(Received for publication, February 20, 1997, and in revised form, May 28, 1997)
From the Section for Molecular Signaling, Department of Cell and Molecular Biology, Lund University, S-221 00 Lund, Sweden and § NHLBI, National Institutes of Health, Bethesda, Maryland 20892
Protein kinase B (PKB) (also referred to as RAC/Akt kinase) has been shown to be controlled by various growth factors, including insulin, using cell lines and transfected cells. However, information is so far scarce regarding its regulation in primary insulin-responsive cells. We have therefore used isolated rat adipocytes to examine the mechanisms, including membrane translocation, whereby insulin and the insulin-mimicking agents vanadate and peroxovanadate control PKB. Stimulation of adipocytes with insulin, vanadate, or peroxovanadate caused decreased PKB mobility on sodium dodecyl sulfate-polyacrylamide gels, indicative of increased phosphorylation, which correlated with an increase in kinase activity detected with the peptide KKRNRTLTK. This peptide was found to detect activated PKB selectively in crude cytosol and partially purified cytosol fractions from insulin-stimulated adipocytes. The decrease in electrophoretic mobility and activation of PKB induced by insulin was reversed both in vitro by treatment of the enzyme with alkaline phosphatase and in the intact adipocyte upon removal of insulin or addition of the phosphatidylinositol 3-kinase (PI 3-kinase) inhibitor wortmannin. Significant translocation of PKB to membranes could not be demonstrated after insulin stimulation, but peroxovanadate, which appeared to activate PI 3-kinase to a higher extent than insulin, induced substantial translocation. The translocation was prevented by wortmannin, suggesting that PI 3-kinase and/or the 3-phosphorylated phosphoinositides generated by PI 3-kinase are indeed involved in the membrane targeting of PKB.
In recent years, the recognition of phosphatidylinositol 3-kinase (PI 3-kinase)1 as an important link in insulin signal transduction has facilitated understanding of new signaling mechanisms. Activation of PI 3-kinase by insulin and growth factors leads to generation of 3-phosphorylated phosphoinositides such as phosphatidylinositol 3,4-bisphosphate and phosphatidylinositol 3,4,5-trisphosphate (1, 2), which are believed to act as second messengers. In a number of cultured cells the serine/threonine protein kinase B (PKB), also known as RAC or Akt, has been shown to be a target for PI 3-kinase-generated signals (3-8). PKB is expressed as three isoforms (9-13), all of which contain an amino-terminal pleckstrin homology (PH) domain (14), which may be involved in protein-protein or protein-lipid interactions (15). A proposed mechanism for the PI 3-kinase-dependent activation of PKB involves translocation of PKB from the cytosol to membranes and subsequent phosphorylation by one or several membrane-associated kinase(s) (7, 16). It has been demonstrated that PKB can bind to phosphatidylinositol 3,4-bisphosphate (17, 18) and phosphatidylinositol 3,4,5-trisphosphate in vitro (18), most likely through its PH domain, suggesting that in vivo the formation of such lipids by activated PI 3-kinase could have a role in the translocation of PKB. It is a matter of controversy whether the 3-phosphorylated phosphoinositides not only bind but also to some extent activate PKB (3, 17-19).
Because almost all of the studies concerning the proposed mechanism(s) for insulin regulation of PKB have been carried out using cell lines or transfected cells and some of the findings are conflicting, there is obviously need for such information also from insulin-responsive target tissues such as liver, muscle, or adipose tissue. Therefore, we have performed such studies in the isolated rat adipocyte. Major findings reported in this paper are that PKB in the intact adipocyte is rapidly and reversibly activated in response to physiological concentrations of insulin and upon stimulation with the insulin-mimicking agent peroxovanadate is translocated to membranes via a wortmannin-sensitive mechanism.
Insulin and PD 98059 were gifts from Novo
Nordisk, Gentofte, Denmark, and Parke Davis, Michigan. 4--Phorbol
12-myristate 13-acetate (PMA), wortmannin, sodium orthovanadate, cAMP
protein kinase inhibitor, and alkaline phosphatase (from bovine
intestinal mucosa, type VII-T) were from Sigma. Rapamycin was from ICN
Biomedical, and protein A-Sepharose from was Pharmacia Biotech Inc.
Peptides KKRNRTLTK (K9), KKRNRTLSK, and Crosstide (6) were synthesized at the Biomolecular Unit, Lund University. [
-32P]ATP
was synthesized as described (20).
Adipocytes
prepared from epididymal adipose tissue of 36-38-day-old male Harlan
Sprague Dawley rats (B&K Universal, Stockholm) (21, 22) were suspended
(1 ml of packed cells/10 ml of medium) in Krebs-Ringer medium, pH 7.4, 25 mM Hepes, 200 mM adenosine, 2 mM
glucose, and 1% bovine serum albumin. Vanadate (300 mM)
was dissolved in water and boiled before use. Peroxovanadate was
prepared fresh by incubating vanadate and H2O2
(12 mM each) at 20 °C in 40 mM Hepes, pH
7.4, for 15 min prior to use. PMA, wortmannin, rapamycin, and PD 98059 were dissolved in Me2SO and added to cells, resulting in a
final Me2SO concentration of 0.15%. Adipocytes (1.5 ml of 10-12% (v/v) cell suspension, unless otherwise stated) were incubated at 37 °C with the indicated additions. The
incubations were terminated by the addition of 7 ml of homogenization
buffer consisting of 50 mM TES, pH 7.4, 2 mM
EGTA, 1 mM EDTA, 250 mM sucrose, 1 mM dithioerythritol, 40 mM phenyl phosphate, 5 mM NaF, 1 mM phenylmethylsulfonyl fluoride,
0.05 mM sodium orthovanadate, antipain (10 µg/ml),
leupeptin (10 µg/ml), and pepstatin A (1 µg/ml). Cells were
centrifuged, resuspended in 1 ml of homogenization buffer, and
homogenized (10 strokes) at room temperature. The homogenates were
centrifuged at 35,000 × g for 60 min at 4 °C, supernatants (referred to as cytosol fractions) withdrawn, and the
pellets (referred to as membrane fractions) resuspended in 0.5 ml of
homogenization buffer. Cytosol and membrane fractions were usually
assayed for kinase activity directly; they could, however, be stored at
20 °C for more than 3 months without detectable loss of kinase
activity.
A fragment of 1,440 base
pairs, encompassing the coding sequence of PKB, was amplified from a
rat adipocyte cDNA library in the pGAD 10 yeast expression vector
(CLONTECH). The primers for polymerase chain
reaction were complementary to nucleotides 1-24 and 1420-1440,
respectively, of PKB
(13). Amplification was performed with 35 cycles of denaturation (1 min at 94 °C), annealing (2 min at
50 °C), and polymerization (2 min at 72 °C). The amplified
cDNA was subcloned into the PCR-Script vector (Stratagene), and the
sequence was verified by automated sequencing. Full-length PKB
(amino acids 1-480) and a PH-domain-containing fragment (PH-PKB, amino
acids 1-110) were obtained as histidine-tagged bacterial fusion
proteins using the pET expression system (Novagen). Restriction sites
for subcloning into the pET15 vector were created by adding NdeI and BamHI, respectively, to the appropriate
primers before reamplification from the PCR-Script/PKB vector.
Expression was induced in the Escherichia coli BL23/pLysS
strain using 1 mM isopropyl
-D-thiogalactopyranoside for 3 h at 37 °C
(full-length PKB) or 6 h at 28 °C (PH-PKB).
Yeast expression of PKB fused to a GAL4 DNA binding domain was
accomplished through subcloning the full-length coding cDNA of
PKB into the pAS2-1 vector (CLONTECH).
pAS2/GAL-PKB was used to transform the Saccharomyces
cerevisiae strain Y190, employing the lithium acetate method (23).
For analysis of expressed protein, yeast extracts were prepared from
mid-log phase cultures using a glass bead cell disruption procedure as
described (24).
Antibodies against amino- and carboxyl-terminal
peptides of PKB (anti-NT-PKB
and anti-CT-PKB
, respectively)
were from Upstate Biotechnology Inc., Lake Placid, NY. Antibodies
against the PH domain of PKB were from Transduction Laboratories,
Lexington, KY. Antibodies against full-length PKB and PH-PKB were
raised in rabbits using the E. coli-expressed,
histidine-tagged proteins, purified from inclusion bodies and eluted
from SDS-polyacrylamide gel electrophoresis (PAGE) gels. The antisera
were affinity purified as described (25).
Adipocyte cytosol and membrane fractions and column fractions
were mixed with Laemmli sample buffer (26) and subjected to SDS-PAGE
(8% polyacrylamide) followed by electrotransfer of protein onto
polyvinylidene difluoride membranes (Millipore). After blocking with
0.5% gelatin in phosphate-buffered saline the membranes were incubated
for 4-16 h with a 1:5,000 dilution of the anti-NT-PKB antibody.
Immunoblot analysis was performed using the enhanced chemiluminescence
system (Amersham) or the Super Signal System (Pierce).
Numerous attempts to immunoisolate PKB from adipocytes using both
anti-PH-PKB and anti-full-length-PKB antibodies and also a set of
commercially available antibodies were made, but these attempts have
failed consistently. This is in contrast to experiments using lysates
from liver and 3T3-L1 cells, from which endogenous PKB was successfully
immunoisolated employing the anti-PH-PKB antibody. Furthermore, the
normally obtained, quantitative immunoprecipitation of recombinant PKB
from yeast extracts was blocked completely by the addition of adipocyte
cytosol fraction or even partially purified cytosol (Mono Q fractions)
to the extracts (Fig. 1). This
observation strongly suggests the presence of components interfering
with the PKB-antibody interaction in adipocytes.
The immunoprecipitation protocol employed made use of affinity purified
anti-PH-PKB antibodies raised by us (see above). Antibodies and protein
A-Sepharose beads were preincubated for 1 h at 4 °C, washed
with phosphate buffer, and added to tissue/cell extracts. After
overnight incubation at 8 °C, the beads were pelleted, washed with
phosphate buffer, and subjected to SDS-PAGE and immunoblot analysis
using the anti-CT-PKB antibody.
Membrane fractions (5 µl), cytosol
fractions (10 µl), and chromatography fractions (10 µl) were
incubated with 5 µl of a mixture containing 150 µM
[-32P]ATP (4-10 µCi), 150 mM TES, pH
7.5, 40 mM MgCl2, 250 mM sucrose, 4 mM dithioerythritol, 5 µM cAMP protein kinase
inhibitor (final incubation volume, 15 µl). Substrates included were
either peptide KKRNRTLTK (K9) (13 µg), KKRNRTLSK
(K9Thr
Ser) (13 µg), or Crosstide (1 µg).
Incubations were terminated after 20 min at 30 °C by addition of 10 µl of 1% bovine serum albumin, 1 mM ATP, pH 3.0, and 5 µl of 30% trichloroacetic acid. Samples were centrifuged and
supernatants applied onto phosphocellulose paper (Whatman P81), washed
three times with 75 mM phosphoric acid and once with
acetone. The amount of 32P incorporated into peptide
substrates was determined by scintillation counting. The kinase assay
was linear with respect to time of incubation and protein
concentration.
Activation of PKB has previously
been shown to be associated with decreased mobility of the protein on
SDS-polyacrylamide gels, indicative of phosphorylation of the enzyme
(4, 5, 7). As shown in Fig.
2A, stimulation of adipocytes
with insulin resulted in reduction in the electrophoretic mobility of
PKB demonstrated by immunoblot analysis of cytosol fractions using an
anti-NT-PKB antibody. Treatment of adipocytes with the PI 3-kinase
inhibitor wortmannin (27), added prior to or after stimulation with
insulin, blocked or reversed the shift in mobility of PKB. In contrast, rapamycin, an agent that blocks activation of p70 S6 kinase, had no
effect on the insulin-induced shift in mobility. Stimulation of
adipocytes with PMA, which results in activation of protein kinase C
and the mitogen-activated protein (MAP) kinase signaling pathway, did
not result in reduction in the electrophoretic mobility of PKB.
Regulation of PKB in adipocytes.
Adipocytes were treated and cytosol fractions prepared as described
under "Experimental Procedures." Panel A, cytosol
fractions (100 µl) were subjected to SDS-PAGE and immunoblot analysis
with the anti-NT-PKB antibody. The immunoblot is representative of
three or more experiments. The positions of PKB are indicated to the
right. The band above PKB represents nonspecific
interaction with bovine serum albumin originating from the incubation
medium. Panel B, cytosol fractions were assayed for kinase
activity with K9 as substrate. Results are mean values ± S.D.
from several different adipocyte preparations (n) and
expressed as percent of the activity in cytosol fraction from control
cells (taken as 100%). Cytosol from control cells gave 32P
incorporation of 28,000 ± 2,500 (n = 4) cpm/20
min of incubation with 6 µCi (0.75 nmol) of
[
-32P]ATP. Cells were treated with 1 nM
insulin (ins), 150 nM PMA, 100 nM
wortmannin (wort), 20 nM rapamycin
(rap), or 50 µM PD 98059 (PD).
Wortmannin and rapamycin were added 10 and 15 min, respectively, before
insulin. Panel C, adipocytes were stimulated with 1 nM insulin for the indicated times (solid line)
or stimulated with 1 nM insulin for 15 min, washed with 7 ml of Krebs-Ringer medium containing 1% bovine serum albumin, and the incubation continued for an additional 15 min
(dotted line) without (open circle) or with 1 nM insulin (filled circles). Results are mean
values ± S.D. from three or more adipocyte preparations and
expressed as percent of the activity in cytosol fraction from control
cells (taken as 100%). Inset, immunoblot analysis with the
anti-NT-PKB
antibody of cytosol fractions from, control cells
(lane 1); cells stimulated with 1 nM insulin for
15 min (lane 2); cells stimulated with 1 nM
insulin for 15 min, washed, and the incubation continued without
(lane 3) or with 1 nM insulin for 15 min
(lane 4).
Despite repeated attempts to immunoprecipitate PKB from adipocytes, either cytosol fractions or chromatography fractions, this has not been successful (see "Experimental Procedures"). To study activation of PKB it was therefore necessary to find a substrate that could selectively detect PKB in crude adipocyte fractions. We noted that after quantitative immunoprecipitation of p70 S6 kinase from adipocytes,2 96 ± 11% (mean ± S.D., n = 13) of the insulin-induced kinase activity detected with the p70 S6 kinase substrate KKRNRTLTK (K9) remained in the immunosupernatants. Furthermore, rapamycin had no effect on the insulin-induced activation of K9 kinase (Fig. 2B). These results show that p70 S6 kinase does not contribute significantly to the insulin-induced kinase activity detected in cytosol fractions. Initial characterization of the insulin-stimulated kinase activity indicated that it could be PKB. Therefore, we proceeded with a more detailed characterization and found, as is shown below, that this kinase activity to a large extent represented PKB.
As shown in Fig. 2B, activation/deactivation of K9 kinase activity correlated well with the appearance/disappearance of the PKB species with lower electrophoretic mobility. Wortmannin, added either before or after stimulation with insulin, completely inhibited the insulin-induced activation of K9 kinase. Direct addition of wortmannin (1 µM) to the assay had no effect on the K9 kinase activity. PMA stimulation of adipocytes (150 nM (Fig. 2B) or 500 nM (data not shown)) only marginally altered K9 kinase activity, which amounted to no more than 15% of the response to insulin. Furthermore, pretreatment of adipocytes with the MAP kinase kinase inhibitor PD 98059, which inhibits insulin-induced activation of MAP kinase,2 had no effect on the insulin-induced activation of K9 kinase. These results suggest that MAP kinase and kinases downstream of MAP kinase, such as p90 rsk, are not involved in the insulin-induced activation of the kinase.
As shown in Fig. 2C, there was substantial activation of K9
kinase in cytosol fractions from adipocytes stimulated with 1 nM insulin for 1 min, and a 5-fold activation was reached
after 5 min in the presence of insulin. No further increase in activity was seen using 100 nM insulin (not shown). Partial
activation of the kinase was seen with 0.1 nM insulin
(15 ± 5% (mean ± S.D., n = 3) of the
activity in response to 1 nM insulin), which was accompanied by a partial shift in the electrophoretic mobility of PKB
(not shown). Although the kinase activity remained elevated for more
than 30 min in the presence of insulin, the activity returned to
control values when insulin-stimulated cells were washed and incubated
without insulin. This coincided with reversal of the insulin-induced
shift in the electrophoretic mobility of PKB (Fig. 2C,
inset). In agreement with these results in intact cells,
treatment of cytosol fractions from insulin-stimulated cells with
alkaline phosphatase resulted in a change in the electrophoretic mobility of PKB as well as reduction of the kinase activity to that
seen in cytosol fractions from control cells (Fig.
3).
The results presented above are consistent with activated PKB as the
kinase phosphorylating K9 in our assay. To establish that
insulin-stimulated K9 kinase activity represents PKB we investigated the elution profile of K9 kinase activity and PKB protein on Mono Q and
Superdex columns. K9 kinase activity quantitatively bound to the Mono Q
column and was eluted as two peaks of activity (Fig. 4A). Increased K9 kinase
activity from insulin-stimulated cells was found in the first peak
eluting at 0.15-0.20 M NaCl. Immunoblot analysis of Mono Q
fractions with anti-NT-PKB antibodies (Fig. 4A,
inset) showed that PKB protein from insulin-stimulated cells was present in this first peak (fractions 19-21) and coeluted with
insulin-stimulated K9 kinase activity. In contrast, PKB protein from
control cells was detected in fractions 17-19, indicating that the
insulin-stimulated form of PKB (phosphorylated) binds more tightly to
the Mono Q column than does PKB from control cells. A peak of insulin
insensitive kinase activity, eluting at about 0.3 M NaCl,
was also detected consistently (four out of four experiments). No
protein cross-reacting with either anti-NT-PKB
antibodies (Fig.
4A, inset) or anti-CT-PKB
antibodies (not
shown) could be detected in this second peak. We do not know the
identity of the kinase(s) in this second peak; however, the kinase
activity is not to any major extent the result of p70 S6 kinase as this kinase elutes in fractions 24 and 25 as determined by immunoblot analysis (not shown). The kinase activity recovered in the first peak
(PKB) varied among different experiments and accounted for 40-65% of
the total kinase activity eluting from the column. The 4-5-fold
activation of K9 kinase observed in cytosol fractions (Fig.
2B) is higher than one would expect when taking into account the relatively large peak of insulin-insensitive kinase activity observed after Mono Q chromatography. The reason could be that the
insulin-insensitive kinase is suppressed in cytosols or that the
insulin-stimulated K9 kinase is partially lost during the purification
procedure.
Subsequent chromatography of PKB-containing Mono Q fractions (fractions 17-20 from control and 19-22 from insulin-stimulated cells) on a gel filtration column revealed coelution of K9 kinase activity (Fig. 4B) and immunoreactive PKB protein (Fig. 4B, inset), in fractions that corresponded to a molecular mass of about 60 kDa. After both Mono Q and Superdex chromatographies PKB from insulin-stimulated cells migrated with reduced electrophoretic mobility. From these results it can be concluded that the insulin-stimulated K9 kinase activity does represent PKB.
Vanadate- and Peroxovanadate-induced Activation of PKBVanadate and peroxovanadate are well known inhibitors of
phosphotyrosine phosphatases (28) and have been shown to mimic several
of the actions of insulin such as stimulation of glucose uptake (29),
lipogenesis (30), and inhibition of lipolysis (30). Stimulation of
adipocytes with either vanadate or peroxovanadate induced activation of
PKB; peroxovanadate was approximately 1,000-fold more potent than
vanadate and active at micromolar concentrations (Fig.
5). In addition, both vanadate and
peroxovanadate, at concentrations exerting no or little activation of
PKB, potentiated the activation induced by 0.25 nM insulin
(Fig. 5) and 1 nM insulin (not shown). Although treatment
with 5 mM vanadate for 20 min resulted in only a partial
activation of PKB (Fig. 5), a 4.5 ± 0.9-fold (n = 7) increase in kinase activity was seen when the incubation was
extended to 40 min. No activation of PKB was seen when adipocytes were treated with 0.25 mM H2O2 (not
shown). Wortmannin pretreatment inhibited the PKB activation induced by
either vanadate or peroxovanadate. The peroxovanadate-induced
activation of PKB was not affected by pretreatment with rapamycin or PD
98059 (not shown). The increase in kinase activity induced by vanadate
and peroxovanadate correlated with a shift in the electrophoretic
mobility of PKB present in the cytosol fraction; the shift in mobility
was prevented by treatment of adipocytes with wortmannin (Fig.
6A).
Translocation of PKB to Membranes
It has been proposed that
formation of 3-phosphorylated phosphoinositides by activated PI
3-kinase may lead to recruitment of PKB to membranes where it is
activated by membrane-associated kinase(s) (7, 16). PKB binds to
vesicles containing phosphatidylinositol 3,4-bisphosphate and
phosphatidylinositol 3,4,5-trisphosphate (17, 18); however, there is no
direct evidence for translocation of PKB to membranes in response to
stimulation of intact cells with agents that activate PKB. Therefore,
adipocytes were stimulated with insulin, homogenized, and the amount of
PKB in the cytosol and membrane fractions was determined. Despite
repeated attempts and the use of different insulin concentrations (up
to 100 nM) we were not able to demonstrate any significant
amount of PKB protein in membrane fractions after incubation with
insulin (Fig. 6A). Similarly, vanadate stimulation did not
result in translocation of PKB (not shown). Because it appeared
possible that translocation of PKB was transient or could have been
reversed during homogenization and therefore difficult to detect,
studies with peroxovanadate were performed. We have observed that this
insulin-mimicking agent is more effective than insulin in recruiting PI
3-kinase to insulin receptor
substrate-1,3 and thus
presumably generates more 3-phosphorylated phosphoinositides. As shown
in Fig. 6A, treatment with peroxovanadate (50
µM) resulted in substantial translocation of PKB to the
membrane fraction. The increase in PKB protein in the membrane fraction
was accompanied by a corresponding decrease in the cytosol fraction.
The translocation of PKB was blocked completely by wortmannin.
Furthermore, the addition of wortmannin subsequent to stimulation with
peroxovanadate (50 µM, 40 min) reversed the membrane
translocation of PKB (not shown). An increase in kinase activity was
also detected in membrane fractions from peroxovanadate-stimulated
cells (Fig. 6B). This increase in activity was inhibited by
pretreatment of the cells with wortmannin. However, the kinase activity
in the membrane fraction was lower than expected as judged from the
amount of PKB protein in this fraction. Kinase assay of membrane
fractions (either from control or stimulated cells) mixed with an equal volume of a cytosol fraction from stimulated cells resulted in substantial inhibition (72%, mean of three experiments) of the kinase
activity in cytosol fraction. This suggests that the membrane fraction
contains components that inhibit kinase activity, resulting in
underestimation of its activity in this fraction.
The major findings in this paper are that PKB is rapidly and reversibly activated via a wortmannin-sensitive mechanism by physiological concentrations of insulin in adipocytes, a major target cell for insulin, and that PKB is recruited to membranes via a wortmannin-sensitive mechanism in the intact cell.
Kohn et al. (4) observed that stimulation of adipocytes with insulin resulted in decreased electrophoretic mobility of PKB on SDS-polyacrylamide gels. Here we show that the decreased electrophoretic mobility of PKB is linked to activation of the kinase and that the activation is wortmannin-sensitive and also appears to involve phosphorylation. Furthermore, the activation is rapid (detectable within 1 min), reversible, and occurs in response to physiological concentrations of insulin (detectable with 100 pM). Therefore, the insulin-induced activation of PKB could well be important in metabolic actions of insulin. Insulin and insulin-like growth factor-1-mediated activation of PKB have been demonstrated using different cell lines and transfected cells, sometimes in the presence of as much as 100-1000 nM insulin (4-6, 16, 31-33). At high concentration of insulin it cannot be excluded that the effects observed are mediated via the insulin-like growth factor-1 receptor and not by the insulin receptor (34). Our results show that in primary rat adipocytes there is a physiological regulation of PKB by insulin.
The K9 peptide (KKRNRTLTK) was originally designed as a substrate for
p70 S6 kinase (35). Our results show that K9 can be used to detect PKB
activity selectively in cytosol fractions from stimulated adipocytes.
The peptide Crosstide (GRPRTSSFAEG), which closely resembles the
sequence containing the site phosphorylated by PKB in glycogen synthase
kinase-3, has been used to determine PKB activity in immunoprecipitates
as well as in partially purified fractions of PKB (6). Both Crosstide
and K9 have basic residues at positions n-3 and
n-5 (where n is the site of phosphorylation). In
the case of Crosstide the phosphate acceptor is a serine, and in K9 it
is a threonine. In a set of experiments (results not shown) we compared
kinase activity in adipocytes using three different peptide substrates;
Crosstide, K9, and a K9 peptide with the most carboxyl-terminal
threonine replaced by a serine (K9Thr Ser). In
contrast to the results in Fig. 2B with K9 as substrate,
Crosstide as well as K9Thr
Ser detected
PMA-stimulated kinase activity in the cytosol fraction to the same
extent as insulin-stimulated kinase activity. Because PMA stimulation
does not result in activation of PKB in adipocytes (Fig. 2) or other cells (3-5) this indicates that kinase assay of crude adipocyte preparations with peptides containing a serine as phosphate acceptor (Crosstide and K9Thr
Ser) are less selective for PKB
and will also detect other kinases such as p90 rsk. This conclusion is
supported by a recent study where the substrate specificity of PKB, p90
rsk, and p70 S6 kinase were compared (36).
The importance of phosphorylation as a mechanism to activate PKB was demonstrated recently by Alessi et al. (32). Site-directed mutagenesis studies of PKB revealed two activity-controlling phosphorylation sites. However, the protein kinase(s) and phosphatase(s) responsible for the phosphorylation of PKB in vivo have not yet been identified. In agreement with findings by others (4-6), alkaline phosphatase treatment of PKB from insulin-stimulated adipocytes resulted in its deactivation as well as reversal of its electrophoretic mobility to that of PKB from control cells. A role for protein phosphatases in the regulation of PKB in intact cells is supported by the observation that treatment of Swiss 3T3 cells with okadaic acid induces activation and reduction in the electrophoretic mobility of PKB (7). Our results demonstrated that the insulin-induced activation of PKB, as well as the corresponding decrease in electrophoretic mobility, was reversed upon removal of insulin or addition of wortmannin subsequent to insulin stimulation, indicating that the activation of PKB is reversed rapidly by protein phosphatase(s) in the intact cell.
The finding that wortmannin blocked the peroxovanadate-induced
translocation of PKB to membranes in intact cells is of considerable interest since it has been proposed that PKB can be targeted to membranes where it can be phosphorylated and activated by
membrane-associated kinase(s) (7, 16). However, membrane translocation
of PKB has not been demonstrated in intact cells but is supported by observations that PKB binds to lipid vesicles containing
phosphatidylinositol 3,4-bisphosphate and phosphatidylinositol
3,4,5-trisphosphate (17, 18) and that targeting of PKB to membranes by
adding the src myristoylation sequence results in
constitutive activation of PKB (5, 8, 31). In contrast to the results
with peroxovanadate, we were unable to find significant amounts of PKB
in membrane fractions from insulin-stimulated cells. We have not
identified the factor responsible for the marked difference in
translocation of PKB to membranes during stimulation of adipocytes with
insulin or peroxovanadate. It is possible that higher concentrations of 3-phosphorylated phosphoinositides are generated in the presence of
peroxovanadate, since severalfold greater amounts of PI 3-kinase were
found in association with insulin receptor substrate-13
after stimulation of adipocytes with peroxovanadate than after treatment with insulin. The amount of phosphatidylinositol
3,4,5-trisphosphate could also have been increased by inhibition of its
degradation. Since vanadate has been shown to inhibit
phosphatidylinositol 3,4,5-trisphosphate 5-phosphatase in
vitro (37), it is tempting to speculate that peroxovanadate could
inhibit this phosphatase in the intact cell and thereby increase the
level of phosphatidylinositol 3,4,5-trisphosphate.
Little is known regarding the physiologically important downstream targets for PKB. Recently, it was demonstrated that the insulin-induced phosphorylation and inhibition of glycogen synthase kinase-3 in myotubes are mediated by PKB, indicating an important role for PKB in the regulation of glycogen synthesis (6). In 3T3-L1 adipocytes the expression of constitutively active PKB resulted in increased glucose uptake, which was associated with increased translocation of GLUT4 to plasma membranes and increased expression of GLUT1 (31). In these cells, increased glucose uptake in the presence of constitutively active PKB was associated with increased lipid synthesis. Another important effect of insulin is to counteract catecholamine-induced hydrolysis of stored adipose tissue triglycerides. A key enzyme in this action of insulin is phosphodiesterase 3B whose activation causes reduction of cellular cAMP (38). We are currently investigating the role of PKB in the insulin-induced phosphorylation and activation of phosphodiesterase 3B. Preliminary results indicate that phosphodiesterase 3B could be a substrate for PKB in vitro.4,5
We acknowledge gratefully the excellent technical assistance of Ann-Kristin Holmén Pålbrink and Maria Bogren.