(Received for publication, May 20, 1997, and in revised form, June 10, 1997)
From the Department of Membrane Research and Biophysics, The Weizmann Institute of Science, 76100 Rehovot, Israel
CASP-8 and CASP-10, members of a cysteine protease family that participates in apoptosis, interact with MORT1/FADD, an adapter protein in the CD120a (p55 tumor necrosis factor receptor), and CD95 (Fas/Apo-1) death-inducing signaling pathways, through a shared N-terminal sequence motif, the death effector domain. We report cloning of two splice variants of a novel protein, CASH, that contain two N-terminal death effector domains and can bind through them to each other, to MORT1/FADD, to CASP-8, and to CASP-10. The unique C-terminal part of the longer variant shows marked sequence homology to the caspase protease region yet lacks several of the conserved caspase active site residues, suggesting that it is devoid of cysteine protease activity. Overexpression of the short CASH splice variant strongly inhibited cytotoxicity induction by CD120a and CD95. Expression of the longer variant, while inhibiting cytotoxicity in HeLa cells, had a marked cytocidal effect in 293 cells that could be shown to involve its protease homology region. The findings suggest that CASH acts as an attenuator and/or initiator in CD95 and CD120a signaling for cell death.
The caspases, conserved cysteine proteases that cleave specific cellular proteins downstream of aspartate residues, play a critical role in all known programmed cell death processes (reviewed in Refs. 1 and 2). These proteases (also called the CED3/ICE proteases, after the first described members of the family) (3-6) are produced as inactive precursors and become activated by proteolytic processing upon death induction. In addition to their homologous C-terminal region from which the mature proteases are derived, the precursor proteins contain unique N-terminal regions. Interactions of these "prodomains" with specific regulatory molecules allow differential activation of the various caspases by different death-inducing signals (7-11). Two recently described caspases with similar prodomains, CASP-8 (MACH/FLICE1/Mch5) (7, 8, 12) and CASP-10 (Mch4/FLICE2) (12, 13), interact through their prodomains with MORT1/FADD (14, 15), an adapter protein in the death-signaling cascades activated by two closely related receptors of the TNF1/nerve growth factor family, CD120a (the p55 TNF receptor) and CD95 (Fas/Apo-1). This interaction, which is required for the signaling to death, involves a protein-binding motif called the "death effector domain" (DED) or the "MORT" motif, found in the N-terminal part of MORT1/FADD and in duplicate in the prodomains of CASP-8 and CASP-10.
Here we report cloning of a novel protein, CASH, that contains duplicated DED at its N terminus and binds through this region to MORT1/FADD. The C-terminal part of the protein shows marked sequence homology to the corresponding regions in CASP-8 and CASP-10 yet lacks several of the residues that are crucial for cysteine protease activity. Functional tests demonstrated an ability of the novel protein to trigger as well as to inhibit signaling for death.
CASH was cloned
by two-hybrid screening (16) of a Gal4 activation domain-tagged human
Jurkat T cell library (donated by J. H. Camonis, Curie Institute)
for proteins that bind to CASP-10 using the HF7c yeast
reporter strain (CLONTECH, Palo Alto, CA). Screening was performed in the absence of 3-aminotriazole according to
the Matchmaker Two-Hybrid System Protocol
(CLONTECH). The binding properties of CASH
, as
well as CASH
were assessed in the yeast SFY526 reporter strain
(CLONTECH) using the pGBT9-GAL4 DNA-binding domain
and the pGAD1318 and pGADGH-GAL4 activation-domain vectors. Quantification of the binding in yeast by the
-galactosidase expression filter assay was performed as described (17).
An expressed
sequence tag clone (GenBank accession number AA198928) was identified
as the mouse homologue of part of the DED region in CASH. Based on this
sequence we cloned the mouse CASH and CASH
splice variants from
mouse liver mRNA by reverse transcription-PCR. The reverse
transcriptase reaction was performed with an oligo(dT) adapter primer
(5
-GACTCGAGTCTAGAGTCGAC(T)17-3
) and the avian myeloblastosis virus reverse transcriptase (Promega) used according to
the manufacturer's instructions. The first round of PCR was carried
out with the Expand Long Template PCR System (Boehringer Mannheim)
using the following sense and antisense primers:
5
-GGCTTCTCGTGGTTCCCAGAGC-3
and 5
-GACTCGAGTCTAGAGTCGAC-3
(adapter)
respectively. The second round was performed with Vent polymerase (NEB)
using the nested sense primer 5
-TGCTCTTCCTGTGTAGAGATG-3
and
adapter.
A radiolabeled mRNA probe corresponding to the DED module region of CASH was prepared using the T7 RNA polymerase (Promega) and used for analysis of human multiple tissue blots (CLONTECH) according to the manufacturer's instructions.
Sequence AnalysesSequence alignment and homology evaluation were performed using the GAP and PILEUP programs of the GCG package and by the CLUSTAL 1.5 software. Sequence data base search was performed using the BLAST program. As parameter of homology significance we used "smallest sum probability" (P(N)), i.e. the probability of observing by chance a score or a group of scores as high as the observed ones when performing a search of the same size. The consensus for the DED region sequence was deduced from the alignment of the DED modules in MORT/FADD (14, 15), MACH/FLICE/Mch5 (7, 8, 12), Mch4/FLICE2 (12, 13), PEA-15 (18), M159, E-8 (19), and K13 (20), and the consensus for the protease-homology region was deduced from the alignment of CASP-1, 2, 3, 6, 7, 8, and 10 (21) and CED3 (3). Residues occurring in more than six of the aligned proteins were included in the consensus.
Expression VectorsThe CASH deletion mutants and the
CD120a/CD95 chimera were produced by PCR and/or conventional cloning
techniques. The CASH splice variants, the CD95 or CD120a
signaling-cascade proteins (all of human origin), and the baculovirus
p35 protein were expressed in mammalian cells using the pcDNA3
expression vector (Invitrogen).
-Galactosidase was expressed using
the pCMV-
-gal vector (Promega).
The human embryonic kidney 293-T, 293-EBNA, and 293 cells and human cervical carcinoma HeLa cells (HeLa-Fas; the HtTA-1 clone (obtained from Dr. H. Bujard)) stably expressing transfected human CD95 (established in our laboratory) were grown in Dulbecco's modified Eagle's minimal essential medium supplemented with 10% fetal calf serum, nonessential amino acids, 100 units/ml penicillin and 100 µg/ml streptomycin.
Cells (5 × 105 293 cells or 3 × 105
HeLa cells per 6-cm dishes) were transiently transfected with the
cDNAs of the indicated proteins together with the pCMV--gal,
using the calcium phosphate precipitation method. Each dish was
transfected with 5 µg of the pcDNA3 construct of interest or,
when transfecting two different constructs, 2.5 µg of each, and 1.5 µg of
-galactosidase expression vector. Cells were rinsed 6-10 h
after transfection and then incubated for a further 14 h without
additional treatment. Anti-CD95 monoclonal antibody (CH11 (Oncor,
Gaithersburg, MD), 0.5 µg/ml) and human recombinant TNF
(100 ng/ml) were applied to the cells together with cycloheximide (10 µg/ml) and incubated for an additional 4 h. Cells were then
stained with
5-bromo-4-chloro-3-indoxyl-
-D-galactopyranoside (22) and
examined by phase contrast microscopy. In all experiments shown, death
was assessed 24 h after transfection for HeLa-Fas cells and
20 h after transfection for 293 cells.
To search for the proteins that bind to CASP-10 (Mch4/FLICE2), we
performed two-hybrid screening of human Jurkat T cell cDNA library
using CASP-10 as a bait. This screen yielded cDNA clones of
MORT1/FADD, previously shown to bind to CASP-10 (13). It also yielded a
partial clone of a novel cDNA, which like CASP-8 and CASP-10,
contained two death effector (MORT) modules (7, 8, 12) just downstream
of its N terminus (Fig. 1). Because of
the similarity of the protein to the caspases (see below) it was dubbed
CASH, for caspase homologue.
Northern blot analysis revealed that the molecule exists in at least
three distinct transcript sizes, 1.5, 2.4, and 4.0 kilobase pairs (data
not shown), whose proportions vary greatly among different tissues. To
obtain the full-length cDNA of CASH, we screened human skin
fibroblast cDNA library (CLONTECH) with a
cDNA probe corresponding to the CASH sequence. We obtained two
cDNA species, apparently corresponding to two splice variants of
CASH. The proteins encoded by these two cDNAs shared the death
effector domain-containing N-terminal region, but their C termini
differed. One (CASH) had a short C terminus, corresponding to that
of the originally cloned cDNA. The other (CASH
) had a long C
terminus.
The amino acid sequence in this longer C-terminal region showed rather
high homology to those of the protease-precursor regions in CASP-8 and
CASP-10 (Fig. 1). However, it lacked several of the residues believed
to be crucial for protease activity, suggesting that the protein is
devoid of cysteine protease activity. Interestingly, CASH contains a
caspase-substrate sequence at the site corresponding to the
proteolytic-processing site within the protease regions in CASP-8 and
CASP-10 (shaded in Fig. 1). Preliminary data suggest that CASH
can
indeed be cleaved at this site by CASP-8.
Based on the nucleotide sequence of an expressed sequence tag clone
found to correspond to the mouse homologue of part of the DED region in
CASH, we cloned the cDNAs of both the mouse CASH and CASH
splice variants from mouse liver mRNA by reverse transcriptase-PCR.
Sequence comparison revealed high conservation throughout the CASH
molecule (71% identity in DED region and 59% in protease homology
region), suggesting that both the DED and protease homology regions in
the protein contribute to its function (Fig. 1).
Two-hybrid testing of the interactive properties of CASH and CASH
(Fig. 2) revealed that both variants
interact with MORT1/FADD and CASP-8, most probably through their shared
DED regions. Notably, although initially cloned by two-hybrid screening
for proteins that bind to CASP-10, CASH
was found in this test to
bind rather weakly to CASP-10, and CASH
did not bind to it at all.
The two CASH variants also self-associated and bound to each other, but did not bind RIP or TRADD (adapter proteins that, like MORT1/FADD, contain death domains but lack DEDs), nor did they bind to a number of
irrelevant proteins used as specificity controls.
To examine the function of CASH, we expressed its two variants
transiently in HeLa and 293-T cells and assessed the effects of the
transfected proteins on the CD120a-induced signaling for cytotoxicity
triggered by TNF or by overexpression of the receptor, as well as on
the CD95-induced signaling for cytotoxicity triggered by antibody
cross-linking of CD95 or by overexpression of a chimeric receptor
comprised of the extracellular domain of CD120a and the intracellular
domain of CD95 (Fig. 3). In both cell
lines, expression of CASH by itself had no effect on cell viability,
but it strongly inhibited the induction of cell death by CD120a as well
as by CD95. Expression of the CASH
variant affected the two cell
lines very differently. In HeLa cells it inhibited the cytotoxicity of
CD120a and CD95, similarly to CASH
. In the 293-T cells, however, it
resulted in marked cytotoxicity. Similar cytotoxicity was observed when
the protein was expressed in 293-EBNA cells or 293 cells (not shown).
This cytotoxic effect could be completely blocked by coexpression of
p35, a baculovirus-derived caspase inhibitor (23, 24).
To assess the contribution of the region of protease homology in
CASH to its cytocidal effect, we examined the functions of two
mutants of the protein, CASH
(1-385) and CASH
(1-408), with
C-terminal deletions at the region corresponding to that part of the
protease domain from which the small subunit of the mature protease is
derived. Both mutants were devoid of any cytotoxic effect. Moreover,
like CASH
they protected the 293 cells from death induction by
CD120a and CD95 (Fig. 3C).
The above findings indicate that CASH can interact with components of the signaling complexes of CD120a and CD95 and that it affects death induction in a way that may differ depending on the identity of the splice variant of CASH and on the cell type in which it is expressed.
The inhibition of cytotoxicity induction by CASH, and in the case of
the HeLa cells also by CASH
, is apparently mediated by the DED
region in this protein. It probably reflects competition of the DED of
CASH with the corresponding regions in CASP-8 and CASP-10 for binding
to MORT1/FADD.
Less easy to explain is the way in which CASH causes death of the
293 cells. The ability of the p35 protein to block this cytotoxic
effect indicates that the cytotoxicity is mediated by the activity of
caspases. Yet CASH
, even though displaying marked sequence homology
to the caspases is unlikely to have cysteine-protease activity because
it lacks several of the conserved caspase active site residues. A more
likely explanation is that it acts by activating other molecules that
do have caspase activity.
An intriguing possibility is that CASH, though unable to act alone
as a protease, can still constitute part of an active protease
molecule. Crystallographic studies of CASP-1 and CASP-3 structure
indicate that the small and large protease subunits in each processed
enzyme are derived from distinct proenzyme molecules (25-28). In view
of the observed dependence of the CASH
cytotoxic activity on
intactness of the region corresponding to the small protease subunit
(Fig. 3C), it is tempting to speculate that this region in
CASH
can associate with the large subunit region of certain
caspase(s) in a way that results in reconstitution of an enzymatically
active molecule. The resulting active heterotetramer should then be
capable of activating other caspases, thus triggering cell death.
The discovery of CASP-8 and CASP-10 and of their association through MORT1/FADD with CD120a and CD95 (7, 8, 13) indicates a plausible mechanism for initiation of the death-inducing cascades by the two receptors. It does not, however, provide any clue to the cause of the marked variation in effectivity of death induction by these receptors, even among cells that express the receptors, their adapter proteins, and the caspases at similar levels. Nor does it explain the frequently observed differences in effectivity of death induction by the two receptors. CASH, through its effects on the signaling for death by CD120a and CD95, which vary depending on the identity of the CASH splice variant expressed and perhaps also on the identity of the specific caspases expressed in the cell, may well contribute to these variations in cytotoxicity induction. It should be stressed, however, that transfection studies such as those described here can provide only a partial view of the function of a protein. It is conceivable that at least part of the effects observed when expressing a protein in amounts far higher than its normal levels will turn out to be unrelated to its real function. Complementing these overexpression tests by assessing the effect of decreased expression of CASH, e.g. by deleting the CASH gene, should provide a more reliable notion of the physiological role of this protein.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) Y14039 for hCASH, Y14040 for hCASH
, Y14041 for
mCASH
, and Y14042 for mCASH
.
We thank Jacques Camonis for the Jurkat T cell two-hybrid library, Mark Boldin for advice, and Sveta Boldin and Giuseppina Cantarella for assistance.