(Received for publication, January 28, 1997)
From the Division of Cell Biology, La Jolla Institute for Allergy and Immunology, San Diego, California 92121
Phosphatidylinositol 3-kinase (PI3-K) has been implicated in the regulation of cell proliferation in many cell types. We have previously shown that in T cells the PI3-K inhibitor, wortmannin, interferes with activation of the mitogen-activated kinase, Erk2, after T cell receptor (TcR) stimulation. To further explore the involvement of PI3-K in T cell activation, we created a set of potentially dominant negative PI3-K constructs comprising individual or tandem domains of the regulatory p85 subunit and tested their effect on downstream signaling events like Erk2 activation and transcription from an NFAT (nuclear factor of activated T cells) element taken from the interleukin-2 promoter. Following TcR stimulation, activation of Erk2 was only inhibited by a previously described truncated form of p85 that cannot bind the catalytic subunit, but not by other constructs of p85. In contrast, several mutant p85 alleles had dramatic effects on NFAT activation. Most interestingly, the N-terminal SH2 domain had an inhibitory effect, whereas a mutant p85 containing only the two SH2 domains enhanced basal NFAT activity in a Ras-dependent manner. Ionomycin induced synergistic activation of NFAT in cells expressing p85 mutants that contained the C-terminal SH2 domain. Analysis of phosphotyrosine-containing proteins bound to truncated p85 constructs revealed cooperative binding of the two SH2 domains but no apparent differences between the N- and C-terminal SH2 domains. Wortmannin did not interfere with NFAT activation, although it inhibited PI3-K and Erk2 activation in the same experiment. These results suggest that PI3-K is involved in NFAT activation through a complex adaptor function of its regulatory subunit and that its lipid kinase activity is dispensable for this effect.
Phosphatidylinositol 3-kinase (PI3-K)1
has been implicated in the regulation of cell growth in a variety of
cell types including T lymphocytes (1). Engagement of the T cell
antigen receptor (TcR) causes an increase in the intracellular levels
of the PI3-K reaction products, phosphatidylinositol 3,4-bisphosphate,
and phosphatidylinositol 3,4,5-trisphosphate (2). These lipids are not
subject to breakdown by phospholipase C but seem to activate Ser/Thr-specific protein kinases such as some isoforms of protein kinase C (3-5), and protein kinase B, also known as c-Akt (6, 7). The
isoform of PI3-K that becomes activated in response to growth factor
receptor stimulation is a heterodimeric enzyme consisting of an 85-kDa
regulatory subunit (p85 or p85
) (8-10) and a 110-kDa catalytic
subunit (p110
or p110
) (11). The p85 subunit contains a number of
domains that mediate protein-protein interactions and are commonly
found in signaling proteins: one Src homology 3 (SH3) domain, two
proline-rich regions, two SH2 domains, and a region with similarity to
the breakpoint cluster region gene (BCR homology region). Binding of
the catalytic p110 subunit occurs through interaction of the region
between the SH2 domains of p85 (inter-SH2 domain or iSH2) and the
extreme N terminus of the catalytic subunit (12, 13). Regulation of
PI3-K activity occurs through interaction of the two subunits (14, 15),
autophosphorylation at Ser-608 (16), and membrane localization (17). In
addition, a number of reports have demonstrated that binding of
cellular proteins to PI3-K domains can increase its enzymatic activity: the SH3 domain of Src family kinases binding to one or both of the
proline-rich regions of p85 (18), phosphotyrosine-containing peptides
binding to the SH2 domains of p85 (19, 20), and GTP-Ras binding to the
catalytic p110 subunit (21). However, the in vivo function
of these and the other PI3-K domains, and their contribution to various
signaling processes downstream of PI3-K, are poorly understood.
We have previously shown that TcR-induced activation of the
mitogen-activated kinase, Erk2, requires PI3-K activity since the PI3-K
inhibitor, wortmannin, blocked Erk2 activation (22). Furthermore, a
mutated form of p85 that lacked the p110-binding iSH2 region
(p85iSH2) reduced Erk2 activation, presumably by occupying PI3-K
binding sites on other cellular proteins. To study this in more detail
and to shed some light on the physiological role of the various
domains, we have generated a set of truncated p85 mutants to study the
role of PI3-K domains in T cell activation.
As a functional readout we used a reporter gene driven by the nuclear factor of activated T cells (NFAT), which is a transcription factor complex that plays a key role in the induction of the interleukin-2 gene and other lymphokine genes during T cell activation (23). It consists of two components: preexisting cytosolic NFATp, which translocates into the nucleus in response to a calcium signal, and a nuclear component, AP-1, which consists of c-Fos and c-Jun proteins and is induced by a cascade of mitogen-activated protein kinase-related protein kinases and as a result of protein kinase C activation. NFAT-driven expression of reporter genes has been widely used as a physiologically relevant assay to study signal transduction events that lead to cytokine expression in T cells.
Here we report that PI3-K has different effects on Erk2 and NFAT
activation. Erk2 activation in response to TcR engagement was sensitive
to wortmannin, and only inhibited by overexpressing p85iSH2, but not
individual p85 domains. NFAT activation, on the other hand, was not
sensitive to wortmannin, but was inhibited by the SH3 domain, the
N-terminal SH2 domain, and a p85 fragment comprising the two
proline-rich regions and the BCR homology domain. In contrast, three
constructs that contain the C-terminal SH2 domain caused an elevated
basal level of NFAT activity, which was synergistically increased by
ionomycin. Both the increased basal NFAT level and the activation
following TcR stimulation depended on functional Ras and calcineurin.
These studies provide evidence that PI3-K is involved in cytokine
induction in a way that does not involve enzymatic activity but a
previously unrecognized adaptor function of the regulatory subunit.
The anti-CD3 mAb, OKT3, was
purified from ascites fluid by protein A-Sepharose chromatography. mAb
4G10 (anti-phosphotyrosine) and anti-p85 rabbit serum were from Upstate
Biotechnology, Inc. (Lake Placid, NY). Anti-HA epitope mAb 12CA5 was
from Boehringer Mannheim (Indianapolis, IN). Anti-Erk2 polyclonal
antibodies were from Santa Cruz Biotechnology, Inc. (Santa Cruz, CA).
The c-Myc-tagged Erk2 cDNA was from Dr. C. Marshall (Ludwig
Institute for Cancer Research). The c-Myc epitope is recognized by mAb
9E10. Anti-phospho-Erk2 antibody was from New England Biolabs, Inc.
(Beverly, MA). The luciferase reporter plasmid, NFAT-luc, was a
generous gift from Dr. G. Crabtree. Luciferin was from Analytical
Luminescence Laboratory (Ann Arbor, MI).
The p85iSH2 and iSH2 constructs have
been described previously (22). p85 fragments encoding the amino acids
indicated in Fig. 1A were amplified by polymerase chain reaction using
primers tailed with XbaI and EcoRI (SH3, PBP,
N-SH2), EcoRI and NdeI (C-SH2), or
XbaI and NdeI (NC, NiC, full-length p85) sites.
p85
iSH2 was used as a template for NC; wild-type bovine p85
was
used as a template for the other constructs. The N-terminal fragment of p110 (amino acids 1-171) was amplified using bovine p110
as a template and primers tailed with NheI and NdeI
sites. The fragments were digested with the appropriate restriction
enzymes and ligated into the vector pEF-HA (22). The resulting fusion
proteins express an influenza hemagglutinin epitope YPYDVPDYA at their
N terminus. All constructs prepared for this study were verified by
sequencing.
Cells and Transient Transfections
Jurkat cells stably expressing the simian virus large T antigen (J-TAg) were kept at logarithmic growth in RPMI supplemented with 10% heat-inactivated fetal calf serum, glutamine, antibiotics, and 0.5 mg/ml G418. Transient transfections were carried out by electroporation as described before (22). Typically, a total amount of DNA of 17-20 µg was added to 20 × 106 cells (5 µg of c-lmyc-tagged Erk2 plus 15 µg of PI3-K construct or empty vector, or 2 µg of NFAT-luc plus 15 µg of PI3-K construct or empty vector).
Immunoprecipitations and in Vitro Kinase AssaysThese were performed essentially as described previously (22).
Luciferase AssaysTwo days after transient transfection, J-TAg cells were stimulated with 10 µg/ml OKT3, 50 ng/ml PMA, or 1 µg/ml ionomycin, or left untreated for 3-4 h in 24-well plates in a tissue culture incubator. The cells were washed with phosphate-buffered saline and lysed in 100 µl of lysis buffer (100 mM KPO4, pH 7.8, 1 mM dithiothreitol, 0.2% Triton X-100). Lysates were clarified by centrifugation at 15,000 × g for 5 min, and 50 µl were used for luciferase assays in an automated luminometer (Monolight 2010, Analytical Luminescence Laboratory, Ann Arbor, MI). The final assay contained 50 µl of lysate plus 100 µl of ATP solution (10 mM ATP, 35 mM glycyl-glycine, pH 7.8, 20 mM MgCl2) plus 100 µl of luciferin reagent (0.27 mM coenzyme A, 0.47 mM luciferin, 35 mM glycyl-glycine, pH 7.8, 20 mM MgCl2). The protein concentration in the cell lysates was determined by the Bradford protein assay and used to normalize the luciferase activity. Typically, the variation in protein concentration between samples was smaller than 20%.
Among the
signaling components thought to be downstream of the TcR and PI3-K is
the mitogen-activated protein kinase, Erk2 (24). We have previously
shown that the PI3-K inhibitor, wortmannin, and a mutated form of p85
that cannot bind the catalytic subunit (p85iSH2) inhibited Erk2
activation in T cells (22). To further investigate the role of p85
domains in Erk2 activation and other processes relevant to T cell
activation we generated a set of truncated p85 constructs (Fig.
1A). Transient expression of these constructs
in J-TAg cells yielded anti-HA reactive proteins of the expected sizes
(Fig. 1B). We tested these constructs for an effect on Erk2
activation by co-expressing them with c-Myc-tagged Erk2 in J-TAg cells.
48 h after transfection, the cells were either stimulated for 3 min with the anti-CD3 antibody, OKT3, or left untreated. c-Myc-tagged
Erk2 was immunoprecipitated using the mAb 9E10, and in vitro
kinase assays were performed using MBP as a substrate. As can be seen
in the upper panel of Fig. 2, only p85
iSH2
clearly inhibited Erk2 activation, presumably because it binds to
PI3-K-activating proteins or sites but fails to transduce a signal to
the catalytic p110 subunit of PI3-K. All other constructs had
negligible effects on Erk2 activation, although they were efficiently
expressed (data not shown). The SH3 domain and PBP seemed to increase
Erk2 activation, but an anti-Erk2 blot on the same 9E10
immunoprecipitates (Fig. 2, lower panel) showed that these
two samples contained slightly more Erk2 protein. Thus, it seems that
multiple domains of endogenous p85 need to be competed away by
transfected constructs to inhibit this pathway.
Complex Role of PI3-K Domains in NFAT Activation
To further
characterize the role of PI3-K in T cell activation we studied the
effect of truncated p85 and p110 constructs on the activation of the
transcription factor NFAT. J-TAg cells were co-transfected with
NFAT-luc and PI3-K constructs and stimulated with OKT3 for 3-4 h.
Luciferase activity was assayed in the cell lysates as a reporter for
NFAT activation. Fig. 3A shows that PI3-K
constructs had complex effects on NFAT activity following TcR/CD3
stimulation. The SH3 domain, a fragment containing two proline-rich
regions and the BCR homology domain (PBP), the N-terminal SH2 domain
(N-SH2), and the inter-SH2 domain (iSH2) all inhibited NFAT activation,
whereas the C-terminal SH2 domain (C-SH2) increased the basal NFAT
activity without affecting the level of NFAT activity after TcR/CD3
stimulation. The C-SH2 domain seemed to have a dominant effect over the
N-SH2 domain since constructs containing both SH2 domains (p85NC and
p85NiC) behaved more like C-SH2 than like N-SH2. p85iSH2 and
full-length p85 both lead to elevated basal levels of NFAT activity
with almost no further stimulation after TcR engagement. The N-terminal
fragment of p110 that binds p85 (p110 NT) did not substantially affect
NFAT activation, but it was expressed at a lower level than the p85
constructs. This experiment was repeated three times with different
batches of DNA and yielded very reproducible results.
Activation of NFAT requires two signals, one involving calcium (inducible by ionomycin), and one involving Ras (inducible by PMA; reviewed in Ref. 25). To test whether the mutated PI3-K constructs used in this study acted in the calcium pathway or in the Ras pathway, we tested their effect on NFAT activation in cells that had been stimulated with either PMA or ionomycin (Fig. 3B). PMA alone did not activate NFAT, and none of the p85 mutants had a synergistic effect on NFAT in the presence of PMA. Ionomycin, on the other hand, synergistically activated NFAT in cells that were transfected with p85 constructs containing the C-terminal SH2 domain. We conclude that these "activating" mutants mimicked or induced a process in the Ras/PKC pathway, which together with an increase in intracellular calcium lead to a strong activation of NFAT.
Cyclosporin A Inhibits TcR-induced and p85NC-induced NFAT ActivationCalcineurin is a cytosolic Ser/Thr-specific protein
phosphatase that dephosphorylates NFATp in a
calcium/calmodulin-dependent way, a critical step for nuclear
translocation of NFATp and assembly of functional NFAT complexes. To
ask if calcineurin is involved in NFAT activation by p85NC, we took
advantage of the immunosuppressant, cyclosporin A (CsA), a potent
inhibitor of calcineurin (26, 27). Fig. 4 shows that CsA
efficiently inhibited NFAT activation after stimulation with either
OKT3 or ionomycin. In cells transfected with inhibitory p85 constructs
(SH3, PBP, and N-SH2), CsA inhibited NFAT even further. Because the
inhibition of NFAT that is caused by these p85 constructs seems to have
an additional effect to the inhibition mediated by CsA, we speculate
that also these p85 constructs act in the Ras/PKC pathway. In the
presence of the activating construct, p85NC, inhibition by CsA was
substantial, but not complete. This is compatible with p85NC
stimulating the Ras/PKC-dependent pathway.
Dominant Negative Ras Blocks NFAT Activation by p85NC
The Ras
GTPase has been implicated in PI3-K signaling (28) and has been
demonstrated to bind directly to the catalytic subunit of PI3-K (21).
To address whether the increase in basal NFAT activity in cells
expressing p85NC requires functional Ras, we co-transfected cells with
NFAT-luc, p85NC, and increasing amounts of dominant negative Ras
(RasN17). Both the basal NFAT activity in unstimulated cells, as well
as the TcR-induced activation, were inhibited by RasN17 in a
dose-dependent manner (Fig. 5). It is
important to note that the expression level of p85NC was not affected
by RasN17. Therefore, RasN17-mediated abrogation of p85NC-induced basal
NFAT activity cannot be explained by loss of p85NC expression.
Wortmannin Does Not Inhibit NFAT Activation
To understand the
complex effects on NFAT activation of the mutant p85 constructs used in
this study, we sought to correlate them with the catalytic activity of
endogenous PI3-K in the transfected cells. We therefore decided to ask
first whether PI3-K catalytic activity is required for NFAT activation.
Wortmannin has been widely used to irreversibly inhibit PI3-K and to
demonstrate the involvement of PI3-K in many cellular processes (29).
We transiently transfected cells with NFAT-luc (plus empty vector). Two
days after transfection, the cells were treated with increasing
concentrations of wortmannin for 30 min and then stimulated with OKT3
for 3 h. To verify inhibition of PI3-K by wortmannin, samples were
taken at the beginning and at the end of the OKT3-stimulation (after 3 min and 3 h, respectively) and from unstimulated control cells and
assayed for PI3-K activity in p85 immunoprecipitates. Activation of
Erk2 was tested by immunoblotting of total cell lysates of the same
samples with an anti-phospho-Erk2 antibody. After 3 h of
stimulation with OKT3, cell lysates were prepared and assayed for
luciferase activity. The upper panel of Fig.
6 shows that increasing concentrations of wortmannin
progressively inhibited PI3-K activity, and that this inhibition lasted
for the entire duration of the stimulation with OKT3. This is
important, because wortmannin is known to be unstable, and de
novo synthesis of PI3-K might partially reverse the effect of
wortmannin once it is hydrolyzed. Erk2 activation was observed after 3 min of stimulation and was sensitive to wortmannin as shown before (22)
(Fig. 6, middle). No Erk2 activation was observed after
3 h of stimulation with OKT3 (data not shown). Surprisingly,
wortmannin did not inhibit NFAT activation (Fig. 6, lower
panel). At the highest wortmannin concentration, we tested to
achieve complete inhibition of PI3-K, NFAT activation was even higher
than in untreated cells, but this may be due to lack of specificity of
wortmannin at this concentration. We therefore conclude that the kinase
activity of PI3-K is not required for NFAT activation or may even have
an inhibitory effect.
Cellular Protein Binding to PI3K Domains
The effect of p85
domains on NFAT is likely to be mediated by cellular proteins that bind
to them. To learn more about the role of PI3-K domains in NFAT
activation, we transiently expressed the constructs described above in
J-TAg cells and immunoprecipitated them with an anti-HA antibody from
resting and from OKT3-stimulated cells. Bound
phosphotyrosine-containing proteins were revealed by
anti-phosphotyrosine Western blotting (Fig. 7). While
the SH3 domain and the PBP fragment did not associate with
phosphotyrosine-containing proteins, all constructs that contained one
or two SH2 domains coprecipitated with a similar set of proteins. A
tandem arrangement of the two SH2 domains seemed to be essential for
efficient binding to cellular phosphotyrosine-containing proteins,
especially for the 21-kDa protein, which we identified as the TcR
chain (data not shown). However, there was no major difference in
the pattern of proteins bound to either the N-SH2 domain or the C-SH2
domain. The functional difference of the two SH2 domain constructs with regard to NFAT stimulation can therefore not readily be explained by
different binding characteristics of the SH2 domains.
In this study, we overexpressed potentially dominant negative mutants to investigate the role of heterodimeric p85/p110 PI3-K in the activation of the mitogen-activated kinase, Erk2, and the transcription factor, NFAT. We found that PI3-K was involved in both processes, but in fundamentally different ways. Erk2 activation was inhibited by wortmannin and by a mutated p85 that cannot bind to the catalytic p110 subunit, but overexpression of other p85 constructs had no effect. Activation of NFAT, on the other hand, was insensitive to wortmannin, but was affected by overexpression of truncated forms of p85 in a different way than Erk2. To the best of our knowledge, this is the first report that describes a role of PI3-K in NFAT activation. Since catalytic activity does not seem to be involved, we speculate that p85 may have an adaptor function that is crucial for NFAT activation. This adaptor function would not only recruit p110 to the membrane but also bring other signaling proteins together, which then activate NFAT.
The used p85 constructs fall into two classes: (i) those that inhibit
TcR/CD3-mediated NFAT activation (SH3, PBP, N-SH2, and iSH2) and (ii)
those that increase NFAT activity in resting cells and synergize with
ionomycin (C-SH2, NC, NiC, p85iSH2, wild-type p85). Most striking is
perhaps that the two SH2 domains had opposite effects on NFAT
activation although their sequence specificity for phosphoprotein
binding is similar (Y*XXM) (30), and although they bound a
comparable pattern of cellular phosphotyrosine-containing proteins. It
is interesting to note that in a study using microinjected antibodies
against either SH2 domain of p85, anti-N-SH2 antibodies had a different
effect than anti-C-SH2 antibodies (31). We have attempted to identify
proteins that bind to the p85 mutants used here in a way that would
explain their role in NFAT activation, but Western blotting using
antibodies against c-Cbl (32, 33), Grb2 (34), Rac (35), Cdc42Hs, SLP-76
(36, 37), PLC
1, and the TcR
chain (38, 39) failed to show any
differences. It is unlikely that p85 acts through Cbl, because a
transforming Cbl mutant that constitutively activated NFAT (70/Z3)
still did so even after its binding to PI3-K was disrupted by a point
mutation (40).
A connection between PI3-K and Ras has been demonstrated in several reports. Ras can bind p110 in a GTP-dependent manner, and transfection of Ras resulted in an elevation of 3-phosphoinositides, whereas dominant negative RasN17 inhibited production of 3-phosphoinositides (21). Together with the finding that GTP-Ras could activate PI3-K (41), this argues for a role of Ras upstream of PI3-K. On the other hand, constitutively active PI3-K increased the amount of GTP-bound Ras and activated the c-fos promoter, and coexpression of dominant negative Ras blocked c-fos activation (42). Ras is also playing a major role in TcR-induced NFAT activation (43, 44). We were wondering if functional Ras was required for the p85NC-mediated increase in NFAT activity, and cotransfection of RasN17 showed that this was indeed the case. This would place Ras downstream of PI3-K in T cells, but does not exclude a role also upstream of PI3-K.
Although we presently do not know the molecular mechanism by which p85 activates NFAT, we found that several p85 constructs acted on NFAT activation via the Ras/PKC pathway. Activation of NFAT depends on two signals; calcium/calcineurin is required for nuclear translocation of NFATp, and Ras/PKC is required for induction of AP-1. Those p85 alleles that increased the basal NFAT level also synergized with ionomycin (but not with PMA), which suggests that they mimicked a process in the Ras/PKC pathway to cooperate with calcium/calcineurin. And while cyclosporin A effectively inhibited NFAT activation, coexpression of inhibitory p85 constructs caused an additional decrease in NFAT activity, most likely by interfering with the Ras/PKC pathway. Finally, the finding that RasN17 blocked p85NC-induced NFAT activation provides additional evidence for a function of p85 in the Ras pathway.
Taken together, our results indicate that p85 with its multiple domains plays an important and complex role in TcR-induced gene activation.