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(Received for publication, October 17, 1995; and in revised form, October 30,
1995) From the
Glucose-stimulated insulin secretion is believed to require
metabolism of the sugar via a high K
Glucose-stimulated insulin secretion (occurring at
concentrations in excess of 5 mM) is believed to require
metabolism of the sugar via a high K
A large body of evidence has accumulated in support of the
notion that glucokinase represents the rate-limiting step of glucose
metabolism in pancreatic islet
Figure 1:
Immunofluorescent
detection of glucokinase and insulin in cultured rat islets. Cultured
islets were treated with AdCMV-
Western blot analysis showed that
treatment of islets with the AdCMV-GKI virus resulted in large
increases in glucokinase protein relative to control islets, as
detected with antibody U343 (11) (Fig. 2A),
which is specific for the unique N-terminal segment of the islet
isoform of glucokinase, or antibody V980 (Fig. 2B),
raised against a region of the protein common to both liver and islet
glucokinases(11) . As shown in Fig. 2B,
treatment of islets with the AdCMV-GKL virus resulted in levels of
immunodetectable protein slightly higher than those achieved with the
AdCMV-GKI virus. Finally, treatment of islets with the AdCMV-HKI virus
resulted in consistent overexpression of hexokinase I protein (Fig. 2C), in agreement with our previous work (5) .
Figure 2:
Immunoblot analysis of adenovirus-mediated
expression of glucose-phosphorylating enzymes in cultured rat islets.
Islets extracts were prepared 3-4 days after treatment with the
indicated recombinant adenoviruses (see text for abbreviations) and
resolved by SDS-polyacrylamide gel electrophoresis, using 20 µg of
total protein/lane. Representative blots are shown. A, immunodetection with antibody U343, which is specific for
the islet glucokinase N-terminal sequence(11) . Included in
this panel is a control lane (GK STD)
containing an extract of bacteria engineered for expression of islet
glucokinase. The appearance of two immunoreactive bands in this sample
is likely due to partial proteolytic degradation, since other samples
that we have analyzed previously contained only a single
band(11) . B, immunodetection with antibody V980,
which recognizes a C-terminal region common to the liver and islet
glucokinase isoforms(11) . C, islets treated with
AdCMV-HKI and immunodetection performed with an antibody specific for
rat hexokinase I(13) . Samples from three separate islet
aliquots treated with AdCMV-HKI are shown.
Glucokinase represents less than half of the total
glucose phosphorylating activity in control islets (4.4 ± 0.7
and 5.6 ± 1.0 units/g measured at 20 mM glucose in the
absence of Glc-6-P and 1.2 ± 0.4 and 2.3 ± 0.5 units/g in
the presence of 10 mM Glc-6-P for untreated and
AdCMV-
Isolated islet
preparations are removed from their normal pancreatic environment and
may be deprived of certain nutritional, nervous, and hormonal signals
that might be required to activate overexpressed
glucokinase(26) . To partially address this concern, we
repeated the foregoing experiments with a rich tissue culture medium
(DMEM) containing 5.5 mM glucose in the basal period and 20
mM glucose in the stimulation period. We found that basal
insulin release from all islet groups was increased approximately
5-fold during perifusion with 5.5 mM glucose in DMEM (average
of 190 microunits/ml/1000 islets) compared with insulin release in
Hanks' buffer containing 3 mM glucose (37
microunits/ml/1000 islets). Untreated islets or islets treated with
AdCMV-
Figure 3:
Metabolic fate of glucose in
adenovirus-treated islets. Assays were performed on islets incubated at
3 mM (hatched bars) or 20 mM glucose (black bars) (see text for explanation of abbreviations). A, glucose usage in intact islets measured as the amount of
Figure 4:
Glucose phosphorylation in whole cells and
cell extracts. Assays were performed with isolated islets or CV-1 cells
treated with the indicated recombinant adenoviruses (see text for
abbreviations). A, accumulation of phosphorylated products in
intact islets or CV-1 cells exposed to
[U-
Figure 5:
Expression of glucokinase regulatory
protein mRNA in pancreatic islets and liver. The levels of glucokinase
regulatory protein mRNA were determined using reverse transcriptase-PCR
as described under ``Materials and Methods.'' The predicted
276-base pair (bp) amplification product is shown for islet
samples from 6-week prediabetic ZDF (fa/fa) (lane 1), 6-week
lean control ZDF (fa/- or -/-) (lane 2),
12-week diabetic ZDF (lane 3), and 12-week lean control ZDF (lane 4) and for liver samples from 12-week diabetic ZDF (lane 5) and Wistar (lane 6) rats. Lane 7 contains molecular weight standards.
In summary, our studies show that
overexpression of glucokinase in isolated islets has minimal effects on
glucose metabolism and insulin release. These findings appear to be
specific to the high K
Volume 271,
Number 1,
Issue of January 5, 1996 pp. 390-394
©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
EVIDENCE FOR FUNCTIONAL SEGREGATION OF THE HIGH AND LOW K ENZYMES (*)
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES
pathway in
which glucokinase (hexokinase IV) is rate-limiting. In this study, we
have used recombinant adenoviruses to overexpress the liver and islet
isoforms of glucokinase as well as low K
hexokinase I in isolated rat islets of Langerhans. Glucose
phosphorylating activity increased by up to 20-fold in extracts from
islets treated with adenoviruses containing the cDNAs encoding either
tissue isoform of glucokinase, but such cells exhibited no increase in
2- or 5-[
H]glucose usage, lactate production,
glycogen content, or glucose oxidation. Furthermore, glucokinase
overexpression enhanced insulin secretion in response to stimulatory
glucose or glucose plus arginine by only 36-53% relative to
control islets. In contrast to the minimal effects of overexpressed
glucokinases, overexpression of hexokinase I caused a 2.5-4-fold
enhancement in all metabolic parameters except glycogen content when
measured at a basal glucose concentration (3 mM). Based on
measurement of glucose phosphorylation in intact cells, overexpressed
glucokinase is clearly active in a non-islet cell line (CV-1) but not
within islet cells. That this result cannot be ascribed to the levels
of glucokinase regulatory protein in islets is shown by direct
measurement of its activity and mRNA. These data provide evidence for
functional partitioning of glucokinase and hexokinase and suggest that
overexpressed glucokinase must interact with factors found in limiting
concentration in the islet cell in order to become activated and engage
in productive metabolic signaling.
pathway in which glucokinase is
rate-limiting(1, 2) . Consistent with an important
role for glucokinase in the high K
regulatory pathway, it has recently been shown that
mutations in this gene are associated with
-cell dysfunction in a
subtype of non-insulin-dependent diabetes mellitus known as
maturity-onset diabetes of the young(3) . Furthermore,
reduction of glucokinase activity by 70% in -cells of transgenic
mice expressing a glucokinase-specific ribozyme results in decreased
glucose-stimulated insulin secretion (GSIS)(
)(4) .
Low K hexokinases are also expressed in
-cells and appear to determine the amount of insulin secreted at
basal glucose concentrations (1, 5, 6, 7) suggesting a functional
segregation from the high K glucokinase-mediated glucose signaling pathway. Implicit in
such a model is that protection against an inappropriately vigorous
response to a glucose challenge might be achieved by regulating access
of the sugar to the high K
pathway by
requiring that glucokinase couple to factors found in limiting
concentration in the islet cell. Since the impact of glucokinase
overexpression has not been studied, it is not known whether increased
abundance of this enzyme will specifically enhance high K
glucose metabolism and insulin
secretion. In order to address this question, we have used the
recombinant adenovirus system to overexpress two isoforms of
glucokinase and hexokinase I in isolated islets of Langerhans.
Preparation of Recombinant
Adenovirus
Recombinant adenovirus containing the cDNA encoding
human islet glucokinase (AdCMV-GKI) was prepared by inserting a
full-length (2.4 kilobase pairs) BamHI fragment into the
pACCMV.pLpA plasmid(8) , followed by co-transfection with the
adenovirus plasmid pJM17(9) , using previously described
techniques(5, 8, 10) . A virus containing the
rat liver glucokinase cDNA (AdCMV-GKL) was prepared by coligation of a
480-base pair BamHI/NsiI fragment from the 5`-end of
rat liver glucokinase (11) and a 1.05-kilobase pairs NsiI/BamHI fragment from the 3`-region of glucokinase
common to the rat liver and islet into pACCMV.pLpA, followed by
recombination as described for the islet construct. Recombinant
adenovirus containing the rat hexokinase I cDNA (AdCMV-HKI) was
prepared as described(5) .Islet Isolation and Perifusion
Pancreatic islets
were isolated from male Wistar rats (140-180 g)(12) ,
transduced with recombinant adenoviruses, and cultured for 3-4
days prior to performing the assays described below(5) . Groups
of 500-1000 islets were perifused (5) in Hanks' buffer or
DMEM medium (Atlanta Biologicals) with additions as described in the
figure legends. Effluent was collected in 0.7-ml aliquots and assayed
for insulin by radioimmunoassay.Assays of Glucokinase Expression
Glucokinase
protein was measured by immunoblot analysis with antibody U343
(specific for islet glucokinase) or antibody V980 (reactive to a
sequence common to islet and liver glucokinases), as
described(11) , and hexokinase I was detected with an antibody
provided by Dr. John Wilson, Michigan State University(13) .
For immunocytochemical measurements(14) , a new glucokinase
antibody (GK-1) was raised in rabbits (Tana Biosystems, Houston,
TX) against a purified rat islet glucokinase/glutathione S-transferase fusion protein prepared in the p-GEX-2T
expression vector (Pharmacia Biotech Inc.). The specificity of
GK-1 was indicated by its capacity to immunoprecipitate a single
band co-migrating with glucokinase from metabolically labeled CV-1
(African green monkey kidney) cells transduced with AdCMV-GKI. (
)Total glucose phosphorylating and glucokinase activities
were measured with a radioisotopic assay in crude cellular extracts or
in cytosolic or mitochondrial fractions as described
previously(5, 15) . Glucose phosphorylation in intact
cells was measured by incubating islets or CV-1 cells with Hanks'
solution containing 3 or 20 mM [U-
C]glucose (DuPont NEN) for 90 min at 37
°C. The labeled medium was then replaced with 50 µl of 0.5%
Triton X-100 and 100 µl of 3% methanol in 95% ethanol. All labeled
and phosphorylated intermediates were captured by spotting an aliquot
of such extracts onto DEAE ion exchange membranes (Schleicher &
Schuell) followed by washes with distilled water and counting of the
filters as described(15) .Metabolic Assays
Conversion of 2- and
5-[H]glucoses to HO was
measured as described previously(5, 16) , using
approximately 350 islets/assay. Lactate production was measured (17) in groups of 400-500 islets incubated at 37 °C
in perifusion medium containing 3 or 20 mM glucose. Glycogen
content was determined as described (17) after culturing islets
for 3-4 days in 11 mM glucose. Glucose oxidation was
determined by measuring CO production from
[U-C]glucose (14) with aliquots of
approximately 25 islets incubated with 3 or 20 mM glucose for
3 h at 37 °C.Reverse Transcriptase-Polymerase Chain Reaction (PCR)
Assay for Glucokinase Regulatory Protein Transcripts
Tissues
were obtained from 6- and 12-week-old male Wistar rats, male Zucker
diabetic fatty rats (fa/fa), and lean controls (fa/- or
-/-)(18) . cDNA was prepared from a total of 2
µg of total liver or islet RNA and 50 pmol of random hexamer
primers (Pharmacia), and glucokinase regulatory protein cDNA was
amplified from 1 µl of this cDNA solution using previously
described methods (19) and primers GR-A
(5`-CCAACTCCAAGCTCTTCTGGAG-3`) and GR-B
(5`-TCCTAACAACCTCACAGACTGAAG-3`)(20) . The 276-base pair PCR
product was identified by electrophoresis in a 1% agarose gel and
quantified by densitometry after ethidium bromide staining (Molecular
Dynamics, Sunnyvale, CA).
-cells. Based solely on kinetic
considerations, one may have predicted that overexpression of
glucokinase in islets would have a potent enhancing effect on glucose
metabolism and, as a consequence, on GSIS. Indeed glucokinase activity,
glucose usage, and GSIS increase coordinately in proportion to the
glucose concentration of islet culture media(21, 22) ,
and hyperglycemic infusion is reported to increase glucokinase activity
and render islets more sensitive to glucose(23) , leading to
the suggestion that the increase in enzyme activity is the likely cause
of the enhanced glucose response. Interpretation of these experiments
is complicated by the fact that expression of a large number of islet
proteins is increased by culture at high glucose(24) . The
present study was designed to evaluate the effect of glucokinase
overexpression in a more specific manner by introducing the gene
encoding this enzyme into isolated islets via recombinant adenovirus.Overexpression of Glucose-phosphorylating Enzymes
We
have previously shown that treatment of islets with a recombinant
adenovirus containing the bacterial -galactosidase reporter gene
(AdCMV-GAL) results in gene transfer to islet cells (including
-cells) with an efficiency of approximately 70%(5) .
Overexpression of glucokinase with similar efficiency in islet cells is
demonstrated by the data of Fig. 1. Sections from islets treated
with AdCMV-GKI and exposed to anti-glucokinase antibody GK-1 (Fig. 1B) exhibited a clear increase in
immunofluorescence intensity in the majority of cells, including
-cells (identified by staining of serial sections with an insulin
antibody, Fig. 1, C and D), relative to
control sections from islets treated with AdCMV-GAL (Fig. 1A).
GAL (A, C, and E) or AdCMV-GKI (B, D, and F).
Sections were treated with anti-glucokinase antibody GK-1 (A, B, E, and F) or guinea pig
anti-insulin antibody (C and D). Sections were viewed
at 
400 (A, B, C, and D) or
1000 (E and F)
magnification.
GAL-treated islets, respectively), consistent with previous
reports(1, 25) . Treatment of islets with AdCMV-GKI or
AdCMV-GKL resulted in 14- and 19.4-fold increases in total glucose
phosphorylation and 37.6- and 53.8-fold increases in glucokinase
activity (measured in the presence of 10 mM Glc-6-P),
respectively (data represent the average of 6-8 groups of islets
per condition). Overexpression of hexokinase I resulted in an 8-fold
increase in total glucose phosphorylation relative to the two control
groups, with nearly all of the observed increase sensitive to Glc-6-P
inhibition.Insulin Secretion from Islets Overexpressing
Glucokinase
As shown in Table 1, insulin secretion in
response to 20 mM glucose was increased by 40-51% in
islets treated with AdCMV-GKI or AdCMV-GKL and by 36-53% when
such cells were challenged with 20 mM glucose plus 30 mM arginine. The differences noted between control islets and islets
treated with AdCMV-GKL or AdCMV-GKI were of marginal statistical
significance (see Table 1for statistical analysis). As
previously reported (5) basal insulin release was nearly
doubled by treatment of islets with AdCMV-HKI.
GAL, AdCMV-GKI, or AdCMV-GKL all responded similarly to 20
mM glucose by increasing insulin release by approximately
2-fold above this new base line (data not shown). Thus, while our data
indicate a minimal secretory impact of overexpressed glucokinases in
isolated islets, it remains possible that future studies of transgenic
animals or in vitro experiments with agents that can
potentiate GSIS such as glucagon-like peptide-1 or acetylcholine
(carbachol) may uncover larger effects.Glucose Metabolism
As shown in Fig. 3,
treatment of islets with AdCMV-GKI or AdCMV-GKL had no effect on
5-[H]glucose usage,
2-[H]glucose usage, or lactate production
relative to untreated or AdCMV-GAL-treated islets, regardless of
whether measurements were made at 3 or 20 mM glucose. The lack
of effect of overexpressed glucokinase is not explained by failure to
overexpress the enzyme efficiently in -cells, based on the results
shown in Fig. 1and on studies in which treatment of the well
differentiated INS-1 cell line (27) with AdCMV-GKI also has no
effect on 5-[H]glucose usage studied at 20
mM glucose. The H label is released to
water at the hexose-phosphate isomerase and triose-phosphate isomerase
reactions, respectively, for 2- and
5-[H]glucoses. 2-[H]Glucose
was used to test the possibility that glucokinase overexpression was
specifically enhancing glucose Glc-6-P recycling without
increasing flux through phosphofructokinase. The similar rates of usage
attained with 2- and 5-[
H]glucoses clearly
indicate that this is not the case. In contrast to the lack of effect
of overexpressed glucokinase, treatment of islets with AdCMV-HKI
resulted in a 2.2-fold increase in 5-[H]glucose
usage, a 2.6-fold increase in 2-[H]glucose usage,
and a 4.2-fold increase in lactate production at 3 mM glucose (Fig. 3). We also measured [U-C]glucose
oxidation and found that while overexpression of glucokinase did not
cause an increase in this parameter, islets treated with AdCMV-HKI
exhibited a 3.3-fold enhancement in this pathway at 3 mM glucose (4.0 ± 0.6 and 3.6 ± 2.9 fmol/h/islet for
untreated and AdCMV-GAL-treated controls, respectively, versus 12.5 for AdCMV-HKI-treated islets). For three of the four
measurements of glucose metabolism (2-[H]glucose
usage, lactate production, and glucose oxidation), the increase in rate
observed in AdCMV-HKI-treated cells at 3 mM glucose was
reflected in a similarly increased flux at 20 mM glucose. No
change in glycogen content was noted in control islets (67 ± 2
and 63 ± 6 ng of glycogen/100 islets for untreated and
AdCMV-GAL-treated groups, respectively) versus islets
overexpressing glucose-phosphorylating enzymes (76 ± 1, 67
± 3, and 68 ± 2 ng of glycogen/100 islets for AdCMV-GKI,
AdCMV-GKL, and AdCMV-HKI-treated groups, respectively).
HO release during incubation with
5-[H]-D-glucose. B, lactate
production from islets. C, glucose usage in intact islets
measured as the amount of HO release during
incubation with 2-[H]-D-glucose. Values
represent the mean ± S.E. for four independent groups of islets
per condition. * indicates those groups in which usage or lactate
production was higher at 20 mM glucose than at 3 mM glucose (p < 0.05). # indicates those groups for which
usage or lactate production was higher than in the respective control
groups (p < 0.05).
Intracellular Glucose Phosphorylating Activity
The
lack of metabolic impact of overexpressed glucokinases is surprising in
light of the high levels of enzyme activity measured in islet extracts.
To determine whether the overexpressed enzyme was active within intact
cells, we incubated AdCMV-GKI or AdCMV-GAL-treated islets with
[U-C]glucose and measured accumulation of
phosphorylated glucose and its by-products. As a control, we also
performed parallel experiments in the monkey kidney cell line CV-1. As
shown in Fig. 4, intact islets overexpressing glucokinase failed
to increase levels of [U-C]glucose-derived
glycolytic intermediates above those attained in control islets,
despite a 28-fold increase in glucose phosphorylating capacity in
homogenates from these same cells. In contrast, similar overexpression
of glucokinase in CV-1 cells resulted in a 4.7 ± 0.8-fold
increase in phosphorylated products at 20 mM glucose relative
to AdCMV-GAL-treated control cells. Metabolic impact (increased
glycogen deposition, [5-H]glucose usage, and
lactate production) is also clearly evident when glucokinase is
overexpressed in hepatoma cells (28) or primary hepatocytes. ()These data suggest either that overexpressed glucokinase
is inhibited by an islet-specific factor or that activation and
metabolic coupling of the overexpressed enzyme does not occur in the
islet environment.
C]glucose for 90 min. B, total
glucose phosphorylating activity (no Glc-6-P added) in islet or CV-1
cell homogenates measured at 3 and 20 mM glucose (hatched and black bars, respectively). In both panels,
data are normalized to the value obtained at 3 mM glucose in
AdCMV-GAL-treated islets for each cell type. Values represent the
mean ± S.D. of four measurements. * in A indicates that
the accumulation of labeled product in the indicated group was greater
than in all other groups (p < 0.001), and # in B indicates that glucose phosphorylating activity was significantly
increased in AdCMV-GKI-treated islets or CV-1 cells at either 3 or 20
mM glucose relative to the respective AdCMV-GAL-treated
controls (p < 0.001).
Lack of Regulation of Overexpressed Glucokinase by the
Glucokinase Regulatory Protein
A glucokinase regulatory protein
that binds the enzyme and inhibits it in a hexose phosphate-sensitive
manner has been described in liver(29) . Glucokinase activity
in islet extracts can be increased slightly by the addition of fructose
1-phosphate, an antagonist of the glucokinase regulatory
protein(30) , but no other information about the level of
expression of the regulatory protein in islets has been presented. We
found that 10 mM Fru-1-P modestly increased glucose
phosphorylating activity measured at 20 mM glucose in islet
extracts with overexpressed liver (from 205.3 ± 7.7 to 269.7
± 5.3 units/g of protein) or islet (from 301.7 ± 6.3 to
329.8 ± 8.1 units/g) glucokinases, while Fru-6-P, an activator
of the regulatory protein (29) , had no effect at either 100
µM or 10 mM. We also found that islets from
6-week-old lean (fa/- or -/-) or obese (fa/fa) ZDF
rats contained only 19 or 33% as much regulatory protein mRNA,
respectively, as found in liver of Wistar rats or 12-week-old obese ZDF
rats (Fig. 5). While the level of regulatory protein mRNA was
maintained in islets of lean controls with age, 12-week-old ZDF obese
animals exhibited a sharp decline in this transcript to a level only
1.4% of that found in liver. The significance of the decline in
regulatory protein mRNA in obese ZDF animals remains to be elucidated.
Since the regulatory protein is thought to work
stoichiometrically(29) , these data argue strongly that the
known glucokinase regulatory protein is unlikely to be present at
levels sufficient to inhibit the large excess of overexpressed
glucokinase in islets. It remains possible that a glucokinase
regulatory factor that is either an isozyme of the known protein or a
member of a completely different gene family is operative in islets.
Partitioning of Overexpressed Glucose-phosphorylating
Enzymes
One explanation for our findings is that a metabolic
impact of overexpressed glucokinase requires assembly of the enzyme
into a complex analogous with those described for sequential enzymes of
the citric acid cycle(31) . Indeed, Malaisse and Bodur (32) have pointed out that the rate of conversion of
[2-H]glucose to HO is
less than the predicted value deduced from known activities of the
relevant enzymes and have suggested from this that early glycolytic
substrates are ``channeled'' from one enzyme to another
within a complex. The idea that metabolic impact may be linked to the
physical partitioning of glucose-phosphorylating enzymes is consistent
with our finding that overexpressed hexokinase I partitions in islets
such that 41% of the total activity is associated with a
mitochondrially enriched fraction (5) , while
mitochondria-enriched fractions of both control and
glucokinase-overexpressing islets are completely lacking in
Glc-6-P-insensitive glucose phosphorylating activity (data not shown).
Association of hexokinase with mitochondria causes activation of the
enzyme by reducing its sensitivity to Glc-6-P as an allosteric
inhibitor(33) . This compartmentation may also be important for
functional segregation of the low K
pathway of
glucose metabolism that is responsible for ``maintenance''
metabolic activity and basal insulin secretion of the -cell. A
recent study has shown that glucokinase may localize to a discrete
``perinuclear'' compartment within -cells(34) .
In light of this study, the lack of metabolic impact of overexpressed
glucokinase in islets can be explained by a model in which discrete
localization of glucokinase and its participation in high K signaling and glucose metabolism require binding
of the enzyme to a limiting number of sites, which are fully occupied
by the endogenous enzyme. glucokinases, since changes
in metabolic parameters and insulin secretion are easily detectable in
islets overexpressing low K hexokinase I. Our
results indicate that the known glucokinase regulatory protein is
unlikely to be present in islets at levels sufficient to explain our
findings. We therefore favor an alternative model, in which
overexpressed glucokinase must interact with factors found in limiting
concentration in the islet cell in order to become activated and engage
in productive metabolic signaling. This regulatory mechanism may be a
unique feature of islet cells, since overexpressed glucokinase is
clearly active within CV-1 or liver cells, and may explain why a
decrease in -cell glucokinase activity has demonstrable effects on
glucose metabolism and insulin release, while overexpression of the
enzyme has little impact.
)))
We are grateful to Dr. Roger Unger, Dr. J. Denis
McGarry, and Dr. Kenneth Polonsky for critical reading of this
manuscript. We are also indebted to Donna Lehman and Dr. Chris
MacAllister for assistance with islet isolation, Kay McCorkle for
insulin radioimmunoassays, and Linda Tompkins for purification of the
glutathione S-transferase-glucokinase fusion protein.
©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
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 J. Yang, R. K. Wong, X. Wang, J. Moibi, M. J. Hessner, S. Greene, J. Wu, S. Sukumvanich, B. A. Wolf, and Z. Gao Leucine Culture Reveals That ATP Synthase Functions as a Fuel Sensor in Pancreatic {beta}-Cells J. Biol. Chem., December 24, 2004; 279(52): 53915 - 53923. [Abstract] [Full Text] [PDF]
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A. R. Green, S. Aiston, C. C. Greenberg, S. Freeman, S. M. Poucher, M. J. Brady, and L. Agius The Glycogenic Action of Protein Targeting to Glycogen in Hepatocytes Involves Multiple Mechanisms Including Phosphorylase Inactivation and Glycogen Synthase Translocation J. Biol. Chem., November 5, 2004; 279(45): 46474 - 46482. [Abstract] [Full Text] [PDF]
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J. R. Bain, J. C. Schisler, K. Takeuchi, C. B. Newgard, and T. C. Becker An Adenovirus Vector for Efficient RNA Interference-Mediated Suppression of Target Genes in Insulinoma Cells and Pancreatic Islets of Langerhans Diabetes, September 1, 2004; 53(9): 2190 - 2194. [Abstract] [Full Text] [PDF]
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L. Wu, W. Nicholson, S. M. Knobel, R. J. Steffner, J. M. May, D. W. Piston, and A. C. Powers Oxidative Stress Is a Mediator of Glucose Toxicity in Insulin-secreting Pancreatic Islet Cell Lines J. Biol. Chem., March 26, 2004; 279(13): 12126 - 12134. [Abstract] [Full Text] [PDF]
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R. Yang and C. B. Newgard Hepatic Expression of a Targeting Subunit of Protein Phosphatase-1 in Streptozotocin-diabetic Rats Reverses Hyperglycemia and Hyperphagia Despite Depressed Glucokinase Expression J. Biol. Chem., June 20, 2003; 278(26): 23418 - 23425. [Abstract] [Full Text] [PDF]
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S. Aiston, B. Andersen, and L. Agius Glucose 6-Phosphate Regulates Hepatic Glycogenolysis Through Inactivation of Phosphorylase Diabetes, June 1, 2003; 52(6): 1333 - 1339. [Abstract] [Full Text] [PDF]
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C. B. Newgard, D. Lu, M. V. Jensen, J. Schissler, A. Boucher, S. Burgess, and A. D. Sherry Stimulus/Secretion Coupling Factors in Glucose-Stimulated Insulin Secretion: Insights Gained From a Multidisciplinary Approach Diabetes, December 1, 2002; 51(90003): S389 - 393. [Abstract] [Full Text] [PDF]
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C. B. Newgard While Tinkering With the {beta}-Cell... Metabolic Regulatory Mechanisms and New Therapeutic Strategies: American Diabetes Association Lilly Lecture, 2001 Diabetes, November 1, 2002; 51(11): 3141 - 3150. [Abstract] [Full Text] [PDF]
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 L. S. Tompkins, K. D. Nullmeyer, S. M. Murphy, C. S. Weber, and R. M. Lynch Regulation of secretory granule pH in insulin-secreting cells Am J Physiol Cell Physiol, August 1, 2002; 283(2): C429 - C437. [Abstract] [Full Text] [PDF]
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P. A. Antinozzi, H. Ishihara, C. B. Newgard, and C. B. Wollheim Mitochondrial Metabolism Sets the Maximal Limit of Fuel-stimulated Insulin Secretion in a Model Pancreatic Beta Cell. A SURVEY OF FOUR FUEL SECRETAGOGUES J. Biol. Chem., March 29, 2002; 277(14): 11746 - 11755. [Abstract] [Full Text] [PDF]
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N. de la Iglesia, M. Mukhtar, J. Seoane, J. J. Guinovart, and L. Agius The Role of the Regulatory Protein of Glucokinase in the Glucose Sensory Mechanism of the Hepatocyte J. Biol. Chem., March 31, 2000; 275(14): 10597 - 10603. [Abstract] [Full Text] [PDF]
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 J. C. JIMÉNEZ-CHILLARÓN, C. B. NEWGARD, and A. M. GÓMEZ-FOIX Increased glucose disposal induced by adenovirus-mediated transfer of glucokinase to skeletal muscle in vivo FASEB J, December 1, 1999; 13(15): 2153 - 2160. [Abstract] [Full Text]
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F. Schuit, K. Moens, H. Heimberg, and D. Pipeleers Cellular Origin of Hexokinase in Pancreatic Islets J. Biol. Chem., November 12, 1999; 274(46): 32803 - 32809. [Abstract] [Full Text] [PDF]
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J. Seoane, A. Barbera, S. Telemaque-Potts, C. B. Newgard, and J. J. Guinovart Glucokinase Overexpression Restores Glucose Utilization and Storage in Cultured Hepatocytes from Male Zucker Diabetic Fatty Rats J. Biol. Chem., November 5, 1999; 274(45): 31833 - 31838. [Abstract] [Full Text] [PDF]
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S. Aiston, K. Y. Trinh, A. J. Lange, C. B. Newgard, and L. Agius Glucose-6-phosphatase Overexpression Lowers Glucose 6-Phosphate and Inhibits Glycogen Synthesis and Glycolysis in Hepatocytes without Affecting Glucokinase Translocation. EVIDENCE AGAINST FEEDBACK INHIBITION OF GLUCOKINASE J. Biol. Chem., August 27, 1999; 274(35): 24559 - 24566. [Abstract] [Full Text] [PDF]
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D. W. Piston, S. M. Knobel, C. Postic, K. D. Shelton, and M. A. Magnuson Adenovirus-mediated Knockout of a Conditional Glucokinase Gene in Isolated Pancreatic Islets Reveals an Essential Role for Proximal Metabolic Coupling Events in Glucose-stimulated Insulin Secretion J. Biol. Chem., January 8, 1999; 274(2): 1000 - 1004. [Abstract] [Full Text] [PDF]
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