Regulation of Ribosomal S6 Kinase 2 by Effectors of the Phosphoinositide 3-Kinase Pathway*

Kathleen A. MartinDagger §, Stefanie S. SchalmDagger , Celeste RichardsonDagger ||, Angela RomanelliDagger **, Kristen L. KeonDagger , and John BlenisDagger DaggerDagger

From the Dagger  Department of Cell Biology, Harvard Medical School, Boston, Massachusetts 02115 and the  Freie Universitat Berlin, Institut fur Biochemie, Thielallee 63, 14195 Berlin, Germany

Received for publication, August 2, 2000, and in revised form, November 1, 2000



    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Ribosomal S6 kinase (S6K1), through phosphorylation of the 40 S ribosomal protein S6 and regulation of 5'-terminal oligopyrimidine tract mRNAs, is an important regulator of cellular translational capacity. S6K1 has also been implicated in regulation of cell size. We have recently identified S6K2, a homolog of S6K1, which phosphorylates S6 in vitro and is regulated by the phosphatidylinositide 3-kinase (PI3-K) and mammalian target of rapamycin pathways in vivo. Here, we characterize S6K2 regulation by PI3-K signaling intermediates and compare its regulation to that of S6K1. We report that S6K2 is activated similarly to S6K1 by the PI3-K effectors phosphoinositide-dependent kinase 1, Cdc42, Rac, and protein kinase Czeta but that S6K2 is more sensitive to basal activation by myristoylated protein kinase Czeta than is S6K1. The C-terminal sequence of S6K2 is divergent from that of S6K1. We find that the S6K2 C terminus plays a greater role in S6K2 regulation than does the S6K1 C terminus by functioning as a potent inhibitor of activation by various agonists. Removal of the S6K2 C terminus results in an enzyme that is hypersensitive to agonist-dependent activation. These data suggest that S6K1 and S6K2 are similarly activated by PI3-K effectors but that sequences unique to S6K2 contribute to stronger inhibition of its kinase activity. Understanding the regulation of the two S6K homologs may provide insight into the physiological roles of these kinases.



    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The 70-kDa ribosomal S6 kinase 1 (S6K1)1 is a ubiquitously expressed serine/threonine protein kinase that phosphorylates the 40 S ribosomal protein S6 in response to mitogen stimulation (1). S6 phosphorylation up-regulates translation of mRNAs with 5'-terminal oligopyrimidine tracts, many of which encode ribosomal proteins and translation elongation factors (2). S6K1 activation thus up-regulates ribosome biosynthesis and enhances the translational capacity of the cell.

Deletion of S6K1 in Drosophila and mice has implicated S6K1 in regulation of cell size. The Drosophila knockout has a high incidence of embryonic lethality, but surviving flies exhibit a marked reduction in size that is cell autonomous (3). Mice lacking S6K1 through targeted disruption also exhibit a small animal phenotype (4). Interestingly, S6 phosphorylation and 5'-terminal oligopyrimidine tract mRNA translation were found to be normal in fibroblasts derived from mice lacking S6K1, suggesting a compensatory mechanism for these S6K1 functions. Our lab and others have recently identified S6K2, a homolog of S6K1 that phosphorylates S6 in vitro (4-7). Elevated S6K2 mRNA levels have been reported in the S6K1 knockout mice (4). Drosophila are thought to express only S6K1, which may account for the more severe S6K1 knockout phenotype in flies. S6K2 is a good candidate kinase that may supply some but not all of the functions of S6K1 in the knockout mouse, because the small animal phenotype persists despite the presence of S6K2, S6 phosphorylation, and 5'-terminal oligopyrimidine tract mRNA translation.

There are two isoforms of both S6K1 and S6K2 derived from alternative splicing at the N terminus. The p70S6K1alpha II isoform is cytosolic, whereas p85 S6K1alpha I is nuclear (8). In contrast, both isoforms of S6K2 (p54 S6K2beta II, p60 S6K2beta I) (5, 6) are primarily nuclear, because of the presence of a C-terminal putative nuclear localization signal sequence (NLS) (7) not found in S6K1. Point mutation of the putative NLS (K474M) results in cytosolic immunolocalization of S6K2beta II (7). The S6K2 beta I and beta II isoforms may reside in distinct nuclear compartments based on subcellular fractionation studies (6).

S6K1 and S6K2 are highly homologous overall, with the greatest sequence homology in the kinase domain and adjacent regulatory linker domain. A schematic diagram of S6K1 and S6K2 outlining regions of homology, features unique to S6K2, and regulatory phosphorylation sites is provided in Fig. 1. Seven of eight mitogen-stimulated regulatory phosphorylation sites identified in S6K1 are conserved in human S6K2. There are interesting differences in S6K2 primary structure that may confer differential regulation and functions to this kinase. There are regions of sequence divergence between S6K1 and S6K2 in the N- and C-terminal domains. In addition to the nuclear localization signal, the C terminus of S6K2 also contains a proline-rich domain not found in S6K1.



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Fig. 1.   Primary structure of S6K1 and S6K2. Major domain boundaries and mitogen-stimulated phosphorylation sites are indicated. The solid black bars indicate regions of high sequence homology. The gray box indicates the homologous acidic domain of S6K1 and S6K2. The diagonally striped box indicates the unique proline-rich region of S6K2. The vertically striped bar indicates the sequence boundaries of the S6K2-Delta CT mutant.

In both S6K1 and S6K2, the conserved core catalytic and linker domains are flanked by regulatory N- and C-terminal domains. For S6K1, it is thought that interaction between N-terminal acidic residues and C-terminal basic residues inhibits the kinase by allowing a C-terminal pseudosubstrate region to occlude the kinase domain. Mitogen-stimulated phosphorylation of the C-terminal Ser/Thr-Pro motifs is believed to disrupt these interactions, relieving autoinhibition of S6K1 and exposing other regulatory sites, including the major rapamycin-sensitive site, T389, and the catalytic activation loop site, Thr229 (9, 10).

The PI3 kinase (PI3-K) and mTOR signaling pathways mediate multiple mitogen-stimulated phosphorylation events that lead to S6K1 activation. Consistent with the important roles of these pathways in S6K1 regulation, S6K1 activation is inhibited by pharmacological inhibitors of these pathways (11, 12). The immunosuppressant rapamycin, an inhibitor of mTOR, leads to rapid and complete dephosphorylation and inactivation of S6K1 (11). The role of mTOR in S6K1 activation may be suppression of an S6K1 phosphatase (13). There is also evidence suggesting that mTOR may directly phosphorylate S6K1 (14). S6K2 activation is also sensitive to rapamycin, and the analogous rapamycin-sensitive mitogen-stimulated S6K1 phosphorylation sites are conserved in S6K2 (Thr388, Ser410, Ser417, and Ser423) (4-7).

Multiple PI3-K effectors provide distinct inputs to S6K1 activation. Phosphoinositide-dependent kinase 1 (PDK1) is a constitutively active kinase whose access to many substrates is regulated by PI3-K-derived phosphatidylinositol 3,4-bisphosphate and phosphatidylinositol 3,4,5-trisphosphate (15). Phosphorylation of Thr229 in the S6K1 catalytic domain activation loop by PDK1 is a critical activating input (15, 16). PDK1 may also phosphorylate Thr389 (17). The PI3-K- and PDK1-regulated atypical PKC isoforms zeta  and lambda  have also been implicated in S6K1 regulation (18, 19). These atypical PKCs interact with S6K1, but it is not yet known whether they directly phosphorylate S6K1. We have reported growth factor-independent coimmunoprecipitation of PDK1, PKCzeta , and S6K1, suggesting the existence of preassembled complexes of PI3-K-regulated signaling molecules (18). Our lab has also demonstrated association of the PI3-K-regulated Rho family G proteins Cdc42 and Rac with S6K1 and has shown that these G proteins contribute to S6K1 activation (20). Interestingly, Cdc42 and PKCzeta or PKClambda have recently been shown to associate (21). The mechanism of Cdc42/Rac activation of S6K1 is not yet known but requires isoprenylation of the G protein, suggesting that membrane targeting is important (20).

Preliminary studies using pharmacological inhibitors suggest that, like S6K1, S6K2 is regulated by the PI3-K and mTOR signaling pathways (4-7). We have shown that a constitutively active PI3-K p110 subunit activates S6K2 and that S6K2 is activated by PDK1 (6). Others have found that S6K2, like S6K1, can be regulated by the PI3-K effector Akt/PKB (7). However, further characterization of the signaling intermediates that regulate S6K2 has not yet been addressed. Given the differences in subcellular localization and primary sequence and the lack of complete functional redundancy between these homologs in the S6K1 knockout mice (4), we aimed to examine in detail the regulation of S6K2. Here, we report that although S6K2 is regulated similarly to S6K1 by PI3-K effectors, the C terminus of S6K2 exerts a more potent inhibitory effect on the kinase.


    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Plasmids and Mutagenesis-- Eukaryotic expression vectors encoding rat p70 S6K1 alpha II (HA-S6K1/pRK7) or human p54 S6K2 beta II (HA-S6K2/pcDNA3) under the control of the cytomegalovirus promoter have been described (6). A schematic alignment of rat S6K1 alpha II and human S6K2 beta II isoforms identifying domain junctions and phosphorylation sites is indicated in Fig. 1. A detailed primary sequence alignment has been published (5). HA-S6K plasmids were mutagenized using the Quik-Change polymerase chain reaction-based method (Stratagene). To generate HA-S6K2-Delta CT, a stop codon was introduced at amino acid 399 (Fig. 1). HA-S6K1-Delta CT has been described (9). Plasmids encoding GST-Cdc42 or GST-Rac1 and mutants (20), Myc-PDK1/pcDNA3 (22), and FLAG-PKCzeta and mutants (18) have been described elsewhere .

Cell Culture and Transfection-- HEK293E cells were cultured in Dulbecco's modified Eagle's medium supplemented with 10% fetal bovine serum, 0.2 units/ml penicillin, and 200 ng/ml streptomycin. Cells were seeded at 1 × 106/60-mm dish 1 day prior to transfection. Cells were transfected with 6-10 µg of total DNA by the calcium phosphate method for 6 h, washed with phosphate-buffered saline, and allowed to recover in Dulbecco's modified Eagle's medium with 10% fetal bovine serum overnight. Cells were then starved in serum-free Dulbecco's modified Eagle's medium for 24 h prior to stimulation and lysis.

Cell Lysis and Immunoblotting-- Cells were pretreated for 30 min with wortmannin or vehicle then stimulated with 100 nM insulin or 50 ng/ml epidermal growth factor for 30 min. Cells were washed with phosphate-buffered saline and scraped in lysis buffer (10 mM KPO4, 1 mM EDTA, 10 mM MgCl2, 50 mM beta -glycerophosphate, 5 mM EGTA, 0.5% Nonidet P-40, 0.1% Brij 35, 0.1% sodium deoxycholate, 1 mM sodium orthovanadate, 40 mg/ml phenylmethylsulfonyl fluoride, 10 µg/ml leupeptin, 5 µg/ml pepstatin, pH 7.28) and centrifuged at 15,000 × g for 10 min. Lysates (10% total) were subjected to 7.5% SDS-polyacrylamide gel electrophoresis, transferred to nitrocellulose membrane, immunoblotted using alpha -HA, alpha -GST (Santa Cruz), alpha -PKCzeta (22), or alpha -Myc (22), and horseradish peroxidase-conjugated secondary antibody, and detected with enhanced chemiluminescence reagents.

Immune Complex Kinase Assay-- One-third of total lysate was immunoprecipitated using alpha -HA antibody and protein A-Sepharose. Alternately, volumes of lysate assayed were normalized to reflect S6K expression levels determined by Western blotting. Immunoprecipitates were washed with 1 ml each of buffer A (10 mM Tris, 1% Nonidet P-40, 0.5% sodium deoxycholate, 100 mM NaCl, 1 mM EDTA, 1 mM sodium orthovanadate, 2 mM dithiothreitol, 10 µg/ml leupeptin, and 5 µg/ml pepstatin, pH 7.2), buffer B (buffer A except with 0.1% Nonidet P-40 and 1 M NaCl), and ST buffer (50 mM Tris-HCl, 5 mM Tris-base, 150 mM NaCl, pH 7.2). Kinase activity toward a recombinant GST-S6 peptide (32 final amino acids of ribosomal S6) in washed immunoprecipitates was assayed in a reaction containing 20 mM HEPES, 10 mM MgCl2, 50 µM ATP unlabeled, 5 µCi of [gamma -32P]ATP (PerkinElmer Life Sciences), 3 ng/µl PKI, pH 7.2, for 12 min at 30 °C. Reactions were subjected to 12% SDS-polyacrylamide gel electrophoresis, and the amount of 32P incorporated into GST-S6 was assessed by autoradiography and quantitated by phosphorimaging (Bio-Rad).


    RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

S6K2, like S6K1, is regulated by the PI3-K pathway. S6K2 is activated by constitutively active p110 PI3-K and inhibited when cells are treated with wortmannin (6). Wortmannin-sensitive phosphorylation sites found in S6K1 are conserved in S6K2 and S6K1. Multiple PI3-K pathway effectors have been implicated in S6K1 activation. Given the differences in primary structure and subcellular localization between S6K2 and S6K1, we sought to determine whether S6K2 is regulated by the same downstream PI3-K effectors known to regulate S6K1 and to investigate the roles of divergent S6K2 C-terminal sequences.

Rho Family G Proteins Regulate S6K2-- Evidence suggests that PI3-K regulates the Rho family G proteins Cdc42 and Rac through activation of their guanine nucleotide exchange factors, such as Dbl and Vav (23). We have previously shown that Cdc42 and Rac regulate S6K1; cotransfection of GTPase-deficient constitutively active point mutants of Cdc42 and Rac (G12V) activates HA-S6K1, and dominant negative point mutants (T17N) with high GDP affinity (which sequester guanine nucleotide exchange factors) antagonize growth factor activation of S6K1 (20). Similarly, transient cotransfection of HEK293 cells with HA-S6K2 and GST-Cdc42V12 or GST-RacV12 enhanced basal (2-5-fold) and insulin-stimulated (2-3-fold) activity as measured in immune complex kinase assays (Fig. 2A). Consistent with a role for Rho family G proteins in regulation of S6K2, cotransfection of HA-S6K2 with the dominant negative GST-Cdc42N17 mutant inhibits insulin stimulation of HA-S6K2, as well as HA-S6K1, activity (Fig. 2B). PDK1 activates S6K1 by phosphorylating Thr229 in the catalytic activation loop (15, 16). It is likely that Cdc42 contributes an S6K-activating function distinct from that of PDK1, because cotransfection of submaximally activating levels of Myc-PDK1 and GST-Cdc42V12 cooperatively activate S6K2. We demonstrate here for the first time that this is also the case with S6K1 (Fig. 3).



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Fig. 2.   Rho family G proteins regulate S6K2. A, constitutively active mutants of Cdc42 or Rac activate HA-S6K2. HEK293 cells were transfected with 1.0 µg of HA-S6K2/pcDNA3 and the indicated amounts of GST-Cdc42V12/pEBG, GST-RacV12/pEBG, or pEBG vector as described under "Experimental Procedures." Transfected cells were quiesced in serum-free medium for 24 h prior to 30 min of stimulation with 100 nM insulin. Cells were lysed as described, and protein expression levels were assayed by immunoblotting with anti-HA or -GST antibodies. HA-S6K2 expression levels were normalized by quantitative immunoblotting using a Bio-Rad FluorS MultiImager prior to immune complex kinase assay. Kinase activity in anti-HA immunoprecipitates was quantitated with a phosphorimager (Bio-Rad). These results are representative of at least two experiments. B, a dominant negative Cdc42 mutant inhibits HA-S6K2 activity. HEK293 cells were transfected with 1.0 µg of HA-S6K2/pcDNA3 or 0.5 µg of HA-S6K1/pRK7 and the indicated amounts of GST-Cdc42N17/pEBG or pEBG vector and starved, insulin-stimulated, and lysed as above. Data from immune complex kinase assay (top panels) and anti-HA or -GST Western blots (bottom panels) are shown and are representative of at least three experiments.



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Fig. 3.   Cdc42 and PDK1 cooperatively activate HA-S6K2 and HA-S6K1. HEK293 cells were transfected with 1.0 µg of HA-S6K2/pcDNA3 or 0.5 µg of HA-S6K1/pRK7 and submaximally activating doses (0.5 µg) of GST-Cdc42V12/pEBG and/or Myc-PDK1/pcDNA3 or pEBG vector. Cells were starved, insulin-stimulated, and lysed as in Fig. 2. Activity of HA-S6K2 or HA-S6K1 is indicated in the top panels. Anti-HA, -GST, or -Myc Western blots are shown in the bottom panels. Data are representative of two experiments.

The mechanism by which Cdc42 activates S6K1 is not yet known, but Cdc42V12 and S6K1 coimmunoprecipitate and a mutation that prevents Cdc42 isoprenylation (C189S) fails to activate S6K1 (20). This suggests that membrane targeting of Cdc42 may be required. An attractive hypothesis is that association with Cdc42 may transiently target S6K1 to a cellular membrane in the course of its activation. This membrane targeting may be important for access to other membrane-associated S6K1 activators such as PDK1 and PKCzeta . Because S6K2 is thought to be primarily nuclear, it is notable that the cytosolic proteins Cdc42 and Rac can regulate this kinase. We determined that isoprenylation of GST-Cdc42V12 is required for this effect, because GST-Cdc42V12,C189S fails to activate HA-S6K2 when cotransfected (Fig. 4). These data suggest that despite localization primarily to the nucleus, S6K2 is regulated by cytosolic, isoprenylated low molecular weight G proteins. We hypothesize therefore that S6K2 may shuttle in and out of the nucleus and target to a membrane during the course of its activation.



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Fig. 4.   A prenylation-deficient mutant Cdc42V12 fails to activate HA-S6K2. HEK293 cells were transfected with 1.0 µg of HA-S6K2/pcDNA3 with 2 µg of GST-Cdc42V12/pEBG, GST-Cdc42V12/C189S/pEBG, or pEBG vector. Cells were starved, insulin-stimulated, and lysed as in Fig. 2. Activity of HA-S6K2 is indicated in the top panel and anti-HA or -GST Western blots are presented in the bottom panel. Data are representative of two experiments.

Atypical PKCzeta Regulates S6K2-- S6K1 associates with and is regulated by the atypical PKCzeta (18). PKCzeta is activated by binding PI3-K-derived phosphatidylinositol 3,4,5-trisphosphate and by interaction with and phosphorylation by PDK1 (22, 24). Although PKCzeta is not sufficient to activate S6K1 under basal conditions, when coexpressed with PDK1, a strong S6K1 activation is observed (18). Coimmunoprecipitation of S6K1, PDK1, and PKCzeta suggests their participation in a PI3-K-regulated signaling complex (18). To address whether PKCzeta can regulate S6K2 in vivo, we cotransfected a constitutively active FLAG-tagged, myristoylated PKCzeta (myr-PKCzeta ) construct with HA-S6K2, which resulted in basal and insulin-stimulated HA-S6K2 activation (Fig. 5A). There was a notable difference between S6K1 and S6K2, because HA-S6K1 was activated only modestly (up to 2-fold) by cotransfection of myr-PKCzeta in quiescent cells (Fig. 5A) and (18), whereas HA-S6K2 was activated 5-30-fold under basal conditions (Fig. 5A), suggesting that S6K2 may be more sensitive to regulation by atypical PKCs. Further supporting a role for PKCzeta in activation of HA-S6K2 was the observation that insulin-stimulated activity was inhibited by cotransfection of the dominant negative FLAG-PKCzeta K281W (PKCzeta K/W) (Fig. 5B), as is the case with S6K1 (18). In addition, HA-S6K2 is cooperatively activated by combined cotransfection of submaximally activating levels of myr-PKCzeta and PDK1 (Fig. 6). Under these conditions, the constitutively active myr-PKCzeta is not further activated by PDK1 (22), but the modest overexpression of both activators results in synergistic activation of S6K2. Although both S6K1 and S6K2 are inhibited by dominant negative PKCzeta (K/W) and cooperatively activated by PDK1 and myr-PKCzeta , only S6K2 basal activity is substantially activated by myr-PKCzeta alone. These data provide the first evidence that S6K1 and S6K2 can be differentially regulated.



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Fig. 5.   Atypical PKCzeta regulates HA-S6K2. A, myristoylated PKCzeta activates HA-S6K2. HEK293 cells were transfected with 1.0 µg of HA-S6K2/pcDNA3 or 0.5 µg of HA-S6K1/pRK7 and 1.0 µg of FLAG-myr-PKCzeta /pCMV6. Cells were quiesced, insulin-stimulated, and lysed as in Fig. 2. HA-S6K activity is presented in the top panel. Anti-HA and anti-PKCzeta Western blots are shown in the bottom panel. Data are representative of three experiments. B, HA-S6K2 activation is inhibited by dominant negative PKCzeta . HEK293 cells were transfected with 1.0 µg of HA-S6K2/pcDNA3 and 4.0 µg of FLAG-PKCzeta K281W/pCMV6 as indicated. Cells were quiesced, insulin-stimulated, and lysed as in Fig. 2. HA-S6K2 activity is presented in the top panel. Anti-HA and anti-PKCzeta , Western blots are shown in the bottom panel. Data are representative of at least two experiments.



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Fig. 6.   PKCzeta and PDK1 cooperatively activate HA-S6K2. HEK293 cells were transfected with 1.0 µg of HA-S6K2/pcDNA3 and 1.0 µg of FLAG-myr-PKCzeta /pCMV6 and/or 0.5 µg of Myc-PDK1/pcDNA3 as indicated. Cells were quiesced, insulin-stimulated, and lysed as in Fig. 2. HA-S6K2 activity is presented in the top panel. Anti-HA, -PKCzeta , and -Myc Western blots are shown in the bottom panel. Data are representative of three experiments.

C-terminal Truncation Potentiates S6K2 Activation-- Structure-function mutational analyses have provided important insight into regulation and activation of S6K1 (9, 10). We employed this approach to further study the regulation of S6K2. Because the C-terminal domain is a region of divergence between S6K1 and S6K2, we sought to determine the effect of deletion of this domain on regulation of S6K2. Amino acids 399-482 encoding the pseudosubstrate and proline-rich regions, as well as the NLS, were deleted from HA-S6K2 (Fig. 1), and the activity of the resulting mutant (HA-S6K2-Delta CT) was assayed in transfected HEK293 cells. Surprisingly, deletion of the C terminus resulted in enhanced basal and insulin-stimulated activity (Figs. 7 and 8). By contrast, the analogous truncation mutant of S6K1 is mitogen-regulated but is less active than the full-length kinase and is not more sensitive to insulin (9, 10) and (Fig. 8). The S6K2 C-terminal truncation did not significantly alter sensitivity of the kinase to wortmannin (Fig. 7B), suggesting that essential inputs from the PI3-K pathway are primarily integrated in regions upstream of amino acid 399. 



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Fig. 7.   C-terminal truncation potentiates HA-S6K2 activation. A, enhanced basal and PDK1 or insulin-stimulated activity of HA-S6K2-Delta CT. HEK293 cells were transfected with 1.0 µg of HA-S6K2 wild type (wt) or 2 µg of HA-S6K2-Delta CT (Delta CT) in the pcDNA3 vector and 1.0 µg of Myc-PDK1/pcDNA3 as indicated. Cells were serum-starved, insulin-stimulated, and lysed as in Fig. 2. Lysates were normalized for HA-S6K2 expression levels after Western blotting, and kinase activity was assayed. Data are representative of at least two experiments. B, HA-S6K2 wild type and HA-S6K2-Delta CT are sensitive to wortmannin. HEK293 cells were transfected with 1.0 µg of HA-S6K2 wild type (wt) or 2 µg of HA-S6K2-Delta CT in the pcDNA3 vector. Cells were serum-starved for 24 h and then pretreated with 100 nM wortmannin or vehicle for 30 min prior to a 30-min stimulation with 100 nM insulin. Cells were lysed and subjected to immunoblotting and kinase assay as in Fig. 2. Activity and anti-HA Western blots are shown. Data are representative of two experiments.



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Fig. 8.   Insulin and Cdc42V12 activation of HA-S6K2 versus HA-S6K1 C-terminal truncation mutants. HEK293 cells were transfected with 1.0 µg of HA-S6K2 wild type (wt) or 2 µg of HA-S6K2-Delta CT in the pcDNA3 vector or with 1.0 µg of HA-S6K1 wild type or HA-S6K2-Delta CT in the pRK7 vector along with 1.0 µg of GST-Cdc42V12/pEBG or pEBG vector as indicated. Cells were starved, insulin-stimulated, lysed, and Western blots (anti-HA, anti-GST), and kinase assays were performed as described for Fig. 7A. Data are representative of at least three experiments.

Another marked difference was that basal and insulin-stimulated HA-S6K2-Delta CT activity was dramatically potentiated by cotransfection with Myc-PDK1 (30-fold basal activation; Fig. 7A). In contrast, HA-S6K1-Delta CT was more modestly activated by PDK1 (4-fold basal activation; data not shown) (18). Insulin-stimulated HA-S6K2-Delta CT activity is also more sensitive to activation by Cdc42V12 than HA-S6K2 wild type (Fig. 8). As with PDK1 activation, Cdc42V12 stimulation of the S6K2 C-terminal mutant is stronger than of the analogous S6K1 mutant under both starved and stimulated conditions (Fig. 8). These data demonstrate that the presence of the intact C-terminal domain exerts a more potent inhibitory influence on S6K2 than on S6K1, because deletion of the domain greatly facilitates S6K2 activation by insulin or PI3-K effectors.

There is a striking difference (10-25-fold) in the specific activity of S6K1 and S6K2. In our immune complex kinase assays, with equivalent protein expression levels, S6K2 is a significantly less active kinase toward GST-S6 or histone H2B substrates (Figs. 2B, 3, 5A, and 8 and Ref. 6). However, the insulin-stimulated specific activity of HA-S6K2-Delta CT upon cotransfection with Myc-PDK1 or Cdc42V12 was similar to the specific activity of wild type HA-S6K1 (Figs. 7A and 8). These data show that the intrinsic specific activity of the S6K2 kinase domain is not less than that of S6K1 but that S6K2 kinase activity is subject to repression in vivo, mediated by the C-terminal domain. Thus, a second major difference between these closely related S6 kinases is the role of the C terminus in the activation process.


    DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In vivo studies suggest that S6K1 and S6K2 may serve both distinct and overlapping physiological functions, because it appears that S6K2 can only partly compensate in cells lacking S6K1 (4). The primarily nuclear localization of S6K2 (7) also suggests that S6K2 may serve unique functions. Given the likely functional differences, as well as regions of divergence in primary sequence, it is important to understand the upstream signaling pathways and intermediates that regulate each S6 kinase to coordinate these physiological responses. Our studies of the recently identified S6K1 homolog, S6K2, reveal similarities as well as differences in the regulation of these related kinases. Both are activated by common effectors of the PI3-K pathway, including Akt (7), Cdc42, Rac, PKCzeta , and PDK1 (this report). In addition, we demonstrate that regions of sequence divergence, particularly in the C terminus, dramatically influence the specific activity and growth factor activation of S6K2.

The PI3-K pathway is critical to activation of S6 kinases, because PI3-K inhibition with wortmannin or LY294002 potently inhibits activation of both S6K1 and S6K2 (4-7). Here, we show that PI3-K effectors known to participate in S6K1 activation also activate S6K2. In addition, Akt overexpression activates both S6K1 and S6K2 (7). Because the various PI3-K effectors examined here exhibit distinct patterns of cytosolic, membrane, and nuclear localization, it is surprising that all were implicated in S6K2 activation. Because there is evidence that Akt and PKCzeta can translocate to the nucleus in stimulated cells (25, 26), it is reasonable to hypothesize that these kinases may regulate S6K2, which is primarily nuclear. However, Cdc42, Rac, and PDK1, thought to be cytosolic and associated with membranes (21, 27), are potent activators of S6K2. It is likely that this regulation is not merely due to overexpression of these proteins, because inhibition of endogenous Cdc42 or PDK1 by expression of dominant negative mutants inhibits S6K2 (this report and Ref. 6). We therefore hypothesize that S6K2 may shuttle between the nucleus and the cytosol during the course of its activation. We and others do not detect a stable change in subcellular localization in HA-S6K2 by immunofluorescence in quiescent versus growth factor-stimulated cells (data not shown and Ref. 7), suggesting that any cytosolic translocation may be rapid and transient and/or involve levels of protein below the range of detection of this method. Such nuclear/cytosolic shuttling models have been suggested for other signaling proteins and kinases including Ste5, MEK, and extracellular signal-regulated kinase (28, 29). Furthermore, our data suggest that S6K2 may transiently associate with a cytosolic membrane during the activation process, as a prenylation-deficient Cdc42 mutant that does not associate with membranes fails to activate S6K2. Additionally, all of the PI3-K effectors implicated in S6K2 regulation can associate with cellular membranes in growth factor-stimulated cells (23).

One difference we have identified in PI3-K-mediated regulation of full-length S6Ks is that S6K2 is more sensitive to activation by PKCzeta than is S6K1. Because the mechanism by which PKCzeta activates S6K1 is not yet understood, why the effect may be stronger on S6K2 is uncertain. The ability of PKCzeta to translocate to the nucleus suggests a potential mechanism (26). We have previously shown that PKCzeta activates S6K1 lacking the C-terminal MEK-dependent sites (18). Similarly, HA-S6K2-D3, in which C-terminal MEK-dependent sites are replaced with aspartic acid residues, is activated by PKCzeta (data not shown). These data suggest that PKCzeta -mediated extracellular signal-regulated kinase activation (30-32) is not a likely mechanism for preferential S6K2 versus S6K1 regulation. In addition, we do not detect activation of extracellular signal-regulated kinase 1/2 by transfection of myr-PKCzeta in our experiments (data not shown and Ref. 18).

We report here a significant difference in the role of the C-terminal domain in regulation of S6K1 and S6K2. Both contain a pseudosubstrate region with high homology to S6. Autoinhibition of S6K1 by this pseudosubstrate domain is thought to be relieved by phosphorylation of four proline-directed sites (Ser411, Ser418, Ser421, and Ser423) within this region. Deletion of the C-terminal domain of S6K1 results in a kinase with activity slightly lower than that of full-length S6K1, which is still sensitive to activation by mitogens and inhibition by wortmannin (9, 10). By contrast, the analogous C-terminal truncation of S6K2 is also sensitive to wortmannin but confers elevated basal activity and hypersensitivity to mitogens or PI3-K effectors. Thus, the greatly reduced specific activity of S6K2 relative to S6K1 appears to be mediated in part by the S6K2 C terminus, because HA-S6K2-Delta CT can be activated by PDK1 and growth factors to levels similar to S6K1 activity.

The C termini of S6K1 and S6K2 are highly homologous (73% identity) in the pseudosubstrate region. However, there is only 25% sequence identity between the kinases from the end of this region to the extreme C terminus (S6K2 beta II amino acids 429-482) (5). It is likely that sequences within this divergent region account for the particularly strong inhibition of S6K2. Of note, this region of S6K2 encodes a polyproline-rich domain not found in S6K1. This domain could potentially interact with SH3 domain containing proteins that may confer unique regulation to S6K2. However, Gout et al. (5) cite unpublished data indicating that selective deletion of this proline-rich domain does not alter activity of S6K2. It is not known whether the effects of coexpressed PDK1 or other PI3-K effectors might be greater on this mutant, as is the case for S6K2-Delta CT.

One hypothesis for the enhanced activity of the S6K2-Delta CT mutant is that deletion of the C-terminal NLS and consequent cytosolic localization facilitates S6K2 activation. Immunofluorescence studies indicate that this mutant is in fact localized to the cytosol (data not shown). We have recently examined the roles of the unique S6K2 C-terminal features in an accompanying study (33). We report that disruption of the unique S6K2 C-terminal NLS by point mutation potentiates S6K2 activation but is not responsible for the dramatic effects observed upon truncation of the entire C-terminal domain. Instead, we find that MEK-dependent regulation of three C-terminal proline-directed phosphorylation sites is the critical regulatory influence on this domain.

PI3-K-derived lipid messengers mediate signals affecting the critical processes of cell growth and size, proliferation, and survival. We demonstrate here that despite distinct patterns of subcellular localization and divergences in primary sequence, S6K1 and S6K2 are regulated similarly by effectors of the PI3-K pathway. However, we also identify differences in activity and regulation of these related kinases, such as reduced specific activity of S6K2 compared with S6K1, greater S6K2 sensitivity to atypical PKCzeta , and a differential C-terminal domain regulatory mechanism. The phenotype of the mice lacking S6K1 through homologous recombination suggests that S6K1 and S6K2 share common as well as nonredundant functions. Our regulatory data further support the possibility that these related kinases may regulate both common and distinct cellular substrates and functions. Differential response to downstream effectors of common pathways, along with discrete subcellular localization, may confer specificity toward potentially unique substrates of these S6 kinases.


    ACKNOWLEDGEMENTS

We thank members of the Blenis laboratory and John Hwa for critical reading of this manuscript.


    FOOTNOTES

* This work was supported by National Institutes of Health Grant GM51405 (to J. B.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ Recipient of a Postdoctoral Fellowship from the American Cancer Society. Present address: Div. of Vascular Surgery, Dartmouth Medical School, Dartmouth-Hitchcock Medical Center, Lebanon, NH 03756.

|| Glaxo Wellcome Gertrude B. Elion Fellow of the Leukemia and Lymphoma Society of America.

** Recipient of the Charles A. King Trust Fellowship Award from the Medical Foundation.

Dagger Dagger To whom correspondence should be addressed: Dept. of Cell Biology, Harvard Medical School, 240 Longwood Ave., Boston, MA 02115. E-mail: jblenis@hms.harvard.edu.

Published, JBC Papers in Press, December 6, 2000, DOI 10.1074/jbc.M006969200


    ABBREVIATIONS

The abbreviations used are: S6K, ribosomal S6 kinase; PI3-K, phosphoinositide 3-kinase; mTOR, mammalian target of rapamycin; PDK1, phosphoinositide-dependent kinase 1; MEK, mitogen-activated protein-extracellular signal-regulated kinase kinase; NLS, nuclear localization signal; PKC, protein kinase C; myr-PKC, myristoylated PKC; GST, glutathione S-transferase; HA, hemagglutinin.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES


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