD (inhibitor of caspase-activated DNase), which releases
active DFF40/CAD (caspase-activated DNase), the inhibitor's associated
endonuclease. Here, we examined whether other apoptotic proteinases
initiated DNA fragmentation via DFF45/ICAD inactivation. In a cell-free
assay, caspases-3, -6, -7, -8, and granzyme B initiated
benzoyloxycarbonyl-Asp-Glu-Val-Asp (DEVD) cleaving caspase activity,
DFF45/ICAD inactivation, and DNA fragmentation, but calpain and
cathepsin D failed to initiate these events. Strikingly, only the DEVD
cleaving caspases, caspase-3 and caspase-7, inactivated DFF45/ICAD and
promoted DNA fragmentation in an in vitro DFF40/CAD assay,
suggesting that granzyme B, caspase-6, and caspase-8 promote DFF45/ICAD
inactivation and DNA fragmentation indirectly by activating caspase-3
and/or caspase-7. In vitro, however, caspase-3 inactivated
DFF45/ICAD and promoted DNA fragmentation more effectively than
caspase-7 and endogenous levels of caspase-7 failed to inactivate
DFF45/ICAD in caspase-3 null MCF7 cells and extracts. Together, these
data suggest that caspase-3 is the primary inactivator of
DFF45/ICAD and therefore the primary activator of apoptotic DNA fragmentation.
Caspase proteinases drive apoptotic signaling and execution by
cleaving critical cellular proteins solely after aspartate residues
(reviewed in Ref. 1). Caspases exist as latent zymogens, but apoptotic
death stimuli activate the initiator caspases, caspase-8 and caspase-9.
Death receptors such as Fas induce caspase-8 activation via the adapter
molecule Fas-associated death domain protein. Chemotherapeutic agents
and UV irradiation cause release of mitochondrial cytochrome
c, which then binds the adapter molecule apoptotic proteinase activating factor-1
(APAF-1),1 and this complex
along with adenine nucleotides promotes caspase-9 autoactivation. Once
activated, initiator caspases in turn activate the executioner
caspases, caspases-3, -6, and -7. The active executioners promote
apoptosis by cleaving cellular substrates that induce the
morphological and biochemical features of apoptosis (1).
DFF45 (DNA fragmentation factor-45)/ICAD (inhibitor of
caspase-activated DNase) is a caspase-3 substrate that must be cleaved before apoptotic internucleosomal DNA fragmentation can proceed (2, 3).
DFF45/ICAD exists as a complex with a 40-kDa endonuclease termed
DFF40/caspase-activated nuclease/CAD (caspase-activated DNase) that
promotes apoptotic DNA fragmentation (3-5). DFF45/ICAD serves as both
a specific inhibitor of DFF40/CAD and as a molecular chaperone to
ensure proper folding of the endonuclease (3, 4, 6, 7). DFF40/CAD
remains inactive while bound to DFF45/ICAD; however, caspase-3 cleaves
DFF45/ICAD at two sites, thereby releasing the endonuclease, which then
cleaves DNA. DFF45/ICAD cleavage at the N-terminal caspase site
(Asp117) is both necessary and sufficient for DFF40/CAD
activation; however, DFF45/ICAD cleaved only at the C-terminal caspase
site (Asp224), retains DFF40/CAD inhibitory activity (6).
In contrast to DFF40/CAD, a mitochondrial protein termed apoptosis
inducing factor, may induce high molecular weight DNA fragmentation in
a caspase-independent manner (8).
Besides caspase-3, caspases-6, -7, -8, -9, the cytotoxic T cell
proteinase granzyme B, the calcium-dependent proteinase
calpain, and the lysosomal proteinase cathepsin D may function during
apoptosis (9-12). These proteinases have all been suggested to
participate in apoptotic DNA fragmentation; however, the mechanism(s)
by which they promote DNA fragmentation remain unclear. Here, we
examined whether these proteinases induced DNA fragmentation by
inactivating DFF45/ICAD. We find that caspase-3 and caspase-7 are the
only direct inactivators of DFF45/ICAD. However, endogenous levels of
caspase-7 failed to inactivate the inhibitor or promote DNA fragmentation in vitro or in intact cells, suggesting that
caspase-3 is the primary regulator of apoptotic DNA fragmentation via
proteolysis of DFF45/ICAD.
Materials--
Benzoyloxycarbonyl-Asp-Glu-Val-Asp-amino-4-trifluoromethyl-coumarin
(DEVD-AFC) and N-acetyl-Leu-Glu-His-Asp-AFC
(LEHD-AFC) were from Enzyme Systems Products.
Benzoyloxycarbonyl-Val-Ala-Asp-fluoromethyl ketone (ZVAD-fmk) was from
Bachem. Antibodies against the following proteins were purchased
commercially: caspases-3, -6, -7, -8 (Pharmingen) and actin (ICN
Biomedicals). Dr. Xiadong Wang (University of Texas Southwestern
Medical Center) provided anti-DFF45/ICAD antibodies (2). Antibodies
against APAF-1 and caspase-9 have been described previously (13).
Expression Constructs--
Dr. Shigekazu Nagata (Osaka
University Medical School, Japan) provided plasmids encoding DFF40/CAD
(pBS-mCAD) and DFF45/ICAD (pBS-mICADL) (3). The DFF45/ICAD
cDNA was subcloned into the EcoRI site of pGex4T1
(Amersham Pharmacia Biotech). Glutathione S-transferase
(GST)-DFF45/ICAD was expressed in E. coli BL21(DE3) and
purified on glutathione-Sepharose (Amersham Pharmacia Biotech).
Drs. Guy Salvesen (The Burnham Institute) and Vishva Dixit
(Genentech) provided plasmids encoding histidine-tagged
caspases-3, -6, -7, and -8 (9, 14). A construct encoding 6×-histidine tagged caspase-9 was produced using the polymerase chain reaction and a
topoisomerase-based cloning system (Invitrogen). Briefly, the coding
region of caspase-9 was amplified from the pRSV-LacZ-caspase-9 plasmid
(15) (Dr. Emad Alnemri, Thomas Jefferson University). The polymerase
chain reaction product was subjected to agarose gel electrophoresis and
purified by gel extraction (Qiagen). The gel-purified product was then
cloned into the pTrcHis2TOPO vector according to the manufacturer's
instructions. The fidelity of the construct sequence was confirmed by
nucleotide sequencing.
Proteinases--
Caspases were expressed in Escherichia
coli, purified on Ni2+-Sepharose, and active site
titrated with ZVAD-fmk as described (13, 16). Granzyme B (13 units/µg) was from Enzyme Systems Products. Calpain was purchased
from Calbiochem and active site titrated with calpeptin (Calbiochem)
(13). Cathepsin D (651 units/mg) was from Calbiochem.
Cell-free Reactions--
Cytosolic extracts from Jurkat cells
and MCF7 cells were prepared as described (13, 17). Cell-free reactions
were conducted in the following buffers (as indicated): CAD buffer (10 mM HEPES-KOH, pH 7.2, 50 mM NaCl, 20% v/v
glycerol, 2 mM MgCl2, 5 mM EGTA, 5 mM dithiothreitol, 1 mg/ml bovine serum albumin), calpain
buffer (CAD buffer lacking EGTA and containing 2.5 mM
calcium chloride and 0.1 mg/ml bovine serum albumin), and cathepsin D
buffer (10 mM PIPES-KOH, pH 6.7, 50 mM NaCl,
20% (v/v) glycerol, 2 mM MgCl2, 5 mM dithiothreitol, 1 mg/ml bovine serum albumin). Since
preliminary experiments demonstrated that calcium present in calpain
buffer promoted DNA fragmentation even without calpain addition, we
performed cell-free reactions in two steps. First, extracts were
treated with proteinases or cytochrome c plus dATP as
indicated in the figure legends. Aliquots of each reaction mixture were
then withdrawn for caspase assay and Western blot analysis (13).
Second, 106 rat liver nuclei and 5 mM EGTA were
added to the extracts and the reactions then continued for the
indicated times. DNA fragmentation was subsequently visualized via
agarose gel electrophoresis and ethidium bromide staining (17). For the
kinetic analysis described in the legend to Fig. 4, cell-free reactions
were performed by mixing cytosolic extract, nuclei, and cytochrome
c plus dATP in a single step as described in the figure legend.
In Vitro Transcription and
Translation--
35S-DFF45/ICAD was prepared from
pBS-ICADL using [35S]methionine (Amersham
Pharmacia Biotech) and a reticulocyte lysate transcription and
translation system (Promega). Since functional DFF40/CAD can only be
produced in the presence of DFF45/ICAD (3, 7), we included 200 ng of
GST-DFF45/ICAD in the transcription/translation reaction to prepare
35S-pro-DFF40/CAD. Aliquots (2 µl) of
35S-DFF45/ICAD and 35S-pro-DFF40/CAD were
incubated with proteinases in caspase buffer (20 mM PIPES,
100 mM NaCl, 10 mM dithiothreitol, 1 mM EDTA, 0.1% CHAPS, 10% sucrose, pH 7.2) as indicated in
the figure legends and the products subjected to SDS-PAGE and autoradiography.
In Vitro DFF40/CAD Assay--
In vitro DFF40/CAD
assays were performed as described (3). Briefly, pro-DFF40/CAD was
prepared by in vitro transcription and translation in the
presence of 200 ng of GST-DFF45/ICAD. Aliquots (2 µl) of
pro-DFF40/CAD were incubated with proteinases for 30 min at 30 °C.
106 nuclei and EGTA (final concentration 5 mM)
were added to the reaction mixture and after 2 h DNA fragmentation
was analyzed via agarose gel electrophoresis and ethidium bromide
staining (17). In control experiments, we determined that the
reticulocyte lysate used for transcription and translation did not have
DNase activity either in the absence or presence of proteinases or
cytochrome c plus dATP.
Cell Culture and Induction of Apoptosis--
Dr. Margret Huflejt
(La Jolla Institute for Allergy and Immunology) provided the MCF7
breast cancer cell line. Cells were maintained in Dulbecco's modified
Eagle's medium (Life Technologies, Inc.), supplemented with fetal calf
serum (10% w/v), L-glutamine (2 mM),
penicillin (50 units/ml), and streptomycin (50 µg/ml). For induction
of apoptosis, cells were incubated for 24 h with 50 ng/ml tumor
necrosis factor- Caspases, Granzyme B, and Cytochrome C plus dATP Promote DFF45/ICAD
Cleavage and DNA Fragmentation in a Cell-free Assay--
We first
assessed whether various apoptotic proteinases could promote DNA
fragmentation in a cell-free assay. Proteinases were incubated with
cytosolic extracts from Jurkat T cells and subsequently examined for
DNase activity using rat liver nuclei as a substrate. We also examined
whether the proteinase-treated extracts cleaved DFF45/ICAD and the
fluorogenic caspase substrate DEVD-AFC.
As shown in Fig. 1, all proteinases
examined promoted DFF45/ICAD cleavage as demonstrated by Western
blotting. However, not all cleavage events inactivated the inhibitor.
Caspases-3, -6, and -7 produced DFF45/ICAD cleavage products of ~23
and ~12 kDa. Note that the ~23-kDa band likely represents
intermediate cleavage products resulting from cleavage at one of the
two caspase cleavage sites; whereas, the broad band at ~12 kDa
probably represents a composite of the three DFF45/ICAD fragments
observed when the inhibitor is cleaved at both caspase sites (2).
The control lane shows a small amount of the intermediate cleavage
products, likely due to background caspase activity. With granzyme B
and cytochrome c plus dATP, only the ~12-kDa fragments were observed, suggesting cleavage had occurred at both caspase cleavage sites. By contrast, calpain prompted loss of DFF45/ICAD immunoreactivity and cathepsin D produced a ~19-kDa DFF45/ICAD fragment. Strikingly, only the caspases, granzyme B, and cytochrome c plus dATP elicited DEVD cleaving caspase activity (Fig.
1A), DFF45/ICAD inactivation, and DNA fragmentation (Fig.
1C). As in apoptotic cells (2), DNA fragmentation correlated
with the production of ~12-kDa DFF45/ICAD fragments. Although calpain
and cathepsin D induced DFF45/ICAD cleavage, they failed to inactivate the inhibitor, induce DNA fragmentation, or activate DEVD cleaving caspases. This suggests that DEVD cleaving caspase activity is not
necessary for DFF45/ICAD cleavage, but is required for inactivation of
the inhibitor and DNA fragmentation.
We also examined whether the initiator caspases functioned in the
cell-free assay. Caspase-8 (50 nM) induced DEVDase
activity, DFF45/ICAD cleavage, and DNA fragmentation (not shown).
Caspase-9 failed to promote these events; however, our caspase-9
preparation showed little activity against the fluorogenic caspase-9
substrate LEHD-AFC. This is probably due to lack of cofactors since
caspase-9 demonstrates little activity in the absence of cytochrome
c, dATP, and cyotsolic factors (APAF-1) (18).
Caspase-3 and Caspase-7, but Not Other Apoptotic Proteinases,
Promote DFF45/ICAD Inactivation and DNA Fragmentation in Vitro--
We
next asked whether the preceding apoptotic proteinases directly cleaved
DFF45/ICAD or DFF40/CAD that was bound to the inhibitor. To accomplish
this, we treated 35S-DFF45/ICAD and
35S-pro-DFF40/CAD with each proteinase and examined the
products by SDS-PAGE and autoradiography. As shown in Fig.
2A, DFF45/ICAD was susceptible
to each proteinase; however, the extent and pattern of DFF45/ICAD
cleavage varied with each proteinase.
Caspase-3, caspase-7, and cytochrome c plus dATP-treated
cytosol produced a similar cleavage pattern with products of ~24, 22, and 12 kDa. Caspase-6 and granzyme B produced a small amount of ~24-
and ~12-kDa products. Cathepsin D and calpain produced distinct
products of ~19 and 25 kDa, respectively. By contrast, only granzyme
B cleaved DFF40/CAD, producing a small amount of a ~35-kDa product
(Fig. 2B). Thus, several apoptotic proteinases cleave
DFF45/ICAD, however, DFF40/CAD resists proteolysis.
To determine whether DFF45/ICAD cleavage inactivated the inhibitor and
released active DFF40/CAD, we treated pro-DFF40/CAD (prepared by
in vitro transcription and translation in the presence of
GST-DFF45/ICAD) with each proteinase and then examined DNase activity
against rat liver nuclei. Strikingly, although each proteinase cleaved
DFF45/ICAD, only caspases-3, and -7 inactivated the inhibitor, prompting release of active DFF40/CAD and DNA fragmentation (Fig. 2C). The initiator caspase, caspases-8, also failed to
inactivate DFF45/ICAD, even at concentrations up to 200 nM
(not shown). DFF45/ICAD inactivation and DNA fragmentation correlated
with production of 24-, 22-, and 12-kDa DFF45/ICAD fragments that were
only observed with caspase-3 and caspase-7 or when
35S-DFF45/ICAD was incubated with cytochrome c
plus dATP-treated cytosol (Fig. 2A). Although the other
proteinases cleaved DFF45/ICAD, they failed to inactivate the
inhibitor. Since granzyme B, caspase-6, and caspase-8 promoted
DFF45/ICAD inactivation and DNA fragmentation in the cell-free assay
(Fig. 1), they probably function in this system via activation of
caspases-3 and/or -7.
Further Analysis of the Reaction of Caspase-3 and Caspase-7 with
DFF45/ICAD and Pro-DFF40/CAD--
We next examined the reaction of
caspase-3 and caspase-7 with DFF45/ICAD in detail since these
proteinases were the only direct inactivators of the inhibitor.
As shown in Fig. 3A, when
equal amounts (40 nM) of caspase-3 or caspase-7 were
reacted with 35S-DFF45/ICAD, caspase-3 cleaved the
inhibitor more rapidly than caspase-7. DFF45/ICAD cleavage was
evident within 10 min following caspase-3 treatment and complete by
2 h. By contrast, caspase-7 did not produce detectable DFF45/ICAD
cleavage until 2 h and only ~50% of the DFF45/ICAD was cleaved
at 4 h. In concentration dependence experiments (Fig.
3B), caspase-3 also cleaved DFF45/ICAD more efficiently than
caspase-7. Following a 30-min incubation, DFF45/ICAD cleavage was
detectable with as little as 8.8 nM caspase-3; however, DFF45/ICAD cleavage by caspase-7 was not detectable until the caspase
concentration was 88 nM.
To determine if DFF45/ICAD cleavage corresponded with release of active
DFF40/CAD, we incubated various concentrations of caspase-3 or
caspase-7 with pro-DFF40/CAD and rat liver nuclei and then monitored
DNA fragmentation. As shown in Fig. 3C, caspase-3 induced
detectable DNA fragmentation at 50 nM, whereas with
caspase-7, DNA fragmentation required 150 nM caspase-7.
Together, the data indicate that caspase-3 inactivates DFF45/ICAD and
induces DNA fragmentation more efficiently than caspase-7.
Caspase-7 Activation Does Not Induce DNA Fragmentation in Caspase-3
Null MCF7 Cells or Cytosolic Extracts--
To determine whether
endogenous levels of caspase-7 could cleave DFF45/ICAD and promote DNA
fragmentation in the absence of caspase-3, we used caspase-3 null MCF7
cell extracts in a cell-free assay. The MCF7 cells lacked caspase-3 as
demonstrated by Western blotting, although they contained caspases-6,
-7, -8, -9, and APAF-1 at comparable levels to Jurkat cells (not
shown). We treated the extracts with cytochrome c plus dATP
and then examined DEVDase activity, procaspase-7 processing, DFF45/ICAD
cleavage, and DNA fragmentation as a function of time. For comparison,
we also analyzed these events in Jurkat cell extracts, which contain
caspase-3.
As shown in Fig. 4, cytochrome
c plus dATP initiated procaspase-7 processing and the onset
of DEVD cleaving caspase activity in Jurkat and MCF7 extracts. However,
procaspase-7 processing occurred earlier and was more extensive in the
Jurkat extracts. Procaspase-3 processing occurred with identical
kinetics to procaspase-7 processing in the Jurkat extracts (not shown).
The Jurkat extracts demonstrated ~10-fold greater DEVDase activity
than the MCF7 cells at 2 h, likely due to the combined activity of
caspase-3 and caspase-7. Although DEVDase activity declined with time
in the Jurkat extracts, the Jurkat DEVDase activity remained
substantially greater than the MCF7 DEVDase activity at all time
points. Caspase-7 processing and DEVDase activity correlated with the
extent of DFF45/ICAD cleavage and DNA fragmentation in both extracts
(Fig. 4, B and C). In the Jurkat extracts,
DFF45/ICAD cleavage was complete by 2 h; whereas, even after
6 h, only ~50% of DFF45/ICAD had been cleaved in the MCF7
extracts. Strikingly, while DNA fragmentation had occurred by 2 h
in the Jurkat extracts, little DNA fragmentation had occurred in the
MCF7 extracts even after 6 h of incubation, despite caspase-7
activation and partial DFF45/ICAD cleavage. Thus, cytochrome
c plus dATP initiate caspase-7 activation in the MCF7
extracts, but this does not inactivate DFF45/ICAD or promote
significant DNA fragmentation. Similarly, we detected caspase-7-like
DEVDase activity in extracts prepared from apoptotic MCF7 cells, but we
detected no DNA fragmentation by agarose gel analysis or propidium
iodide staining and fluorescence-activated cell sorter analysis (not
shown).
We next incubated caspase-3 with MCF7 extracts and nuclei to determine
whether this proteinase could initiate DNA fragmentation. Fig.
4D shows that 125 nM caspase-3 induced DNA
fragmentation in the extracts. Similarly, addition of exogenous
caspase-7 to the extracts initiated DNA fragmentation, although this
required a higher concentration than caspase-3 (not shown). Together,
these data suggest that in the absence of caspase-3, endogenous levels of caspase-7 do not inactivate DFF45/ICAD.
In this paper, we examined whether various apoptotic proteinases
could promote internucleosomal DNA fragmentation by inactivating DFF45/ICAD, thereby releasing active DFF40/CAD. Of the eight
proteinases examined, we find that only caspase-3 and caspase-7 are
direct inactivators of DFF45/ICAD. However, caspase-3 was the more
efficient inactivator and endogenous levels of caspase-7 failed to
release active DFF40/CAD, suggesting that caspase-3 is the primary
activator of apoptotic DNA fragmentation. These findings confirm and
extend those of Liu et al. (19) who recently demonstrated
that caspases-3 and -7, but not caspases-6 and -8, inactivate
recombinant DFF45, releasing active DFF40 (19). Additionally, our work
emphasizes the central importance of caspase proteinases, particularly
caspase-3, as the principal mediators of apoptosis.
Three lines of evidence support our finding that caspase-3 is the
primary inactivator of DFF45/ICAD and thus the primary activator of
apoptotic DNA fragmentation. First, only proteinases that initiated DEVDase activity in Jurkat extracts, which is due primarily to caspase-3 inactivated DFF45/ICAD and initiated DNA fragmentation (Fig.
1). Second, caspase-3 cleaved DFF45/ICAD and promoted DNA fragmentation
more effectively than caspase-7, the only other direct DFF45/ICAD
inactivator (Figs. 2 and 3). Third, caspase-3 null MCF7 cells failed to
fragment DNA during apoptosis and cytochrome c plus
dATP-activated MCF7 extracts did not inactivate DFF45/ICAD or promote
DNA fragmentation, despite caspase-7 activation (Fig. 4). However,
addition of caspase-3 to these extracts restored their
caspase-dependent DNase activity. These findings are
consistent with the delayed or absent apoptotic DNA fragmentation
observed in caspase-3 null cells and mice (20-23). Caspase-3
activation is therefore fundamentally important for DFF45/ICAD inactivation.
Although caspase-7 initiated DNA fragmentation in a cell-free assay
(Fig. 1) and inactivated DFF45/ICAD in an in vitro nuclease assay (Fig. 2), our data suggest that caspase-7 plays a secondary role
in inactivating the inhibitor. Like caspase-3, caspase-7 prefers
DEVD-based peptide substrates (1), however, caspase-3 cleaved
DFF45/ICAD more effectively than caspase-7 (Fig. 3) in vitro
and the low level of caspase-7 DEVDase activity generated in MCF7 cells
and extracts (Fig. 4) did not inactivate DFF45/ICAD. This suggests that
the two caspases cleave macromolecular substrates with different
efficiencies and that endogenous levels of caspase-7 do not initiate
DNA fragmentation. Furthermore, since active caspase-7 localizes to
mitochondrial and microsomal membranes (24), the caspase may be
physically sequestered from DFF45/ICAD and therefore unable to react
with the inhibitor. Overall, the data suggest that caspase-7 is not a
physiologic inactivator of DFF45/ICAD and that critical caspase-7
substrates remain unidentified.
Caspase-6 and granzyme B induced DFF45/ICAD inactivation and DNA
fragmentation in Jurkat extracts (Fig. 1); however, although they
cleaved DFF45/ICAD, they failed to inactivate the inhibitor in an
in vitro nuclease assay (Fig. 2). Since these proteinases effectively activate caspase-3 (16, 25), these results suggest that
they inactivate DFF45/ICAD via caspase-3 activation. Non-activating DFF45/ICAD cleavage was also observed with calpain and cathepsin D
(Figs. 1 and 2); however, since these proteinases do not activate caspases (Fig. 1 and Ref. 13), they were unable to initiate DNA
fragmentation in a cell-free assay (Fig. 1). Caspase-6, granzyme B,
calpain, and cathepsin D probably cleave DFF45/ICAD at or near the
C-terminal caspase cleavage site (Asp224) since DFF45/ICAD
mutants that can only be cleaved at this site retain DFF40/CAD
inhibitory activity (6). Non-activating cleavage of DFF45/ICAD by these
proteinases could be synergistic with activating cleavage events
mediated by caspase-3 or caspase-7 if the partially cleaved inhibitor
is more susceptible to cleavage by caspases-3 and -7. Alternatively,
non-activating cleavage might alter interaction of DFF40/CAD with
cofactors such as histone H1 (19) or target the endonuclease for
destruction. These possibilities are currently under investigation.
In summary, our data indicate that caspase-3 is the primary inactivator
of DFF45/ICAD and suggest that proteolytic pathways that induce
apoptotic internucleosomal DNA fragmentation must involve this
proteinase. Fig. 5 summarizes our
findings and presents a model of apoptotic DNA fragmentation. In this
model, the initiator caspases, caspases-8 and -9, promote apoptotic
signaling and activate the executioner caspases, which in turn degrade
apoptotic substrates. Similarly, granzyme B functions primarily to
activate executioner caspases and not to cleave apoptotic substrates.
Studies demonstrating that granzyme B activates caspase-3 more
efficiently than caspase-8 (16) and the lack of DNA fragmentation
observed in the absence of caspase activation during granzyme
B-mediated apoptosis (9) support this hypothesis. Once activated,
caspase-3 plays a central role in apoptotic DNA fragmentation by
inactivating DFF45/ICAD, thereby releasing active DFF40/CAD. Caspase-3
also activates caspase-6 (26), which in turn promotes nuclear apoptosis
by degrading lamins (27). Caspase-6 can also activate procaspase-3
(25), providing the opportunity for amplification of caspase-3
activity. Caspase-7, which may be localized to mitochondria and
microsomes plays a secondary role in DNA fragmentation as a back up
DFF45/ICAD inactivator. By contrast, calpain and cathepsin D do not
activate caspases and function downstream or independently of caspase
cascades. However, calpain, which localizes to mitochondria during
apoptosis (28), could potentially induce high molecular weight DNA
fragmentation via release of mitochondrial apoptosis inducing factor.
Although lysosomes release cathepsin D during some forms of apoptosis
(29), this proteinase does not inactivate DFF45/ICAD and its cellular substrates remain undefined. Thus, many proteinases may function in
nuclear apoptosis, but caspase-3 is the key determinant of DFF45/ICAD
inactivation and apoptotic internucleosomal DNA fragmentation.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
(Genentech) plus 10 µg/ml cycloheximide (Sigma)
or with 50 µM paclitaxel (Sigma). DNA fragmentation was assessed by agarose gel electrophoresis with ethidium bromide staining
(13, 17) and fluorescence-activated cell sorter analysis with propidium
iodide staining (17).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
Caspases, granzyme B, and cytochrome
c plus dATP initiate DEVDase activity, DFF45/ICAD
cleavage, and DNA fragmentation in a cell-free assay. Jurkat
cytosolic extracts (final concentration 12 mg of protein/ml) were
prepared as described in the text and incubated with caspase-3 (final
concentration 0.25 µM), caspase-6 (0.25 µM), caspase-7 (0.25 µM), granzyme B (50 milliunits/µl), cytochrome c (10 µM) plus
dATP (1 mM), calpain (100 nM), or cathepsin D
(50 milliunits/µl). After 30 min at 37 °C, aliquots (40 µg of
protein) of each reaction mixture were analyzed for DEVD cleaving
caspase activity (A) and subjected to Western blotting (12%
gels) with anti-DFF45/ICAD antibodies (B). 106
rat liver nuclei and EGTA (final concentration 5 mM) were
added to each reaction and the samples then incubated for an additional
2.5 h at 37 °C. DNA fragmentation was then assessed by agarose
gel electrophoresis and ethidium bromide staining (C).
Unless indicated otherwise, reactions were conducted in CAD buffer.
Note that DFF45/ICAD has a predicted molecular mass of 36.5 kDa based
on amino acid sequence (2); however, the protein and its alternatively
spliced short isoform run as bands of ~45 and ~38 kDa, respectively
(2). Cleavage at the N-terminal caspase site gives predicted products
of ~23.7 and 12.8 kDa; whereas, cleavage at the C-terminal caspase
cleavage site yields products of ~24.8 and 11.7 kDa. Hydrolysis at
both caspase sites therefore yields fragments of ~12.8, 12.0, and
11.7 kDa. In B, L and S indicate the long and
short DFF45 isoforms, I represents the intermediate caspase
cleavage products (~23.7, 24.8 kDa), and the asterisk (*)
denotes the ~12-kDa DFF45 fragments that correspond with DNA
fragmentation. In A, error bars represent the
S.E., n = 3. In B and C, the data
are representative of three independent experiments.
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Fig. 2.
Limited proteolysis of DFF45/ICAD by
caspase-3 and caspase-7, but not other apoptotic proteinases, releases
active DFF40/CAD in vitro.
35S-DFF45/ICAD and 35S-pro-DFF40/CAD (prepared
by transcription and translation of pBS-mCAD in the presence of
GST-DFF45/ICAD) were incubated with caspase-3 (0.25 µM),
caspase-6 (0.25 µM), caspase-7 (0.25 µM),
granzyme B (50 milliunits/µl), Jurkat cytosol (100 µg of protein)
activated with cytochrome c (10 µM) plus dATP
(1 mM), cathepsin D (50 milliunits/µl), or calpain (10 nM). After 1 h at 30 °C, 35S-DFF45/ICAD
(A) and 35S-DFF40/CAD (B) proteolysis
were assessed by SDS-PAGE (15% slabs) and autoradiography. In
C, pro-DFF40/CAD was incubated with proteinases or
cytochrome c plus dATP for 30 min at 30 °C.
106 rat liver nuclei and EGTA (final concentration 5 mM) were then added and after 2 additional hours DNA
fragmentation was assessed by agarose gel electrophoresis and ethidium
bromide staining. Unless indicated otherwise, reactions were conducted
in CAD buffer. L indicates the long isoform of DFF45/ICAD
used for in vitro transcription and translation.
Cleavage of DFF45/ICAD at both caspase sites gives predicted products
of 12.8, 12.0, and 11.7 kDa (*), with intermediate cleavage products of
23.7 and 24.8 kDa (I). The presented data are representative
of three independent experiments.
View larger version (58K):
[in a new window]
Fig. 3.
Caspase-3 inactivates DFF45/ICAD and
activates DNA fragmentation more efficiently than caspase-7. In
A, 35S-DFF45/ICAD (2 µl) was incubated with
caspase-3 (40 nM) or caspase-7 (40 nM) for the
indicated times at 37 °C. Reactions were terminated by denaturing
samples in Laemmli sample buffer and the products subjected to SDS-PAGE
(12% slabs) and autoradiography. In B,
35S-DFF45/ICAD (2 µl) was incubated with the indicated
concentrations of caspase-3 and caspase-7 for 30 min at 37 °C.
Samples were then denatured and analyzed by SDS-PAGE (12% slabs) and
autoradiography. In C, pro-DFF40/CAD was incubated with
106 rat liver nuclei for 2.5 h at 30 °C and the
indicated concentrations of caspase-3 and caspase-7. DNA fragmentation
was then assessed by agarose gel electrophoresis and ethidium bromide
staining. The data are representative of three independent
experiments.
View larger version (39K):
[in a new window]
Fig. 4.
Endogenous levels of caspase-7 cleave
DFF45/ICAD inefficiently and fail to promote DNA fragmentation.
Cytosolic extracts were prepared from Jurkat cells and caspase-3 null
MCF7 cells as described in the text. Extracts (final concentration 12 mg of protein/ml) were incubated at 37 °C with buffer or cytochrome
c (10 µM) plus dATP (1 mM) and
106 rat liver nuclei. At the indicated times, the nuclei
were pelleted by centrifugation and analyzed for DNA fragmentation
(C). Aliquots of the supernatant (40 µg protein) were
analyzed for DEVD cleaving caspase activity (A) and
subjected to Western blotting with antibodies against caspase-7,
DFF45/ICAD, and actin (B). In D, MCF7 extracts
were incubated with 106 rat liver nuclei and the indicated
concentrations of caspase-3. After 2.5 h at 37 °C, DNA
fragmentation was assessed by agarose gel electrophoresis and ethidium
bromide staining. In A, error bars represent the
S.E., n = 3. In B, C, and D, the
data are representative of three independent experiments.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (28K):
[in a new window]
Fig. 5.
A model of apoptotic DNA fragmentation.
The model emphasizes release of active DFF40/CAD via caspase-3
dependent inactivation of DFF45/ICAD and highlights how other apoptotic
proteinases may intersect this pathway. Note that the initiator
caspases and granzyme B function primarily via activation of
executioner caspases. Active caspase-3 is the primary inactivator of
DFF45/ICAD, but caspase-7, which may be localized to mitochondria,
plays a secondary role in DFF45/ICAD inactivation. Caspase-3 in turn
activates caspase-6, which aids in nuclear apoptosis via cleavage of
nuclear lamins. Caspase-6 can also amplify caspase-3 activity via
activation of procaspase-3. Cathepsin D and calpain apparently function
independently of caspases and DFF40/CAD, although calpain could
potentially initiate high molecular weight DNA fragmentation via
release of mitochondrial apoptosis inducing factor.
| |
ACKNOWLEDGEMENTS |
|---|
We thank Drs. Xiadong Wang, Shigekazu Nagata, Guy Salvesen, Vishva Dixit, and Emad Alnemri for reagents.
| |
FOOTNOTES |
|---|
* This is publication 325 from the La Jolla Institute for Allergy and Immunology.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§ Supported by Mentored Clinical Scientist Development Award CA75268-01. To whom correspondence should be addressed: La Jolla Institute for Allergy and Immunology, 10355 Science Center Dr., San Diego, CA 92121. Tel.: 858-558-3500; Fax: 858-558-3525; E-mail: 102251.1444@compuserve.com.
¶ Recipient of a postdoctoral fellowship from the Dr. Mildred Scheel Stiftung fur Krebsforschung.
Supported by National Institutes of Health Grants CA69831 and AI40646.
| |
ABBREVIATIONS |
|---|
The abbreviations used are: APAF-1, apoptotic proteinase activating factor-1; DFF40, DNA fragmentation factor-40; DFF45, DNA fragmentation factor-45; CAD, caspase-activated DNase; ICAD, inhibitor of caspase-activated DNase; DEVD-AFC, benzoyloxycarbonyl-Asp-Glu-Val-Asp-amino-4-trifluoro-methylcoumarin; LEHD-AFC, N-acetyl-Leu-Glu-His-Asp-AFC; ZVAD-fmk, benzoyloxycarbonyl-Val-Ala-Asp-fluoromethyl ketone; GST, glutathione S-transferase; PIPES, 1,4-piperazinediethane sulfonic acid; CHAPS, 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonic acid; PAGE, polyacrylamide gel electrophoresis.
| |
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RESULTS
DISCUSSION
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