(Received for publication, September 12, 1996, and in revised form, May 5, 1997)
From the Departments of Medicine and Developmental
and Molecular Biology, The Albert Einstein Cancer Center, Albert
Einstein College of Medicine, Bronx, New York 10461 and
Department of Medicine, Northwestern University Medical School,
Chicago, Illinois 60611
A broad array of stressors induce ACTH release from the anterior pituitary, with consequent stimulation of the adrenal cortex and release of glucocorticoids critical for survival of the animal. ACTH stimulates adrenocortical gene expression in vivo and inhibits adrenocortical cell proliferation. Binding of ACTH to its G-protein-coupled receptor stimulates the production of cAMP and activation of the protein kinase A pathway. The stress-activated protein kinases (SAPKs) (or c-Jun N-terminal kinases) and the extracellular signal-regulated kinases (ERKs) are members of the mitogen-activated protein kinase family of serine/threonine kinases, which have recently been implicated in G-protein-coupled receptor intracellular signaling. The SAPKs are preferentially induced by osmotic stress and UV light, whereas the ERKs are preferentially induced by growth factors and proliferative signals in cultured cells. In these studies, ACTH stimulated SAPK activity 3-4-fold both in the adrenal cortex in vivo and in the Y1 adrenocortical cell line. 12-O-Tetradecanoylphorbol-13-acetate but not cAMP induced SAPK activity in Y1 cells. The isoquinolinesulfonamide inhibitors H-8 and H-89 blocked ACTH induction of SAPK activity at protein kinase C inhibitory doses but not at protein kinase A inhibitory doses. The calcium chelating agent EGTA inhibited ACTH-induced SAPK activity and the calcium ionophore A23187 induced SAPK activity 3-fold. In contrast with the induction of SAPK by ACTH, ERK activity was inhibited in the adrenal cortex in vivo and in Y1 adrenal cells. Together these findings suggest that ACTH induces SAPK activity through a PKC and Ca+2-dependent pathway. The induction of SAPK and inhibition of ERK by ACTH in vivo may preferentially regulate target genes involved in the adrenocortical stress responses in the whole animal.
ACTH binds to specific G-protein (Gs)-coupled surface receptors in the adrenal cortex to induce secretion of steroid hormones critical for the normal stress response. The stimulatory guanine nucleotide-bound Gs couples to adenylate cyclase, leading to a series of signaling cascades. The acute ACTH response is associated with a rapid increase in steroid secretion and is mediated by cAMP and cAMP-dependent protein kinase A (PKA)1 (1, 2). Although ACTH stimulates an increase in cAMP formation (3-5), other secondary messengers including protein kinase C (PKC) (6), Ca+2-calmodulin-dependent protein kinase (7) and the phosphoinositol pathway (8, 9) are also induced by ACTH. Early and delayed gene expression is elicited by ACTH (5). The immediate early genes junB, c-myc, and c-fos were stimulated by ACTH in cultured adrenocortical cells (10), and c-fos and c-jun mRNAs were induced by ACTH in the Y1 adrenal cell line (11). The steroidogenic P-450 genes, including P-450 side chain cleavage (CYP11A1), are induced in a more delayed manner in both the adrenal cortex in vivo and in Y1 cells (5).
Several observations suggest that ACTH regulates PKA-independent signaling. ACTH and cAMP induced immediate early gene expression with quite different kinetics (11). The immediate early gene expression profile induced by ACTH in Y1 cells resembled the expression profile induced by stimulating the PKC pathway with phorbol esters (11). In addition, c-myc mRNA levels were induced by the PKC activator 12-O-tetradecanoylphorbol-13-acetate (TPA), and ACTH-induced c-myc expression was blocked by the PKC inhibitor H-7 in rat primary adrenal cell cultures (10).
Stimuli that activate either the PKC, the Ca+2-calmodulin-dependent protein kinase, or the phosphoinositol pathway, also induce members of the mitogen-activated protein kinase family of serine/threonine kinases (12). Mitogen-activated protein kinases include the related but distinct p54 stress-activated protein kinases (SAPKs) (or c-Jun N-terminal kinases), the p42 and p44 extracellular signal-regulated kinases (ERKs), and p38 kinases (13-17). These serine/threonine kinases activate downstream transcription factors, which in turn induce expression of target genes. A variety of environmental stressors induce SAPK activity in cultured cells, including heat shock and UV irradiation and calcium ionophores (17-22). Angiotensin II, activating mutations of G-protein-coupled receptors, and activators of the PKC pathway also induce SAPK activity (13-17, 23, 24). Relatively little is known about the regulation of the SAPK pathway in vivo. The effects of ACTH on SAPK activity were previously unknown.
ERK activity is stimulated by proliferative stimuli including growth factors and increases in intracellular Ca+2 in a cell type-specific manner (25-27). ERK activity induced by either epidermal growth factor or platelet-derived growth factor in fibroblast cell lines was inhibited by cAMP (25, 28, 29). In contrast, cAMP induced ERK activity in PC12 cells (30), rat ovarian granulosa cells (31), and cardiac myocytes (32), indicating that the effect of cAMP on ERK activity is cell type-specific.
In addition to adrenal cells, ACTH receptors are expressed on a number of different cell types including lymphocytes (33), pancreatic islet cells (34), and adipose tissue (35); thus, an understanding of intracellular signaling by ACTH may have implications in a broad array of different cell types. To understand more fully the intracellular signaling pathways governing ACTH action, we examined the effect of ACTH on the activity of the mitogen-activated protein kinases, SAPK, and ERK kinases in vivo and in cultured adrenocortical cells. Since previous studies suggested that the induction of several immediate early genes by ACTH appeared to involve mechanisms separate from the PKA pathway, we examined the regulation of immediate early gene expression and promoter activity in response to ACTH.
Male CD rats (175-200 g; Charles River Laboratories, Wilmington, MA) were used for the experiments. The rats used in this study were maintained in accordance with the guidelines of the animal care committee of Northwestern University. Free-feeding rats were injected with ACTH (5 units/100 g weight; Cortrosyn, Organon, Bedford, OH) by the tail vein and sacrificed by decapitation after CO2 inhalation. Adrenals were taken at the time point indicated in the text. The adrenal cortex was dissected free from the medulla and lysed with radioimmune precipitation buffer (100 mM Tris, pH 7.5, 150 mM NaCl, 0.1% SDS, 1% Nonidet P-40, 0.1 mM Na3VO4, 0.5% deoxycholate, 0.1 mM phenylmethylsulfonyl fluroide, 1 µg/ml leupeptin), and the extracts were used for immune complex kinase assays and Western blotting. Porcine adrenocorticotropic hormone (ACTH(1-39)) (Sigma), 8-bromo-cAMP (Sigma), N-(2-(methylamino)ethyl)-5-isoquinolinesulfonamide hydrochloride (H-8), N-(2-(p-bromocinnamyl)amino)ethyl-5-isoquinolinesulfonamide hydrochloride (H-89), A23187 (Calbiochem-Novabiochem International), BAPTA (Molecular Probes, Inc. Eugene, OR), EGTA (Sigma), and TPA (Sigma) were reconstituted and stored as recommended by the manufacturer. The SignaTECT cAMP-dependent protein kinase A assay system (Promega, Madison, WI), which uses biotinylated Leu-Arg-Arg-Ala-Ser-Leu-Gly (Kemptide) as substrate, and the SignaTECT protein kinase C assay system (Promega), which uses biotinylated Ala-Ala-Lys-Ile-Gln-Ala-Ser-Phe-Arg-Gly-His-Met-Ala-Arg-Lys-Lys (Neurogranin) peptide, were used as recommended by the manufacturer.
SAPK, p42ERK, p44ERK Immune Complex AssaysAssays were performed as recently described on extracts
derived from rats or cultured cells (24, 36). Staphylococcal protein A-agarose beads were incubated with anti-ERK antibody (C14, Santa Cruz
Biotechnology, Santa Cruz, CA) or anti-SAPK antibody (a gift from Dr.
J. Kyriakis) (17) for 1 h at 4 °C. The antibody-beads complexes
were washed once with radioimmune precipitation buffer and incubated
with 200 µg of extracts for a further 2 h at 4 °C. The
immunoprecipitates were washed with radioimmune precipitation buffer,
wash buffer (0.5 M LiCl, 0.1 M Tris-Cl, pH 8.0, 1 mM dithiothreitol, and kinase buffer (for SAPK: 20 mM MOPS, pH 7.2, 2 mM EGTA, 10 mM
MgCl2, 0.1% Triton X-100, 1 mM dithiothreitol;
for ERK: 25 mM HEPES, pH 7.2, 10 mM
MgCl2, 10 mM MnCl2, 1 mM dithiothreitol). The reactions were performed at
30 °C for 20 min in 40 µl of kinase buffer with 10 µCi of
[-32P]ATP (6000 Ci/mmol, 1 Ci = 37 GBq) and 2 µg of glutathione S-transferase c-Jun (1-135) protein
fragment for SAPK activity or 2 µg of myelin basic protein for ERK
activity. The samples were analyzed by SDS-polyacrylamide gel
electrophoresis upon termination of the reaction with Laemmli buffer
and boiling. The phosphorylation of glutathione
S-transferase c-Jun or myelin basic protein was quantified
by densitometry using a Bio-Rad Molecular Analyst 1.1.1.
The cell extracts used for
immunoprecipitation kinase assays were also used to quantify protein
abundance of the immediate early gene and Cyp11A1 gene
products. Western blotting was performed as described previously using
antibodies to JunB (N-17), JunD (329), c-Fos (K-25), c-Myc (C-8, Santa
Cruz Biotechnology), -tubulin (5H1) (37), and the rat Cyp11A1 (38,
39). Reactive proteins were visualized by the enhanced
chemiluminescence system (Amersham Life Science, Inc.). The abundance
of immunoreactive protein was quantified by densitometry using a
Bio-Rad Molecular Analyst 1.1.1.
The reporter c-fosLUC (24)
contains the human c-fos promoter from 361 to +157 in the
pA3LUC reporter (40). The junB promoter was
cloned by polymerase chain reaction using oligonucleotides to the
published sequences (5
GGTACCCGCGAGCCGCCTCCTCCC, 3
AAGCTTCCGGGCGGCCCAGGCGGT) and was subcloned into the reporter
pA3LUC to create the reporter junBLUC. The
c-myc P1/P2 promoters from
157 to +500 (41) were linked to
the pA3LUC reporter to form c-mycLUC. The
cAMP-responsive chorionic gonadotropin
subunit promoter fragments
linked to the luciferase reporter gene
846
LUC referred to as
CRELUC and
172
LUC were previously described (42). The
reporter plasmid
172 m4
LUC reporter that contains a mutation
within the chorionic gonadotropin
subunit cAMP response element
(CRE) which abolishes cAMP responsiveness and cAMP-responsive element
binding protein binding was described previously (42). The
2700-base
pair ovine CYP11A1 promoter fragment linked to the
luciferase reporter gene,
2700 CYPLUC, was described previously (43).
The integrity of all constructs was determined by restriction enzyme
analysis and dideoxy DNA sequencing (44) using an Applied Biosystems
Inc. automated sequencer. The construction of the plasmid encoding the
wild type and inactive mutant catalytic subunits of protein kinase A
were described previously (45).
Cell culture, DNA transfection, and luciferase assays were performed as described previously (42, 46). The Y1 cell line was a gift from Dr. B. Schimmer. Y1 cells were grown in Ham's F-10 medium with 1% penicillin, streptomycin, 2.5% fetal bovine serum, and 15% horse serum. 3 × 105 cells were transfected by calcium phosphate precipitation, the medium was changed after 6 h, and luciferase activity was determined after a further 24 h (42, 46). Luciferase assays were performed using an Autolumat LB 953 (EG & G Berthold). Luciferase content was measured by calculating the light emitted during the initial 30 s of the reaction, and the values are expressed in arbitrary light units (36, 42). The percent effect was determined by comparison with its untreated activity. Statistical analyses were performed using the Mann Whitney U test.
To examine the effect of ACTH on adrenal cortical SAPK
activity in vivo, rats were treated with intravenous ACTH.
The adrenal cortex was dissected from the medulla, and immune complex
kinase assays were performed using a polyclonal SAPK antibody and the amino terminus of c-Jun (amino acids 1-135) as the substrate (17, 24,
43). Adrenal cortical SAPK activity was increased 2-fold at 15 min
(Fig. 1A) and 3-fold (3.1 ± 0.5, n = 5) at 30 min (Fig. 1, A and
B). SAPK activity remained elevated at 1 h (3.2-fold) and at 6 h (2-fold), indicating the response to ACTH was both rapid and sustained (Fig. 1, A and B). The
sustained induction of SAPK activity contrasts with the transient
induction of SAPK activity we previously observed in response to growth
factors (43). In control animals treated with intravenous saline, there was no increase in SAPK activity. In contrast with the induction of
SAPK activity, ERK activity was reduced 40% at 30 min in the same
ACTH-treated adrenal cortical extracts (data not shown).
SAPK Activity Is Stimulated by ACTH in Cultured Adrenocortical Y1 Cells
The effect of ACTH on SAPK and ERK activity was also
determined in cultured Y1 adrenal cells. ACTH (106
M) treatment for 30 min stimulated SAPK activity an average
of 3-fold in Y1 cells (Fig.
2A). To determine the time
course of SAPK induction by ACTH in Y1 cells, treatment with ACTH was
conducted for 15 min to 24 h, and the cells were harvested. SAPK
activity was induced 2.5-fold (n = 6, range
1.4-4-fold) within 15 min and was sustained at 2 h (Fig.
2B), returning to baseline at 6 h (data not shown). The
induction of SAPK was observed at 10
8 M and
10
10 M ACTH (Fig. 2B). SAPK
activity was also induced by ACTH in the absence of serum (Fig.
2C). In contrast with the effect of ACTH on SAPK, ERK
activity was reduced by ACTH treatment with a mean reduction of 45% at
30 min (Fig. 2, D and E). The inhibition of ERK
activity by ACTH was observed at 10
6 M and
10
8 M ACTH (Fig. 2E).
SAPK Activity Is Induced by Intracellular Stressors but Not by cAMP in Y1 Cells
Studies were performed to investigate the second
messenger pathways regulating SAPK activity and involved in ACTH
regulation of SAPK activity. In previous studies of cultured
hepatocytes, heat shock and tumor necrosis factor (TNF
) were
shown to induce SAPK activity 4- and 5-fold, respectively (17). When Y1
cells were treated with heat shock (42 °C) or TNF
(50 ng/ml) for
15 min, SAPK activity was induced 4-fold and 5-fold, respectively (Fig.
3A). ERK activity was induced
4.5-fold by heat shock but was induced only 1.5-fold by TNF
(not
shown). As cAMP is activated by ACTH, the effect of cAMP on SAPK
activity was determined. cAMP (10
3 M)
treatment was associated with a modest reduction in SAPK activity shown
at 20 min (Fig. 3B). Previous studies have demonstrated activation of the PKC pathway in ACTH-treated Y1 cells (33). To examine
whether activation of the PKC pathway induced SAPK activity, Y1 cells
were treated with the phorbol ester TPA (100 ng/ml). SAPK activity was
induced 4-fold at 15 min and 5.5-fold at 30 min (Fig. 3C).
Intracellular Ca+2 fluxes played an important role in both
angiotensin II-induced SAPK activity in liver epithelial cells (19) and
T cell activation of SAPK activity (22). To examine the role of
intracellular Ca+2 on SAPK activity in Y1 cells, the effect
of the calcium ionophore A23187 was assessed. SAPK activity was induced
4.5-fold at 15 min and 12-fold at 30 min by A23187 (60 µM) (Fig. 3D). Together these studies indicate
that several distinct intracellular stressors induce, but that cAMP
inhibits, SAPK activity in Y1 cells.
PKC and Extracellular Ca+2 Are Involved in ACTH-mediated SAPK Induction
To further investigate the secondary
messenger pathways involved in ACTH-induced SAPK activity, chemical
inhibitors of the isoquinolinesulfonamide family were used. H-8 is a
preferential and potent inhibitor of PKA (Ki 1.3 µM) compared with its effect against protein kinase C
(Ki, 15 µM) (47). Treatment of Y1
cells with the PKA inhibitor H-8 (3 µM) did not significantly affect ACTH-induced SAPK activity (Fig.
4A). At higher concentrations,
H-8 (30 µM) inhibits the PKC pathway (48), and
ACTH-induced SAPK activity was inhibited 40% by pretreatment with 30 µM H-8 (Fig. 4A, lane 4). The
isoquinolinesulfonamide H-89 preferentially inhibits PKA
(Ki, 500 nM) compared with the PKC
pathway (Ki, 76 µM). Pretreatment of
Y1 cells with 76 µM H-89 abolished SAPK induction by ACTH
(not shown).
Intracellular Ca+2 levels are increased in ACTH-treated Y1 cells (33). To examine the role of Ca+2 levels in ACTH-induced SAPK activity, the Ca+2 chelating agent EGTA was used. The increase in SAPK activity by ACTH was completely blocked by the addition of EGTA, suggesting that the transport of Ca+2 from the extracellular to the intracellular space may play a role in the ACTH-induced SAPK activity (Fig. 4B, lanes 6 and 7 versus 8). Together these studies suggest SAPK activity is induced by the PKC pathway and that ACTH induction of SAPK involves both the PKC and Ca+2 pathway.
Because H-8 at 3 µM did not affect SAPK induction by ACTH
and was used to inhibit PKA activity, we examined the effect of H-8 at
this concentration on cAMP-induced activity in Y1 cells. cAMP activity
was assayed using either transient reporter studies or biochemical
assays. Recent studies have demonstrated the high sensitivity of a
luciferase reporter system using the CRE to assay cAMP-regulated
activity in cultured cells (49). We therefore employed a chorionic
gonadotropin subunit reporter gene
172
LUC (42) as a
synthetic cAMP-responsive reporter to examine the cAMP pathway in Y1
cells. cAMP treatment induced the
172
LUC reporter 12-fold (Fig.
5). Pretreatment of Y1 cells with H-8 (3 µM) reduced cAMP-induced reporter activity by
approximately one-half (Fig. 5). Comparison was made with the reporter
172 m4
LUC (42) in which the CRE was mutated to abolish binding of
the cAMP-responsive element binding protein. Mutation of the CRE
reduced induction by cAMP 90% (Fig. 5), indicating the induction of
the wild type CRE reporter was a specific measure of the
cAMP/cAMP-responsive element binding protein pathway in Y1 cells.
The effect of H-8 on the PKA pathway was also assessed using the SignaTECT cAMP-dependent protein kinase A assay system. This assay is highly specific for PKA and uses biotinylated Kemptide as substrate. This peptide substrate is derived from the in vivo substrate pyruvate kinase. The high affinity of Kemptide for PKA (Km = 5-10 µM) also provides for high sensitivity. Y1 cells were pretreated with 3 µM H-8. Assays were performed in duplicate. The cAMP-induced PKA activity (6.2-fold) was reduced by 3 µM H-8 to 38% that of full induction (38% ± 9, n = 6, p < 0.05). These studies indicate that 3 µM H-8 inhibits cAMP-induced PKA activity in Y1 cells.
To examine the effect of H-8 (30 µM) on the PKC pathway, the SignaTECT protein kinase C assay system was used (50). This assay uses biotinylated Neurogranin peptide, which is the most specific substrate commercially available for PKC activity. Treatment of Y1 cells with TPA (100 ng/ml) for 15 min induced PKC activity 1.5-fold (1.54 ± 0.3 pmol of ATP/min/µg of protein, n = 3), consistent with studies in other cell types. The addition of 30 µM H-8 reduced the induction of PKC activity by TPA a mean of 65% (n = 3) (not shown). These studies indicate that 30 µM H-8 inhibits TPA-induced PKC activity in Y1 cells.
ACTH Induces Immediate Early Gene Expression in VivoThe
induction of SAPK activity is thought to induce expression of immediate
early and other specific target genes. To determine whether ACTH
regulated immediate early gene expression at concentrations that
induced SAPK activity, Western blotting was performed of the adrenal
cortex from ACTH-treated animals. Because experiments in cultured
adrenal cells suggested that JunB is induced by ACTH (51), the effect
of ACTH on adrenocortical JunB protein abundance was assessed. JunB
abundance was increased 17-fold after 30 min, with a peak 40-fold
increase at 2 h, returning to basal after 12 h (Fig.
6A). c-Fos was induced
1.3-fold within 30 min, returning to basal within 6 h (data not
shown). ACTH induced c-Myc abundance 2-fold after 30 min, returning to
basal at 24 h (Fig. 6C). The Western blots, which were
loaded with equal amounts of protein, were also probed for -tubulin.
The relative abundance of
-tubulin was unchanged by ACTH (Fig.
6D). The abundance of JunD was increased 1.6-fold after
6 h (Fig. 6B). Together these studies demonstrate that
ACTH treatment, at the concentrations shown to induce SAPK activity,
induces several immediate early gene products including JunB, c-Fos,
c-Myc, and JunD in vivo.
ACTH Induces Immediate Early Gene Expression and Promoter Activity in Y1 Cells
Western blot analyses were performed to determine
whether ACTH treatment of Y1 cells induced similar immediate early
genes as those induced by ACTH in vivo. The abundance of
JunB was increased after 30 min of ACTH (106
M) treatment, with maximal 12-fold induction at 2 h,
returning to basal levels after 24 h (Fig.
7A). JunD increased 2.4-fold by 6 h, and c-Myc was increased 2.1-fold after 3 h as
previously shown (10, 11) (data not shown).
To determine whether DNA sequences sufficient for ACTH responsiveness were located within the promoter regions of the ACTH-responsive immediate early genes (junB, c-myc, and c-fos), the promoters of these genes were cloned and linked to the luciferase reporter gene. ACTH induced the junBLUC reporter 2.5-fold at 3 h and 3.6-fold at 6 h (Fig. 7B). The effect of ACTH was assessed further at 6 h for the other immediate early gene promoters. ACTH induced c-fosLUC activity 2.5-fold, c-mycLUC activity 2-fold, and CRELUC activity 2.4-fold (Fig. 7C). The effect of cAMP on promoter activity was next assessed. At 6 h, junBLUC activity was induced 2-fold, c-fosLUC reporter was not induced significantly (1.1-fold), c-mycLUC reporter was induced 1.4-fold, and CRELUC reporter was induced 2.6-fold (Fig. 7D). In previous studies with a c-fos chloramphenicol acetyl transferase reporter, the cAMP induction of the c-fos promoter in NIH-3T3 cells was rapid and transient, returning to basal at 3 h (52). To determine whether sustained activation of the PKA pathway could induce c-fosLUC reporter activity, the catalytic subunit for protein kinase A was overexpressed with the c-fosLUC reporter. Overexpression of the PKA catalytic subunit induced the c-fosLUC reporter 10-fold and CRELUC reporter activity 27-fold (Fig. 7E), indicating that sustained induction of cAMP activates the c-fos promoter in Y1 cells. In addition, as previously shown with cAMP in Y1 cells (46), the CYP11A1 promoter was induced 3-fold by overexpression of the PKA catalytic subunit (Fig. 7E). These studies indicate that ACTH induces immediate early gene expression and promoter activity at the concentrations that induced SAPK activity.
The SAPKs are preferentially phosphorylated at tyrosine and threonine residues in response to toxins and intracellular stressors (12, 17-21), and SAPK activity appears to be involved in differentiation and apoptosis (53-55). The role of the SAPKs in response to stress hormones in vivo remained to be investigated. These studies demonstrate the novel finding that ACTH induces SAPK activity both in the rat adrenal cortex in vivo and in cultured Y1 adrenal cells. TPA, but not cAMP, induced SAPK activity. ACTH-induced SAPK activity was reduced by isoquinolinesulfonyl chemical inhibitors of the PKC pathway. EGTA blocked ACTH-induced SAPK activity, indicating a requirement for extracellular Ca+2 in ACTH-induced SAPK activity. Together these studies suggest that the Ca+2 and PKC pathway are involved in ACTH-induced SAPK activity.
The induction of SAPK activity by ACTH was inhibited by either H-8 or H-89 at concentrations that inhibited PKC activity but not at concentrations that inhibited PKA activity. H-8 is a preferential inhibitor of PKA with a Ki for PKA of 1.2 µM and a Ki for PKC of 15 µM (47). cAMP-induced PKA activity was assayed in Y1 cells using either a cAMP-responsive reporter gene system or biotinylated Kemptide as substrate. At 3 µM, H-8 inhibited PKA activity approximately 40-50% using either of these systems. This concentration of H-8 did not inhibit ACTH-induced SAPK activity in Y1 cells. PKC activity was assayed using biotinylated Neurogranin in Y1 cells. At the higher concentration of 30 µM H-8, previously shown to inhibit PKC activity (50), TPA-induced PKC activity was inhibited approximately 60% in Y1 cells. SAPK induction by ACTH was also inhibited 40% by 30 µM H-8. Together these studies suggest that ACTH induction of SAPK involves the PKC pathway.
EGTA blocked ACTH-induced SAPK activity, suggesting a requirement for extracellular Ca+2 in ACTH-induced SAPK activity. EGTA was recently shown to reduce SAPK activity induced by angiotensin II in hepatic cells, suggesting that intracellular calcium may be a common component required for SAPK activation by these two hormones (19). The intracellular Ca+2 chelating agent BAPTA also reduced angiotensin II-induced SAPK activity (19) and ACTH-induced SAPK activity by 40%.2 Calcium plays an important role in several aspects of normal adrenal function. ACTH-induced steroid secretion was inhibited by calcium channel blockade in cultured bovine adrenal cells (56, 57). In Y1 cells, ACTH-stimulated steroid secretion was enhanced by the addition of Ca+2 and inhibited by 5 mM EGTA (58). The extracellular concentration of calcium affects the distribution of microfilaments and the morphological response induced by ACTH (59). In part this may be because the calcium-binding protein, calmodulin, is both involved in the coupling of the ACTH receptor to the adenylyl cyclase regulatory protein and also binds to cytoskeletal proteins (7). Together these findings indicate the importance of Ca+2 in ACTH-induced SAPK activity and normal adrenal steroid secretion.
ACTH inhibited basal ERK activity in the rat adrenal cortex in vivo and in cultured Y1 cells. In many circumstances, induction of ERK activity is associated with enhanced cellular proliferation (12, 60), S-phase progression, and DNA synthesis (25). ACTH inhibits cellular proliferation in fetal adrenal cells (61) and inhibits DNA synthesis in Y1 cells (2). The inhibition of ERK activity by ACTH may contribute to the inhibition of cellular proliferation and DNA synthesis induced by ACTH (2).
Several previous studies suggested that ACTH induced PKA-dependent and PKA-independent effects in adrenal cells. Although both ACTH and cAMP treatment of adrenal cells induced immediate early gene expression, the magnitude of induction and the kinetics of immediate early gene expression were different. The induction of c-Fos (62) and JunB (11) by ACTH was greater than that observed with cAMP treatment in Y1 cells. The induction of c-myc expression by ACTH in rat adrenal cells was PKC-dependent (10), and the induction of CYP11A1 mRNA in fetal adrenal cells was partially inhibited by H-7 or staurosporine, suggesting a role for the PKC pathway (61). Our studies provide further evidence for an intracellular signaling pathway that is induced by ACTH and not by cAMP, as SAPK was induced by ACTH and not by cAMP. The induction of SAPK by ACTH may contribute to some of the differences in immediate early gene expression induced by ACTH compared with cAMP because SAPK is thought to induce expression of immediate early genes. SAPK is thought to induce several different immediate early genes through phosphorylation and activation of transcription factors including c-Fos (63), c-Jun (13), Ets family proteins (64), and ATF-2 (65). In our studies, at least at the time points examined, the c-fos promoter and the JunB promoters were induced preferentially by ACTH compared with cAMP. The independent role of SAPK in ACTH-induced immediate early gene expression and the other effects mediated by ACTH in vivo may be investigated further when specific chemical inhibitors for SAPK become available.
ACTH also stimulates rounding of cultured adrenal cortical cells and the induction of microfilament polymerization and plasma membrane microvilli formation that facilitates endocytosis of precursors for steroid hormone biosynthesis (66, 67). The induction of SAPK may also be linked to these ACTH-induced cytoskeletal changes (66, 67). Recent studies have suggested that the small GTPase Rac1 (68, 69) is responsible for both actin polymerization and the induction of SAPK activity. The role of the SAPK regulatory protein Rac1 in ACTH induced cytoskeletal changes, and steroid hormone secretion is currently under investigation in this laboratory.
Angiotensin II, which also signals through a G-protein-coupled receptor, was recently shown to induce SAPK activity in cultured hepatic (19) and adrenal cells (24). Our results provide further evidence that seven transmembrane G-protein-coupled receptors regulate SAPK activity (19, 23). The rapid and sustained induction of adrenocortical SAPK activity by ACTH in vivo suggests an important role for SAPK in the whole animal response to stress.
We are grateful to Drs. R. Maurer and N. Hay and E. DesJardins for plasmids, Drs. J. Richards, L. Binder, J. Avruch, and J. Kyriakis for antibodies, and Dr. B. Schimmer for Y1 cells.