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J Biol Chem, Vol. 274, Issue 48, 34343-34349, November 26, 1999
From the The role of the calcium-binding protein,
calbindin-D28k in potassium/depolarization-stimulated
increases in the cytosolic free Ca2+ concentration
([Ca2+]i) and insulin release was investigated in
pancreatic islets from calbindin-D28k nullmutant mice
(knockouts; KO) or wild type mice and Calbindin-D28k is a 28,000 Mr
calcium-binding protein initially identified in avian intestine and was
the first known target of vitamin D action (1). Calbindin has since
been reported in many other tissues including kidney and bone and in
tissues that are not primary regulators of serum calcium such as brain and pancreas (2-4). This calcium-binding protein has been conserved during evolution and is regulated by a number of different hormones and
factors (3, 4). Calbindin-D28k, a predominantly cytosolic protein, is a member of a family of high affinity calcium-binding proteins that includes calmodulin, S100 protein, and parvalbumin (5).
It has been suggested that the role of calbindin in kidney and
intestine is to facilitate transcellular calcium diffusion (6, 7). In
brain, calbindin is not vitamin D-dependent and its
proposed function is to buffer calcium, resulting in protection against calcium-mediated neurotoxicity (8, 9).
In 1979 the discovery in the pancreas of a high affinity receptor for
the hormonally active form of vitamin D, 1,25- dihydroxyvitamin D3 (1,25(OH)2D3), was the first
demonstration of a nonclassical target tissue to contain vitamin D
receptors (10). Further autoradiographic and immunohistochemical
analyses have shown that vitamin D receptors and
calbindin-D28k are both localized in the Although isolated islets and perfused pancreas from vitamin D-deficient
animals have previously been used to study the effects of
1,25-(OH)2D3 on In this study, to understand the role of calbindin-D28k in
the pancreatic Materials--
1-Isobutyl-3-methylxanthine
(IBMX),1
12-O-tetra-decanoylphorbol-13-acetate (TPA), glucose, bovine
serum albumin, proteinase K, and acrylamide were obtained from Sigma.
Kodak BioMAX MR film, [ Calbindin-D28k Nullmutant (Knockout, KO)
Mice--
The calbindin-D28k KO mice were generated in the
laboratory of Dr. Michael Meyer as described previously (24). For these studies colonies of calbindin-D28k nullmutant and wild type
mice (C57BL6) were maintained on Purina mouse chow and water ad
libitum in the barrier room of the Research Animal Facility at New
Jersey Medical School. Genotypes were determined by Southern blot
analysis or by PCR using genomic DNA obtained from the tails of mice at 3 weeks of age. For Southern analysis (25), DNA was digested with
HindIII, and an external probe that recognizes a
7.8-kilobase wild type band and 5.5-kilobase mutant band was used (24).
PCR was performed to determine the genotypes using the primers Cs3 (common primer; sequence 5'-GCAAGTAACTAATGGCATCG-3'), C2 (wild type
primer; '5-TGCAGCGGCTAGTTTGAGAGTG-3'), and Pa1 (mutant primer; 5'-TGACTAGGGGAGGAGTAGAAG-3'). The PCR reaction was run in a
thermocycler using the following program: 95 °C for 2 min (1 cycle);
95 °C for 45 s, 60 °C for 45 s, and 72 °C for 2 min
(35 cycles); 72 °C for 10 min (1 cycle), and soaking at 4 °C. The
reaction mixture was run on a 1.75% agarose gel stained with ethidium
bromide. The wild type band appears at 753 base pairs and the knockout (mutant) band appears at 226 base pairs. Calbindin deficiency was not
found to affect development and calbindin KO mice exhibited normal
fecundity. No significant differences in blood glucose levels were
noted under fasting or fed conditions between WT and KO mice (fed,
105.7 ± 5.3 mg/dl (WT) versus 105.4 ± 4.3 mg/dl (KO), p > 0.5; fasting, 61.5 ± 2.4 mg/dl (WT)
versus 56.8 ± 2.1 (KO), p > 0.5).
Additionally, there were no differences between WT and KO mice in the
levels of serum insulin under these conditions. There were also no
changes observed in pancreatic insulin content and pancreatic insulin
mRNA levels between WT and KO mice. The lack of difference between
WT and KO mice may be due to compensation by other proteins in the
pancreas of the KO mice. The phenotype expressed in the calbindin KO
mice is ataxia (24).
Insulin and Calcium Assays--
Insulin was determined by
radioimmunoassay using rat insulin as a standard (rat Insulin
125I kit, Incstar, Stillwater, MN). Serum calcium was
measured by atomic absorption spectrophotometry.
Immunohistochemistry--
Immunohistochemical analysis of
calbindin-D28k was performed as described previously (26)
using rabbit antiserum to rat renal calbindin-D28k (23).
Controls for antibody specificity consisted of absorption of the rabbit
antiserum with excess of electrophoretically pure rat renal calbindin
D28k (27).
Cell Culture, Stable Transfection, and Clonal
Selection--
Western Blot Analysis and Calbindin-D28k
Radioimmunoassay--
Cell extracts of various clones were prepared by
short (<5 s) burst sonication in phosphate-buffered saline (0.01 M sodium phosphate, 0.15 M NaCl, pH 7.4) and 5 mM phenylmethylsulfonyl fluoride. The supernatant solution
obtained after centrifugation at 14,000 × g for 15 min. at 4 °C was used for protein estimation with the Bradford
method (29). 10 µg of protein was analyzed by Western blot analysis
using a Chemiluminescence Western blotting kit (NEN Life Science
Products). Calbindin protein levels were determined by radioimmunoassay
using antiserum against rat renal calbindin and purified rat renal
calbindin-D28k as a standard as described previously
(30).
Insulin Release: Perifusion and Static
Incubation--
Pancreatic islets from 2-3-month-old mice (KO and WT)
were isolated by collagenase dispersion (31) and hand-picked under a
stereomicroscope. Insulin release from islets was measured under perifusion conditions. The dynamics of insulin release from pancreatic islets were examined using a perifusion system as described previously (32) with minor modifications. Twenty size-matched islets were placed
in each 0.7-ml perifusion chamber and perifused with glucose-free Krebs-Ringer bicarbonate (KRB) buffer (129 mM NaCl, 5 mM NaHCO3, 4.8 mM KCl, 1.2 mM KH2PO4, 2.0 mM
CaCl2, 1.2 mM MgSO4, 10 mM HEPES, 0.1% bovine serum albumin, pH 7.4) at the rate
0.8 ml/min at 37 °C. Experiments were started after a 60-min
perifusion equilibration period. Perifusate samples for insulin
radioimmunoassay were collected every 1 or 2 min. The data were
obtained from five chambers for each group of three independent
experiments. Insulin release from Measurement of
[Ca2+]i--
[Ca2+]i was
measured using isolated islets as described previously (34) with some
modification. Islets were loaded with 5 µM indo-1
acetomethylester (Molecular Probes, Eugene, OR) in KRB buffer
containing 250 µM sulfinpyrazone (to inhibit transport of
indo-1 out of the cell) and 20 mM glucose for 90-120 min.
After washing twice in fresh KRB buffer, the islets were kept in buffer plus 20 mM glucose and 250 µM sulfinpyrazone
at 37 °C until used in experiments. For measurement of
[Ca2+]i individual islets were placed on a glass
coverslip in the Teflon chamber of a Narishige microincubation system
mounted on the stage of a Nikon Diaphot 200 inverted epifluorescence
microscope. The islets were maintained at 37 °C on the microscope
stage. Each islet was incubated in glucose-free KRB buffer for at least
10 min prior to stimulation. KCl (45 mM) was added to the
incubation chamber by pipette. The single islets were excited at 360 nm
using a 75 watt xenon lamp and emission monitored at 405 and 485 nm using a microphotometer (Photon Technology International). The ratio of
detected light (405 nm/485 nm) was calculated and displayed using FELIX
software (Photon Technology International) and a Dell Optiplex 433/L
computer. Changes in [Ca2+]i were represented by
changes in the fluorescence ratio (405 nm/485 nm). All calcium tracings
were obtained for single islets. All fluorimetry experiments were
performed under static incubation.
[Ca2+]i in Statistical Analysis--
Results are presented as the
means ± S.E. Data were analyzed with Student's t test
or one-way analysis of variance. The post-hoc analysis used with
one-way analysis of variance was Tukey's method.
Calbindin-D28k KO Mice--
To verify the
nullmutation, tissues from WT and KO mice were analyzed by Western
blotting and immunocytochemistry for the presence of
calbindin-D28k (Fig. 1).
Western analysis of extracts of kidney, pancreas, and brain (cortex and
cerebellum) demonstrated that the immunoreactivity detected in WT mice
by calbindin-D28k antiserum was absent in tissues from
calbindin KO mice (Fig. 1, left panel). In addition,
immunocytochemistry indicated the presence of calbindin in the distal
tubule of the kidney (Fig. 1, middle panel A), in the
pancreatic islet (Fig. 1, right panel A), and in some cells
but not others throughout the brain (not shown) in WT mice and the
complete absence of calbindin in the kidney (Fig. 1, middle panel
B), pancreas (Fig. 1, right panel B), and brain (not
shown) in KO mice. In the WT mouse pancreas, immunostaining was
cytoplasmic and diffuse (Fig. 1, right panel A), consistent with results of calbindin immunostaining in human and rat pancreas (13), and was specific for the pancreatic islet. Acinar tissue did not
show any immunostaining.
Because previous studies in calbindin-D28k KO mice
indicated that calbindin in the nervous system has a role in modulation of depolarization-induced calcium transients (24), in this study we
focused on the role of calbindin in the
To determine whether the increase in potassium-stimulated insulin
release in the islets isolated from KO mice may be due, at least in
part, to an increase in [Ca2+]i because of lack
of Ca2+ buffering by calbindin, indo-1 was used to measure
K+ induced rises in [Ca2+]i in single
pancreatic islets. In islets from both wild type and KO mice 45 mM KCl caused an immediate, significant increase in
[Ca2+]i, which then decreased over several
minutes to reach a plateau concentration that remained elevated over
the basal [Ca2+]i for the remainder of the time
(Fig. 3). The peak
[Ca2+]i was markedly increased in islets from KO
as compared with those from WT mice (3.5-fold greater;
p < 0.01). The plateau [Ca2+]i
was also significantly increased. These findings show that calbindin
acts as a modulator of induced calcium transients in the
In response to glucose (16.7 mM) preliminary results
indicate that significant changes in insulin secretion in the calbindin overexpressing clones were not observed (data not shown). In addition, Northern analysis indicated that there was no change in insulin mRNA levels in calbindin-overexpressing cells as compared with vector-transfected cells in response to treatment with glucose (not
shown). Under basal conditions changes in insulin mRNA were also
not observed between vector transfected and calbindin-transfected cells
(not shown). This differs from calbindin overexpressing high passage
RIN 1046-38 cells, which showed a marked increase in insulin mRNA
under basal condition when compared with vector transfected cells (19).
High passage RIN cells differ from
Because a significant inhibitory effect of calbindin on insulin
secretion was observed in response to K+-induced
depolarization, similar to the studies in isolated islets, we asked
whether the effect of calbindin on potassium-stimulated insulin release
may similarly be related to regulation of [Ca2+]i
by calbindin.
In addition to In this study we found that calbindin acts as a modulator of
depolarization-induced calcium transients in the pancreatic In addition to calbindin, calmodulin (45) and calcyclin (46) are two
other calcium-binding proteins present in the In addition to depolarizing concentrations of potassium, calbindin
overexpression was also found to suppress insulin secretion in response
to the phorbol ester TPA, which is known to activate certain forms of
protein kinase C. TPA can stimulate insulin secretion in the presence
or absence of basal glucose (35, 53, 54). It has been suggested that
phorbol ester-stimulated insulin secretion is linked with membrane
depolarization and an increase in [Ca2+]i (35,
55), similar to the effect of KCl. The Ca2+ channels
responsible for the increased [Ca2+]i signal in
response to TPA have been reported to be the L-type
Ca2+ channels (35, 55, 56). It has been suggested that the
role for PKC is to maintain the phosphorylation state of the
voltage-gated L-type Ca2+ channel, thus
enabling the appropriate function of this channel (55). The resulting
effect of TPA is similar but not identical to the effect of KCl because
less depolarization is observed in response to TPA and additional
actions of TPA have been suggested (35, 55). Thus calbindin may be a
modulator of insulin secretion in response to both KCl and TPA because
both secretagogues act, at least in part, by a similar mechanism.
Calbindin, in response to both secretagogues, may act by reducing
Ca2+ influx through voltage dependent calcium channels.
Although this study clearly establishes for the first time a role for
calbindin in the modulation of depolarization-stimulated insulin
release (in response to KCl or TPA), the exact role of calbindin in
response to other secretagogues (including glucose, a variety of
neuropeptides, and other transmitter substances that can combine to
activate Ca2+ oscillations in the It is also likely that calbindin can have functions in the The role of calcium targets in the The secretarial assistance of Sharon
Washington and Lucy Cintron is gratefully acknowledged.
*
This work was supported by National Institutes of Health
Grants DK38961 and DK 55050 and by a grant from the American Diabetes Association (to S.C.), by National Institutes of Health Grants DK54243
and DK42063 (to G. W. G. S.), by National Research
Service Award DK 09603 (to T. S.), and by NASA-Ames grant
NAG2-1194 (to W. B. R.). The Diabetes Research and Training
Center of Albert Einstein College of Medicine is supported by National
Institutes of Health Grant DK20541.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.
§
The first three authors contributed equally to this work.
§§
To whom correspondence should be addressed: Dept. of Biochemistry
and Molecular Biology, UMDNJ-New Jersey Medical School, 185 South
Orange Ave., Newark, NJ 07103-2714. Tel.: 973-972-4033; Fax:
973-972-5594; E-mail: christak@umdnj.edu.
The abbreviations used are:
IBMX, 1-isobutyl-3-methylxanthine;
TPA, 12-O-tetra-decanoylphorbol-13-acetate;
PCR, polymerase chain
reaction;
KO, knockout;
WT, wild type;
1, 25-(OH)2D3, 1,25-dihydroxyvitamin
D3.
Calbindin-D28k Controls [Ca2+]i
and Insulin Release
EVIDENCE OBTAINED FROM CALBINDIN-D28k KNOCKOUT
MICE AND 
CELL LINES*
§,
,,,§§
Department of Biochemistry and Molecular
Biology, University of Medicine and Dentistry of New Jersey, New
Jersey Medical School and Graduate School of Biomedical Sciences,
Newark, New Jersey 07103, the ¶ Department of
Molecular Medicine, New York State College of Veterinary Medicine,
Cornell University, Ithaca, New York 14853, the ** Department of
Anatomy, Cell and Neurobiology, Marshall University School of Medicine,
Huntington, West Virginia 25704, the Department of
Neurochemistry, Max-Planck Institute, D-82152 Martinsried, Germany, and
the Department of Medicine and the Diabetes Research and
Training Center, Albert Einstein College of Medicine,
Bronx, New York 10461
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
cell lines stably transfected
and overexpressing calbindin. Using single islets from KO mice and
stimulation with 45 mM KCl, the peak of
[Ca2+]i was 3.5-fold greater in islets from KO
mice compared with wild type islets (p < 0.01) and
[Ca2+]i remained higher during the plateau phase.
In addition to the increase in [Ca2+]i in
response to KCl there was also a significant increase in insulin
release in islets isolated from KO mice. Evidence for modulation by
calbindin of [Ca2+]i and insulin release was also
noted using cell lines. Rat calbindin was stably expressed in
TC-3 and HC-13 cells. In response to depolarizing concentrations
of K+, insulin release was decreased by 45-47% in
calbindin expressing TC cells and was decreased by 70-80% in
calbindin expressing HC cells compared with insulin release from
vector transfected TC or HC cells (p < 0.01).
In addition, the K+-stimulated intracellular calcium peak
was markedly inhibited in calbindin expressing HC cells compared
with vector transfected cells (225 nM versus
1,100 nM, respectively). Buffering of the depolarization-induced rise in [Ca2+]i was also
observed in calbindin expressing TC cells. In summary, our findings,
using both isolated islets from calbindin-D28k KO mice and
cell lines, establish a role for calbindin in the modulation
of depolarization-stimulated insulin release and suggest that calbindin
can control the rate of insulin release via regulation of
[Ca2+]i.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
cell (11-13).
Although these studies and others (14-17) established a link between
the pancreatic cell and the vitamin D endocrine system and although the importance of calcium in insulin secretion is well known, there is
still little information available concerning the exact mechanism
whereby vitamin D may affect cell function. It has been suggested
that the role of vitamin D in calcium metabolism of the cell may
involve a genomic effect of 1,25-(OH)2D3,
including the production of calbindin.
cell function (14-17),
recently we reported that the cell line R1N1046-38 contains both
calbindin and receptors for 1,25-(OH)2D3
and suggested that cell lines may provide a useful in
vitro system for studying the effects of the vitamin D endocrine
system on cell function (18, 19). Although interesting data have
been generated in numerous studies using RIN cells, the RIN cell line
may not be the best model because these cells have little or no
response to glucose and the insulin content of these cells is only
approximately 0.1% of the insulin content found in the normal cell.
cells, calbindin was transfected and overexpressed in HC and TC cells, pancreatic cells that secrete insulin in
a regulated manner and at levels more comparable with those of normal
cells. Both cell lines are derived from transgenic mice that
express the SV40 T-antigen in cells under the control of the
insulin gene regulatory region (20-22). In addition,
calbindin-D28k nullmutant (or knockout) mice were also used
because they provide a good model in which to examine the effect of
complete ablation of calbindin in the pancreatic islet on insulin
release. This study, which is the first to address the role of
calbindin in the cell using both islets and cell lines,
suggests that calbindin has an important role in controlling
depolarization-induced increases in intracellular calcium and therefore
insulin release from the pancretic cell.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-32P]CTP (1 mCi/ml), and
Renaissance chemiluminescence Western blot kits were purchased from NEN
Life Science Products. Tissue culture media for cell culture,
antibiotics, agarose, LipofectAMINE, Taq polymerase, and all
restriction enzymes were obtained from Life Technologies, Inc. Sera for
culture and G418 were purchased from Gemini (Calabasas, CA).
Collagenase P was from Roche Molecular Biochemicals. Bradford protein
reagent and nitrocellulose membranes were purchased from Bio-Rad.
Primers for PCR were obtained from Operon (Alameda, CA). The Gene Amp
PCR core kit was from Perkin-Elmer (Foster City, CA). DNA purification
kits were obtained from Qiagen (Chatsworth, CA). Antibody against rat
calbindin-D28k was generated and characterized as described
previously (23). All chemicals and reagents were of analytical grade.
HC-13 cells (from Dr. Douglas Hanahan, University of
California, San Francisco (22)) and TC-3 cells (20, 21) were maintained in Dulbecco's modified Eagle's medium supplemented with 17 mM glucose, 15% horse serum, 2.5% fetal bovine serum, and
10% penicillin-streptomycin in 5% CO2-95% air at
37 °C. Cells were grown in 100-mm tissue culture plates (Falcon,
Oxnard, CA) and maintained with one passage/week. In addition, grown
cells were stored in liquid N2 (passage <35) and revived.
All stably transfected clones were maintained under identical
conditions except that the medium was supplemented with 800 µg/ml of
G418. For stable transfection, approximately 50-60% confluent
HC-13 and TC-3 cells (passages 20-30) were used. 10 µg each of
pBSR (vector alone; a gift of Dr. Michael Olszowy, Washington
University School of Medicine, St. Louis, MO) or pBSR-CB28 (vector
containing calbindin-D28k cDNA isolated by PCR from
cDNA prepared from rat renal distal tubular mRNA (28) to create
an expression plasmid designated pBSR-CB28), were mixed with 50 µl
LipofectAMINE, added to cells in Optimem (Life Technologies, Inc.) and
2% fetal bovine serum and incubated for 20 h at 37 °C. Normal
growth medium was added the next day. Three days after transfection,
selection began with increasing amounts of G418 to a final
concentration of 800 µg/ml. After 8 weeks of G418 selection, colonies
were picked under sterile conditions and grown in 24-well plates.
TC-3 or HC-13 cells was
measured by static incubation as described previously (20, 33).
HC-13 and TC-3 cells were
measured in cell suspensions as described previously (33). Cells
dispersed by a Ca2+-free solution containing trypsin and
EDTA were suspended in KRB buffer containing 1 µM fura-2
acetoxymethyl ester (Molecular Probes, Eugene, OR) and 250 µM sulfinpyrazone at a concentration of 2 × 106 cells/ml and then loaded with fura2 by incubation at
37 °C for 30 min. with continuous shaking. Sulfinpyrazone was added
to diminish the transport of fura-2 out of the cells and thus increase
the precision of the fluorescence measurements. After loading, the cells were washed and resuspended in KRB buffer containing 250 µM sulfinpyrazone; 3 ml of the suspension was placed in
quartz cuvettes with continuous stirring; and the temperature was
maintained at 37 °C. Calcium was measured using a spectrofluorimeter
(Perkin-Elmer LS-5) at an excitation wavelength of 340 nm and an
emission wavelength of 510 nm. [Ca2+ ]i values
were calculated by the use of values of auto- and extracellular fura-2
emitted fluorescence as described previously (35).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
Calbindin-D28k protein is absent
in calbindin-D28k knockout mice; analysis by Western
blotting and immunocytochemistry. Left panel, Western
blot analysis of kidney, pancreas, brain (cortex), and cerebellum of
adult WT and calbindin KO mice using a polyclonal
calbindin-D28k antiserum (30). Middle panel,
immunocytochemical analysis of wild type (A) and
calbindin-D28k knockout (B) mouse kidney using a
rabbit anti-rat calbindin-D28k antiserum. Right
panel, immunocytochemical analysis of the expression of calbindin
in WT (A) and calbindin-D28k KO (B)
mouse islet.
cell in membrane depolarization-stimulated insulin release. Studies using perifused isolated islets showed that when voltage-gated Ca2+
channels were opened by depolarizing the cell membrane by treatment with KRB containing 45 mM KCl, islets from both WT and KO
mice showed increased insulin release with a sharp initial phase that peaked by 3 min after stimulation (Fig.
2). From the peak level, insulin release
decreased, despite the continuing presence of high K+, to
reach a sustained phase after 10 min. Insulin release declined gradually over time. The peak insulin release was of similar magnitude for WT and KO islets. However a significant potentiation in the sustained phase of KCl-induced insulin release was observed in islets
isolated from calbindin KO mice as evident from the time for insulin
release to decline to 25% of the peak release (45 ± 6 min for KO
islets versus 29 ± 3 min for WT islets,
p < 0.05).
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Fig. 2.
Potassium-stimulated insulin release from WT
and calbindin-D28k KO pancreatic islets under perifusion
conditions. Islets were perifused in 4.8 mM KCl (basal
conditions) for 10 min before increasing the total K+ in
the perifusion buffer to 45 mM for 60 min. Data are shown
as the means ± S.E. for n = 5 separate, paired
experiments.
cell and
that calbindin may have a role in modulating sustained insulin release
via regulation of [Ca2+]i.
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Fig. 3.
Intracellular calcium levels in islets
isolated from WT and calbindin-D28k KO mice after
depolarization with K+. A, representative
tracing of KCl-induced changes in [Ca2+]i levels
in single islets loaded with indo-1. After a preincubation in 4.8 mM KCl (basal conditions) the KCl was increased to 45 mM (indicated by arrows). Basal
[Ca2+]i levels in islets from KO and WT mice were
not significantly different (KO, 111 ± 17; WT, 125 ± 19 nM, n = 10; p > 0.5).
B, graphical representation of the changes in
[Ca2+]i shown in A. from basal to peak
and during the plateau phase after treatment with 45 mM
KCl. There was a significant increase in [Ca2+]i
(basal to peak and in the plateau phase) in response to 45 mM KCl in islets isolated from calbindin-D28k
KO mice compared with those from WT mice (p < 0.01).
Cell Lines--
In addition to the studies with isolated
islets from knockout and wild type mice, the role of calbindin in
insulin secretion and modulation of [Ca2+]i
transients was also examined using transfected cell lines
overexpressing calbindin. TC cells were transfected with the pBSR
vector or pBSR-CB28 and selected with G418. After transfection, hundreds of G418-resistant colonies were initially selected. Pooled colonies were screened by Western analysis (Fig.
4) and radioimmunoassay. The clones that
expressed the highest levels of calbindin were designated TC-CaBP47
(expressing 515 ± 37 ng/mg protein) and TC-CaBP54 (expressing
300 ± 17 ng/mg protein). Another G418-resistant TC-3 clone
designated TC-CaBP14 (not shown), a low calbindin expressing clone
(barely detectable levels of calbindin using Western blot analysis and
levels below the limits of detection using the calbindin
radioimmunoassay (30), similar to vector transfected cells), was used
as a control in addition to the vector transfected clone vector 8. The
responses of TC-3 cells to a variety of secretory stimuli have
previously been characterized and shown to resemble the effects of
those secretagogues in normal islets (20). Using the same treatment
protocols previously reported for stimulation of insulin release from
TC-3 cells (20), we examined the effect of calbindin overexpression
on insulin release stimulated by depolarizing concentrations of
potassium as well as by TPA (a tumor promoting phorbol ester and
activator of protein kinase C whose actions on the cell have been
linked with membrane depolarization, 35). In response to 45 mM potassium plus 0.5 mM IBMX insulin release
was stimulated 26-fold over basal levels in the vector 8 transfected
clones (Fig. 5), similar to the results observed previously using nontransfected TC-3 cells (20). Insulin release was also markedly stimulated by potassium plus IBMX treatment of the very low calbindin expressing clone TC-CaBP14 (no significant difference in insulin release between vector 8 and TC-CaBP14 clone,
p > 0.5). However, under the same treatment
conditions, insulin release was decreased by 45 and 47% in the two
highest calbindin expressing clones (TC-CaBP47 and TC-CaBP54
respectively) compared with insulin release from vector transfected
TC-3 cells (Fig. 5). The phorbol ester TPA is also a potent
stimulator of insulin release in TC-3 cells (Fig. 5 and Ref. 20). In
response to 1 µM TPA, similar to the response to
K+, insulin release was significantly decreased in the
calbindin overexpressing clones TC-CaBP47 and TC-CaBP54 (73 and
66%, respectively) compared with vector 8 (Fig. 5). In response to
TPA, insulin release from clone TC-CaBP14 was not significantly
different than insulin release from the vector transfected clone (Fig.
5).
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Fig. 4.
Western blot analysis of the expression of
calbindin-D28k in TC-3 cells.
Proteins in 50 µg of cytoplasmic extract from TC-3 cells
transfected with pBSR-CB28 (TC-CaBP47 and TC-CaBP54) and
TC-3 cells transfected with vector alone (TC-vector 8) were
separated by SDS-polyacrylamide gel electrophoresis and transferred to
nitrocellulose sheets. Cytoplasmic extract from rat kidney was used as
a positive control. Calbindin-D28k protein was visualized
by a chemiluminescent peroxidase method after incubation with a
polyclonal rat calbindin-D28k antibody (30).
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Fig. 5.
Insulin release in response to secretagogues
in TC-3 cells overexpressing
calbindin-D28k. Insulin release was measured from
vector-transfected (V8) and calbindin-transfected
(CaBP 14, CaBP 47, and CaBP 54)
TC-3 cells. Cells were plated at a density of 4 × 105 cells/well in a 24-well dish, and insulin release was
measured after a 1-h preincubation in control media and a 2-h
incubation in the specific treatment media. KCl, 45 mM KCl + 0.5 mM IBMX; TPA, 1 µM TPA. Insulin release is reported as fold increase over
basal. Under basal conditions insulin release (as percentages of
insulin content) ranged from 2.5-2.7% among the different clones.
Data represent the means ± S.E. for n = 3-4
experiments. In each experiment for each clone and specific treatment
four replicates were analyzed at two different dilutions (** = p < 0.01 compared with vector transfected).
TC cells because they are not
glucose-responsive, and the insulin content of RIN cells (0.1% of
normal islets) is much lower than the insulin content of TC cells
(20-30% of that of normal islets; 20). Thus it is possible that
calbindin may affect calcium-mediated regulation of components of the
insulin transcription complex in the low insulin synthesizing RIN cells
but not in TC cells.
TC-3 cell clones (vector 8, TC-CaBP14, and
TC-CaBP54) were treated with a depolarizing concentration of 25 mM KCl (this concentration was found to be optimal for
TC-3 cells to minimize variation in measurements of
[Ca2+]i). Note that the peak change in
[Ca2+]i in response to KCl was significantly
lower in the calbindin-expressing clone TC-CaBP54 compared with
vector transfected cells (vector 8; p < 0.01; see Fig.
6). Although the change in [Ca2+]i in response to KCl was lower in clone
TC-CaBP14 compared with the vector transfected clone, the difference
was not significant (p > 0.5). These findings show
that the overexpression of calbindin results in a reduction in the rise
of [Ca2+]i in response to depolarization with
extracellular potassium and less insulin release.
View larger version (22K):
[in a new window]
Fig. 6.
Increases in intracellular calcium levels
in TC-cells in response to depolarization with
K+ are attenuated by calbindin-D28k.
Clones vector 8, CaBP14, and CaBP54 were treated with 25 mM
KCl, and the change in [Ca2+]i from time = 0 to time = 0.2 min (basal to peak) is represented graphically as
the average change in [Ca2+]i in nM.
Data are shown as the means ± S.E. (n = 3;
p < 0.01 for CaBP54 versus vector 8). No
significant change was found in the plateau phase (not shown)
TC-3 cells, HC-13 cells (22) were also transfected
with the pBSR vector or pBSR-CB28 and selected. For studies using
the HC-13 cells the highest calbindin expressing clone, designated
HC-CaBP40 (expressing 583 ± 90 ng
calbindin-D28k/mg protein) and vector-transfected clone
vector 1 were used for all subsequent experiments (Fig.
7). As shown in Fig.
8 potassium stimulated insulin release
from both vector transfected and HC-13 cells overexpressing
calbindin (HC-CaBP40) in a concentration-dependent manner, with half-maximal values between 30 and 40 mM KCl
for both cell types. Similar to the finding in TC-3 cells,
overexpression of calbindin in HC-13 cells was found to markedly
impair K+-stimulated insulin release (Fig. 8). Calcium
rises were also buffered in calbindin-overexpressing HC-13 cells in
response to K+ stimulation (Fig.
9). Vector transfected cells (vector 1)
showed a rapid increase in [Ca2+]i levels
immediately after treatment with KCl, from a resting level of 200 nM to a level of 1100 nM. This is compared with
a rise to 225 nM for calbindin transfected cells
(HC-CaBP40) from a resting level of 200 nM. Basal
[Ca2+]i levels in HC cells transfected with
vector or overexpressing calbindin (HC-CaBP40) were not
significantly different. These results agree with the results obtained
from isolated islets and TC-3 cells and suggest that calbindin has a
role in modulating depolarization-induced calcium transients and
therefore insulin release from the pancreatic cell.
View larger version (50K):
[in a new window]
Fig. 7.
Western blot analysis of the expression of
calbindin-D28k in HC-13
cells. Proteins in 50 µg of cytoplasmic extract from in HC-13
cells and HC-13 cells transfected with pBSR-CB28
(HC, CaBP 40) or vector alone
(HC, Vec1) were separated by
SDS-polyacrylamide gel electrophoresis and transferred to
nitrocellulose sheets. Cytoplasmic extract from rat kidney was used as
a positive control. Calbindin-D28K protein was visualized
by a chemiluminescent peroxidase method after incubation with a
polyclonal rat calbindin-D28k antibody (30).
View larger version (18K):
[in a new window]
Fig. 8.
Potassium-stimulated insulin release
from HC-13 cells is impaired by
calbindin-D28k. Potassium-stimulated insulin release
was measured in vector-transfected (Vec 1) and
calbindin-D28k-overexpressing HC-13 cells (CaBP
40) and is reported as fold increase over basal. Under basal
conditions the fractional insulin release (as percentages of insulin
content) was 1.4% for both vector transfected cells and CaBP40. Values
are shown as the means ± S.E. from n = 3-4
separate experiments at each KCl concentration; p < 0.01 CaBP40 versus vector 1 at KCl concentrations > 20 mM.
View larger version (20K):
[in a new window]
Fig. 9.
Intracellular calcium levels of
HC-13 clones transfected with vector (Vec
1) or calbindin-D28k (CaBP 40)
in response to depolarization with K+.
[Ca2+]i was measured in vector-transfected
(vector 1) and calbindin-D28k-overexpressing (CaBP40)
HC-13 cells in response to 45 mM KCl. KCl was added at
time = 0. Note that [Ca2+]i was
significantly lower in the calbindin overexpressing cells at every time
point measured after treatment with KCl (p < 0.01).
Data are shown as the means ± S.E. for 6-8 individual
experiments.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
cell
and that calbindin has a role in controlling depolarization-induced insulin release via regulation of
[Ca2+]i. The data show that in islets
isolated from calbindin-D28k KO mice, in addition to an
increase in [Ca2+]i in response to KCl, there is
also an increase in sustained insulin release when compared with WT
islets. Although both the peak and plateau
[Ca2+]i in response to KCl are significantly
greater in the islets from KO mice, only the sustained phase of
KCl-induced insulin release (and not peak insulin release) is
significantly greater in islets from KO mice when compared with WT
islets (Figs. 2 and 3). The most likely explanation of this finding is
that 45 mM KCl increases [Ca2+]i in
WT islets to a level that is sufficient to maximally induce first phase
insulin release. The greater rise in peak [Ca2+]i
observed in the islets from the KO mice cannot result in a further
increase in the first phase insulin release rate, although the
sustained phase of insulin release (which may not be maximally induced
in the WT islets) is significantly increased. Thus the role of
calbindin may be as a modulator of the sustained phase of insulin
release via regulation of [Ca2+]i. A
role for calbindin in modulation of insulin release via regulation of
[Ca2+]i was also noted in the studies using
calbindin overexpressing cells. In response to K+
stimulation both the [Ca2+]i peak as well as
insulin release are decreased or inhibited compared with cells not
expressing calbindin (Figs. 5, 6, 8, and 9). Thus the changes noted in
insulin release from cells overexpressing calbindin and islets from KO
mice as well as the presence of calbindin in the normal cell
strongly suggest that calbindin plays a role in normal insulin
secretory physiology. Reduction of [Ca2+]i
transients evoked by voltage depolarization has previously been
observed to be a function of calbindin in neurons (24, 36, 37). It was
suggested that impaired motor coordination, which is the phenotype of
the calbindin KO mice, may be the result of abnormal cerebellar
activity because of altered depolarization-induced calcium transients
in the Purkinje cells (24). Calbindin was also reported to play a role
in the control of hypothalamic neuroendocrine neuronal firing patterns.
Calbindin was introduced into rat supraoptic neurons using the whole
cell patch clamp method. Calbindin suppressed Ca2+-dependent depolarization after-potentials,
and it was suggested that calbindin, by regulating
depolarization-induced potentials, may be involved in the control of
hormone secretion from hypothalamic neuroendocrine neurons (38). Thus
calbindin appears to act similarly in cells and neurons. Functional
and phenotypic similarities have previously been reported between
neurons and pancreatic cells. For example cells, similar to
neurons, express proteins and amino acids specialized for
neurotransmission such as glutamate receptors, 
-aminobutyric acid
and synapsin I (39-43). Glutamate has been shown to induce
depolarization in islets and currents evoked by glutamate in islets
show properties very similar to currents induced in neurons (39). It is
of interest that in previous studies in neurons, calbindin has been
reported to reduce [Ca2+]i in response to
glutamate (8). Thus it is possible that calbindin may similarly
modulate the rise [Ca2+]i in response not only to
K+ but also to glutamate in the cell. In our study we
focused on the effect of calbindin on modulation of calcium transients in islets and cell lines induced by depolarizing concentrations of
KCl. Not much is known, however, about the ability of calbindin to
modulate calcium influx in the cell in response to other secretagogues. In one study using RIN1046-38 cells, induction of
calbindin was shown to attenuate the [Ca2+]i
response to the secretagogues glucose and KCl as well as to the calcium
ionophore ionomycin and to thapsigargin (which releases
Ca2+ from intracellular calcium stores) (44). These
studies, combined with our findings, suggest a basic role for calbindin
in controlling various calcium fluxes in the cell.
cell that have been
reported to play a role, through their interaction with
Ca2+, in modulating the insulin secretory response.
Calcyclin, unlike calbindin, which acts as a Ca2+ buffer,
was reported to enhance insulin release by a mechanism involving
Ca2+-induced exocytosis (46). Studies using transgenic mice
with the calcium-binding protein calmodulin overexpressed in the
pancreatic cells show that these mice (referred to as CaM mice)
have decreased plasma insulin levels, leading to increased serum
glucose levels and early onset of diabetes (47). Impairment in the
metabolism of glucose and the subsequent generation of ATP was reported
to be the underlying mechanism involved in the defective insulin secretion in the calmodulin transgenic mouse (48). Further studies were
done on another mouse transgenic line, referred to as CaM-8. CaM-8
expresses in its cells a mutant form of calmodulin that is
functionally similar to calbindin because it binds calcium with high
affinity, and, unlike calmodulin but similar to calbindin, it does not
activate effector proteins such as protein phosphatases and kinases
(49, 50). The CaM-8 transgenic mice also display defective insulin
secretion. However the mechanism responsible for the underlying defect
in insulin secretion is different than the mechanism reported for the
CaM mice. The primary defect in the CaM-8 mice is not a defect in
glucose utilization but rather a reduction in Ca2+ current
flowing through voltage-gated calcium channels resulting in a reduction
in the rise in [Ca2+]i (50). CaM-8 mice showed a
marked attenuation in the elevation in [Ca2+]i
observed in response to depolarizing concentrations of KCl (50),
similar to the attenuation observed in our studies in isolated islets
and in cells overexpressing calbindin. Further, patch clamp
measurements using cells from CaM-8 mice revealed a significant
decline in the peak amplitude of voltage-gated Ca2+ channel
currents. The Ca2+ channels affected by the CaM-8 mutation
are the L-type Ca2+ channels because
dihydropyridines blocked these currents (50). It is of interest that
previous patch clamp studies using GH3 pituitary cells stably
transfected with calbindin found that calbindin reduces
Ca2+ influx through voltage dependent L-type
Ca2+ channels (51). In addition, immunohistochemical
studies mapping calbindin in brain noted the similarity between the
distribution of calbindin immunoreactivity and the distribution of
L-type calcium channels mapped using autoradiography (52).
Further studies are needed to determine (as suggested by our studies
with KCl and the similarities observed between calbindin and CaM-8)
whether calbindin can act not only as a buffer protein but also as a
protein that can affect other Ca2+-regulating proteins such
as Ca2+ channels not only in GH3 cells but also in cells. In the future, it will be of interest to examine whether
calbindin can modulate Ca2+ channel activity by a direct
binding mechanism or whether calbindin can affect other proteins
involved in regulating calcium channels.
cell) remains to be
determined. Further studies in HC cells, which have been reported to
preserve the major characteristics of glucose metabolism of native cells better than other murine cell lines (22, 57, 58), will be of
interest to examine the consequences of calbindin overexpression on
glucose-dependent functions in the cells. It is
possible that calbindin has a "fine tuning" modulatory role on
glucose-dependent insulin release that may not be obvious
unless the effect is amplified (for example by activation of protein
kinase A).
cell in
addition to modulation of insulin release. Previous studies by Bourlon
et al. (59) indicated the presence of calbindin in as
well as cells of the rat pancreatic islet and suggested an
additional role for islet calbindin in glucagon secretion. In this
study correlations were made between levels of calbindin as measured by
densitometry of immunocytochemically stained sections of pancreas and
glucagon secretion. Additional studies using more sensitive methods of
quantitation as well as studies with islets from calbindin KO mice may
provide additional insight with regard to the interesting possibility
of a relationship between calbindin and glucagon secretion. In the
nervous system the proposed role of calbindin, similar to its role in
the cell, is to buffer calcium. In the nervous system buffering of
calcium by calbindin results in protection against calcium-mediated
toxicity. Thus in the cell, similar to the neuron, in response to
depolarization-induced increases in [Ca2+]i,
calbindin may buffer the rise in [Ca2+]i to
prevent calcium-mediated cell death. Further studies are needed to
examine other potential functions of calbindin in the cell.
cell has not been well
understood. Although further studies are needed to determine additional mechanisms and multiple consequences of calbindin in the cell, our
findings, using islets from KO mice and cells lines, are important
because they define a role for calbindin in the cell in calcium
regulation and modulation of insulin release.
ACKNOWLEDGEMENTS
FOOTNOTES
ABBREVIATIONS
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DISCUSSION
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 J. G. J. Hoenderop, B. Nilius, and R. J. M. Bindels Calcium Absorption Across Epithelia Physiol Rev, January 1, 2005; 85(1): 373 - 422. [Abstract] [Full Text] [PDF]
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 C. I. Turnbull, K. Looi, J. E. Mangum, M. Meyer, R. J. Sayer, and M. J. Hubbard Calbindin Independence of Calcium Transport in Developing Teeth Contradicts the Calcium Ferry Dogma J. Biol. Chem., December 31, 2004; 279(53): 55850 - 55854. [Abstract] [Full Text] [PDF]
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W. Zheng, Y. Xie, G. Li, J. Kong, J. Q. Feng, and Y. C. Li Critical Role of Calbindin-D28k in Calcium Homeostasis Revealed by Mice Lacking Both Vitamin D Receptor and Calbindin-D28k J. Biol. Chem., December 10, 2004; 279(50): 52406 - 52413. [Abstract] [Full Text] [PDF]
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A. Rabinovitch, W. L. Suarez-Pinzon, K. Sooy, K. Strynadka, and S. Christakos Expression of Calbindin-D28k in a Pancreatic Islet {beta}-Cell Line Protects against Cytokine-Induced Apoptosis and Necrosis Endocrinology, August 1, 2001; 142(8): 3649 - 3655. [Abstract] [Full Text] [PDF]
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 K. A. Cox and M. A. Dunn Aluminum Toxicity Alters the Regulation of Calbindin-D28k Protein and mRNA Expression in Chick Intestine J. Nutr., July 1, 2001; 131(7): 2007 - 2013. [Abstract] [Full Text] [PDF]
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