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Previous Article | Next Article 
Journal of Virology, June 1999, p. 4631-4639, Vol. 73, No. 6
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Herpesvirus Ateles Gene Product Tio Interacts with
Nonreceptor Protein Tyrosine Kinases
Jens-Christian
Albrecht,1,*
Ute
Friedrich,1
Christian
Kardinal,2
Jadranka
Koehn,1
Bernhard
Fleckenstein,1
Stephan M.
Feller,2 and
Brigitte
Biesinger1
Institut für Klinische und Molekulare
Virologie, Universität Erlangen-Nürnberg, 91054 Erlangen,1 and Institut für
Medizinische Strahlenkunde und Zellforschung, Universität
Würzburg, 97078 Würzburg,2 Germany
Received 23 November 1998/Accepted 10 March 1999
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ABSTRACT |
Herpesvirus ateles is a gamma-2-herpesvirus which naturally infects
spider monkeys (Ateles spp.) and causes malignant
lymphoproliferative disorders in various other New World primates. The
genomic sequence of herpesvirus ateles strain 73 revealed a close
relationship to herpesvirus saimiri, with a high degree of variability
within the left terminus of the coding region. A spliced mRNA
transcribed from this region was detected in New World monkey T-cell
lines transformed by herpesvirus ateles in vitro or derived from T
cells of infected Saguinus oedipus. The encoded viral
protein, termed Tio, shows restricted homology to the oncoprotein
StpC and to the tyrosine kinase-interacting protein Tip, two gene
products responsible for the T-cell-transforming and oncogenic
phenotype of herpesvirus saimiri group C strains. Tio was detectable in lysates of the transformed T lymphocytes. Dimer formation was observed
after expression of recombinant Tio. After cotransfection, Tio was
phosphorylated in vivo by the protein tyrosine kinases Lck and Src and
less efficiently by Fyn. Stable complexes of these Src family kinases
with the viral protein were detected in lysates of the transfected
cells. Binding analyses indicated a direct interaction of Tio with the
SH3 domains of Lyn, Hck, Lck, Src, Fyn, and Yes. In addition,
tyrosine-phosphorylated Tio bound to the SH2 domains of Lck, Src, or
Fyn. Thus, herpesvirus ateles-encoded Tio may contribute to viral
T-cell transformation by influencing the function of Src family kinases.
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INTRODUCTION |
Two simian viruses, herpesvirus
saimiri (HVS) and herpesvirus ateles (HVA), have been isolated from
squirrel (Saimiri sciureus) and spider (Ateles
spp.) monkeys, respectively. They have proven unique in the ability to
induce T-cell lymphomas and leukemias in several New World primate
species cognate to the natural hosts. HVS and HVA are related viruses
of the genus Rhadinovirus (gamma-2-herpesviruses) which
differ in their biological properties (reviewed in reference 28). While genomic sequences in general are well
conserved among these rhadinoviruses, the far left ends of the coding
sequences display a pronounced variability (1, 2, 23, 58, 66, 67,
73). In the case of HVS, this led to the classification of the
viral isolates into subgroups A, B, and C (53). The
divergence correlated with differences in the ability of HVS strains to
immortalize T lymphocytes in vitro (4, 72).
Sequence analyses of this variable region revealed open reading frames
for all of the HVS isolates examined. Subgroup A strains code for StpA
(saimiri transformation-associated protein of group A) (48,
57), the corresponding reading frame of subgroup B isolate SMHI
was designated StpB (3), and two open reading frames in
subgroup C genomes give rise to StpC and Tip (5, 31). The
viral proteins have only limited sequence similarities. A hydrophobic
carboxy terminus is common to all of these proteins and probably serves
as a membrane anchor (3, 38, 42, 51). The amino-terminal
parts of StpA, StpC, and Tip are rich in acidic amino acids
(42). The central region of StpC consists of 18 consecutive
collagen-like triplets (Gly-X-Y, where X and/or Y represent Pro), and
individual triplets are spread over the amino-terminal halves of StpA
and StpB (3, 42). Spontaneous and targeted viral deletion
mutants of subgroup A and C strains indicated that these proteins are
not required for virus replication but are responsible for the
oncogenic phenotype of these viruses in vitro and in vivo (13, 14,
18, 43, 44, 52). StpA and StpC were also shown to be oncogenic in
the absence of other viral factors. Both proteins were found to be
sufficient to transform rodent fibroblast cells in vitro
(42). In addition, mice carrying an StpC-encoding transgene
developed malignant epithelial tumors (56), while animals
with a StpA-encoding transgene developed peripheral T-cell lymphomas
(46).
The transforming effects are supposed to be mediated by cellular
factors interacting with the viral proteins. StpA was found to interact
with cellular Src and, after phosphorylation by Src, bound to Lck and
Fyn kinase Src homology 2 (SH2) domains in vitro (48). SH2
domains generally consist of about 150 amino acids and directly bind to
phosphotyrosine residues. Specificity of distinct SH2 domains is
determined by flanking sequences of the tyrosine residues (69,
70). The tyrosine-containing motif of StpA (V/IYAEV/I) represents
the consensus for optimal binding to the SH2 domain. The tyrosine
residue within this domain is required for interaction with Src
(48). In contrast, StpC associates with cellular Ras and
activates mitogen-activated protein kinase (39). In the
viral context, active Ras may substitute for StpC in viral
transformation (34), indicating that Ras is indeed a major
effector of the transforming functions of StpC. However, StpC alone did
not induce detectable alterations of the T-cell compartment in
transgenic mice (56). Additional viral factors were
suspected to determine the cell tropism of viral transformation. This
function was attributed to the tyrosine kinase-interacting protein Tip,
which has been shown to associate with the lymphocyte-specific kinase
Lck (6, 51).
This interaction was found to be mediated by a region of Tip
containing a proline-rich Src homology 3 (SH3)-binding (SH3B) motif, a
motif referred to as the C-terminal Src kinase homology (CSKH) motif,
and a spacer sequence between SH3B and CSKH (40). On the
other hand, the SH3 domain of Lck has been shown to be sufficient to
form a stable complex with Tip in vitro (41). SH3 domains
are protein modules mediating protein-protein interactions with short,
specific, proline-rich sequences that possess a left-handed polyproline
type II helix structure (25, 26, 65). The consequences of
the Tip-Lck interaction have been controversial, ranging from inhibition of Lck-mediated signal transduction by Tip to dramatic stimulation of Lck signaling and increased Lck phosphotransferase activity in cell-free systems (41, 50, 59, 75). HVS
expressing an SH3B mutant form of Tip (Pro to Ala) effectively
transformed T lymphocytes in vivo and in vitro, leading to the
assumption that Lck interaction is not necessary for the Tip effector
function (19). A novel Tip-associated protein, Tap, might
instead be the mediator of Tip functions essential for transformation.
Stable expression of Tap together with Tip in Jurkat cells induced the surface expression of adhesion molecules, leading to lymphocyte aggregation and NF-
B activation (77).
While HVS has been studied extensively during the last 2 decades, very
little is known about HVA. In this report, we describe the HVA strain
73-encoded protein Tio, which shares homologies with HVS oncoprotein
StpC and with Lck-interacting protein Tip. This protein appears to be
functionally related to HVS proteins StpA and StpB, as well as to Tip.
Thus, Tio is considered to be the prime candidate for a novel oncogene
encoded by HVA strain 73.
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MATERIALS AND METHODS |
Cells, virus, and cell culture.
Owl monkey kidney (OMK)
cells (12) (OMK 637 [ATCC CRL 1556]) and 293T cells
(20, 63) were kept in Dulbecco modified Eagle medium
supplemented with 10% fetal bovine serum, L-glutamine, streptomycin, and penicillin. Virus was propagated on permissive OMK
cells by following standard protocols (27). HVA strain 73 was originally isolated from lymphocytes by cocultivation with permissive cell cultures from a healthy spider monkey (Ateles paniscus) imported from Colombia. Marmoset cell line A661 was isolated after in vitro transformation of cotton-topped marmoset (Saguinus oedipus) lymphocytes (28), cell line
A1022 was obtained after isolation of lymphocytes from an S. oedipus marmoset infected with HVA strain 73 (24).
Lymphoid cell lines were cultured in RPMI 1640 medium supplemented with
10% fetal bovine serum, L-glutamine, streptomycin, and
penicillin but without exogenous interleukin-2. Cell line A17 was
established from the spleen of an S. oedipus marmoset
infected with HVS strain A11, cell line B1 was isolated from an
S. oedipus marmoset after infection with HVS group B strain SMHI, and cell line C37 was established from a lymph node of an S. oedipus marmoset infected with HVS strain C-488.
Molecular cloning of Tio, expression cloning, and recombinant
proteins.
The genomic sequence of the Tio-encoding gene was
obtained in the course of the sequencing of the complete genome of HVA
strain 73 as previously described (1). mRNA was isolated
from cell lines A661 and A1022, reverse transcribed, and amplified by
PCR using primers corresponding to the 5' end of orf2 and
oligo(dT) or a primer derived from the 3' end of orf1. To
facilitate cloning, restriction enzyme recognition sites and sequences
corresponding to the Flag or AU1 epitope tag were attached to the
primer sequences, resulting in N-terminally tagged proteins. Identity
to the genomic sequence was confirmed for all derived clones by
automated DNA sequencing on an ABI377 sequencer. Tio cDNA was cloned
into pGEX-2TK with or without a Flag epitope tag to give glutathione
S-transferase (GST) fusion proteins. These proteins were
expressed in standard Escherichia coli XL2-Blue bacteria or
in bacteria expressing a constitutively active Elk-1 tyrosine kinase
(47) (TKX1; Stratagene, La Jolla, Calif.). After affinity
chromatography using glutathione-Sepharose CL4B, Flag epitope-tagged
Tio (Flag-Tio) and untagged Tio were purified by thrombin cleavage of
GST-Flag-Tio in accordance with the manufacturer's (Amersham Pharmacia
Biotech, Freiburg, Germany) instructions. Eukaryotic expression clones
were constructed by cloning of Tio, Flag-Tio, or AU1 epitope-tagged Tio
(AU-Tio) into pcDNA3 (Invitrogen, Carlsbad, Calif.). Human Lck was
cloned into the pFJ expression vector (41), pFJ-Src was
obtained from S. M. Lang, Erlangen, Germany (17), and
human Fyn (21) was cloned into the pcDNA-3.1(
)/Myc-HisA
vector (Invitrogen). GST-SH3 fusion proteins used for fluorescence
spectrometry were expressed and purified as previously described
(60). The functionality of these fusion proteins has been
previously described.
Antisera, antibodies, and synthetic peptides.
Anti-Tio serum
was raised in rabbits immunized with purified GST-Tio or with Tio
protein whose GST tag had been removed through site-specific
proteolysis with thrombin. The antiserum was used at a dilution of
1:5,000. Antibodies against Src family kinases were purchased from
Santa Cruz Biotechnologies (Santa Cruz, Calif.), Pharmingen (San Diego,
Calif.), Upstate Biotechnology Inc. (Lake Placid, N.Y.), or
Transduction Laboratories (Lexington, Ky.). Horseradish peroxidase
(HRP)-conjugated secondary antibodies were purchased from Dako
(Hamburg, Germany), Jackson Immunoresearch Laboratories (Dianova,
Hamburg, Germany), or Medac (Hamburg, Germany). Anti-myc hybridoma cell
line 9E10 was obtained from the American Type Culture Collection (ATCC
CRL-1729), and tissue culture supernatants were used at a dilution of
1:100. Antiphosphotyrosine monoclonal antibody PY99 (unconjugated or
HRP coupled) was purchased from Santa Cruz Biotechnologies and used at
a dilution of 1:3,000. Synthetic peptides were synthesized and purified
at the Institute for Biochemistry, University of Erlangen. The
authentic sequences of the peptides were determined by mass spectrometry.
Transient transfection, immunoprecipitation, and
immunoblotting.
293T cells were transfected with plasmid DNA by
using a CaCl2 transfection method. Briefly, cells were
distributed among the wells of six-well plates. The next day, each well
was fed with 3.6 ml of complete medium. DNA (1 to 5 µg) was diluted
in 180 µl of H2O, 20 µl of 2.5 M CaCl2 was
added, and the combination was mixed with 200 µl of BES buffer [50
mM N,N-bis(2-hydroxyethyl)-2-aminoethanesulfonic acid, 280 mM NaCl, 1.5 mM Na2HPO4, pH 6.96]. This
mixture was applied to the cells, which were then incubated at 37°C
overnight. The cells were washed twice with phosphate-buffered saline
(PBS), pH 7.4, fed with 2 ml of complete medium, and incubated for 16 to 24 h. Cells were harvested and frozen at 80°C or lysed for further analyses. For immunoprecipitation assays, cells were lysed in
TNE buffer (50 mM Tris [pH 8.0], 150 mM NaCl, 2 mM EDTA, 1% Nonidet
P-40) supplemented with 1 mM Na3VO4, 5 mM NaF,
and 10 µg each of aprotinin and leupeptin (Sigma, St. Louis, Mo.) per ml for 20 min on ice. Lysates were cleared by centrifugation at 14,000 × g for 10 min, and the protein concentration
of the supernatants was determined. For each experiment, the same
amount of total protein was used. A 5-µl volume of antiserum/mg of
protein or 1 to 2 µg of monoclonal antibody was added, and the
mixture was incubated for at least 1 h at 4°C to allow complex
formation. Flag epitope-tagged proteins were precipitated by using
monoclonal antibody M2 covalently bound to agarose (Kodak, New Haven,
Conn.). Immunoprecipitation with uncoupled antibodies was completed by incubation with protein A-Sepharose or with rabbit anti-mouse antibodies coupled to protein A-Sepharose. The immunoprecipitates were
washed at least five times in TNE buffer. For immunoblotting, cell
lysates or immunoprecipitates were separated by sodium dodecyl sulfate
(SDS)-8, 9, 10, or 12% polyacrylamide gel electrophoresis (PAGE) and
transferred to polyvinylidene difluoride (PVDF) membrane filters
(Amersham Pharmacia Biotech, Freiburg, Germany). The PVDF membrane
filters were incubated for 1 h at room temperature in blocking
buffer (PBS [pH 7.4], 0.1% Tween 20, 5% [wt/vol] nonfat dried
milk powder) and then incubated with antiserum or antibody diluted in
blocking buffer. After thorough washing in PBS containing 0.1% Tween
20, immunoblots were incubated with secondary antibodies coupled to
HRP. Bands were visualized by enhanced chemiluminescence (Amersham
Pharmacia Biotech) in accordance with the manufacturer's instructions.
Antiphosphotyrosine immunoblotting was performed in accordance with the
same protocol but without milk powder.
Fluorescence spectrometry and calculation of the binding
constant.
Fluorescence measurements were based on the interaction
of peptides with aromatic residues in the SH3 domains, predominantly tryptophan. Measurements were performed essentially as previously described (64) in a Perkin-Elmer 760-40 fluorescence
spectrophotometer at an excitation wavelength of 290 nm (slit width, 2 nm) and an emission wavelength of 345 nm (slit width, 17 nm). A mini
magnetic stirrer was used to mix the solution in a 1-cm2
quartz fluorescence cell. A circulating water bath was used to maintain
the sample temperature at 18°C. To obtain the titration curves for
calculation of the binding constants, peptides from a stock solution of
5 mg/ml in PBS-1 mM dithiothreitol were added in small increments to 1 ml of PBS-1 mM dithiothreitol containing 50 µg of GST-SH3 domain
fusion proteins. Upon addition of the peptide solution, changes in
fluorescence were measured. Since the concentration of the SH3
domain-containing protein was low, the experimental data were fitted to
the following equation: F = Fmax × [peptide]/(Kd + [peptide]), where
[peptide] is the final peptide concentration at each measurement
point, F is the measured protein fluorescence intensity at
the particular peptide concentration, and
Fmax is the observed maximal fluorescence
intensity of the protein when saturated with the peptide. Nonlinear
regression curve fitting was carried out to fit the experimental data
to the equation, with Fmax and
Kd as fitted parameters. The change in protein
concentration that occurred as a result of peptide addition was
properly corrected.
In vitro binding assays.
One microgram of GST-SH2 domain
fusion proteins was incubated with 500 ng of purified Flag-Tio protein
in 1 ml of TNE for 1 h at 4°C. Complexes were precipitated with
glutathione-Sepharose (Amersham Pharmacia Biotech) for 1 or 2 h at
4°C, washed five times with RIPA buffer (1% [wt/wt] Nonidet P-40,
1% [wt/vol] sodium deoxycholate, 0.1% [wt/vol] SDS, 0.15 M NaCl,
0.01 M sodium phosphate [pH 7.2], 2 mM EDTA), resolved on by SDS-9%
PAGE, and transferred onto a PVDF membrane filter. Immunoblot detection
was performed as described above.
Nucleotide sequence accession number.
The nucleotide
sequence of the gene for Tio is available under GenBank accession no.
AF083423.
| |
RESULTS |
Cloning and prediction of the tio gene product of
herpesvirus ateles.
The complete nucleotide sequence of the coding
unique DNA of herpesvirus ateles has been determined recently
(1). The transformation-relevant region at the left terminus
of HVS unique DNA displays a strong variability among HVS subgroups and
HVA, while the rest of the genome of HVA shows a high degree of
conservation with respect to the complete sequence of HVS strain A11
(Fig. 1) (1, 2). Initially, an
open reading frame (ORF1) encoding 193 amino acids was identified
at the genomic position of the transformation-associated proteins of
HVS. The amino acid sequence predicted from ORF1 showed significant similarities to the product of the tip gene
(Fig. 1 to
3). The
homologies found were restricted to definite domains of Tip,
namely, a serine-rich stretch of amino acids duplicated in Tip of
strain C488, a domain surrounding a conserved tyrosine residue (Y-127),
the CSKH motif which is homologous to the 
I helix of Src (6,
76), the proline-rich SH3B motif, and a C-terminal transmembrane
domain (Fig. 2).
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FIG. 1.
Left-terminal genome variation among strains of HVS and
HVA. The variable regions of HVS subgroups A and C encode the proteins
StpA, StpC, and Tip, respectively, which are necessary for the
transforming phenotype of the virus. Two open reading frames (ORF1
and ORF2) were identified in the corresponding genomic region of
HVA strain 73. This region was transcribed into an mRNA of about 1 kb.
The transcript was found to be spliced and to code for a single
protein, Tio, that has homology to Tip and StpC. The splice occurs
within the StpC-homologous portion of the Tio mRNA. Two of the small U
RNAs of HVS (HSUR and HAUR) and reading frame 3 (HVS and HVA 03) are
conserved. The other HSUR copies and the reading frame for
dihydrofolate reductase (DHFR) found in HVS are not present in the
genome of HVA.
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FIG. 2.
Modular structure of Tio. The Tio molecule can be
divided into two sections. The N-terminal third displays 36% amino
acid identity to HVS StpC. This homology relies on richness in glycine
and proline residues which are also common to collagen repeats. The
perfect repetitive collagen-like structure of StpC (small boxes, 30%
grey) was not found in Tio. Instead, individual collagen triplets are
dispersed between positions 11 and 77 and connected by proline-rich
sequences (60% grey boxes). The C-terminal two-thirds of Tio shows
33% identity to Tip. The most prominent feature here is the
conservation of the SH3B domain (10% grey) and its functionally
associated domain, CSKH (80% grey). The distance between these domains
is also conserved. Other Tip-related regions of Tio include a
serine-rich motif (S pattern box) and the region around a conserved
tyrosine residue (checkerboard pattern box). The hydrophobic C terminus
(black box) probably serves as a membrane anchor.
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FIG. 3.
Primary structure of the gene for Tio. The presentation
is inverted relative to the standard orientation of the HVA strain 73 genome. The nucleotide sequence starts with a region homologous to the
StpC promoter and ends with the first nucleotide of the nonrepetitive
DNA. The splice donor and acceptor sites of the mRNA are indicated
above the nucleotide sequence. The amino acid translation of Tio (amino
acids [aa] 1 to 269) is given in single-letter code. The line below
the amino acid sequence (H) shows the homology of Tio to StpC and Tip
of HVS strain C488. Identical amino acids are marked by plus signs, and
similar amino acids are marked by tilde symbols. Similar amino acids
were hydrophobic (L, I, V, M, F, Y, and W), basic (R and K), acidic (D
and E), polar (N and Q), or small and neutral (G, A, S, and T). The
underlined amino acid sequences are those of the synthetic peptides
used for fluorescence spectrometry.
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Further analysis of the left terminal nucleotide sequence of HVA
suggested that a second reading frame (ORF2) encoding 61 amino
acids may have homology to StpC. While StpC consists primarily of 18 consecutive collagen-like motifs (Gly-X-Y, where X or Y is Pro)
(5), the deduced amino acid sequence of ORF2 displays a
dispersed pattern of four collagen-like motifs that are flanked by
multiple proline-rich sequences (Fig. 2 and 3). Within the nucleotide
sequence of ORF2, we recognized a possible splice donor consensus
sequence, and consequently, we found a possible splice acceptor site
which lies within the 5' untranslated region of ORF1.
Computational translation of this region again revealed a high proline
content and two additional collagen-like motifs.
Finally, we examined mRNA from HVA-transformed monkey T cells by
reverse transcription and PCR. Analysis of the resulting cDNA clones
uncovered a single, spliced mRNA where a 608-bp intron has been spliced
out (Fig. 3). This mRNA encodes a 269-amino-acid protein that displays
homology to StpC in the amino-terminal third of its amino acid sequence
and to Tip in the C-terminal half of its amino acid sequence (Fig. 2
and 3); thus, we refer to it as the two-in-one (Tio) protein of
herpesvirus ateles strain 73.
Identification of Tio in transformed monkey T-cell lines.
In
order to identify the predicted protein in HVA-transformed monkey cell
lines, an antiserum against a GST-Tio-fusion protein was raised in
rabbits. Upon Western blot analysis, the antiserum specifically
recognized a number of proteins in the 44- to 46-kDa range in lysates
of cell line A661, which was generated by in vitro transformation of
S. oedipus peripheral lymphocytes, and of cell line A1022,
which was isolated from an S. oedipus marmoset infected with
HVA strain 73. The main difference between these cell lines is in the
numbers of genome equivalents they carry (28). While A661
cells harbor approximately 103 genome copies per diploid cell, A1022
cells have only 4 genome copies per cell, which might reflect
differences in expression levels as detected by Western blotting (Fig.
4B, lanes 1 and 2). The appearance of Tio
as at least a doublet of 43 and 46 kDa is thought to be related to
posttranslational modifications. The specificity of the antiserum was
confirmed by incubating anti-Tio serum with lysates of S. oedipus T cells which were transformed by an HVS subgroup A, B, or
C strain (Fig. 4, lanes 3 to 5). Expression cloning of Tio and
transfection into 293T cells gave rise to a protein pattern with the
same electrophoretic mobility as the proteins identified in the
transformed monkey T cells, confirming the identity of Tio (data not
shown).
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FIG. 4.
Expression of Tio in transformed monkey T cells. (A)
Coomassie-stained SDS-PAGE gel loaded with 15 µg of total cell lysate
of transformed S. oedipus T cells in each lane. Lanes: 1, cell line A661; 2, cell line A1022; 3 to 5, cell lines established with
HVS subgroups A, B, and C, respectively. (B) Parallel gel transferred
to a PVDF membrane filter and incubated with rabbit anti-Tio serum.
Molecular size standards are given on the left.
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Multimerization of Tio.
The viral protein was also expressed
in 293T cells as a fusion protein with an N-terminal Flag epitope tag
(Flag-Tio) which caused a mobility shift of Tio to a 45- and 47-kDa
doublet. Flag-specific Western blot analyses of immunoprecipitated
Flag-Tio often revealed an additional band twice the size of the Tio
band which was sensitive to high concentrations of 
-mercaptoethanol
and extended boiling (data not shown). This band was not observed in
control reactions and raised the question of whether Tio dimerizes or
multimerizes when expressed in 293T cells. To assess the possibility of
Tio homodimer formation, an additional expression plasmid was
constructed with an AU1 epitope tag fused to the N terminus of Tio
(AU-Tio). When Flag-Tio and AU-Tio were expressed in the same cells,
the Flag and AU1 epitope-tagged proteins coprecipitated (Fig.
5, lanes 4 and 9). However, mixture of
separately expressed Flag-Tio and AU-Tio proteins did not lead to
coprecipitation of the respective proteins (Fig. 5, lanes 5 and 10). We
concluded that Tio forms homodimers or even multimers in transfected
293T cells. The fact that Flag-Tio and AU-Tio did not aggregate in
vitro argues against an artifact due to overexpression or gel
overloading. Furthermore, this observation suggests that Tio homodimers
or multimers are very stable and have a low exchange rate.
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FIG. 5.
Tio forms homodimers. 293T cells were transfected with
expression vectors (lanes 1 and 6), with an expression construct for
Flag-Tio (lanes 2 and 7) or AU-Tio (lanes 3 and 8), or with a mixture
of both Tio expression plasmids (lanes 4 and 9). In addition, lysates
containing either Flag-Tio or AU-Tio were mixed prior to
immunoprecipitation (I.P.) (lanes 5 and 10). Precipitations were
performed with anti-Flag agarose (lanes 1 to 5) or with anti-AU1
antibody bound to protein A-Sepharose (lanes 6 to 10). Coprecipitated
proteins and their controls were detected by Western blotting (W.B.)
with anti-Flag (upper panel) or anti-AU1 (lower panel) antibodies.
Molecular mass standards are given on the right.
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Tio is phosphorylated on tyrosine when coexpressed with Lck, Src,
or Fyn.
HVS-C488 Tip is known to be associated with Lck, and StpA
of HVS strain A11 interacts with cellular Src. To compare the
functional relatedness of Tio to Tip and StpA, we performed
cotransfection experiments with 293T cells by employing Flag-Tio and
Src family kinase Lck, Src, or Fyn. Crude lysates of transfected cells
were analyzed by Western blotting using phosphotyrosine-specific,
kinase-specific, or anti-Flag antibodies (Fig.
6). The kinases were expressed at comparable levels in the appropriate samples (Fig. 6B) and were phosphorylated on tyrosine (Fig. 6A, lanes 3 and 4). After coexpression of Tio, an additional phosphoprotein was detected in the presence of
Lck and Src. A corresponding protein was not observed in the absence of
Tio or when Tio was expressed alone or together with Fyn (Fig. 6A). The
total amount of Flag-Tio detected by the epitope-specific antibody was
approximately constant in all Tio-transfected samples, but in the
presence of Lck or Src, a shift to the slower-migrating forms was
observed (Fig. 6C, compare lanes 2 to lanes 4) which was most likely
due to tyrosine phosphorylation (Fig. 6A, lanes 4).
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FIG. 6.
Tio is tyrosine phosphorylated by Src family kinases in
vivo. 293T cells were transfected with expression vectors (lane 1) or
an expression plasmid for Flag-Tio (lane 2), Lck, Src, or myc-tagged
Fyn kinase (lane 3) or for Flag-Tio plus the respective kinase (lane
4). Twenty micrograms of total cell lysates was separated by SDS-9%
PAGE and analyzed for tyrosine-phosphorylated proteins (A) by Western
blotting (W.B.). Expression of the transfected plasmids was controlled
by detection of each individual kinase with specific antibodies (B) or,
for Flag-Tio, with epitope-specific antibodies (C). Arrowheads to the
right of the phosphotyrosine blots indicate a protein detected only
after cotransfection of Flag-Tio with Lck or Src. Molecular mass
standards are given on the right.
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While phosphorylation of Flag-Tio by Fyn was not detected in standard
cell lysates (Fig. 6A), treatment of the transfected cells with
orthovanadate prior to lysis revealed tyrosine phosphorylation of Tio
by endogenous kinases with an increase after coexpression of Fyn.
Antiphosphotyrosine Western blotting after Flag immunoprecipitation of
untreated cell lysates confirmed tyrosine phosphorylation of Flag-Tio
in the presence of Fyn. However, compared to that by Lck and Src,
phosphorylation of Tio by Fyn was significantly lower (data not shown).
Thus, Tio was found to be tyrosine phosphorylated in vivo in the
presence of Lck, Src, or Fyn. Two of these Src family kinases (Lck and
Fyn) play an important role in T-cell signaling and might link Tio to
lymphocyte growth regulation.
Association of Tio with Lck, Src, and Fyn in transfected 293T
cells.
To investigate the direct association of Tio with the
tyrosine kinases, cDNA expression constructs of Flag-Tio and of the Src
kinases were cotransfected into 293T cells and coimmunoprecipitation assays were performed. Immune complexes from mock-transfected cells did
not react with any of the antibodies used in these assays (Fig.
7, lanes 1 and 5). An anti-Flag
monoclonal antibody directly precipitated Flag-Tio (Fig. 7, lanes 2)
and was not cross-reactive with the tyrosine kinases (Fig. 7, lanes 3).
On the other hand, antibodies directed against the recombinant kinases
were specific (Fig. 7, lanes 7), as no binding to Flag-Tio was observed
(Fig. 7, lanes 6).
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|
FIG. 7.
Tio coprecipitates with Src family kinases. 293T cells
were transfected with expression vectors (lanes 1 and 5) or an
expression plasmid for Flag-Tio (lanes 2 and 6), Lck, Src, or
myc-tagged Fyn kinase (lanes 3 and 7), or Flag-Tio plus the respective
kinase (lanes 4 and 8). Flag-Tio was immunoprecipitated (I.P.) by
anti-Flag (lanes 1 to 4) antibody, and Western blotting (W.B.) was
performed by using specific antibodies to detect coprecipitated Lck
(A), Src (B), or myc-tagged Fyn (C). The reverse experiments were
performed by using kinase-specific or anti-myc antibodies for
immunoprecipitation (lanes 5 to 8) and anti-Flag antibody for Western
blotting. The lower panel shows the results of control Western blotting
after reprobing of the membranes with the antibodies used for
immunoprecipitation. Open arrowheads, Flag-Tio; black arrowheads, Lck,
Src, or Fyn-myc; HC, immunoglobulin heavy chains. Molecular mass
standards are given on the right.
|
|
After coexpression of Flag-Tio with Lck, anti-Flag, as well as
anti-Lck, immune complexes contained both Lck and Flag-Tio (Fig. 7A,
lanes 4 and 8), indicating direct binding of Tio to Lck. An analogous
experiment was performed with expression constructs for Flag-Tio and
c-Src (Fig. 7B). Exogenous Src associated with Tio and vice versa (Fig.
7B, lanes 4 and 8). In contrast, endogenous Src was detectable in Src
immunoprecipitates (Fig. 7B, lanes 5 and 6), but Flag-Tio was not
coprecipitated (Fig. 7B, lane 6). Furthermore, Flag-Tio did not
coprecipitate endogenous Src (Fig. 7B, lane 2). This is consistent with
the finding that no tyrosine phosphorylation of Tio by endogenous Src
was detected (Fig. 6). The third tyrosine kinase tested was Fyn. To
facilitate the experimental procedure, myc epitope-tagged Fyn was used.
Coprecipitation analysis revealed that Tio associates with Fyn and vice
versa (Fig. 7C). Remarkably, Fyn appeared to favor association with a
45-kDa Flag-Tio phosphoprotein while Lck and Src associated
preferentially with a 47-kDa Flag-Tio phosphoprotein. This observation
may be due to differential phosphorylation by Lck, Src, or Fyn.
Alternatively, the individual kinases may display different affinities
for the Tio variants.
Tio interacts with the SH3 domains of Src family tyrosine
kinases.
Sequence analysis and comparison with Tip suggested that
Tio interacts with Src family kinases through their SH3 domains and that this interaction is mediated by its class II SH3B motif. To test
this hypothesis, we performed GST affinity chromatography experiments.
A GST-Lck-SH3 fusion protein and Flag-Tio were purified from E. coli. GST-Lck-SH3 specifically bound Flag-Tio as monitored by Flag
Western blotting. In a reverse assay, Flag-Tio coimmunoprecipitated GST-Lck-SH3 (data not shown). These experiments confirmed that Tio is
comparable to HVS Tip with respect to Lck-SH3 interaction.
To investigate the direct interaction of Tio with other Src family
tyrosine kinases, a synthetic peptide corresponding to the most obvious
candidate SH3B motif of Tio was synthesized and its affinity to SH3
domains was measured by fluorescence spectrometry. This assay revealed
that the predicted SH3B domain of Tio is sufficient to bind directly to
the SH3 domains of all of the Src family members tested (Table
1). Surprisingly, the affinity of the
peptide for the Lyn and Hck SH3 domains was high, while it was moderate
for the Lck SH3 domain and relatively low for the Fyn, Src, and Yes SH3
domains. The SH3 domains of Grb2, Abl, and phosphatidylinositol 3-kinase (PI3K) subunit p85-alpha did not bind to the Tio SH3B peptide.
No binding to any of the SH3 domains tested was observed with a
synthetic peptide from the proline-rich N terminus of Tio. This
indicates that the interaction of the class II SH3B motif of Tio is
specific for Src family kinases.
Tyrosine-phosphorylated Tio binds directly to the SH2 domains of
Lck, Src, and Fyn.
The direct interaction of Tio with the SH3
domains of Src kinases and the tyrosine phosphorylation of Tio in vivo
raised the possibility that binding to the SH2 domains of these kinases
might be allowed. To determine the capability of Tio to bind to SH2 domains, tyrosine-phosphorylated or nonphosphorylated Flag-Tio was
incubated with various GST-SH2 fusion proteins. The resulting complexes
were purified by GST affinity chromatography, resolved by SDS-PAGE, and
analyzed for the presence of Tio bound to GST-SH2 domains (Fig.
8). No binding of nonphosphorylated Tio
to SH2 domains was observed, but complex formation of phosphorylated
Tio with the SH2 domains of Lck, Src, and Fyn was detected. A GST
fusion protein containing the SH2 and SH3 domains of Lck served as a positive control, demonstrating phosphorylation-independent binding of
Tio to the Lck SH3 domain. Similar to the SH3 interaction, SH2 binding
seemed to be specific for Src family kinases, as no association of
phosphorylated Tio was observed with the SH2 domain of phospholipase
C-
, Abl, Grb2, or Vav.
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|
FIG. 8.
Tyrosine-phosphorylated Tio binds to GST-SH2 domains of
Src family kinases. Flag-tagged Tio fusion proteins were expressed in
bacteria with or without an active tyrosine kinase. Both phosphorylated
(pY+) and unphosphorylated (pY) Tio proteins were purified and tested
for the ability to bind to GST-SH2 domains derived from the proteins
given at the top. Western blotting was performed to control the amount
of input GST fusion proteins (GST) and to detect
tyrosine-phosphorylated (pTyr), as well as total (Flag), Flag-Tio bound
by the GST-SH2 proteins. A GST-SH3/SH2 fusion protein of Lck was used
to analyze the binding capacity of the unphosphorylated Tio
preparation. Molecular mass standards are given on the right.
|
|
In conclusion, our experiments demonstrate that Tio can bind to Src
family kinases via their SH3 domains and, upon tyrosine phosphorylation, via their SH2 domains. Thus, Tio combines properties of Tip, which binds directly to the Lck SH3 domain, and StpA, which
interacts with Src kinases in a phosphotyrosine dependent manner.
| |
DISCUSSION |
We have identified Tio as a protein encoded by the putative
transformation-relevant region of HVA strain 73. Expression of Tio in
virus-transformed monkey T cells hints at a functional role for this
viral protein in lymphocyte growth transformation. Its potential to
form dimers or multimers and its association with nonreceptor tyrosine
kinases of the Src family are reminiscent of oncoproteins of other DNA
tumor viruses (16).
Homodimerization of viral effector proteins was shown to be essential
for the oncogenic properties of several tumor viruses. A prominent
example is the bovine papillomavirus (BPV). BPV oncoprotein E5 acts as
a disulfide-linked homodimer which induces dimerization of
platelet-derived growth factor receptor in the absence of ligand
(16). Autophosphorylation of dimerized platelet-derived growth factor receptor augments intrinsic kinase activity
(35). Further tyrosine phosphorylation generates specific
binding sites for cellular signaling molecules containing SH2 or
phosphotyrosine-binding (PTB) domains and initiates a sustained
mitogenic signal through activation of the ras (32),
mitogen-activated protein kinase (33), and PI3K pathways
(9, 32). Finally, BPV E5 expression results in
transformation of cultured fibroblasts (16). Dimeric protein
gp55 of spleen focus-forming virus appears to use a similar mechanism
of cellular transformation. This protein activates the erythropoietin
receptor and is responsible for the induction of erythroleukemia by
spleen focus-forming virus (16).
Polyomavirus middle T antigen (mT) is also able to form dimers or
multimers, but this property is not necessary for the transforming phenotype (68). Like Tio, mT associates with Src kinase
family members (reviewed in reference 54), namely,
with Src (11), Yes (45), and Fyn (10,
36). The interaction has been mapped to the kinase domain of Src
(22) and results in increased Src (7) and Yes
(45) kinase activities. Tyrosine phosphorylation of mT
generates binding sites for SH2 and PTB domains and results in the
recruitment of PI3K (74), phospholipase C-1
(71), and the adapter molecule Shc (15).
Furthermore, mT associates with 14-3-3 proteins (61) and
with protein phosphatase 2A (62). In addition, proline-rich
sequences of mT might serve as interaction sites for SH3 domains. These
properties of mT suggest that the viral oncoprotein leads to
transformation of rodent cells by inducing the constitutive
dimerization-independent formation of signaling complexes.
Association with tyrosine kinases has also been described for
transformation-related proteins of other gammaherpesviruses and was the
basis of our experiments. The Tio-related protein Tip of HVS strain
C488 binds to the T-cell-specific tyrosine kinase Lck (6).
This interaction has been mapped to a proline-rich region of the viral
protein and to the SH3 domain of the kinase (40, 41).
However, mutation of the SH3B site of Tip enhanced the transforming
phenotype of HVS strain C488 (18), indicating that
SH3-mediated Lck interaction of Tip is not essential for T-cell growth
transformation. The absolute requirement for Tip in this system
(19) suggests that Tip employs other mechanisms to promote
T-cell transformation. Association of Tio with Src also hints at a
functional relationship with StpA of HVS strain A11. This protein is
required for the transforming phenotype of the virus (57)
and is oncogenic by itself when expressed in rodent fibroblasts or in
transgenic mice (42, 46). While association of StpA with Src
was found to be mediated by an SH2-binding site (48), the
significance of this interaction for transformation has not been
analyzed so far. Finally, Epstein-Barr virus latent membrane protein 2A
(LMP2A) associates with several tyrosine kinases expressed in
transformed B cells. LMP2A interacts with the B-cell-specific kinase
Lyn via the SH2 domain, and its binding to Syk kinase depends on
phosphorylation of an immuno tyrosine-based activation motif (29,
30). LMP2A appears not to be required for B-cell transformation but is thought to maintain latency by downregulation of Lyn and prevent
Epstein-Barr virus from reactivation by blocking B-cell receptor
signaling (49, 55). However, expression in transgenic mice
recently revealed novel B-cell-stimulatory effects of LMP2A (8).
In this context, our findings of Tio dimerization and association with
Src family kinases support the hypothesis that Tio is the oncoprotein
of HVA, which was initially based on sequence homologies. Through
dimerization and/or simultaneous binding of SH3 and SH2 domains, Tio
might assemble signaling complexes which finally initiate sustained
mitogenic signals leading to T-cell transformation. Most critical in
this context appears to be the involvement of the protein tyrosine
kinases Lck and Fyn, which are key enzymes in T-cell activation. In
contrast, signals mediated by Lyn, Hck, Src, or Yes in T cells are not
described. Initial binding of Tio to SH3 domains of tyrosine kinases
enables Tio phosphorylation and subsequent binding to SH2 or PTB
domains. Thereby, Tio might serve as an adapter either among Src family kinases or between these kinases and other signaling molecules. Besides
SH3- and phosphotyrosine-dependent interactions, sequence homologies
suggest that Tio also might recruit cellular factors known to associate
with the HVS oncoprotein StpC. These proteins, the GTPase Ras and the
NFB-inducing tumor necrosis factor receptor-associated factors
(reviewed in reference 37), could link Tio to
additional growth-promoting cellular pathways.
Our experiments demonstrate that the HVA protein Tio is expressed in
virus-transformed T lymphocytes and has the potential to interfere with
cellular growth regulation. Further analyses are necessary to determine
the transforming properties of Tio and the composition of the Tio
complexes and to identify the signaling pathways leading to T-cell
transformation by HVA.
| |
ACKNOWLEDGMENTS |
This work was supported by the Deutsche Forschungsgemeinschaft,
Sonderforschungsbereich 466 (B2), and a grant of the Wilhelm-Sander Stiftung to S.M.F.
We thank F. Friedrich for technical assistance and S. M. Lang for
providing 9E10 hybridoma supernatants and for critical reading of the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institut
für Klinische und Molekulare Virologie,
Friedrich-Alexander-Universität Erlangen-Nürnberg,
Schlossgarten 4, D-91054 Erlangen, Germany. Phone: 49-9131-8526483. Fax: 49-9131-8526493. E-mail:
jsalbrec{at}viro.med.uni-erlangen.de.
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Journal of Virology, June 1999, p. 4631-4639, Vol. 73, No. 6
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
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