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Journal of Virology, May 2000, p. 4705-4709, Vol. 74, No. 10
Department of Microbiology and Immunology,
Albert Einstein College of Medicine, Bronx, New York 10461
Received 18 November 1999/Accepted 24 February 2000
Adenoviruses (Ad) code for immunoregulatory and cytokine regulatory
proteins, one of which is the early region 3, 14.7-kDa protein (Ad
E3-14.7K), which has been shown to inhibit tumor necrosis factor
alpha-induced apoptosis. In an effort to understand the mechanism of
action of Ad E3-14.7K, we previously searched for cell proteins with
which it interacted. Three Ad E3-14.7K-interacting proteins (FIP-1, -2, and -3) were isolated. FIP-1 is a small GTPase which was used in this
report as bait in the yeast two-hybrid system to find other interacting
cell targets. The search resulted in the isolation of a protein, which
we called GIP-1 (GTPase-interacting protein) that subsequently was
shown to be identical to one of the light-chain components of human
dynein (TCTEL1). FIP-1 was able to bind both TCTEL1 and Ad E3-14.7K
simultaneously and was necessary to form a complex in which the viral
protein was associated with a microtubule-binding motor protein. The
functional significance of these interactions is discussed with respect
to the steps of the Ad life cycle which are microtubule associated.
Adenoviruses express several
proteins which downregulate the host's immune response (32,
34). It has been postulated that these immunoregulatory and
cytokine-regulatory proteins either prevent early cell lysis before the
production of viral progeny during acute infection or enable the virus
to establish a state of persistence or latency within the host
(reviewed by Lukashok and Horwitz [17]). The
adenovirus genes which code for many of these proteins are clustered in
early transcription region 3 (E3). The type 2 adenovirus E3 14.7-kDa
protein, named Ad E3-14.7K, is one of seven gene products expressed in
this region and is a small hydrophilic protein which inhibits tumor
necrosis factor alpha (TNF- Because the mechanism by which Ad E3-14.7K exerts its anti-TNF- A protein identical to FIP-1 was independently isolated using
degenerate oligonucleotide primers from conserved sequences in other
GTPases and was named RagA (21). RagA appears to be involved
in the Ran/Gsp 1 GTPase pathway responsible for nucleus-cytoplasm trafficking of macromolecules (7). Ran-GTP has also recently been associated with cell cycle control by affecting aster formation induced by chromosome-binding protein RCC1 at centrosomes and controlling microtubule assembly originating from this structure during
mitosis (18, 31). The involvement of FIP-1/RagA in this
process has been inferred because of mutational analysis in the yeast
homologues of human RCC1 (PRP20) and FIP-1 (GTR1). In order to
determine cell proteins that might be involved, together with FIP-1, in
these cell signaling pathways, FIP-1 was used as bait in the yeast
two-hybrid system. This search identified a human protein, which we
initially named GTPase-interacting protein 1 (GIP-1). However, in view
of the subsequent publication of the sequences of light chains (LC) of
mouse and human dyneins, GIP-1 appears to be identical to TCTEL1, the
human homologue of one of the three LC (Tctex-1) of mouse dynein
(11, 29). Dynein is part of the molecular motor system,
which is located at the negative ends of microtubules near the nuclear
membrane. Microtubules have been shown to be involved in many transport
processes including movement of adenovirus, herpes simplex virus, and
cytoplasmic organelles such as endosomes from the plasma membrane to
the nuclear membrane (16, 23, 24, 30). Our studies show that
Ad E3-14.7K can be found in a complex with GIP-1/TCTEL1 but only when
FIP-1 (RagA) is present as a bridging protein. These observations
appear to link two pathways: (i) the Ran-GTP effects either on
nucleus-cytoplasm transport or on centrosome formation and (ii) the
dynein-microtubule effects on transcytoplasmic transport of organelles,
viruses, and signal transduction molecules.
Cell lines.
For cotransfection and immunofluorescence
labeling of cells, E293 human embryonic kidney cells and A549 human
lung cells, respectively, were used. These cells were maintained in
Dulbecco's modified Eagle's medium supplemented with 10% fetal
bovine serum, 2 mM glutamine, 50 U of penicillin/ml, and 50 µg of
streptomycin/ml. For coimmunoprecipitation experiments requiring
radioactive labeling of proteins, T293 cells which express simian virus
40 T antigen were used. T293 and E293 cells were maintained in an
identical manner.
Plasmid constructs.
pBMT-FIP-1, the bait, was constructed by
cloning the FIP-1-8a cDNA in frame at the C terminus of the coding
sequence for the LexA domain. pBMT116 was linearized by digestion with
SmaI and SalI, and the FIP-1-8a cDNA was inserted
between the restriction sites. Construction of pcDNA-T7 and pcDNA-FLAG
from pcDNA-3 (Invitrogen) has been previously described
(15). pcDNA-T7-GIP-1 was made by excising the GIP-1 cDNA
from the pGAD vector at the BamHI and XhoI sites
and inserting it in pcDNA-T7 linearized with BamHI and
XholI. pcDNA-FLAG-FIP-1 was made by excising the FIP-1 cDNA from pBMT-FIP-1 at the EcoRI and XhoI restriction
sites and cloning it into the pcDNA-FLAG plasmid with FLAG expressed at
the 5' end of the FIP-1 coding sequence. For the glutathione
S-transferase (GST) assay, the pGEX-FIP-1 construct,
previously described (15) was used. pCITE-GIP-1 was
constructed by inserting the GIP-1 clone into the pCITE plasmid
(Novagen) at the BamHI and XhoI sites. All
constructs were confirmed by sequencing. The pcDNA-FLAG-RIP plasmid was
obtained from David Wallach, Weizmann Institute. The pcDNA-CMV-GFP
plasmid, which expresses green fluorescent protein, was previously
described (12).
The yeast two-hybrid screen and specificity test.
The yeast
two-hybrid screen has been previously described (15, 19,
20). The pBMT-FIP-1 was used as the bait to screen a HeLa cDNA
library expressed as fusion proteins with the Gal 4 activation domain.
The screening was done with Saccharomyces cerevisiae L40
yeast, which expresses reporter genes conferring histidine auxotrophy
and Northern blots of GIP-1.
A Northern blot of human tissues
(Clontech) was probed with GIP-1 cDNA labeled with
[32P]dCTP (Pharmacia) according to the manufacturer's directions.
Coimmunoprecipitation of FIP-1 and GIP-1.
Human T293 cells
were grown as a monolayer in 10-cm-diameter dishes and transfected with
4 µg of either pcDNA-FLAG-FIP-1 or pcDNA-T7-GIP-1 or with both
plasmids (2 µg of each) using Lipofectamine (Gibco). Twenty-four
hours after transfection, the cells were labeled with
[35S]methionine and -cysteine (1 mCi/ml) in methionine-
and cysteine-free medium for 3 h at 37°C. Cells were scraped
from the dish, washed with ice-cold phosphate-buffered saline (PBS),
and lysed with ice-cold lysis buffer (150 mM NaCl, 50 mM Tris-HCl [pH
8], 1% Nonidet P-40 [NP-40], 1 mM phenylmethylsulfonyl fluoride
(PMSF), aprotinin [1 µg/ml], leupeptin [1 µg/ml]) for 30 min at
4°C on a rotating platform. ATP (5 mM) was added to the solution to
prevent GIP-1 precipitation (10). Samples were preincubated
with protein A- and protein G-agarose (Santa Cruz Biotechnology) and
briefly centrifuged at 13,000 × g; 500 µl of each
sample was immunoprecipitated with 1 µg of monoclonal anti-T7
antibody (Novagen), and 500 µl of each sample was precipitated with 1 µg of monoclonal anti-FLAG antibody (Sigma) for 1 h on a rocking
platform at 4°C. Forty microliters of protein A and protein G beads
(50% [wt/vol] was added to the lysate, and the mixture was incubated
an additional hour at 4°C. The beads were washed three times with
ice-cold lysis buffer and resuspended in 40 µl of Laemmli buffer (2%
sodium dodecyl sulfate [SDS], 10% glycerol, 100 mM dithiothreitol,
60 mM Tris [pH 6.8], 0.001% bromphenol blue) and boiled. After
centrifugation, samples were analyzed by SDS-10% polyacrylamide gel
electrophoresis (PAGE). The gel was dried and exposed to X-ray film (Kodak).
GST assay to test for specific in vitro binding between FIP-1 and
GIP-1.
The GST binding assay has been previously described
(2, 15). The GST-FIP-1 fusion protein was expressed in
Escherichia coli and bound to glutathione beads as
previously described. The single tube protein 2 T7 assay (Novagen) was
used to translate and transcribe pCITE-GIP-1 into the coding sequence
for [35S]methionine-labeled GIP-1 protein. An aliquot of
35S-labeled GIP-1 was incubated with an aliquot of
glutathione beads with either bound GST-FIP-1 or GST alone for 1 h at 4°C. The beads were washed three times with 1 M NaCl-NETN buffer
(1 mM EDTA, 50 mM Tris-HCl [pH 8.0], 0.5% NP-40, 1 mM PMSF) and then
once with 0.1 M NaCl-NETN buffer. the beads were resuspended in Laemmli buffer, heat denatured, and subjected to SDS-12% PAGE followed by autoradiography.
In vitro cotranslation of GIP-1, FIP-1, and Ad E3-14.7K.
GIP-1, FIP-1 and Ad E3-14.7K were translated as T7- or FLAG-tagged
pcDNA 3.1 plasmids either alone or in various combinations by the
single tube protein 3 T7 assay (Novagen) according to the manufacturer's protocol. 35S-labeled proteins were
incubated with anti-T7 monoclonal antibodies, anti-Ad E3-14.7K rabbit
polyclonal antibodies, or anti-FIP-1 antibodies for 1 to 2 h at
4°C following precipitation with protein A- and protein G-agarose
(Santa Cruz Biotechnology) for 1 h at 4°C. The beads were washed
three or four times with ice-cold PBS containing 1% NP-40 and a
cocktail of protease inhibitors (Boehringer). The labeled proteins were
eluted by boiling for 5 min in Laemmli buffer. After SDS-PAGE, the gel
was dried and exposed to X-ray film (Kodak). Polyclonal anti-FIP-1
antibodies were produced in rabbits using an N-terminal peptide linked
to keyhold limpet hemocyanin.
Flow cytometric analyses of cell cycle status and apoptosis.
Transfected or untransfected cells (E293) were harvested, washed in
ice-cold PBS, and fixed in 70% ethanol for 1 h. After an
additional wash in PBS, 3 × 104 to 5 × 104 cells were resuspended in propidium iodide solution (10 µg/ml) with DNase-free RNase (20 u/ml) in PBS. After 30 min at 37°C
in the dark followed by filtration through a 35-mm-diameter cell strainer cap (Falcon), the cell cycle status was tested by flow cytometry on a FACSort (Beckton Dickinson). The number of sub-G1 phase
cells is a measure of the number of cells undergoing apoptosis (5). Apoptosis also was estimated by direct microscopy in
living cells by cotransfection of various plasmids together with
pcDNA-CMV-GFP as described previously (12).
FIP-1 interacts specifically with the cell protein
GIP-1/ TCTEL1 in the yeast two-hybrid assay.
By using the
yeast two-hybrid assay, we have identified a specific interaction
between FIP-1 and the cell protein which we initially named GIP-1.
GIP-1 was isolated in 19 of 44 colonies tested. In the yeast two-hybrid
assay, GIP-1 did not interact with a battery of unrelated baits, i.e.,
hLamin-C, mMyc TAD, mMyc bHLH, mMaxI, Ad E1B-19K, or Bcl-2 proteins,
thus confirming that the interaction between FIP-1 and GIP-1 was specific.
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
An Adenovirus Inhibitor of Tumor Necrosis Factor
Alpha-Induced Apoptosis Complexes with Dynein and a Small
GTPase
and
ABSTRACT
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
INTRODUCTION
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
)-mediated cell killing. Its mechanism of
action remains incompletely understood (8), but it has been
shown that Ad E3-14.7K does not affect the number of TNF- receptors
or the affinity of TNF- for its receptor (6, 33). Ad
E3-14.7K inhibits the TNF--induced activation of cytoplasmic
phospholipase A2, an enzyme that results in the release of arachidonic
acid from the cell membrane (35). It has also been reported
that Ad E3-14.7K binds to caspase 8 and prevents cell killing by
inhibiting this caspase (1), but additional observations
have failed to confirm the importance of this interaction (Horwitz et
al., personal observations). Tufariello et al. (27, 28)
demonstrated an in vivo effect of Ad E3-14.7K by showing that mice
infected with a vaccinia virus expressing both Ad E3-14.7K and TNF-
had a more severe pulmonary pathology, a higher mortality rate, and
higher viral titers than mice infected with a vaccinia virus expressing
TNF- alone (27, 28). These data support the conclusion
that Ad E3-14.7K counteracts the inflammatory and antiviral protective
effects of TNF- in an in vivo model of viral infection.
effect remains incompletely understood, we used the yeast two-hybrid
system to look for proteins which interact with Ad E3-14.7K
(15). Proteins from a HeLa cell (human) library were identified and named Ad E3-14.7K-interacting proteins (FIPs). BLAST
sequence analysis revealed that one of these, FIP-1, was a member of a
new family of low-molecular-weight (LMW) GTPases (15, 21).
FIP-1 associated with various phosphorylated proteins in the presence
of TNF-, suggesting that it is involved in TNF- signaling
pathways (15). It has two regions of homology with bacterial
proteases, although no proteolytic function has yet been demonstrated.
FIP-1 colocalized with Ad E3-14.7K in a perinuclear structure and
at the cell membrane.
MATERIALS AND METHODS
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
-galactosidase activity. The screening was carried out in
histidine-deficient medium supplemented with 35 mM 3-aminotriazole, and
2 × 107 colonies were screened. Specificity of the
GIP-1 clone was confirmed by cotransforming S. cerevisiae
with pGAD-GIP-1 and each of four control proteins expressed in the bait
vector to look for His auxotrophy and -galactosidase activity. The
proteins were the basic helix-loop-helix domain (bHLH) of mouse c-myc
(mMyc), the transactivation domain (TAD) of mMyc, mouse MaxI (mMaxI),
and human lamin (hLamin). GIP-1 was also tested against Ad E1B-19K and
Bcl-2 to see if it interacted with known antiapoptotic proteins. hLamin, bHLH TAD, and mMaxI were generously provided by Ron DePinho, Albert Einstein College of Medicine. Bcl-2 and Ad E1B-19K were provided
by R. Chinnaduri, St. Louis University, St. Louis, Mo. The HeLa cell
library was provided by Greg Hannon and David Beach, Cold Spring Harbor
Laboratory, and amplified according to standard protocols.
RESULTS
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
View larger version (19K):
[in a new window]
FIG. 1.
Comparison of the sequence of a human library-derived
clone of GIP-1 and mouse Tctex-1. The cDNA sequence was derived from
clones from the yeast two-hybrid screening. Polypeptide primary
structures were deduced by using conventional genetic codons through
the computerized program GCG (Genetics Computer Group, Madison, Wis.).
GIP-1 was found to be identical to TCTEL1 (29).
GIP-1/TCTEL1 mRNA is expressed in many human tissues.
A
Northern blot of eight human tissues was probed with a GIP-1/TCTEL1
cDNA probe, and the mRNA of the protein was detected in all tissues
except human brain, with the highest levels in skeletal muscle. The
probed band measured approximately 1 kb, which is consistent with the
size of the full-length GIP-1/TCTEL1 clone (Fig.
2).
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FIP-1 binds specifically to GIP-1/TCTEL1 in vitro and in vivo and
does not require the addition of TNF-.
The interaction between
FIP-1 and GIP-1/TCTEL1 revealed by the yeast complementation assay was
further confirmed by in vitro and in vivo binding assays. The
GST-FIP-1 fusion protein bound to glutathione beads retained
GIP-1/TCTEL1 specifically, while there was no binding between GST alone
and GIP-1/TCTEL1 (Fig. 3A).
|
. Analysis of the cells overexpressing the immunofluorescent
FIP-1 and GIP-1/TCTEL1 had shown that both proteins colocalized in the
cytoplasm of transiently transfected cells (data not shown).
FIP-1 promoted complex formation between GIP-1/TCTELI and Ad
E3-14.7K.
The in vitro system was used for studying the
interactions between GIP-1/TCTEL1, FIP-1, and Ad E3-14.7K. When
GIP-1/TCTEL1 and Ad E3-14.7K were cotranslated in the reticulocyte
lysate system and immunoprecipitated by an antibody to Ad E3-14.7K, no
GIP-1/TCTEL1 was detected in the immunoprecipitate (Fig.
4, lane 5). In contrast, transcription
and translation in vitro of Ad E3-14.7K and FIP-1 together followed by
immunoprecipitation with an antibody to Ad E3-14.7K resulted in the
detection of FIP-1 and Ad E3-14.7K in the immunoprecipitate (Fig. 4,
lane 6) as had been shown previously in vivo (15). Because
FIP-1 binds to both GIP-1/TCTEL1 (Fig. 4, lane 7) and Ad E3-14.7K but
the latter two proteins do not bind directly, it was possible to show
that FIP-1 promoted the formation of a complex containing both
GIP-1/TCTEL1 and Ad E3-14.7K (Fig. 4, lanes 8 to 10).
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Overexpression of GIP-1/TCTEL-1 does not affect cell cycle
progression or lead to cell death.
Because GIP-1/TCTEL1 formed a
complex with the Ad E3-14.7K inhibitor of TNF- cytolysis, we studied
whether GIP-1/TCTEL1 would either cause or prevent apoptosis. When
GIP-1/TCTEL1 was overexpressed in 293 cells, the cells maintained their
normal morphology both in medium with 10% serum and in the absence of
serum, as detected by coexpression with a green fluorescent protein
expressing plasmid (data not shown). This was confirmed by
fluorescence-activated cell sorter analysis of propidium iodide-stained
transfected cells, which showed few cells with subdiploid amounts of
DNA and no cell cycle differences between FIP-1-transfected,
GIP-1/TCTEL1-transfected, and cotransfected cells (Fig. 5A to
D). As a positive control, FIP-3-transfected cells, some of which do undergo apoptosis
(13), are shown in the inset of Fig. 5D. An increase in the
number of cells with subdiploid amounts of DNA and a decrease in the
number of cells in G1 are shown. When GIP-1/TCTEL1 was
overexpressed in combination with the receptor-interacting protein
(RIP), the apoptotic effects of RIP were not reversed (data not shown).
These results suggest that the GIP-1/TCTEL1 is not directly involved in
TNF- apoptotic pathways.
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DISCUSSION |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Using a yeast two-hybrid assay, we have determined that FIP-1, a LMW GTPase, binds specifically to GIP-1. Although there is no direct interaction between GIP-1 and Ad E3-14.7K, the complex containing FIP-1 and GIP-1 is also able to bind the Ad E3-14.7K protein. BLAST analysis revealed that GIP-1 has a very high degree of homology with the mouse Tctex-1 protein, which has been identified as one of the LC of cytoplasmic dynein (10, 11, 29).
The mouse Tctex-1 protein is encoded in the t complex, a large region on chromosome 17 which is implicated in transmission ratio distortion. This is a process whereby a chromosomal haplotype is not inherited in a Mendelian fashion, but rather is preferentially passed on to the offspring. In mice, heterozygous males pass the t haplotype to 99% of their offspring and males homozygous for the t haplotype are sterile. The exact mechanism of transmission ratio distortion remains unknown. In 1996, King et al. determined that Tctex-1 is the 14-kDa LC of cytoplasmic dynein (10). It therefore seems that Tctex-1, either alone or in association with cytoplasmic dynein, plays a role in the transmission of ratio disorder and male sterility in mice.
Dyneins are energy-dependent motor proteins. Axonal dynein mediates flagellar movement, while cytoplasmic dynein is involved in the translocation of cellular organelles. Cytoplasmic dynein is a multimer made up of two heavy chains, a 74-kDa intermediate chain, and three LC molecular masses of 8, 14, and 22 kDa. King et al. isolated, purified, and characterized the 14-kDa LC, thus determining that it is a 113-amino-acid protein. GIP-1/TCTEL1 is also 113 amino acids long and has 93% homology with the mouse Tctex-1 protein; therefore, we conclude that GIP-1 is the 14-kDa LC of dynein.
The concept that Ad E3-14.7K associates with FIP-1, which associates with the LC of dynein, is indeed provocative. There have been a number of reports of adenovirus type 5 associating with microtubules and cytoskeletal elements. It has been shown by electron microscopy that the adenovirion binds to microtubules, and it was hypothesized that this represents a mechanism to vectorially transfer virions from the cell membrane to the nucleus (4). These early studies were confirmed and extended to show that binding was specifically between the hexon protein and microtubules (16). Further data suggested that cytoplasmic dynein plays a role in translocating adenovirus to the cell nucleus (P. L. Leopold, G. Kreitzer, S. Rempel, K. K. Pfister, and R. Crystal, Abstr. 1st Ann. Meet. Am. Soc. Gene Ther., p. 178a, 1998). The rate of movement of adenoviruses toward the negative ends of the microtubules, which are nearest the nuclear membrane and which contain dynein with the TCTEL1 subunit, was determined recently (23). This study showed that even early after infection there was some bidirectional movement toward the positive microtubule end, which is placed near the plasma membrane and which is the site of the exit of adenovirus from the endosome. However, in the first hour postinfection, the net vectorial movement during a productive infection is toward the nucleus. In addition to the binding of Ad E3-14.7K to a component of microtubules mediated by the FIP-1 cell protein, another adenovirus E3 protein, gp19K, which interacts with class I major histocompatibility complex (MHC-I) molecules, has been reported to bind directly to microtubules (3). This was proposed as a mechanism for anchoring or retaining MHC-I molecules in the endoplasmic reticulum and downregulating cell surface expression of this immunoregulatory protein (3).
The conceptual problem with proposing that Ad E3-14.7K is involved in the transport of virus across the cytoplasm during viral entry is that this virally encoded protein is not a structural component of the virion. Ad E3-14.7K is synthesized only after entry of the viral DNA into the nucleus, viral mRNA transcription, and subsequent translation. Unless viral entry during natural infections can be sequential over 10 to 12 h (25), it is unlikely that Ad E3-14.7K plays a functional role in viral entry or transport across the cytoplasm. However, during exit of the virus from its assembly site in the nucleus, Ad E3-14.7K may function, perhaps together with the ADP (adenovirus death protein), another E3 protein that has been implicated in the exit of the virus from the nucleus and viral spread (26). Alternatively, Ad E3-14.7K may function in the cytoplasm-nucleus-shuttling of the myriad of viral macromolecules that undergo intracellular migration during viral infection. Some of these steps are virus specific, such as the exit of viral mRNA from the nucleus; however, the retention of host mRNA in the nucleus during the late phase of the adenovirus cycle has been reported to be a function of adenovirus E1 and E4 (23).
The association of Ad E3-14.7K, an LMW GTPase and the LC of dynein brings together a number of molecules that could control the formation of the microtubule spindle and centrosomes, which are important in mitosis. Indeed, the net effect of adenovirus infection in human cells is the inhibition of mitosis, although there are a number of adenovirus early gene products, primarily from E-1 (E1A and E1B), which promote entry of the cells into the S phase (9, 22).
The functional significance of our finding that Ad E3-14.7K can be
complexed with dynein is still unknown, although we hypothesize that it
is one step in the mechanism of action of Ad E3-14.7K. It is also
possible that the FIP-1-GIP-1/TCTEL1 complex may be involved in
transporting the Ad E3-14.7K protein itself to its destined site of
action, or in mediating signals initiated by Ad E3-14.7K in its role as
an inhibitor of TNF--induced cell death. We have shown that Ad
E3-14.7K is capable of inhibiting cell death induced by a number of
molecules on the TNF--induced cell signaling pathway (13,
14). These molecules include the TNF- receptor, RIP, and a
recently isolated protein (FIP-3/IKK
), all of which can induce cell
death after transfection (13). However, overexpression of
GIP-1/TCTEL1 did not cause cell death, nor did it counteract the effect
of RIP, a mediator of cell death, suggesting that the Ad E3-14.7K
protein may have an additional role other than as a modulator of
TNF- cytolysis.
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ACKNOWLEDGMENTS |
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S. Lukashok and L. Tarassishin contributed equally to the results.
This research was supported by NIH grant RO1 CA72963 (M.S.H., L.T.), the Oncology Research Faculty Development Program (L.T.), and Cancer Center of the Albert Einstein College of Medicine grant P30-CA13330.
We gratefully acknowledge the assistance of Michael Cammer of the Analytical Imaging Facility, David Gebhard of the FACS Facility, and W.S.M. Wold (St. Louis University School of Medicine, St. Louis, Mo.) for antibodies against Ad E3-14.7K.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Microbiology and Immunology, Albert Einstein College of Medicine, 1300 Morris Park Ave., Bronx, NY 10461. Phone: (718) 430-2230 or -2083. Fax: (718) 430-8702. E-mail: horwitz{at}aecom.yu.edu.
Present address: Emory University, Atlanta, Ga.
Present address: Glaxo Wellcome, Research Triangle Park, N.C.
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Materials and Methods
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Discussion
References
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Journal of Virology, May 2000, p. 4705-4709, Vol. 74, No. 10
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