J Biol Chem, Vol. 274, Issue 36, 25250-25253, September 3, 1999
Effect of Glucose on Endothelin-1-induced Calcium Transients
in Cultured Bovine Retinal Pericytes*
Ann
McGinty
,
C. Norman
Scholfield§,
Wei-Hua
Liu,
Paul
Anderson,
D. E. Elaine
Hoey, and
Elisabeth R.
Trimble¶
From the Department of Clinical Biochemistry and the
§ School of Biomedical Science, Queen's University of
Belfast and the ¶ Department of Clinical Biochemistry, Royal
Group of Hospitals, Belfast BT12 6BA, United Kingdom
 |
ABSTRACT |
Published work has shown that
endothelin-1-induced contractility of bovine retinal pericytes is
reduced after culture in high concentrations of glucose. The purpose of
the present study was to establish the profile of endothelin-1-induced
calcium transients in pericytes and to identify changes occurring after
culture in high concentrations of glucose. Glucose had no effect on
basal levels of cytosolic calcium or on endothelin-1-induced calcium release from intracellular stores. However, influx of calcium from the
extracellular medium after endothelin-1 stimulation was reduced in
pericytes that had been cultured in 25 mM
D-glucose. L-type Ca2+ currents were identified
by patch clamping. The L-type Ca2+ channel agonist,
(
)-Bay K8644, caused less influx of calcium from the extracellular
medium in pericytes that had been cultured in 25 mM
D-glucose than in those cultured with 5 mM
D-glucose. However, 3-O-methylglucose, a
nonmetabolizable analogue of glucose which can cause glycation, had
similar effects to those of high concentrations of glucose. The results
suggest that reduced function of the L-type Ca2+ channel
that occurs in bovine retinal pericytes after culture in high
concentrations of D-glucose is probably due to glycation of
a channel protein.
| |
INTRODUCTION |
In epidemiological studies hyperglycemia is the single factor most
consistently associated with diabetic microangiopathy, including
retinal microangiopathy (1). Longitudinal studies in diabetes have
shown that alterations in capillary function and blood flow occur in
advance of the structural changes seen in diabetic retinopathy such as
pericyte loss, microaneurysm formation, and neovascularization (2).
Pericyte tone normally regulates retinal capillary blood flow (3).
Because retinal capillaries are devoid of extrinsic innervation (4),
pericyte tone is controlled to a large extent by changes in the partial
pressures of blood gases (5) and endothelium-derived agonists such as
endothelin-1 (ET-1)1 (6).
We have previously shown (7) that exposure to high ambient glucose
concentrations in vitro caused a reduction in the
contractile response of the bovine retinal pericyte (BRP) to ET-1
without any reduction in either ET-1 binding or generation of inositol trisphosphate (Ins(1,4,5)P3). The aim of the present study
was 1) to establish the profile of ET-1-induced changes in cytosolic calcium concentrations ([Ca2+]i)
in the cultured pericyte and 2) to determine whether prior exposure to
raised concentrations of glucose would alter ET-1-induced calcium
transients in these cells.
| |
EXPERIMENTAL PROCEDURES |
Isolation and Culture of Bovine Retinal Pericytes--
BRP were
isolated as described by Gitlin and D'Amore (8). Briefly, bovine
retinal homogenates were subjected to microscopically controlled enzyme
digestion, and the resultant microvessel fragments were trapped on a
53-µm mesh. The microvessels were suspended in Dulbecco's modified
Eagle's medium (DMEM, Life Technologies, Inc.) containing 5 mM glucose, antibiotics (200 units/ml penicillin and 200 µg/ml streptomycin, Sigma), and 20% fetal calf serum (FCS, Life
Technologies, Inc.), a growth medium which promotes pericyte proliferation and discourages the growth of endothelial cells. The
suspension was then seeded into 25-cm2 flasks (Falcon,
Becton Dickinson Ltd., Cowley, UK) to be maintained at 37 °C in a
mixture of 5% CO2 and air until confluent. The pericytes were identified by their stellate appearance and immunocytochemically by the presence of smooth muscle actin (Amersham Pharmacia Biotech); the lack of Factor VIII staining confirmed the absence of endothelial cells. All experiments were performed on BRP derived from passages 2 and 3.
Determination of [Ca2+]i by Fura-2 Fluorescence
Spectroscopy--
BRP from a common cell pool were seeded onto glass
slips and maintained in DMEM and 20% FCS containing 5 mM
glucose, 25 mM glucose, or 5 mM glucose + 20 mM 3-O-methylglucose (3-OMG) for 3, 7, or 10 days; experiments were also carried out using 5 mM glucose + 20 mM mannitol to assess the effect of osmolality. Cells were serum-starved for 24 h prior to experiments by placing them in basal DMEM containing the appropriate hexose concentration. BRP were
loaded with the intracellular calcium probe, fura-2, by incubating them
in basal DMEM (5 mM glucose, 25 mM glucose, or
5 mM glucose + 20 mM 3-OMG) containing 3 µM fura-2-acetoxymethyl ester and 0.02% Pluronic F127
(Molecular Probes, Eugene, OR) for 80 min at 37 °C. Cells were
washed for 10 min in Hepes-buffered Krebs solution, pH 7.4, containing
0.1% bovine serum albumin, placed into the cuvette holder of a
Perkin-Elmer LS-50B spectrofluorimeter, and stirred constantly
throughout the procedure while being maintained at 37 °C. 1 nM ET-1 (Bachem UK, Saffron Walden, UK) was added to the
same medium that contained either 1 mM Ca2+ or
was essentially Ca2+-free. Cells in Ca2+-free
medium were previously washed in this solution and had 0.1 mM EGTA added to the cuvette 15 s prior to the
addition of ET-1. In parallel experiments cells were preincubated with
the calcium channel inhibitor, 0.2 mM diltiazem (Sigma),
for 30 min at 37 °C prior to stimulation with ET-1 in the presence
of 1 mM calcium. In a separate series of experiments cells
were stimulated alone with 1 µM dihydropyridine L-type
calcium channel agonist ()-Bay K8644 (Research Biochemicals Ltd.,
Natick, MA) (9). Fluorescence ratios were measured at 510 nM with excitation at 340 and 380 nM, and
following determinations of Rmax and
Rmin (the fluorescence ratios under saturating
and Ca2+-free conditions, respectively),
[Ca2+]i was determined by the
method of Grynkiewicz et al. (10). To determine
Rmin, 4 µM ionomycin was added to
the cuvette at the end of the experiment, followed by 5 mM
EGTA 10 s later. To determine Rmax, in
alternate runs the [Ca2+]i of the
medium was raised to 4 mM (3 mM in the case of
Ca2+-free buffer) 10 s after the addition of
ionomycin. All plateau phase
[Ca2+]i calculations were made at
a standard time of 210 s after application of the stimulus. Thus,
the final result was the mean of 30 consecutive values recorded at
0.5-s intervals equally spaced before and after 210 s.
DMEM contains iron. Free/redox-sensitive iron was measured in DMEM in
the absence and presence of 10% FCS by the bleomycin method (11).
8-epi-PGF2
levels in pericytes were measured by a specific enzyme immunoassay kit (Cayman Chemicals, Ann Arbor, MI).
Patch Clamping--
Cultured pericytes were resuspended and
allowed to settle out on 0.12-mm-thick glass slips. These slips were
placed on a glass-bottomed recording chamber on an inverted microscope
through which bathing solution flowed. Drug solutions were delivered
through a separate flow tube, 0.3 mm in diameter, directed at the cell.
Conventional whole cell patch recordings were made at 34 °C from
cells that had begun to flatten out. Recordings were made in voltage
clamp mode, and the cells were held at 40 mV. The bathing medium
contained the following (in mM, pH 7.3): sodium, 145;
potassium, 6; magnesium, 1.3; calcium, 2; chlorine, 150; HEPES, 10; and
glucose, 5. Theaflavin (20 mM) was added to block potassium
currents. The solution in the patch electrode contained the following
(in mM): cesium gluconate, 145; HEPES, 10;
MgCl2, 1; EGTA, 5; Na2ATP, 2; phosphocreatine, 2; GTP, 0.1; and Ca2+, 50 nM (calculated).
Statistical Analysis--
The Mann-Whitney U, Wilcoxon, and
Student's t tests were used as appropriate. Within each
experiment a given condition was represented by 2-4 replicates;
p values less than 0.05 were taken to be significant.
| |
RESULTS |
ET-1-induced Changes in [Ca2+]i--
In 1 mM extracellular calcium the ET-1-evoked calcium transient
was characterized by an initial peak in
[Ca2+]i followed by a sustained
plateau phase during which the
[Ca2+]i remained elevated (Fig.
1A). In calcium-free medium the initial peak induced by ET-1 was attenuated, and the plateau phase
was abolished (Fig. 1B). Under these conditions rises in [Ca2+]i were due to
ET-1/Ins(1,4,5)P3-induced calcium release from the
endoplasmic reticulum. If BRP were preincubated in medium containing 1 mM Ca2+ and the calcium channel inhibitor, 0.2 mM diltiazem, for 30 min ET-1 produced an effect similar to
that in Ca2+-free medium (Fig.
2). These observations indicate that a
large portion of the ET-1-induced rise in
[Ca2+]i in BRP was due to influx
from the extracellular medium.
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Fig. 1.
Effect of ET-1 on
[Ca2+]i in pericytes grown in 5 and 25 mM glucose for 10 days. BRP cultured in 5 mM ( ) and 25 mM (- - -) glucose were
stimulated with ET-1 (1 nM) in the presence (A)
and absence (B) of 1 mM extracellular calcium.
The traces shown are from a representative experiment.
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Fig. 2.
Effect of diltiazem on ET-1-induced calcium
transients in retinal pericytes. Comparison between calcium
mobilization responses of BRP stimulated with ET-1 (1 nM)
in calcium-free medium () and in the presence of 1 mM
extracellular calcium following a 30-min incubation with diltiazem (0.2 mM) (- - -) is shown. The trace shown is from a
representative experiment.
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Characterization of Ca2+ Channels in the Plasma Membrane of
BRP--
()-Bay K8644 (10-20 µM) generated an
enhanced inward current that activated at 30 mV and peaked at +10 mV
(107 ± 70 pA) (Fig. 3). 30% of
those cells showing stable patches had transient inward currents of
10-200 pA that activated at 30 mV and peaked at 0 to +10 mV (Fig.
4). The inward current was increased by
raising the Ca2+ concentration to 8 mM (Fig.
4). This was reduced by 80% with 0.2 µM nifedipine (not
shown) and completely blocked with 1 µM nifedipine (Fig.
4) or 100 µM Cd2+ (not shown). All of these
effects are consistent with a L-type Ca2+ current.
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Fig. 3.
A current record from a bovine retinal
pericyte on a 120-ms voltage step from 40 to +10 mV in normal
solution and 20 s after adding 20 µM ()-Bay K8644.
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Fig. 4.
A current voltage relationship from another
cell held at 40 mV and stepped to various voltages between 35 and
+40 mV and bathed in normal solution (2 mM
Ca2+,  ), 8 mM Ca2+ ( ), and 8 mM Ca2+ in the presence of 1 µM nifedipine ( ). The current
was measured at the peak of the inward transient or at the same
latency.
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|
Effect of Glucose on ET-1-induced Calcium Transients--
Basal
levels of [Ca2+]i were similar in
cells maintained in 5 and 25 mM glucose (Table
I). Cells grown in 25 mM
glucose for 10 days produced a smaller rise in
[Ca2+]i with ET-1 (1 nM) than those maintained in 5 mM glucose (Fig.
1A, Table II). No significant
differences were seen at 3 or 7 days (results not shown). All
subsequent experiments utilized cells grown for 10 days in 25 mM glucose. In Ca2+-free medium there was no
difference in the [Ca2+]i response
to ET-1 between the two groups of cells.
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Table I
The basal levels of [Ca2+]i in pericytes cultured in
5 mM glucose, 25 mM glucose, and 5 mM glucose + 20 mM 3-OMG for 10 days
Values are mean ± S.E. n = the number of
replicates for each condition.
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Table II
Effect of ET-1 (1 nM) on [Ca2+]i in BRP
grown in 5 mM glucose, 25 mM glucose, or 5 mM glucose + 20 mM 3-OMG for 10 days
Results for 1 mM and 0 [Ca2+]e are from
twelve and six independent experiments, respectively; n = number of replicates for each condition.
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Plateau levels of [Ca2+]i were
reduced in BRP cultured in 25 mM glucose (Table II,
top). Plateau phase levels of
[Ca2+]i were almost exclusively
due to influx of extracellular calcium (Table II, bottom).
BRP were also stimulated with the L-type Ca2+ channel
agonist, ()-Bay K8644, which caused a sustained increase in
[Ca2+]i. At 210 s after
addition of 1 µM ()-Bay K8644 increases in
[Ca2+]i were less in cells
cultured in 25 mM glucose than those grown in 5 mM glucose (Table III).
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Table III
Effect of () Bay K8644 (1 µM) on
[Ca2+]i, in cultured BRP grown in 5 mM
glucose, 25 mM glucose, or 5 mM glucose
3-OMG for 10 days
Results are mean ± S.E. of seven (Table III, top) or
five (Table III, bottom) independent experiments. ()-Bay
K8644 (1 µM) was added to the cuvette, and the
increases in [Ca2+]i were measured after
210 s.
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To clarify whether the observed attenuation of the ET-1-induced calcium
transient in BRP was due to glucose metabolism or was in fact due to
non-enzymic glycation of a functional calcium channel protein cells
were also grown in the presence of the non-metabolizable glucose
analogue 3-OMG. With ET-1, BRP cultured for 10 days in 5 mM
glucose + 20 mM 3-OMG showed lower plateau phase levels of [Ca2+]i than those grown in 5 mM glucose (Table II, top). This suggests that
the effect was not dependent on glucose metabolism by the pericyte.
Cells grown in 5 mM glucose + 20 mM mannitol did not display any differences in basal or ET-1-evoked
[Ca2+]i changes from those grown
in 5 mM glucose alone (data not shown), indicating that the
effects seen with 25 mM glucose were not due to an osmotic
effect. When stimulated with ()-Bay K8644, BRP grown in 5 mM glucose + 20 mM 3-OMG also had a smaller increase in [Ca2+]i than those
grown in 5 mM glucose alone (Table III, bottom).
We have previously shown that, in contrast to vascular smooth muscle
cells, pericytes show no increase in malondialdehyde levels after 10 days of exposure to 25 mM glucose (12) suggesting the
absence of free radical mediated damage. In this series of experiments
the F2-isoprostane, 8-epi-PGF2,
was measured. The levels were 100.6 pg/mg of protein and 94.4 pg/mg of
protein for 5 and 25 mM glucose, respectively (mean,
n = 2). Bleomycin-detectable iron content of DMEM was
0.221 ± 0.022 µM (mean ± S.D.,
n = 3) in the absence of FCS. No bleomycin-detectable
iron was found in DMEM containing 10% FCS.
| |
DISCUSSION |
ET-1 produced a biphasic rise in
[Ca2+]i that consisted of an
initial peak followed by a sustained plateau phase. The plateau phase
was abolished in Ca2+-free medium, showing that this phase
arose from influx through Ca2+ channels. The probability
that these were L-type Ca2+ channels was suggested by
identification of a nifedipine-sensitive inward current and by ()-Bay
K8644-induced increases in
[Ca2+]i. The plateau phase was
depressed in high concentrations of glucose; the implication of this is
that culture in high concentrations of D-glucose attenuated
Ca2+ channel function. This idea was supported by the
effects of ()-Bay K8644, an L-type channel agonist that had a lesser
effect on Ca2+ influx in cells grown in 25 mM
glucose compared with those grown in 5 mM glucose. These
differences were unlikely to result from differences in resting
membrane potential, which is unchanged by high concentrations of
glucose (13). The present study shows that sustained exposure to high
concentrations of glucose alters the properties of L-type
Ca2+ channels in BRP.
The initial phase of the ET-1-induced Ca2+ transient is
composed of Ins(1,4,5)P3-induced Ca2+
release from the endoplasmic reticulum, and this is
superimposed on the earliest part of influx from the extracellular
medium. In the absence of extracellular Ca2+, the
Ins(1,4,5)P3-induced increase in
[Ca2+]i was similar in BRP grown
in 5 or 25 mM glucose. This is consistent with previous
results that showed that ET-1 binding and Ins(1,4,5)P3
production by BRP were unaffected by glucose under similar culture
conditions (7). Thus, the present results show that continued exposure
to high concentrations of glucose attenuates the
[Ca2+]i rise produced by ET-1 by
an action on L-type Ca2+channels but has no effect on that
mediated by Ins(1,4,5)P3. The results from studies with
3-OMG strongly suggest that glucose affects the Ca2+
channel by a mechanism involving glycation. We have not been able to
detect any evidence of free radical attack, at least on lipids, either
in this study where F2-isoprostanes were measured or in a
previous study (12) where malondialdehyde was measured after 10 days of
exposure to 25 mM glucose; we have detected increased malondialdehyde after 18 days only. The attenuated increase in [Ca2+]i may explain, at least in
part, the previously observed reduced contractile response to ET-1 of
BRP grown in high concentrations of glucose despite the fact that ET-1
binding and Ins(1,4,5)P3 production were unchanged (7).
In conclusion, culture of BRP in high concentrations of glucose for
extended periods leads to reduced function of L-type Ca2+
channels; the observed effects may be due to glycation of a channel protein. These results suggest that glycation of Ca2+
channel proteins may affect the quality of retinal pericyte response to
ET-1 and, hence, control of retinal capillary blood flow in the
presence of sustained hyperglycemia.
| |
ACKNOWLEDGEMENTS |
We are grateful to Dr. U. Chakravarthy for
teaching the pericyte culture technique and to the colleagues of
Professor J. M. C. Gutteridge for measuring bleomycin-detectable
iron levels in the culture medium.
| |
FOOTNOTES |
*
This work was supported by a grant from the British Diabetic
Association (to A. M. and E. R. T.).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.
To whom correspondence should be addressed: Dept. of Clinical
Biochemistry, Inst. of Clinical Science, Royal Group of Hospitals, Belfast BT12 6BA, UK. Tel.: 44-1232-263108; Fax: 44-1232-236143; E-mail: e.trimble@qub.ac.uk.
| |
ABBREVIATIONS |
The abbreviations used are:
ET-1, endothelin-1;
Ins(1,4,5)P3, inositol trisphosphate;
BRP, bovine retinal
pericytes;
[Ca2+]i, cytosolic
calcium concentration;
DMEM, Dulbecco's modified Eagle's medium;
FCS, fetal calf serum;
3-OMG, 3-O-methylglucose.
| |
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Copyright © 1999 by The American Society for Biochemistry and Molecular Biology, Inc.
TOP
ABSTRACT
INTRODUCTION
