Juvenile Diabetes Foundation International/Medical Research Council Group in Diabetic Nephropathy, University of Toronto, Toronto, Ontario, Canada M5S 1A8
![]() |
ABSTRACT |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Glomerular hypertension
and hyperglycemia are major determinants of diabetic nephropathy. We
sought to identify the mechanisms whereby stretch-induced activation of
mesangial cell extracellular signal-regulated kinase 1 and 2 (ERK1/ERK2) is enhanced in high glucose (HG). Mesangial cells cultured
on fibronectin Flex I plates in normal glucose (NG; 5.6 mM) or HG (30 mM), were stretched by 15% elongation at 60 cycles/min for up to 60 min. In HG, a 5-min stretch increased ERK1/ERK2 phosphorylation by
6.4 ± 0.4/4.3 ± 0.3-fold (P < 0.05 vs. NG
stretch). In constrast, p38 phosphorylation was increased identically
by stretch in NG and HG. Unlike many effects of HG, augmentation of ERK
activity by HG was not dependent on protein kinase C (PKC) as indicated
by downregulation of PKC with 24-h phorbol ester or inhibition with
bisindolylmaleimide IV. In both NG and HG, pretreatment with
arginine-glycine-aspartic acid peptide (0.5 mg/ml) to inhibit integrin
binding or with cytochalasin D (100 ng/ml) to disassemble filamentous
(F) actin, significantly reduced phosphorylation of ERK1/ERK2 and p38.
To determine whether the rate of mitogen-activated protein kinase
dephosphorylation is affected by HG, cellular kinase activity was
inhibited by depleting ATP. Post-ATP depletion, phosphorylation of
ERK1/ERK2 was reduced to 36 ± 9/51 ± 14% vs. 9 ± 5/7 ± 6% in NG (P < 0.05, n = 5). Thus stretch-induced ERK1/ERK2 and p38 activation in both NG and HG is 1-integrin and F-actin dependent. Stretch-induced
ERK1/ERK2 is enhanced in high glucose by diminished dephosphorylation,
suggesting reduced phosphatase activity in the diabetic milieu.
Enhanced mesangial cell ERK1/ERK2 signaling in response to the combined effects of mechanical stretch and HG may contribute to the pathogenesis of diabetic nephropathy.
cyclic-strain; p38; 1-integrin; arginine-glycine
aspartic acid peptide; dephosphorylation; extracellular
signal-regulated kinase 1 and 2
![]() |
INTRODUCTION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
DIABETIC NEPHROPATHY IS CAUSED by high glucose (25) and accelerated by glomerular hypertension (31). In diabetes, glomerular mesangial cells demonstrate excessive growth and extracellular matrix (ECM) protein synthesis (36). High glucose induced activation of mesangial cell protein kinase C (PKC) (12, 20) and mitogen-activated protein kinases (MAPKs) (12, 14), and subsequent gene expression, have been implicated. Increased glomerular pressure precedes mesangial cell growth and ECM production in diabetes (42) and could contribute to extracellular signal-regulated kinase (ERK) activation by high glucose. However, at present, the combined effects of high glucose and cell stretch in mesangial cells are poorly understood.
Members of the MAPK family, such as ERK and p38, are regulated by a variety of stimuli, including PKC and phosphatases. High glucose causes activation of mesangial cell PKC (22), ERK1/ERK2 (10), and p38 (14, 21), but not all the effects of high glucose on MAPK are attributable to PKC. We have observed that the enhanced response of ERK1/ERK2 to endothelin-1 (ET-1) in high glucose is PKC dependent (10) whereas enhanced p38 activation is PKC independent (40). Mechanical stretch also activates ERK (34). This has been reported to occur through multiple mechanisms including PKC, Ca2+, and src kinase-dependent signaling pathways (37). The activity of MAPK family members is tightly controlled not only by the rate of phosphorylation but also by dephosphorylation. Inactivation of MAPK signaling is mediated by serine/threonine protein phosphatases, protein tyrosine phosphatases (24) and a class of 9 dual specificity protein phosphatases that include mitogen-activated protein phosphatase-1 (MKP-1). MKP-1 is expressed in both cultured mesangial cells (4, 38) and in isolated rat glomeruli (2) and its expression is inhibited in mesangial cells exposed to high glucose for 5 days in a PKC-dependent manner (2). In rat vascular smooth muscle cells (VSMC), exposure to 12- and 24-h high glucose decreases basal MKP-1 protein by 75% via a p38-dependent pathway (3). Therefore, we postulated that high glucose increases activation of mesangial cell ERK1/ERK2 and p38 MAPK by mechanical stretch through mechanisms involving both PKC and phosphatases.
The composition of extracellular matrix modifies the ERK response to
mechanical stretch. For instance, rat cardiac fibroblasts (28) and rat VSMC (32) require fibronectin
for stretch-induced activation of ERK1/ERK2. In vivo, mesangial cells
attach to mesangial matrix proteins including collagen IV, laminin,
perlecan and fibronectin via 1-integrins
(8). This study is the first to examine the effects of
mechanical stretch and high glucose on MAPKs in mesangial cells
attached to fibronectin.
To analyze the effects of high glucose and mechanical stretch together, activation of ERK1/ERK2 and p38 were analyzed by immunoblot of total cell content of phospho- and total MAPKs, and by immunoprecipitation of phospho-ERK1/ERK2 and p38, followed by phosphorylation of an Elk-1 and ATF-2 fusion proteins, respectively. The roles of PKC-dependent and -independent pathways in the stretch-activation of ERK1/ERK2 and p38 were studied by inhibition of signaling via PKC, Ca2+ and tyrosine kinase phosphorylation. Confocal fluorescence imaging was used to examine focal adhesion complexes and filamentous (F)-actin, with and without inhibitors of attachment and F-actin assembly. The change in stretch-induced ERK1/ERK2 and p38 phosphorylation after ATP depletion in normal and high glucose was used to unmask the rate of MAPK dephosphorylation. These experiments demonstrated a role for integrins, the actin cytoskeleton, and phosphatases, but not PKC, in the enhancement of stretch-activated ERK by high glucose on fibronectin.
![]() |
MATERIALS AND METHODS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Materials. Dulbecco's modified Eagle medium (DMEM), penicillin, streptomycin and trypsin were purchased from GIBCO Life Technologies (Burlington, ON). Fetal bovine serum (FBS) was purchased from Wisent (St. Bruno, QC). Phorbol 12-myristate 13-acetate (PMA), arginine-glycine-aspartic acid (RGD), cytochalasin D, leupeptin, pepstatin A, aprotinin, bensamidine, Tween-20, sodium-orthovanadate, dithiothreitol (DTT), rotenone, 2-deoxyglucose, and ATP somatic cell assay kit were obtained from Sigma (St. Louis, MO). Herbimycin A (Herb A), 4-amino-5-(4-chlorophenyl)- 7-(t-butyl)pyrazolo[3,4-d]pyrimidine (PP2), bisindolylmaleimide IV (BIM IV), and wortmannin were obtained from Calbiochem-Novabiochem (La Jolla, CA). 1,2-Bis(2-aminophenoxy)ethane-N,N,N',N',-tetraacetic acid (BAPTA) and rhodamine-phalloidin were from Molecular Probes (Eugene, OR). Monoclonal phospho-specific ERK1/ERK2 antibody (Thr-202/Tyr-204), polyclonal phospho-specific p38 antibody (Thr-180/Tyr-182), polyclonal total ERK1/ERK2 and total p38 antibodies, and the Elk-1 and ATF-2 fusion protein MAPK activity assay kits were purchased from New England Biolabs (Beverly, MA). Horseradish peroxidase (HRP)-labeled goat anti-rabbit and goat anti-mouse secondary antibodies were from Bio-Rad (Hercules, CA) and Jackson Immunoresearch Laboratories (West Grove, PA), respectively. Monoclonal PY-20 anti-phosphotyrosine and anti-vinculin were purchased from Upstate Biotechnology (Lake Placid, NY) and SeroTec (Hornby, ON), respectively. All other chemicals were of analytical or electrophoresis grade and purchased from BDH (Toronto, ON).
Cell culture. Mesangial cells were cultured from collagenase-treated glomeruli obtained by seiving of kidney cortex of 150- to 200-g male Sprague-Dawley rats (Charles River, QC) as previously described (13). The mesangial cells were maintained in DMEM, pH 7.4, supplemented with 20% FBS, 100 U/ml penicillin, 100 µg/ml streptomycin, and 10 mM HEPES. Mesangial cells were characterized by their spindle or stellate shape, and immunofluorescence staining was positive for the presence of desmin and vimentin and negative for cytokeratin and factor VIII to differentiate them from glomerular endothelial and epithelial cells (7).
Mechanical stretch.
Mesangial cells were seeded (25,000 cells/well) on fibronectin-coated
25-mm Flex-I flexible-bottomed plates (Flexercell, McKeesport, PA). The
cells were allowed to grow for 48 h in 20% FBS DMEM in 5.6 mM
D-glucose and were then growth-arrested for 48 h in
0.5% FBS DMEM in 5.6 or 30 mM D-glucose, then
serum-starved for 3 h preceeding mechanical stretch. Stretch was
regulated by a computer-controlled vacuum manifold providing
12-15% elongation at a frequency of 60 cycles/min with 0.5-s
strain alternating with 0.5 s in the neutral position. Cells were
stretched for 2, 5, 10, 30 and 60 min. To inhibit and/or downregulate
PKC, cells were either pretreated with 1 µM BIM IV for 1 h or
with 0.1 µM PMA for 24 h prior to stretch. To chelate
Ca2+, cells were pretreated with 25 µM BAPTA for 10 min
prior to stretch. To inhibit protein tyrosine kinases, cells were
either pretreated with 10 µM Herb A or 10 µM PP2 for 18 h
prior to stretch. To inhibit PI 3-kinase, cells were pretreated for
1 h with 1 µM wortmannin. To inhibit 1-integrin
binding, cells were pretreated with 0.5 mg/ml RGD peptide for 1 h.
To disrupt F-actin, cells were pretreated with 100 ng/ml cytochalasin D
for 3 h. Phosphotyrosine immunoblots were used to validate the
effectiveness of the protein tyrosine kinase inhibitors.
Immunoblotting of ERK1/ERK2, p38, and phosphorylated tyrosine. Stretched and unstretched cells were quickly washed twice with ice-cold phosphate buffered saline (PBS) before the addition of 125 µl boiling 2× SDS sample buffer/well containing 130 mM Tris-base, pH 6.8, with HCl, 4% SDS, and 20% glycerol. The cells were scraped and the lysates were passed 5× through a 26 G × 1/2-in. needle. The samples were then boiled for 2 min and clarified by centrifugation at 15,000 g for 10 min. Protein concentration was determined using the modified micro Lowry detergent-compatible protein assay (Bio-Rad) with bovine serum albumin (BSA, BioShop, Toronto, ON) as the standard. Equal amounts of protein (15 µg) from each sample were then separated by SDS-PAGE. Anisomycin-treated C-6 glioma cell extract (New England Biolabs) served as a positive control. Gels were equilibrated in transfer buffer at room temperature (RT) for 10 min and then transferred overnight at 4°C to polyvinylidene difluoride (PVDF) membranes (Millipore, Bedford, MA).
PVDF membranes were rinsed with PBS and blocked with 5% skim milk powder in Tris-buffered saline (TBS), pH 7.5, containing 0.05% Tween-20 (TTBS) for 2 h at RT. The blots were incubated overnight at 4°C with primary antibodies in 5% skim milk or 5% BSA TTBS with dilutions as follows; 1:3,000 for phosphorylated ERK1/ERK2, PY-20 and 1:2,000 for phosphorylated p38. After three 5-min washes with TTBS, secondary antibodies, either goat anti-mouse HRP or goat anti-rabbit HRP, were used at 1:5,000 dilution in 5% skim milk TTBS for 20 min at RT and were visualized using enhanced chemiluminescence (ECL; Kirkegaard & Perry Laboratories, Gaithersburg, MD). The blots were exposed to Kodak X-Omat Blue film (Eastman Kodak, Rochester, NY) for 10-60 s. The same membranes were then reprobed to detect total ERK1/ERK2 and total p38 protein. For ERK1/ERK2, the membranes were exposed to 15% hydrogen peroxide in TBS for 20 min at RT. For total p38, the membranes were stripped in 0.1 M glycine, pH 2.9, for 20 min at RT. After two 5-min washes, the membranes were reblocked with 5% skim milk TTBS, and the immunoblots were repeated using a polyclonal anti-ERK1/ERK2 antibody (1:3,000) and polyclonal anti-p38 MAPK antibody (1:2,000), respectively. This was followed by a 20-min incubation at RT with an HRP-conjugated goat anti-rabbit secondary. Densitometry was performed using National Institutes of Health Image software (version 1.62, National Institutes of Health, Bethesda, MD) on a Macintosh 7200/100 computer. Densitometry was performed on both sets of blots and the results were expressed as a ratio of phosphorylated to total MAPK. All results were expressed as a ratio compared with unstretched cells in 5.6 mM glucose.Analysis of ERK1/ERK2 and p38 activation.
Basal and stretch-induced ERK1/ERK2 and p38 activities were measured
using immunoprecipitation and phosphorylation of Elk-1 and ATF-2 fusion
protein following the manufacturer's instructions (New England
Biolabs). Briefly, cells were rinsed twice with ice-cold PBS and then
lysed with 100 µl of radioimmunoprecipitation buffer (RIPA). The
lysate was clarified by centrifugation at 15,000 g for 10 min at 4°C, and 20-µl aliquots were collected for protein assay as
described above. Fifteen microliters of either an immobilized monoclonal anti-phospho-ERK1/ERK2 antibody or an immobilized
anti-phospho p38 antibody were added to 200 µg of cellular protein
overnight at 4°C. The MAPK immunocomplexes were then microcentrifuged
for 30 s at 4°C, washed twice with 200 µl RIPA buffer and
twice with kinase buffer containing 25 mM Tris (pH 7.5), 5 mM
-glycerophosphate, 2 mM DTT, 0.1 mM Na3VO4,
10 mM MgCl2, suspended in 50 µl kinase buffer
supplemented with 200 µM ATP and either 2 µg ATF-2 for p38 activity
measurement or 2 µg Elk-1 fusion protein, followed by incubation for
30 min at 30°C. The reaction was terminated by addition of 25 µl of
3× SDS sample buffer and boiling for 5 min. Reaction products were
separated by 10% SDS-PAGE and transferred onto PVDF membranes
overnight as described above. After blocking in 5% skim milk TTBS for
2 h at RT, the membranes were incubated with phospho-specific
ATF-2 or Elk-1 antibodies (1:2,000 in 5% BSA TTBS) overnight at 4°C.
Active ERK1/ERK2 (New England Biolabs) and anisomycin-treated cells
served as positive controls. Fusion protein phosphorylation was
detected by ECL, and densitometry was performed as described above.
Inhibition of MAPK activation and measurement of MAPK dephosphorylation. To inhibit MAPK activation, mesangial cells were depleted of ATP by preincubation in PBS preheated to 37°C supplemented with 5 µM rotenone and 10 mM 2-deoxyglucose for 10 and 15 min after stretch (29). To verify ATP depletion, cellular ATP content was measured using an ATP bioluminescent somatic cell assay kit (Sigma) and normalized to cellular protein. Mesangial cells were lysed in 75 µl boiling 2× SDS sample buffer, and total cellular protein was determined as described above. Lysates were electrophoresed, and membranes were subsequently immunoblotted with anti-phospho-ERK1/ERK2, anti-phospho-p38 and total ERK1/ERK2 and total p38 antibodies. The change in the amount of phosphorylated ERK1/ERK2 or phosphorylated p38 between successive time points after ATP depletion was used to determine the extent of MAPK dephosphorylation after mechanical stretch.
Confocal imaging.
Mesangial cells were growth-arrested for 2 days in 0.5% FBS DMEM on
coverslips coated with fibronectin (50 µg/ml). Cells were then serum
starved for 3 h in DMEM prior to labeling of F-actin and
vinculin with rhodamine-phalloidin and FITC-conjugated goat anti-mouse
IgG according to our previously published methods (43). Cells were either pretreated for 1 h with 0.5 mg/ml RGD peptide or
for 3 h with 100 ng/ml cytochalasin D. Briefly, cells were washed
three times with PBS, fixed in 3.7% formaldehyde, and permeabilized with 100% methanol at 20°C for 10 min. After washing in PBS, cells
were blocked in 1% goat serum plus 0.1% BSA in PBS for 1 h at
RT. Monoclonal anti-vinculin antibody was diluted 1:4 in blocking
solution and 200 µl were added to each coverslip. After 1-h
incubation at 37°C, cells were washed three times in PBS then exposed
to 200 µl of a combination of 0.165 M rhodamine-phalloidin and
FITC-conjugated goat anti-mouse secondary antibody, 1:160, in blocking
solution. After a 1-h incubation at 37°C, cells were washed and
mounted on glass slides with Immunofluore mounting media (ICN
Biomedical, Costa Mesa, CA) and imaged with a dual channel confocal
laser scanning microscope (Zeiss LSM 410, Düsseldorf, Germany).
The following controls were performed: 1) incubation with
FITC-conjugated secondary antibody alone, which demonstrated no
significant labeling; and 2) preincubation of the primary
antibody with specific blocking peptide, which prevented fluorescence
labeling of vinculin.
Statistical analyses. All results are expressed as means ± SE. Statistical analysis was performed using InStat 2.01 statistics software (Graph Pad, Sacramento, CA). The means of three or more groups were compared by the one-way ANOVA. If significance of P < 0.05 was obtained in the ANOVA, the Tukey multiple comparison posttest was applied. If the Bartlett's test indicated non-Gaussian distribution then the nonparametric Kruskal-Wallis test, followed by Dunn's multiple comparison or the Mann-Whitney test was utilized. Differences described as significant in the text are P < 0.05 unless otherwise stated.
![]() |
RESULTS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Mechanical stretch stimulates ERK1/ERK2.
Cyclic stretch stimulated the phosphorylation of ERK1/ERK2 in a
time-dependent manner as observed in Fig.
1. The responses were rapid and transient
with peak phosphorylation at 5 min of stretch, returning to basal
values by 30-60 min. Immunoblotting of cell extracts with
anti-ERK1/ERK2 antibody revealed no change in total levels of ERK1/ERK2
protein.
|
Mechanical stretch stimulates p38.
Cyclic stretch also stimulated the phosphorylation of p38 in a
time-dependent manner (Fig.
2A). Phosphorylation of p38
was significantly increased by 2 min and was maximal at
5-10 min. The response was transient, returning to static basal
levels by 30-60 min.
|
Effect of osmolarity.
Cells were growth-arrested for 2 days in normal glucose supplemented
with either 24.4 mM L-glucose or 24.4 mM mannitol to serve
as osmotic controls. Static or stretch-activated ERK1/ERK2 was not
enhanced in the presence of either L-glucose or mannitol (Fig. 3A). Similar results
were observed for p38 (Fig. 3B).
|
Inhibiton of PKC.
To examine the role of PKC in mechanical stretch-induced ERK1/ERK2
activation, cells were pretreated for 1 h with the PKC inhibitor
BIM IV (1 µM) or downregulated with 24-h PMA (0.1 µM). Inhibition
or downregulation of PKC did not alter stretch-activated ERK1/ERK2 or
p38 phosphorylation in normal or high glucose. Total ERK1/ERK2 and p38
protein were not affected by PKC inhibition (Fig.
4). In translocation experiments with
PKC-isoform-specific antibodies, high glucose or stretch did not alter
cytosol, membrane or particulate fraction PKC-,-
, -
, and -
content (data not shown).
|
Inhibition of potential upstream signaling pathways.
Tyrosine phosphorylation of stretched cells in normal and high glucose
was examined with immunoblotting using a PY-20 anti-phosphotyrosine antibody (Fig. 5A). On
fibronectin, mesangial cells displayed a high basal level of tyrosine
phosphorylation of proteins with molecular masses of ~225, 150, 90, and 70 kDa. Mechanical stretch stimulated tyrosine phosphorylation of
two additional proteins with a molecular mass of 44 and 42 kDa,
consistent with ERK1/ERK2. To confirm the effectiveness of tyrosine
phosphorylation inhibitors, erbstatin, herbimycin A, and PP2 pretreated
cells (10 µM for 18 h) were challenged with 50 ng/ml
platelet-derived growth factor (PDGF) for 10 min. In untreated cells,
PDGF markedly stimulated the phosphorylation of ERK1/ERK2 (Fig.
5B). Only PP2 prevented the PDGF-induced activation of
ERK1/ERK2 phosphorylation (Fig. 5B). Total levels of
ERK1/ERK2 were not affected by any of the inhibitors.
|
|
Effect of RGD peptide and cytochalasin D on ERK1/ERK2 and p38.
Cells in normal and high glucose were pretreated for 1 h with 0.5 mg/ml RGD peptide. In the static condition, RGD peptide did not affect
basal levels of either ERK1/ERK2. RGD pretreatment reduced
stretch-induced ERK1/ERK2 phosphorylation to 72 ± 9/62 ± 7% of stretch (n = 5, P < 0.05 vs. no
RGD) (Fig. 6A), which was no
different in high glucose, 82 ± 6/79 ± 9% of stretch.
|
|
|
The effects of high glucose on ERK1/ERK2 and p38 dephosphorylation.
The overall phosphatase activity on ERK was examined using the method
of Meriin et al. (29). Rotenone and 2-deoxyglucose were
used to rapidly inhibit cellular kinase activity, and the rate of ERK
dephosphorylation was then followed by immunoblotting. Pretreatment of
mesangial cells with rotenone and 2-deoxyglucose led to a 10 fold
decrease in cytosolic ATP concentration in 10 min in both normal and
high glucose (10.4 ± 0.3 and 5.2 ± 0.8% , P < 0.01 vs. normal glucose time 0,
n = 3) (Fig.
9A). ERK1/ERK2 phosphorylation
levels after ATP depletion are shown in Fig. 9B. In the
static condition, 10-min ATP depletion did not alter basal levels of
ERK1/ERK2 in normal and high glucose, but by 15 min, ERK1/ERK2
phosphorylation was undetectable. In normal glucose, stretch-induced
ERK1/ERK2 phosphorylation was reduced to 15 ± 3/20 ± 7% of
stretch (P < 0.01, n = 5) 10 min after
ATP depletion and to 9.4 ± 5/7.4 ± 6% of stretch
(P < 0.01, n = 5) at 15 min. By
contrast, in high glucose, ERK1/ERK2 dephosphorylation was reduced to
36 ± 9/51 ± 13% and 18 ± 9/22 ± 10%
(P < 0.05 vs. normal glucose stretch,
n = 5) after 10- and 15-min ATP depletion,
respectively. Figure 9C shows the results of similar
experiments performed with p38. In normal and high glucose, basal p38
levels were 58 ± 20 and 66 ± 15% (n = 5, P < 0.05 vs. basal), respectively 10 min after ATP
depletion. At 15 min, phosphorylated p38 was not detectable. In normal
glucose, at 10 and 15 min after ATP depletion, stretch-induced p38
phosphorylation was reduced to 38 ± 15 and 8 ± 7% of
stretch (P < 0.01, n = 5),
respectively. The effect was no different in high glucose (32 ± 12 and 7 ± 6% of stretch, respectively).
|
![]() |
DISCUSSION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
In glomerular mesangial cells cultured on fibronectin, exposure to
15% stretch rapidly and transiently activates ERK1/ERK2 and p38.
ERK1/ERK2, but not p38 activation is enhanced by high glucose.
Stretch-induced stimulation of MAPKs in both normal and high glucose is
1-integrin and F-actin dependent and appears to be
independent of activation by PKC, Ca2+, PI 3-kinase,
tyrosine kinases and src-kinases. The high glucose-enhanced activation of ERK1/ERK2, but not p38, appears to be dependent on
reduced dephosphorylation.
This study is the first to report that both ERK1/ERK2 and p38 are rapidly activated by 15% stretch in mesangial cells cultured on fibronectin. A similar response has been reported in bovine aortic endothelial cells (15). In cardiac fibroblasts on fibronectin, ERK1/ERK2, but not p38, was activated by stretch (28). High surface pressure directly applied to mesangial cells on collagen I also rapidly and transiently activated ERK1/ERK2 (23). Ingram et al. (16) stretched mesangial cells 20 and 30% for 30-120 min on collagen I. They observed, at 20% stretch, activity of ERK1/ERK2, but not p38. At 30% stretch, ERK1/ERK2 and p38 stimulation and proliferation were observed (16). In a later study, the same group showed activation of p38, ERK1/ERK2, and stress-activated protein kinase/c-Jun NH2-terminal kinase (SAPK/JNK) with 20% stretch for 10 min (17). Ishida et al. (19) report that mesangial cells on collagen I demonstrate a rapid, transient, and stretch intensity-dependent activation of ERK1/ERK2 and SAPK/JNK, whereas p38 was not examined. Taken together, these observations indicate that mesangial cell ERK1/ERK2 and p38 are more stretch responsive when attached to fibronectin compared with collagen I.
In our study, activation of ERK1/ERK2 and p38 was not likely due to autocrine factor release in response to stretch, since conditioned media from stretch plates failed to stimulate both ERK1/ERK2 and p38 in static controls (data not shown). The transient response of ERK1/ERK2 and p38 may be partly explained by the rapid activation of mitogen-activated protein kinase phosphatases (MKPs). Li et al. (26) recently demonstrated that as little as 8- to 30-min cyclic strain in rat VSMC grown on collagen I stimulated simultaneous rapid expression of MKP-1 mRNA and protein, which was dependent on prior activation of both ERK1/ERK2 and p38 MAPK (26). In rat VSMC, angiotensin II and PMA also stimulate ERK1/ERK2, accompanied by enhanced MKP-1 activity (5). Simultaneous stimulation of MKP-1 may be a negative feedback mechanism regulating ERK1/ERK2 and p38 MAPK.
An advantage of the present experiments is that culture of cells on
fibronectin more closely mimics in vivo conditions compared with
plastic. After 2 days exposure to high glucose, basal levels of
ERK1/ERK2 and p38 were not changed in the current experiments. By
contrast, we have reported previously that mesangial cells cultured on
plastic demonstrate increased basal activity of ERK1/ERK2 (10). Consistent with these findings, 3 days of high
glucose did not alter basal levels of p38, ERK1/ERK2, and SAPK/JNK in mesangial cells cultured on collagen I (17). We have
previously reported that culturing cells in high glucose on plastic for
2 days increases PKC activity and PKC-, -
, and -
membrane
translocation (22). In the current study, neither 2 days
of high glucose, nor stretch stimulated PKC isoform translocation in
mesangial cells on fibronectin (data not shown). This suggests that
fibronectin alters responsiveness of PKC isoforms to high glucose.
In human keratinocytes (39) and in Caco-2 intestinal
epithelial cells (11) cultured on collagen I, stretch
stimulated transient translocation of PKC- and PKC-
within 5 min
(39) and PKC-
and PKC-
within 30 s
(11). It is possible that in our study, transient
activation of some PKC isoforms occurred prior to the earliest 2-min
time point. Nevertheless, neither BIM IV nor 24-h PMA, prevented
stretch-induced ERK1/ERK2 and p38 activation. This is in contrast to
the work of Ingram et al. (18) who showed that 28%
stretch-induced p38 activation was attentuated by 24-h PMA. Akai et al.
(1) observed enhanced membrane PKC activity in mesangial
cells on collagen I after 12-h stretch, but the individual isoforms
involved were not examined. ERK1/ERK2 activation stimulated by either
direct pressure to mesangial cells grown on collagen I
(23) or stretch (19), was also PKC independent.
In our study, mesangial cells plated on fibronectin in either normal or high glucose displayed a higher basal level of protein tyrosine phosphorylation than those cultured on plastic (data not shown). Stretch stimulated the appearance of only two additional tyrosine phosphorylated protein bands at 44 and 42 kDa, consistent with ERK1/ERK2. MacKenna et al. (28) also reported no dramatic changes in the phosphotyrosine profile of cardiac fibroblasts stretched on fibronectin. In our study, only PP2, a src-kinase inhibitor partially reduced basal tyrosine phosphorylation on fibronectin and completely attenuated PDGF stimulation of ERK1/ERK2. PP2 did not inhibit the stretch-induced activation of either ERK1/ERK2 or p38. By contrast, in mesangial cells attached to collagen I, ERK1/ERK2 activation by either direct pressure (23) or stretch (19), was totally prevented by protein tyrosine kinase inhibition with either 10 µM genistein or 10 µM herbimycin A. These inhibitors, used at the same concentration in our study, had only a slight inhibitory effect on PDGF-stimulated ERK1/ERK2 phosphorylation and had no effect on mechanical stretch-induced MAPK activation.
Integrins are implicated in the activation of ERK1/ERK2 and the
SAPK/JNK pathways (28). The precise mechanisms are not
known, but p21 ras-dependent (35) and ras-independent
pathways (6) are proposed. In our study, preincubation of
cells with RGD peptide markedly attenuated stretch-activated p38
and blunted ERK1/ERK2 activation. This is in contrast to rat
cardiofibroblasts, where RGD alone had no effect on stretch-activated
ERK1/ERK2 (28), whereas various -integrin antibodies
were more effective in preventing stretch-activated ERK1/ERK2
(28). These differences in integrin-dependent responses
may be due to cell phenotype or the RGD concentration and duration of
exposure. Interestingly, in rat VSMC, RGD peptide prevented
stretch-induced proliferation, which was also blocked by
3- and av
3-integrin
antibodies but not by an antibody to
1-integrins
(41), and ERK1/ERK2 activation was not measured (41).
Confocal imaging revealed the presence of an intact cytoskeleton (normal F-actin assembly) in the presence of RGD, despite reduced focal adhesion. The actin cytoskeleton may play a direct role in integrin signaling (27). In our cells, maintenance of F-actin assembly, despite reduced focal adhesion contacts in the presence of RGD (33), suggests that a mechanism(s) other than integrin attachment maintains F-actin stress fibers. Disassembly of F-actin with cytochalasin D, which also appeared to reduce focal adhesion, inhibited stretch-induced ERK1/ERK2 and p38 activation, emphasizing that intact F-actin is necessary for ERK1/ERK2 and p38 activation.
In our experiments, mesangial cell 1-integrin content
was not altered after 2 days high-glucose exposure (data not shown), and RGD appeared to have the same effect on MAPKs in normal and high
glucose. Therefore, the high-glucose effect appears independent of
1-integrin.
In high glucose, stretch-induced ERK phosphorylation decayed at a slower rate than in normal glucose (Fig. 9). This indicates that a decrease in phosphatase activity may explain our findings of enhanced ERK1/ERK2 activation in high glucose. Awazu et al. (2) reported a PKC-dependent decrease in expression of MKP-1 in mesangial cells cultured in high glucose for 5 days and in isolated glomeruli from streptozotocin-induced diabetic rats after 1-3 wk of hyperglycemia. This was accompanied by increased basal phosphorylation of ERK1/ERK2 in high glucose (2). In our study, basal ERK1/ERK2 activity was unchanged after 2 days of high glucose and during stretch, PKC inhibition had no effect on high glucose-enhanced ERK1/ERK2 activity. Another candidate is MKP-3, a dual specificity cytosolic phosphatase that is specific for ERK1/ERK2 inactivation (30).
In summary, mechanical stretch of glomerular mesangial cells on
fibronectin causes ERK1/ERK2 and p38 MAPK activation, which is in
part 1-integrin and F-actin dependent. High-glucose
enhancement of stretch-activated mesangial cell ERK1/ERK2 is mediated
by reduced dephosphorylation. Increased mechanical stretch due to
glomerular hypertension may contribute to progressive
glomerulopathy through enhanced activation of mesangial cell
ERK1/ERK2.
![]() |
ACKNOWLEDGEMENTS |
---|
J. A. Dlugosz was supported by a grant from the Heart and Stroke Foundation of Canada. This work was jointly funded by the Juvenile Diabetes Foundation International and Medical Research Council of Canada.
![]() |
FOOTNOTES |
---|
Address for reprint requests and other correspondence: C. I. Whiteside, JDF/MRC Group in Diabetic Nephropathy, Medical Sciences Bldg. Rm. 7302, 1 King's College Circle, Univ. of Toronto, Toronto, Ontario, Canada M5S 1A8 (E-mail: catharine.whiteside{at}utoronto.ca).
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.
Received 1 November 1999; accepted in final form 7 June 2000.
![]() |
REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
1.
Akai, YR,
Homma T,
Burns KD,
Yasuda T,
Badr KF,
and
Harris RC.
Mechanical stretch/relaxation of cultured rat mesangial cells induces protooncogenes and cyclooxygenase.
Am J Physiol Cell Physiol
267:
C482-C490,
1994
2.
Awazu, M,
Ishikura K,
Hida M,
and
Hoshiya M.
Mechanisms of mitogen-activated protein kinase activation in experimental diabetes.
J Am Soc Nephrol
10:
738-745,
1999
3.
Begum, N,
and
Ragolia L.
High glucose and insulin inhibit VSMC MKP-1 expression by blocking iNOS via p38 MAPK activation.
Am J Physiol Cell Physiol
278:
C81-C91,
2000
4.
Bokemeyer, D,
Sorokin A,
and
Dunn MJ.
Differential regulation of the dual-specificity protein tyrosine phosphatases CL100, B23, and PAC1 in mesangial cells.
J Am Soc Nephrol
8:
40-50,
1997[Abstract].
5.
Bokemeyer, D,
Lindemann M,
and
Kramer HJ.
Regulation of mitogen-activated protein kinase phosphatase-1 in vascular smooth muscle cells.
Hypertension
32:
661-667,
1998
6.
Chen, Q,
Lin TH,
Der CJ,
and
Juliano RL.
Integrin-mediated activation of MEK and mitogen-activated protein kinase is independent of Ras.
J Biol Chem
271:
18122-18127,
1996
7.
Davies, M.
The mesangial cell: a tissue culture view.
Kidney Int
45:
320-327,
1994[ISI][Medline].
8.
Gauer, S,
Yao J,
Schoecklmann HO,
and
Sterzel RB.
Adhesion molecules in the glomerular mesangium.
Kidney Int
51:
1447-1453,
1997[ISI][Medline].
9.
Glass, WF, II,
and
Kreisberg JI.
Regulation of integrin-mediated adhesion at focal contacts by cyclic AMP.
J Cell Physiol
157:
296-306,
1993[ISI][Medline].
10.
Glogowski, EA,
Tsiani E,
Zhou XP,
Fantus IG,
and
Whiteside C.
High glucose alters the response of mesangial cell protein kinase C isoforms to endothelin-1.
Kidney Int
55:
486-499,
1999[ISI][Medline].
11.
Han, O,
Li GD,
Sumpio BE,
and
Basson MD.
Strain induces Caco-2 intestinal epithelial proliferation and differentiation via PKC and tyrosine kinase signals.
Am J Physiol Gastrointest Liver Physiol
275:
G534-G541,
1998
12.
Haneda, M,
Kikkawa R.,
Sugimoto T,
Koya D,
Araki S,
Togawa M,
and
Shigeta Y.
Abnormalities in protein kinase C and MAP kinase cascade in mesangial cells cultured under high glucose conditons.
J Diabetes Complications
9:
246-248,
1995[ISI][Medline].
13.
Hurst, RD,
Whiteside CI,
and
Thompson JC.
Diabetic rat glomerular mesangial cells display normal inositol trisphosphate and calcium release.
Am J Physiol Renal Fluid Electrolyte Physiol
263:
F649-F655,
1992
14.
Igarashi, M,
Wakasaki H,
Takahara N,
Ishii H,
Jiang ZY,
Yamauchi T,
Kuboki K,
Meier M,
Rhodes CJ,
and
King GL.
Glucose or diabetes activates p38 mitogen activated protein kinase via different pathways.
J Clin Invest
103:
185-195,
1999
15.
Ikeda, M,
Takei T,
Mills I,
Kitao H,
and
Sumpio BE.
Extracellular signal-regulated kinases 1 and 2 activation in endothelial cells exposed to cyclic strain.
Am J Physiol Heart Circ Physiol
276:
H614-H622,
1999
16.
Ingram, AJ,
Ly H,
Thai K,
Kang M,
and
Scholey JW.
Activation of mesangial cell signaling cascades in response to mechanical strain.
Kidney Int
55:
476-485,
1999[ISI][Medline].
17.
Ingram, AJ,
Ly H,
Thai K,
Kang MJ,
and
Scholey JW.
Mesangial cell signaling cascades in response to mechanical strain and glucose.
Kidney Int
56:
1721-1728,
1999[ISI][Medline].
18.
Ingram, AJ,
Thai K,
Ly H,
and
Scoley JW.
Mechanism of stretch activation of p38 MAPK in mesangial cells (Abstract).
J Am Soc Nephrol
10:
477A,
1999.
19.
Ishida, T,
Haneda M,
Maeda S,
Koya D,
and
Kikkawa R.
Stretch-induced overproduction of fibronectin in mesangial cells is mediated by the activation of mitogen-activated protein kinase.
Diabetes
48:
595-602,
1999[Abstract].
20.
Ishii, H,
Jirousek MR,
Koya D,
Takagi C,
Xia P,
Clermont A,
Bursell SE,
Kern TS,
Ballas LM,
Heath WF,
Stramm LE,
Feener EP,
and
King GL.
Amelioration of vascular dysfunctions in diabetic rats by an oral PKC beta inhibitor.
Science
272:
728-731,
1996[Abstract].
21.
Kang, MJ,
Wu X,
Ly H,
Thai K,
and
Scholey JW.
Effect of glucose on stress-activated protein kinase activity in mesangial cells and diabetic glomeruli.
Kidney Int
55:
2203-2214,
1999[ISI][Medline].
22.
Kapor-Drezgic, J,
Zhou XP,
Babazono T,
Dlugosz JA,
Hohman T,
and
Whiteside C.
Effect of high glucose on mesangial cell protein kinase C- and -
is polyol pathway dependent.
J Am Soc Nephrol
10:
1193-1203,
1999
23.
Kawata, Y,
Mizukami Y,
Fujii Z,
Sakumura T,
Yoshida KI,
and
Matsuzaki M.
Applied pressure enhances cell proliferation through mitogen activated protein kinase activation in mesangial cells.
J Biol Chem
273:
16905-16912,
1998
24.
Keyse, SM.
Protein phosphatases and the regulation of MAP kinase activity.
Semin Cell Dev Biol
9:
143-152,
1998[ISI][Medline].
25.
Larkins, RG,
and
Dunlop ME.
The link between hyperglycemia and diabetic nephropathy.
Diabetologia
35:
499-504,
1992[ISI][Medline].
26.
Li, C,
Hu Y,
Mayr M,
and
Xu Q.
Cyclic strain stress-induced mitogen-activated protein kinase (MAPK) phosphatase 1 expression in vascular smooth muscle cells is regulated by Ras/Rac-MAPK pathways.
J Biol Chem
274:
25273-25280,
1999
27.
Lin, TH,
Chen Q,
Howe A,
and
Juliano RL.
Cell anchorage permits efficient signal transduction between Ras and its downstream kinases.
J Biol Chem
271:
8849-8852,
1997.
28.
MacKenna, DA,
Dolfi F,
Vuori K,
and
Ruoslahti E.
Extracellular signal-regulated kinase and c-Jun NH2-terminal kinase activation by mechanical stretch is integrin-dependent and matrix-specific in rat cardiac fibroblasts.
J Clin Invest
101:
301-310,
1998
29.
Meriin, AB,
Yaglom JA,
Gabai VL,
Mosser DD,
Zon L,
and
Sherman MY.
Protein-damaging stresses activate c-Jun N-terminal kinase via inhibition of its dephosphorylation: a novel pathway controlled by HSP72.
Mol Cell Biol
19:
2547-2555,
1999
30.
Muda, M,
Theodosiou A,
Rodrigues N,
Booschert U,
Camps M,
Gillieron C,
Davies K,
Ashworth A,
and
Arkinstall S.
The dual specificity phosphatases M3/6 and MKP-3 are highly selective for inactivation of distinct mitogen activated protein kinases.
J Biol Chem
271:
27205-27208,
1996
31.
North, RH,
Krolewski AS,
Kaysen GA,
Meyer TW,
and
Schambelan M.
Diabetic nephropathy: hemodynamic basis and implications for disease management.
Ann Intern Med
110:
795-813,
1989[ISI][Medline].
32.
Reusch, HP,
Chan G,
Ives HE,
and
Nemenoff RA.
Activation of JNK/SAPK and ERK by mechanical strain in vascular smooth muscle cells depends on extracellular matrix composition.
Biochem Biophys Res Commun
237:
239-244,
1997[ISI][Medline].
33.
Ruoslahti, E.
RGD and other recognition sequences for integrins.
Annu Rev Cell Dev Biol
12:
697-715,
1996[ISI][Medline].
34.
Sadoshima, J,
and
Izumo S.
The cellular and molecular response of cardiac myocytes to mechanical stress.
Annu Rev Physiol
59:
551-571,
1997[ISI][Medline].
35.
Schlaepfer, DD,
Hanks SK,
Hunter T,
and
van der Geer P.
Integrin-mediated signal transduction linked to Ras pathway by GRB2 binding to focal adhesion kinase.
Nature
372:
786-791,
1994[ISI][Medline].
36.
Steffes, MW,
Osterby R,
Chavers B,
and
Mauer M.
Mesangial expansion as a central mechanism for loss of kidney function in diabetes.
Diabetes
38:
1077-1081,
1989[Abstract].
37.
Sugden, PH,
and
Clerk A.
Regulation of the ERK subgroup of MAP kinase cascades through G protein-coupled receptors.
Cell Signal
9:
337-351,
1997[ISI][Medline].
38.
Sugimoto, T,
Haneda M,
Togawa M,
Isono M,
Shikano T,
Araki S,
Nakagawa T,
Kashiwagi A,
Guan KL,
and
Kikkawa R.
Atrial natriuretic peptide induces the expression of MKP-1, a mitogen-activated protein kinase phosphatase, in glomerular mesangial cells.
J Biol Chem
271:
544-547,
1996
39.
Takei, T,
Han O,
Ikeda M,
Male P,
Mills I,
and
Sumpio BE.
Cyclic strain stimulates isoform-specific PKC activation and translocation in cultured human keratinocytes.
J Cell Biochem
67:
327-337,
1997[ISI][Medline].
40.
Tsiani, E,
Zhou XP,
and
Whiteside CI.
Activation of mesangial cell p38 mitogen-activated protein kinase in response to high glucose (Abstract).
J Am Soc Nephrol
9:
A3282,
1998.
41.
Wilson, E,
Sudhir K,
and
Ives HE.
Mechanical strain of rat vascular smooth muscle cells is sensed by specific extracellular matrix/integrin interactions.
J Clin Invest
96:
2364-2372,
1995[ISI][Medline].
42.
Zatz, R,
Dunn BR,
Meyer TW,
Andersen S,
Rennke HG,
and
Brenner BM.
Prevention of diabetic glomerulopathy by pharmacological amelioration of glomerular capillary hypertension.
J Clin Invest
77:
1925-1930,
1986[ISI][Medline].
43.
Zhou, XP,
Hurst RD,
Templeton D,
and
Whiteside CI.
High glucose alters actin assembly in glomerular mesangial and epithelial cells.
Lab Invest
73:
372-383,
1995[ISI][Medline].