(Received for publication, September 7, 1995; and in revised form, November 13, 1995)
From the
Expression of phosphoenolpyruvate carboxykinase (PEPCK), the
rate-limiting step in hepatic gluconeogenesis, is primarily regulated
at the level of gene transcription. Insulin and phorbol esters inhibit
basal PEPCK transcription and antagonize the induction of PEPCK gene
expression by glucocorticoids and glucagon (or its second messenger
cAMP). Insulin activates a signaling cascade involving Ras Raf
p42/p44 mitogen-activated protein (MAP) kinase kinase (MEK)
p42/p44 MAP kinase (ERK 1 and 2). Recent reports suggest that
activation of this Ras/MAP kinase pathway is critical for the effects
of insulin on mitogenesis and c-fos transcription but is not
required for insulin action on metabolic processes such as glycogen
synthesis, lipogenesis, and Glut-4-mediated glucose transport. We have
used three distinct approaches to examine the role of the Ras/MAP
kinase pathway in the regulation of PEPCK transcription by insulin in
H4IIE-derived liver cells: (i) chemical inhibition of Ras
farnesylation, (ii) infection of cells with an adenovirus vector
encoding a dominant-negative mutant of Ras, and (iii) use of a chemical
inhibitor of MEK. Although each of these methods blocks insulin
activation of MAP kinase, none alters insulin antagonism of cAMP- and
glucocorticoid-stimulated PEPCK transcription. Although phorbol esters
activate MAP kinase and mimic the effects of insulin on PEPCK gene
transcription, inhibition of MEK has no effect on phorbol ester
inhibition of PEPCK gene transcription. Using the structurally and
mechanistically distinct phosphatidylinositol 3-kinase (PI 3-kinase)
inhibitors, wortmannin and LY 294002, we provide further evidence
supporting a role for PI 3-kinase activation in the regulation of PEPCK
gene transcription by insulin. We conclude that neither insulin nor
phorbol ester regulation of PEPCK gene transcription requires
activation of the Ras/MAP kinase pathway and that insulin signaling to
the PEPCK promoter is dependent on PI 3-kinase activation.
A major physiological function of insulin is the maintenance of
glucose homeostasis, and the liver plays a pivotal role in this
regulation. In the fasted state, blood glucose levels are maintained
through hepatic glucose output, and in noninsulin-dependent diabetes
mellitus, fasting hyperglycemia develops predominantly as a result of
unrestrained hepatic
gluconeogenesis(1, 2, 3) . The enzyme
phosphoenolpyruvate carboxykinase (PEPCK; ()GTP:oxalacetate
carboxylyase (transphosphorylating) EC 4.1.1.32) catalyzes the
rate-limiting step in gluconeogenesis. Increased hepatic PEPCK
expression has been demonstrated in several animal models of
diabetes(4) , and overexpression of PEPCK in transgenic mice
results in the phenotype of noninsulin-dependent diabetes mellitus (5) . There are no known allosteric modifiers of PEPCK; its
activity is regulated by the level of gene
expression(4, 6) . Insulin and phorbol esters inhibit
basal PEPCK gene transcription and antagonize the induction of PEPCK
expression by glucocorticoids and glucagon (or its second messenger
cAMP)(4, 7) . Although insulin regulates the
transcription of many genes, the regulation of PEPCK transcription has
been the most extensively studied and has served as a useful model (6) .
The signaling pathways involved in insulin action have been the subject of intense research (for review see (8) and (9) ). Ligand binding stimulates insulin receptor-mediated tyrosine phosphorylation of IRS-1 and Shc. These molecules then function as high affinity binding sites for several downstream effectors through src homology 2 domains. The two best studied effectors that bind to the IRS-1 docking protein are PI 3-kinase and Grb-2-Sos. The mechanism through which PI 3-kinase activation by insulin or other agents leads to biologic effects is poorly understood. Phosphorylated inositol products have been proposed to activate specific phorbol ester-insensitive protein kinase C isoforms(10, 11) , and recently a serine/threonine protein kinase encoded by the Akt proto-oncogene was identified as a novel target of PI 3-kinase-generated lipids(12) . PI 3-kinase also appears to be tightly associated with or contain a protein kinase activity(13, 14) . Whatever the downstream mechanisms, studies based on PI 3-kinase inhibition have provided clear evidence for a role of this enzyme in the effect of insulin on Glut-4-mediated glucose transport(15, 16) , antilipolysis(15, 17) , c-fos expression(18, 19) , mitogenesis(18, 20) , glycogen synthase kinase-3(21, 22) , glycogen synthesis(23, 24, 25) , amino acid transport(20) , and membrane ruffling (26) .
The
other major insulin signaling pathway that is initiated by src homology
2-dependent binding to IRS-1 is the Ras/MAP kinase cascade. Binding of
the Grb-2-Sos adapter complex to IRS-1 (or Shc) activates Ras through a
Sos-mediated GDP:GTP exchange. Ras subsequently stimulates Raf through
a poorly understood mechanism requiring the involvement of other as yet
unidentified factors(27, 28) . A linear
phosphorylation cascade of Raf MEK
p42/p44 MAP kinase
(ERK 1 and 2) subsequently occurs. MAP kinase activation represents a
major branch point, and this enzyme may translocate to the nucleus to
activate several specific transcription factors. Phorbol esters (via
stimulation of protein kinase C) also activate the MAP kinase cascade,
and although the precise mechanism is unclear, protein kinase C
activation of Raf has been implicated(29, 30) .
Several approaches have been taken to study the role of the Ras/MAP kinase pathway in the metabolic effects of insulin. Cells have been transfected or microinjected with Ras mutants (19, 31, 32, 33, 34) or a dominant-negative Sos(35) , thereby blocking Ras activation by insulin. Adipocytes have been permeabilized to allow the entry of GTP analogs that inactivate Ras(36) . Antisense oligonucleotides have also been used to block Raf activity(37) . Clonally selected cells in which active raf mutants were introduced by retroviral infection have also been studied(38) . In addition, the ability in certain cells of other growth factors to stimulate the Ras/MAP kinase cascade has been compared with the selective metabolic effects of insulin in these cells(39, 40, 41) . Recently, a specific chemical inhibitor of MEK has been developed(42) , and its effects were studied in muscle and adipose cell lines(43) . Collectively, these studies support a role for activation of the Ras/MAP kinase pathway in nuclear effects of insulin on mitogenesis and c-fos expression(19, 33, 34, 37) , but no obligatory role has been established in insulin stimulation of Glut-4-mediated glucose transport(31, 38) , glycogen synthesis(23, 25, 35, 41, 43) , or lipogenesis(40, 43) . Available evidence also suggests that the regulation of c-fos gene transcription by insulin requires both Ras and PI 3-kinase activation(18, 19, 33, 34) . To date, however, the involvement of the Ras/MAP kinase pathway in insulin signaling in the liver has not been examined. This has in part been the result of the inability to utilize some of the approaches described above (microinjection and transfection) in well characterized liver cell lines.
Although the regulation of PEPCK is a critical physiological site of insulin action, little is understood regarding the initial signal transduction mechanisms involved. We have used three different approaches to examine the involvement of the Ras/MAP kinase pathway in insulin signaling to PEPCK gene transcription in H4IIE-derived liver cells. Farnesylation, an obligatory step in Ras processing, was blocked by two structurally distinct farnesyltransferase inhibitors. An adenovirus containing a dominant-negative ras mutant was used to attenuate the Ras pathway. Finally, a newly described chemical inhibitor of MEK (42) was employed to prevent the activation of this pathway. Each of these three mechanistically distinct approaches used to inhibit the Ras/MAP kinase pathway failed to alter insulin regulation of PEPCK gene transcription. In addition, phorbol ester signaling, which mimics insulin action on the PEPCK gene, in part through the same promoter sequence(44) , was likewise not dependent on Ras/MAP kinase pathway activation. Recently, the PI 3-kinase inhibitor wortmannin has been shown to block the effects of insulin on PEPCK gene transcription(45) . We extend these results by demonstrating similar effects of the structurally and mechanistically distinct PI 3-kinase inhibitor LY 294002, and we corroborate the original report (45) by demonstrating inhibition of PI 3-kinase activity at the wortmannin concentrations used to antagonize insulin's actions on PEPCK gene transcription. We conclude that insulin regulation of PEPCK gene transcription does not require Ras/MAP kinase pathway activation but is dependent on PI 3-kinase activation.
Elements of the insulin signaling pathway involved in the regulation of PEPCK gene transcription were studied in the rat hepatoma-derived cell line (H4IIE) stably transfected with the PEPCK promoter sequence from -2100 to +69 (relative to the transcriptional start site) ligated to a CAT reporter gene (termed HL1C cells)(46) . This stable transfectant has been previously characterized, and the PEPCK-CAT fusion gene exhibits similar regulation by insulin, glucocorticoid, cAMP, and phorbol esters when compared with the endogenous gene. That is, insulin and phorbol esters act in a dominant fashion, blocking the induction of PEPCK-CAT transcription by cAMP and dexamethasone(46) . Given the low basal level of PEPCK transcription in the absence of other effectors, transcriptional regulation of PEPCK has been best studied using the ability of insulin to counteract stimulation of gene transcription by glucagon (or cAMP) and glucocorticoids(4, 7, 45, 46, 51) . A similar need to observe insulin effects as the antagonism of the actions of counter-regulatory hormones has been reported for many of insulin's actions in liver. Here we focus on the signaling pathways that mediate insulin's antagonism of maximally stimulatory concentrations of cAMP (using the nonhydrolyzable analog 8-CPT-cAMP) and the synthetic glucocorticoid dexamethasone.
Figure 1:
Inhibition of Ras or
MEK blocks insulin stimulation of MAP kinase activity. H4IIE cells
stably transfected with a PEPCK promoter CAT construct (HL1C, see
``Experimental Procedures'') were preincubated with the
farnesyltransferase inhibitors (50 µM B581 and 10
µM PD 152440-0011B) or adenovirus containing the
Asn dominant-negative mutant of Ras for 16 h in DMEM
containing serum. Cells were subsequently washed twice with PBS and
placed in serum-free DMEM prior to the addition of insulin. The MEK
inhibitor PD 98059 (10 µM) was added 30 min prior to the
addition of insulin to cells deprived of serum for 18 h. Cells
preincubated with inhibitors as above were then treated with insulin
(10 nM) for 5 min and subsequently analyzed for MAP kinase
activity as described under ``Experimental Procedures.'' The
results are the means ± S.E. of three
experiments.
The farnesyltransferase inhibitors B581 and PD 152440 had no effect on the ability of insulin to antagonize cAMP/dexamethasone induction of the PEPCK-CAT fusion gene (Fig. 2, A and B). Despite completely blocking insulin stimulation of MAP kinase, there was no change in the ability of either submaximal or maximal insulin concentrations to inhibit PEPCK-CAT expression ( Fig. 2and data not shown).
Figure 2:
Effect of farnesyltransferase inhibitors
(B581 and PD 152440) on PEPCK-CAT gene transcription. In A cells were incubated with 50 µM B581 or
MeSO carrier (control) or in B 10
µM PD 152440 or an equivalent amount of Me
SO
carrier (control) for 18 h in DMEM containing serum. Cells
were then washed twice with PBS and incubated in serum-free DMEM in the
absence of hormone (basal) or 0.1 mM 8-CPT-cAMP and
500 nM dexamethasone (cAMP/Dex) with or without the
indicated concentrations of insulin. After 4 h CAT protein was
determined as described under ``Experimental Procedures.''
The results are expressed as the percentage of CAT protein relative to
cAMP/Dex-stimulated CAT protein in the absence of B581 or PD
152440-0011B. In each case, the effects of these inhibitors were
compared with those of an equivalent amount of Me
SO carrier
as a control. The results are the means ± S.E. of four different
experiments.
HL1C cells were infected with an adenovirus expressing a
dominant negative mutant of ras (Asn) to assess
the role of this component of the signaling pathway. Whereas infection
with this adenovirus completely blocked insulin stimulation of MAP
kinase activity (Fig. 1), it had no effect on insulin inhibition
of PEPCK-CAT gene expression (Fig. 3). The same adenovirus
containing a
-galactosidase gene instead of the mutant ras had no effect on insulin stimulation of MAP kinase or insulin
action on PEPCK-CAT gene expression (data not shown). These results
indicate that insulin signaling to the PEPCK promoter does not require
the activation of Ras.
Figure 3:
Adenovirus-mediated expression of the
Asn dominant-negative mutant of Ras does not affect
insulin regulation of PEPCK-CAT gene expression. Adenovirus containing
the Asn
mutant of Ras (described under ``Experimental
Procedures'') was added to a final concentration of 10
pfu/ml to HL1C cells for 16 h in DMEM containing serum. Cells
were then washed twice in PBS and incubated in serum-free DMEM for 4 h
as follows: no additions (basal), 0.1 mM 8-CPT-cAMP
and 500 nM dexamethasone (cAMP/Dex), or 8-CPT-cAMP,
dexamethasone, and the indicated concentrations of insulin (0.5, 1, or 10 nM). Cells were
subsequently analyzed for CAT protein as described. The results are
expressed as the percentage of CAT protein in the absence of
adenovirus. The results are the means ± S.E. of three separate
experiments.
Interestingly, either mechanism of Ras inhibition (farnesyltransferase inhibition or expression of dominant-negative Ras) augments the effects of cAMP and dexamethasone on PEPCK-CAT gene expression. This response is the result of a super-induction of the dexamethasone response (data not shown), possibly due to an effect of basal Ras activity to tonically inhibit dexamethasone action. Whatever the mechanism, however, insulin was clearly capable of antagonizing the synergistic induction of PEPCK-CAT transcription by cAMP and dexamethasone in the presence or the absence of Ras inhibition ( Fig. 2and Fig. 3). Insulin also blocked the induction of PEPCK-CAT expression by dexamethasone alone in the presence of the farnesyltransferase inhibitor B581 (data not shown).
Figure 4:
MEK inhibition by PD 98059 does not block
insulin or phorbol ester regulation of PEPCK-CAT gene expression. Cells
deprived of serum for 18 h were preincubated with 10 µM PD
98059 or MeSO carrier (control) for 30 min prior
to the addition of 0.1 mM 8-CPT-cAMP and 500 nM dexamethasone (cAMP/Dex). Insulin (10 nM) or
phorbol myristate acetate (1 µM) was added as indicated.
The results are expressed as the percentage of CAT protein relative to
cAMP/Dex-stimulated CAT protein in the absence of PD 98059 and
represent the means ± S.E. for four separate
experiments.
Figure 5:
Regulation of endogenous PEPCK gene
transcription by insulin or phorbol ester is not affected by the MEK
inhibitor PD 98059. HL1C cells were deprived of serum for 20 h then
incubated with PD 98059 (10 µM), insulin, dexamethasone,
cAMP, and PMA as indicated in Fig. 4. 3 h after hormone
additions, total mRNA was isolated, and primer extension assays were
performed as described under ``Experimental Procedures.'' The
products were subsequently separated by urea-acrylamide gel
electrophoresis and quantified by PhosphorImager analysis. A
measurement of -actin mRNA was used to establish equal loading of
mRNA in each lane(45) . The results are presented as the
percentage PEPCK mRNA relative to that obtained in the presence of cAMP
and dexamethasone (cAMP/Dex) and represent the means ± S.E. of
four separate experiments.
Phorbol esters mimic the effects of insulin on PEPCK gene transcription in this system by acting in part through the same promoter sequence (44) . Activation of protein kinase C by phorbol esters can stimulate the MAP kinase signaling cascade, and it has been suggested that this may occur through protein kinase C activation of Raf, which lies immediately upstream of MEK(29, 30) . Consequently, the effects of MEK inhibition on phorbol ester (PMA) signaling to PEPCK gene transcription were examined. Interestingly, MEK inhibition had no effect on PMA regulation of either the PEPCK-CAT fusion gene (Fig. 4) or the endogenous PEPCK gene (Fig. 5). Similarly, inhibition of Ras using either of the farnesyltransferase inhibitors did not alter phorbol ester mediated inhibition of PEPCK-CAT gene expression (data not shown). These results indicate that phorbol esters, like insulin, inhibit PEPCK gene transcription through a mechanism independent of Ras/MAP kinase pathway activation.
Figure 6: PI 3-kinase inhibition diminishes insulin signaling to the stably transfected PEPCK-CAT fusion gene. The PI 3-kinase inhibitor LY 294002 (50 µM) was added to HL1C cells (deprived of serum for 18 h) 15 min prior to the addition of hormones. Wortmannin (100 nM) was also added to serum-deprived cells 15 min prior to hormone additions, and at 2 h 100 nM wortmannin was re-added. In all cases, 4 h after hormone addition, cells were analyzed for CAT protein as described under ``Experimental Procedures.'' Hormone additions were as follows: no addition (basal), 0.1 mM 8-CPT-cAMP and 500 nM dexamethasone (cAMP/Dex) or 8-CPT-cAMP, dexamethasone, and insulin at the indicated concentrations (0.5, 1, of 10 nM). The results are expressed as the percentage of CAT protein relative to cAMP/Dex-stimulated CAT protein in the absence of wortmannin or LY 294002 and represent the means ± S.E. of four separate experiments.
Both wortmannin and LY 290042 blunted the effect of insulin on inhibition of PEPCK-CAT gene expression (Fig. 6). Insulin-stimulated PI 3-kinase activity was blocked in the presence of 100 nM wortmannin (Fig. 7). Dexamethasone and cAMP had no effect on PI 3-kinase activity (data not shown). Therefore, using two structurally and mechanistically distinct inhibitors of PI 3-kinase, we demonstrate an important role for PI 3-kinase in insulin regulation of PEPCK gene transcription.
Figure 7:
Wortmannin blocks insulin stimulation of
PI 3-kinase activity in HL1C cells. Serum-deprived cells were incubated
with 100 nM wortmannin or MeSO carrier for 15 min
and subsequently 10 nM insulin was added for 5 min. PI
3-kinase activity was measured in cell extracts as described under
``Experimental Procedures,'' and the products were analyzed
by thin layer chromatography. An autoradiograph of a representative
experiment is shown. The location of the reaction product,
phosphatidylinositol-3-phosphate (PI3P), is
indicated.
Liver, a key target of insulin action, controls fasting blood
glucose primarily by regulating the rate of gluconeogenesis. The rate
of gluconeogenesis is controlled in large part by changes in the
transcription of the rate-limiting enzyme in this pathway,
PEPCK(4, 6) . Although there has been a great deal of
progress in identifying the cis-acting elements that mediate the
effects of insulin on PEPCK gene transcription, little is known
regarding the early components of the insulin signal transduction
pathway responsible for this action of insulin. Recently, wortmannin
has been used to show that PI 3-kinase activation plays an important
role in insulin regulation of PEPCK gene transcription(45) .
Activation of the Ras Raf
MEK
MAP kinase pathway
is another major component of insulin signal transduction. Previous
studies have suggested that Ras pathway activation plays a pivotal role
in the effects of insulin on mitogenesis and c-fos expression (19, 33, 34, 37) but may not be
required for many of the classic metabolic effects of insulin such as
stimulation of glycogen
synthesis(23, 25, 35, 40, 41) ,
Glut-4-mediated glucose transport(31, 38) , and
lipogenesis(40, 43) . Despite the importance of the
liver in glucose homeostasis and the extensive scrutiny of the Ras/MAP
kinase cascade in many systems, the only attempt to study the role of
this pathway in hepatic insulin action has focused on the regulation of
mitogenesis(37) . For this reason we examined the involvement
of the Ras/MAP kinase pathway in the regulation of PEPCK gene
transcription by insulin. We describe the use of three mechanistically
distinct approaches to inhibit the Ras/MAP kinase pathway in liver
(farnesyltransferase inhibition, dominant-negative Ras adenovirus
infection, and a chemical inhibitor of MEK) and demonstrate that they
all fail to alter the ability of insulin to regulate PEPCK gene
transcription.
Ras requires post-translational farnesylation to localize it to the plasma membrane. Recently, farnesyltransferase inhibitors have been developed with the goal of blocking Ras transformation(61) . A new specific peptidomimetic farnesyltransferase inhibitor, B581, which mimics the CAAX binding site of the farnesyltransferase enzyme, blocks Ras transformation and activation of MAP kinase, a downstream target of Ras activation(52) . We have used this inhibitor and a structurally distinct analog (PD 152440) to assess the role of the Ras/MAP kinase cascade in the regulation of PEPCK gene transcription by insulin. Lovastatin has been the only other farnesyltransferase inhibitor used to study the role of Ras in insulin signaling(62) . Unfortunately, lovastatin has several sites of action apart from inhibiting farnesylation including inhibition of the rate-limiting step of cholesterol biosynthesis. Lovastatin can also block cell transformation by Raf(63) , a downstream target of Ras, and decrease insulin activation of PI 3-kinase activity in Rat-1 fibroblasts(64) . Lovastatin inhibition of PI 3-kinase activity may account for its ability to block the effects of insulin on glycogen synthesis(62) , a process that appears to be dependent on PI 3-kinase activation (23, 24, 25) but not Ras/MAP kinase pathway activation(25, 35, 43) . The farnesyltransferase inhibitors used in this study, B581 and PD 152440, are designed to specifically target farnesyltransferase activity without affecting cholesterol biosynthesis(52, 53) . B581 prevents Ras but not Raf transformation(52) . It is unlikely that they significantly inhibit insulin activation of PI 3-kinase because PI 3-kinase inhibition does diminish the insulin response on PEPCK transcription ( Fig. 7and (45) ). Although these inhibitors block insulin activation of MAP kinase, they fail to alter insulin's ability to suppress PEPCK gene transcription ( Fig. 1and Fig. 2).
The introduction of
genes into mammalian cells has sometimes been difficult because many
cell types are difficult to transfect with the high efficiency
necessary to observe the effects of overexpression or inhibition. This
problem has been partially circumvented by the use of retroviral
vectors; however, these require integration of viral DNA into genomic
DNA during cell division, often over several days during which a
variety of adaptive changes may occur. Recently, adenoviral vectors
have been used to introduce genes of interest into mammalian cells and
tissues for metabolic studies(48) . This approach allows high
efficiency expression of genes within several hours, minimizing
cellular adaptation to these genetic changes. Here we have used an
adenovirus vector encoding a dominant negative mutant of ras (Asn) to demonstrate that Ras is not required for the
regulation of PEPCK gene expression by insulin.
In addition to
direct inhibition of Ras, we studied the effects of blocking activation
of a downstream component of the Ras/MAP kinase cascade. Although the
Ras cascade of Ras Raf
MEK
MAP kinase is believed
to be a linear series of activations, some Ras-independent mechanisms
of MEK and MAP kinase activation have been proposed (54, 55, 56) . Recently, a specific chemical
inhibitor of MEK has been developed and used in 3T3 adipocytes, L6
myocytes, and PC12 cells to specifically inhibit MAP kinase activation
without any measurable effect on a variety of other kinases, including
the insulin receptor kinase, protein kinase C, cAMP-dependent protein
kinase, and PI 3-kinase(42, 43) . Consistent with
results obtained following Ras inhibition, the MEK inhibitor, PD 98059,
did not inhibit the ability of insulin to decrease PEPCK gene
transcription ( Fig. 4and 5).
Phorbol esters activate protein kinase C and mimic the effects of insulin on PEPCK gene transcription. Phorbol esters also stimulate the MAP kinase cascade in many cell types. This appears to occur through activation of Raf because dominant negative mutants of raf block the stimulation of MAP kinase by PMA(29) . Here we demonstrate that inhibition of the Ras pathway either upstream of Raf (through inhibition of Ras farnesylation) or downstream of Raf (through MEK inhibition) fails to alter PMA inhibition of PEPCK gene transcription. Interestingly, the PI 3-kinase inhibitor wortmannin attenuated insulin but not PMA action on PEPCK gene transcription(45) , although the signals generated by these agents converge at the same cis-acting DNA element within the PEPCK promoter(44) . These data suggest that signaling from PMA-stimulated protein kinase C isoforms to the PEPCK gene promoter is through some molecule independent of both the Ras/MAP kinase pathway and PI 3-kinase activation.
Although mounting evidence suggests that the Ras/MAP kinase pathway is not required for many of the classic metabolic actions of insulin, a clear role for PI 3-kinase activation in these pathways has emerged. PI 3-kinase activation by insulin appears to be required for insulin effects on Glut-4-mediated glucose transport(15, 16) , glycogen synthesis(23, 24, 25) , antilipolysis(15, 17) , amino acid transport(20) , membrane ruffling(26) , mitogenesis(16, 18, 20) , and c-fos expression(18, 19) . Recently, an important role for PI 3-kinase activation in insulin regulation of PEPCK transcription was demonstrated using the selective PI 3-kinase inhibitor wortmannin(45) . Here we extend these results by showing that lower concentrations of wortmannin (100 nM), followed by a re-addition at 2 h (to compensate for the compound's instability(58, 59) ), also diminishes the effect of insulin on PEPCK transcription. This concentration of wortmannin completely blocked stimulation of PI 3-kinase activity by insulin (Fig. 7). The results obtained with LY 290042, which has a unique mechanism of action, supports those noted with wortmannin (Fig. 6). This adds the regulation of PEPCK gene transcription to the growing list of wortmannin/LY 290042-sensitive pathways. Based on the requirement of PI 3-kinase but not Ras/MAP kinase pathway activation, it appears that the mechanism of insulin regulation of PEPCK gene transcription is more analogous to the regulation of other classic metabolic actions of insulin (i.e. glucose transport, glycogen synthesis, lipogenesis) and differs from that involved in the mitogenic/growth-promoting actions of insulin, which require both PI 3-kinase and Ras/MAP kinase pathway activation.
Inhibition of either the Ras/MAP kinase pathway or PI 3-kinase augments the ability of dexamethasone to stimulate PEPCK-CAT fusion gene expression (Fig. 2, Fig. 3, and Fig. 4and data not shown). Whether these effects are due to inhibition of constitutively active Ras, MEK, or PI 3-kinase activities, a direct effect on dexamethasone signaling, or some other mechanism is unclear. In Chinese hamster ovary cells overexpressing the insulin receptors (35) and H4IIE hepatoma cells (37) , Ras pathway inhibition diminished basal mitogenesis. Thus there is evidence for constitutive activity of the Ras/MAP kinase pathway. In addition, basal transcription of the collagenase gene is also reduced by Ras inhibition(33) . However, the ability of wortmannin to augment the dexamethasone response was not observed when endogenous PEPCK mRNA was measured(45) . The mechanism underlying this augmentation of dexamethasone action on PEPCK-CAT fusion gene expression remains to be determined.
Insulin regulates the transcription of many genes (for review, see (6) ); however, participation of the Ras pathway in these effects of insulin has only been studied with regards to c-fos and collagenase gene regulation(19, 33, 34) . The MEK inhibitor, PD 98059, was used to delineate the obligatory role of Ras in the regulation of c-fos transcription (43) confirming earlier reports using ras mutants in cell transfection and microinjection experiments(19, 33, 34) . Likewise insulin activation of a collagenase promoter-CAT construct was suppressed by transfection with a dominant negative ras mutant(33) . In contrast we now demonstrate that the regulation of PEPCK gene transcription by insulin is not dependent on Ras/MAP kinase pathway activation. Whether this observation represents a unique transcriptional signaling mechanism in liver, a mechanism unique to the PEPCK gene, or a common mechanism for insulin regulation of gene expression remains to be resolved. There is emerging evidence that many signaling events and mechanisms of insulin action may be tissue-specific. For example, Ras does not seem to be required for insulin stimulation of Glut-4-mediated glucose transport in adipose cell lines (31, 38) but may be important in cardiac myocytes (32) . There are also suggestions that glycogen synthase is regulated differently in muscle (65) and other cell types (i.e. Chinese hamster ovary cells)(35) . In addition, Shc, an alternative substrate for the insulin receptor tyrosine kinase, appears to play a predominant role in Rat1 fibroblasts(66) , whereas this does not appear to be true in PC12 cells (67) or in intact liver(68) . These tissue-dependent differences make further investigation of insulin signaling in metabolically important tissues, such as liver, of great interest.
A potential Ras independent pathway that may explain the
ability of insulin and PMA to repress PEPCK transcription is the
stress-activated or c-jun N-terminal kinase pathway (JNK). JNK, a
member of the MAP kinase superfamily, can be activated independent of
the Ras Raf
MEK
MAP kinase
cascade(69, 70) , possibly involving other members of
the Ras GTPase superfamily(70, 71) . JNK appears to
act through the regulation of specific transcription
events(72) . In Chinese hamster ovary cells overexpressing
insulin receptors, however, insulin does not appear to stimulate JNK
activity. (
)Further studies will be necessary to clarify the
role of JNK in the regulation of transcription by insulin.
In conclusion, we have used several approaches to study the role of the Ras pathway in liver cells: inhibition of Ras farnesylation, adenovirus infection with a Ras dominant-negative mutant, and inhibition of MEK. All three methods block insulin stimulation of MAP kinase, but none affect insulin action on PEPCK gene transcription. We conclude that insulin regulation of PEPCK gene expression does not require Ras/MAP kinase pathway activation but is dependent on PI 3-kinase stimulation. Similar approaches will be readily applied to delineating the role of the Ras cascade in other aspects of liver metabolism.