| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
J. Biol. Chem., Vol. 277, Issue 22, 20020-20025, May 31, 2002
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
From the
Received for publication, January 23, 2002, and in revised form, March 6, 2002
Activating transcription factor 3 (ATF3), a
member of the ATF/cAMP-responsive element-binding protein family
of transcription factors, is a transcriptional repressor, and the
expression of its corresponding gene, ATF3, is induced by
many stress signals. In this report, we demonstrate that transgenic
mice expressing ATF3 in the liver had symptoms of liver
dysfunction such as high levels of serum bilirubin, alkaline
phosphatase, alanine transaminase, aspartate transaminase, and bile
acids. In addition, these mice had physiological responses consistent
with hypoglycemia including a low insulin:glucagon ratio in the serum
and reduced adipose tissue mass. Electrophoretic mobility shift assays
indicated that ATF3 bound to the ATF/cAMP-responsvie element site
derived from the promoter of the gene encoding the gluconeogenic enzyme
phosphoenolpyruvate carboxykinase (PEPCK). Furthermore, transient
transfection assays indicated that ATF3 repressed the activity of the
PEPCK promoter. Taken together, our results are consistent
with the model that the expression of ATF3 in the liver
results in defects in glucose homeostasis by repressing
gluconeogenesis. Because ATF3 is a stress-inducible gene,
these mice may provide a model to investigate the molecular mechanisms
of some stress-associated liver diseases.
The liver is a critical organ for homeostasis. Two
metabolic processes in the liver, glycogenolysis and gluconeogenesis,
help to maintain glucose homeostasis (1-5). In newborns, to adjust to
the discontinued supply of glucose by maternal blood, glycogenolysis is
turned on to degrade glycogen to glucose, and gluconeogenesis is turned
on to synthesize glucose from non-carbohydrate precursors. In adults,
these two metabolic processes also function to maintain the glucose
homeostasis of the body. During the fasting state, glycogenolysis and
gluconeogenesis are stimulated to produce glucose, whereas during the
fed state these processes are inhibited. The main regulator of these
processes is the ratio of two hormones secreted by the endocrine
pancreas, insulin and glucagon. When the blood glucose level is low,
the insulin:glucagon ratio is low, resulting in the activation of the
intracellular cAMP signaling pathway that in turn stimulates
glycogenolysis and gluconeogenesis. However, when the blood glucose
level is high, the insulin:glucagon ratio is high and these metabolic
processes are repressed. In addition to maintaining glucose
homeostasis, the liver plays an important role in the other functions
including (a) metabolism of xenobiotic toxins and
endogenous substances such as heme, steroids, and biogenic amines,
(b) synthesis of plasma proteins such as albumin and
clotting factors, and (c) carrying out the acute phase responses upon inflammation, infection, or trauma (6).
Because of its metabolic functions, the liver is the primary target for
a variety of stress signals such as carcinogens and toxins. Therefore,
to understand many liver diseases, it is important to understand the
effects of stress signals on the liver. We have been investigating a
stress-inducible gene, activating transcription factor 3 (ATF3).1 ATF3, the
corresponding protein product of this gene, is a member of the ATF/CREB
family of basic region leucine zipper transcription factors (for
reviews see Refs. 7-10). Although cDNA encoding ATF3 was isolated
from a human library (11), homologous cDNAs from rats and mice with
~95% identity to ATF3 at the amino acid level have been identified
as liver-regenerating factor-1 in the rat (12) and lipopolysaccharide
responsive gene-21 (13), cytokine-responsive gene-5 (14), or
TI-241 (15) in the mouse. For the convenience of discussion, we
use the ATF3 nomenclature in the rest of this report.
Overwhelming evidence from many laboratories indicates that
ATF3 is induced by a variety of stress signals in the liver
(for review see Ref. 16). By in situ hybridization, we
demonstrated that the mRNA level of ATF3 greatly
increases in the liver after exposing the animals to chemicals such as
carbon tetrachloride, alcohol, acetaminophen, and cycloheximide (16,
17). Others have demonstrated that ATF3 is induced in the
liver by hepatic ischemia (18) and partial hepatectomy (12). In
addition, ATF3 is induced in cultured hepatocytes by
cycloheximide, endothelial growth factor, and human growth factor (19).
Importantly, ATF3 is also induced in many other tissues by
stress signals (for reviews see Refs. 7 and 16) such as the heart by
ischemia coupled with reperfusion (ischemia reperfusion) (17), the
peripheral nerves by axotomy (20), and the pancreas by partial
pancreatectomy, ischemia reperfusion, and streptozotocin treatment
(21). Therefore, ATF3 is induced in many tissues by a
variety of stress signals, suggesting that it is a key regulator in
cellular stress responses.
Although the induction of ATF3 by stress signals is neither
tissue-specific nor stimulus-specific, one common theme of all the
signals that induce ATF3 is that they induce cellular damage (for reviews see Refs. 7 and 16). This correlation raises an important
question. Is the induction of ATF3 a protective response for
the cells to cope with stress or a part of the cellular response that
leads to detrimental outcomes? To address this question, we took a
gain-of-function approach and generated transgenic mice expressing
ATF3 in selective tissues. Our results are consistent with
the interpretation that the expression of ATF3 leads to
detrimental outcomes. Transgenic mice expressing ATF3 in the
heart under the control of the As described previously (21) and under "Experimental Procedures,"
the TTR-ATF3 transgenic founders did not express detectable levels of the ATF3 transgene, presumably due to mosaicism or
silencing of the transgene. However, they could pass on the transgene
to their progeny, and the F1 mice expressed the ATF3
transgene. These mice had growth retardation and died within hours
after birth (21). The analyses of phenotypes were facilitated by the
generation of "F1 hybrid" between the transgenic founders (FVB/N
mice) and wild type BALB/c mice. The F1 hybrid had the
advantage of hybrid vigor and survived longer (for up to 7 days).
Consistent with the observations that the TTR promoter is
predominantly active in the liver (24-26), F1 transgenic mice derived
from all 24 founders expressed the ATF3 transgene in the
liver (21). However, F1 mice derived from some founders also expressed
the transgene in the pancreas, presumably due to the differences in the
integration sites and/or copy numbers of the transgene. Previously, we
described that the expression of ATF3 in the pancreatic
ductal epithelium impairs endocrine pancreas development (21). In this
report, we describe the hepatic phenotypes of these mice.
Because ATF3 is a stress-inducible gene and because
expression of ATF3 leads to detrimental outcomes in other
tissues (heart and pancreas as described above), we hypothesized that
transgenic mice expressing ATF3 in the liver have hepatic
dysfunction. Furthermore, because ATF3 is a transcriptional repressor
and because the PEPCK promoter contains an ATF/CRE site, we
hypothesized that ATF3 represses the PEPCK promoter,
providing a mechanistic explanation for the reduced expression of
PEPCK gene in the TTR-ATF3 transgenic mice. Below
we present evidence supporting these hypotheses.
The TTR-ATF3 Transgenic Mice--
The generation of these mice
was described previously (21). The human ATF3 open reading
frame was cloned into the pTTRexV3 vector to make the transgene, and
the transgenic mice were generated in the FVB/N background. The
transgenic founders did not express the transgene, presumably because
of mosaicism or silencing of the transgene but could pass on the
transgene to their progeny. The F1 mice expressed the gene and died
within hours after birth. Because of this perinatal lethality, it was
not possible to establish transgenic lines. Repeated injections were
carried out to generate 24 founders and thus sufficient F1 mice for
analysis. To facilitate the analyses of F1 mice, we crossed FVB/N
transgenic founders with BALB/c non-transgenic mice to generate
F1 hybrid mice. These F1 mice had the advantage of hybrid vigor and
survived longer. Most of them survived for 4 days, and some survived
for up to 7 days. Because the F1 hybrid mice are genetically uniform
except at the locus of the transgene, a comparison of the transgenic mice with the non-transgenic littermates allowed the assessments of
phenotypes attributed to ATF3 expression. As described
previously (21), F1 hybrids derived from all 24 founders expressed ATF3 transgene in the liver, but F1 hybrids derived from some founders also
expressed ATF3 in the pancreas. The pancreatic phenotypes were
described previously (21). In this report, we describe the hepatic
phenotypes. To avoid hepatic phenotypes resulting from indirect effects
of pancreatic expression of ATF3 (see "Discussion"), we only
describe the phenotypes observed in mice with hepatic but not
pancreatic expression of ATF3. Because not all founders gave
rise to progeny efficiently, detailed analyses were limited to a subset
of founders. The phenotypes described in this report were observed in
F1 hybrid mice derived from >8 founders. This reproducibility strongly
suggests that these phenotypes were not because of the artifacts of
integration sites.
Preparation and Staining of Tissue Sections--
Newborn mice
between postnatal days (P) 1 and 7 were sacrificed by decapitation.
Tissues were removed and rinsed in ice-cold phosphate-buffered saline
(PBS). For samples from embryos, the appearance of a vaginal plug was
considered to be day 0.5 of gestation. Embryos at embryonic day 18.5 were dissected in ice-cold PBS. Tissues or embryos were fixed for 1-3
days in 10% phosphate-buffered formalin (Fisher Scientific), pH 7.0, at 4 °C. Paraffin sections were prepared and stained by hematoxylin
and eosin or periodic acid-Schiff stain according to established
procedures by the Ohio State University Veterinary Histology Laboratory.
Serum Chemistry and Hormone Assays--
Newborn mice were
decapitated with scissors, and the blood was immediately collected in
microhematocrit capillary tubes (Fisher Scientific) and transferred to
MicrotainerTM serum-separator tubes (BD PharMingen). The
tubes were centrifuged according to the instruction from the
manufacturer, and the top layer (serum) was analyzed on the same day or
after storage. Serum Electrophoretic Mobility Shift Assay--
ATF3 protein was
generated using the vaccinia virus expression system and isolated from
HeLa cells as described previously (27). ATF3 generated by this system
specifically binds to an ATF/CRE site as demonstrated previously (27)
and by the competition and supershift experiments used in this study
(see Fig. 5A). DNA-binding reactions and gel electrophoresis
were carried out as described previously (11) using
32P-labeled double-stranded oligonucleotides containing the
ATF/CRE site derived from the PEPCK promoter,
5'-AGGGCCCCTTACGTCAGGGCGAGA-3' (ATF/CRE site is underlined).
Transient Transfection and Chloramphenicol Acetyltransferase
(CAT) Assay--
CAT reporter driven by the PEPCK promoter
( Because F1 mice derived from some TTR-ATF3 founders
also expressed ATF3 in the pancreas, we only describe
phenotypes obtained from mice with hepatic but not pancreatic
expression of ATF3 to exclude hepatic phenotypes resulting
from indirect effects of pancreatic expression of ATF3.
Importantly, the phenotypes described below were observed in F1 hybrid
mice derived from >8 founders. This reproducibility strongly suggests
that these phenotypes were not attributed to the artifacts of
integration sites.
Physiological and Biochemical Analyses of Transgenic Mice
Expressing ATF3 in the Liver--
Because the liver is the major organ
that maintains homeostasis of many endogenous substances (6), we
carried out a serum profile analysis to address whether the expression
of ATF3 in the liver affects its functions. As shown in
Figs. 1 and
2, serum levels of alkaline phosphatase,
bile acids, alanine transaminase, aspartate transaminase, and bilirubin
were significantly higher (p < 0.001) in the
transgenic mice than in the non-transgenic mice, indicating general
liver dysfunction. An analysis of conjugated versus
non-conjugated bilirubin indicated that both forms of bilirubin were
increased (p < 0.001) in transgenic mice (Fig. 2,
B and C), suggesting defects in the uptake or
conjugation of bilirubin by the liver and the release of bilirubin via
the biliary ducts. Because of the low body weight of the transgenic
mice, the volumes of blood collected from the newborn transgenic mice
were very low. Therefore, we combined sera from several mice for each
assay, and the results shown in Figs. 1 and 2 were derived from
multiple samples (from 12 to 35) with each sample containing sera
combined from 3 to 10 mice as indicated in the legends. We also
examined the serum for other compounds and found no significant
differences between the transgenic and non-transgenic mice in the
concentrations of sodium, potassium, calcium, chloride, phosphorus,
creatine kinase, serum urea nitrogen, cholesterol, lipase, albumin, and total protein (Table I).
As described previously, the serum glucose levels in these mice were
consistently lower than in the non-transgenic littermates (64 ± 7 versus 128 ± 26 mg/dl) (21). Radioimmunoassays
showed that these mice had lower insulin but higher glucagon levels
than the non-transgenic littermates (Table
II), indicating that the transgenic mice
had a proper hormonal response to low serum glucose levels (low
insulin:glucagon ratio). To assay insulin, glucagon, and glucose in
parallel from each sample, we combined sera from several mice to obtain
enough sera for all three assays. The results shown in Table II were
derived from five samples with each sample containing combined sera
from multiple mice as described in the legend.
To determine whether the mice could respond to these hormonal changes,
we examined the adipose tissue and serum ketone bodies. As shown in
Fig. 3A, the transgenic mice
had lower adipose tissue mass than the non-transgenic mice. This result
was reproduced in multiple mice; however, the relative degree of
decrease in white adipose tissue versus brown adipose tissue
varied among the mice. Despite this variation, the combined white
adipose tissue and brown adipose tissue was consistently lower in the
transgenic mice than that in the non-transgenic mice. The serum
Glycogenolysis, Gluconeogenesis, and the Repression of the PEPCK
Promoter by ATF3--
As described in the Introduction, glycogenolysis
and gluconeogenesis are activated in the liver during the perinatal
period to maintain glucose homeostasis. To investigate the glycogen
stores in the transgenic livers, we examined them by periodic
acid-Schiff stain. As shown in Fig. 4,
transgenic livers had high levels of magenta stain before birth at
embryonic day 18.5 but low levels after birth at P7, supporting the
notion that the transgenic newborns could use their glycogen stores via
glycogenolysis. We note two caveats in the interpretation of these
results. First, periodic acid-Schiff stains glycogen and other
substances such as mucopolysaccharides and glycolipids; therefore, it
is not absolutely specific for glycogen. Second, this assay does not
directly detect the activity of glycogen phosphorylase, an enzyme that
degrades glycogen to glucose 1-phosphate. Therefore, additional
experiments are required to make a definitive conclusion on
glycogenolysis.
The lack of magenta stain in the transgenic livers at P7 also suggests
that the mice could not replenish their glycogen store, consistent with
the reduced gluconeogenesis in these mice. As described previously
(21), the transgenic livers had a low level of PEPCK
mRNA, which encodes a key enzyme in the gluconeogenic pathway.
Because the PEPCK promoter contains an ATF/CRE site (29, 30)
and because ATF3 is a transcriptional repressor (31), it is possible
that ATF3 represses the expression of PEPCK gene, resulting
in reduced PEPCK mRNA levels. To test this possibility, we analyzed the ability of ATF3 to bind to the ATF/CRE site derived from the PEPCK promoter (PEPCK ATF/CRE site). As
shown by electrophoretic mobility shift assay, recombinant ATF3
isolated from a vaccinia virus expression system bound to the
PEPCK ATF/CRE site (Fig. 5A, lane 2). The
specificity of the binding is demonstrated by the observation that an
ATF3-specific antiserum shifted the mobility in the DNA-protein complex
(lane 3), but a nonspecific antiserum did not (lane
4). Furthermore, the formation of the DNA-protein complex was
inhibited by a DNA fragment containing the ATF/CRE sequence (lane
5).
To determine whether ATF3 represses the PEPCK promoter, we
transfected HepG2 hepatocytes with DNA expressing ATF3 and a
CAT reporter driven by the ATF3 in Stress-associated Liver Diseases--
In this report, we
demonstrated that transgenic mice expressing ATF3 in the
liver have decreased adipose tissue mass, disturbed glucose
homeostasis, and show signs of hepatic dysfunction (i.e. elevated levels of aspartate transaminase, alanine transaminase, alkaline phosphatase, bile acids, and bilirubin). Because
ATF3 is a stress-inducible gene and because many of the
hepatic phenotypes observed in the TTR-ATF3 mice resemble
those observed in stress-associated liver diseases, transgenic mice
expressing ATF3 may provide a good model to investigate how
stress-induced gene expression affects hepatic functions. Because of
the perinatal lethality and the small size of the transgenic mice,
repeated transgenic injections were necessary to obtain the results
described in this report. Therefore, transgenic mice expressing
ATF3 in an inducible manner would greatly facilitate further
mechanistic studies. As an example, one could investigate the
expression of genes encoding bile acid transporters and
bilirubin-conjugating enzymes to elucidate the mechanism for elevated
serum bile acids and bilirubin, two commonly observed changes in liver
diseases. In addition, one could make primary hepatocytes or nuclear
extracts from the mice to investigate the transcriptional programs in
the transgenic livers with ATF3 expression versus
those without ATF3 expression.
In this context, we note the differences between induction of
ATF3 and release of epinephrine and norepinephrine during a stress response. We showed in this report that ATF3 represses PEPCK gene expression, which would result in reduced
gluconeogenesis. However, epinephrine and norepinephrine release under
acute stress response activates the cAMP pathways and leads to
increased gluconeogenesis and glycogenolysis (5). Therefore,
different types of stress response have different physiological
significance. The release of epinephrine and norepinephrine increases
the blood glucose level that is critical for the organism to fight or
flee in an acute response. The induction of ATF3 affects the
transcriptional programs at the cellular level, which in turn sets
things in motion and contributes to the long term detrimental
consequences observed in many stress-associated diseases.
Repression of PEPCK Gene Expression by ATF3--
Previously, we
showed by Northern blot analysis that the PEPCK mRNA
level is lower in the livers of the TTR-ATF3 transgenic mice
than those in the non-transgenic mice (21). In this report, we showed
that ATF3 binds to the CRE site derived from the PEPCK promoter in an in vitro assay and represses the
PEPCK promoter in a transient transfection assay. Taken
together, these results support a model in which ectopic expression of
ATF3 in the transgenic livers represses the expression of
PEPCK, providing an explanation for the disturbed glucose
homeostasis observed in these mice. The PEPCK promoter has a
consensus ATF/CRE site, which plays a key role in the up-regulation of
PEPCK by the cAMP pathway (for review see Refs. 34 and 35
and references therein). When a PEPCK promoter with a
mutated ATF/CRE site was used in the assay, ATF3 did not repress the
promoter (data not shown), suggesting that ATF3 represses the
PEPCK promoter via the ATF/CRE site. However, we can not
rule out the possibility that ATF3 may repress the PEPCK
promoter by other mechanisms such as forming dimers with CCAAT/enhancer-binding protein or activating protein-1, which has been demonstrated to play important roles in the regulation of the
PEPCK promoter (for reviews see Refs. 34, 36, and 37). Because ATF3 is a stress-inducible gene, our results are
consistent with a previous report by Granner and colleagues (38) that
the expression of PEPCK gene is repressed by stress signals
in cultured hepatocytes. It is possible that stress signals inhibit
PEPCK expression, at least in part, by inducing
ATF3. However, more work is required to determine the
validity of this speculation. Recently, Magnuson and colleagues (39)
generated liver-specific PEPCK knock-out mice and
demonstrated that PEPCK plays a critical role in the
integration of multiple pathways in energy metabolism, a previously
unidentified function for PEPCK. Therefore, the decrease in
PEPCK gene expression in our transgenic mice may also
contribute to impairments in other metabolic pathways not examined in
the current study.
Disturbance of Hepatic Gene Expression and Its Effects on Liver
Function--
In this study, we used transgenic mice expressing
ATF3, a stress-inducible transcription factor gene, in the
liver to investigate how disturbance in transcriptional programs may
affect liver function. As described earlier, there are two groups of
TTR-ATF3 mice: group 1 had expression of ATF3 in
the liver, and group 2 had expression in the liver and pancreas. The
difference was "founder-specific." Founders giving rise to F1 mice
with the group 1 expression pattern always gave rise to F1 mice with
the group 1 expression pattern, and the same was true for the group 2 expression pattern. Presumably, the difference between groups 1 and 2 mice was because of the differences in the sites of integration
and/or copy numbers of the transgene. The hepatic phenotypes presented
under "Results" were all derived from the group 1 mice, which did
not express ATF3 in the pancreas. Therefore, they are not
because of the indirect effects of pancreatic defects. As an example of
this indirect phenotype, osmium tetroxide stain for lipid indicated
that the group 2 mice had fatty
liver,2 but the group 1 mice
did not. We suspect that the fatty liver phenotype in the group
2 mice was because of the deficiency of insulin, an important regulator
of lipid metabolism, in these mice (21).
Other genetically altered mice have been used to elucidate how
disturbance in transcriptional programs may affect liver function. Examples are knock-out mice deficient in
C/EBPa (40) or
C/EBP We thank Dr. R. Hanson for insightful
suggestions, Dr. P. Quinn for the reporters driven by the
PEPCK promoter, protocols, and helpful suggestions, and Drs.
G. Darlington, R. Costa, and C. Croniger for comments and discussions.
*
This study was supported in part by NIEHS, National
Institutes of Health Grant 08690 and grants from the American Diabetes Association, Central Ohio Cancer Research Associates, and Central Ohio
Diabetes Association (to T. H.).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: Room 148, Rightmire
Hall, 1060 Carmack Rd., Ohio State University, Columbus, OH 43210. E-mail: hai.2@osu.edu.
Published, JBC Papers in Press, March 26, 2002, DOI 10.1074/jbc.M200727200
2
A. E. Jennings, G. J. Kociba,
and T. Hai, unpublished results.
The abbreviations used are:
ATF3, activating transcription factor 3;
CRE, cAMP-responsive element;
CREB, cAMP-responsive element-binding protein;
PEPCK, phosphoenolpyruvate
carboxykinase;
TTR, transthyretin;
CAT, chloramphenicol
acetyltransferase;
PBS, phosphate-buffered saline;
Txg, transgenic;
Non-Txg, non-transgenic;
P, postnatal day.
The Roles of ATF3 in Liver Dysfunction and the
Regulation of Phosphoenolpyruvate Carboxykinase Gene Expression*
§¶
,§**,, and§¶**§§
Department of Molecular and Cellular
Biochemistry, the § Neurobiotechnology Center, ¶ Ohio
State Biochemistry Program, ** Molecular, Cellular, and
Developmental Biology Program, and
Veterinary Biosciences, Ohio State
University, Columbus, Ohio 43210
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-myosin heavy chain promoter exhibit
conduction abnormality and contractile dysfunction (22). Transgenic
mice expressing ATF3 under the control of the transthyretin
(TTR) promoter, a promoter that is predominantly active in
the liver but could also be active in the pancreas (23), have defects
in glucose homeostasis and reduced expression of the gene encoding the
gluconeogenic enzyme phosphoenolpyruvate carboxykinase
(PEPCK) (21). In the rest of this report, we refer to these
mice as the TTR-ATF3 mice.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-hydroxybutyrate levels were determined using
the -hydroxybutyrate dehydrogenase method (Sigma). All other serum
tests were performed according to the instructions from the
manufacturer (Roche Molecular Biochemicals) on an automated discrete
random access multianalysis clinical chemistry analyzer (Hitachi 911 Analyzer, Roche Molecular Biochemicals). All analyses described above
were performed by the Ohio State University Veterinary Teaching
Hospital Clinical Chemistry Laboratory. Serum insulin and glucagon
levels were measured by radioimmunoassay at Linco (St. Charles, MO).
Because of the low body weight and low blood volume of the transgenic
mice, sera from multiple mice were combined to generate each
data point. Student's t test was used to analyze the data,
and the p values are indicated in the figure legends.
600 to +69 region) was transfected into HepG2 cells with effector
DNAs (pCG, PCG-ATF3, or pCG-ATF4) using the calcium phosphate method
with modifications. 350 µl of 2× Hepes-buffered saline (28) were
gradually added to 350 µl of solution containing 12 µg of
PEPCK-CAT reporter and 2 µg of effector in 0.25 M CaCl2 with constant mixing to make total 700 µl of a DNA mixture. The mixture was allowed to incubate at room
temperature for 30 min to form DNA precipitates before being added to
the cell suspension prepared as follows. The cells from two 10-cm
plates at 70% confluency were washed with PBS, trypsinized, and
resuspended in 800 µl of medium. The cell suspension with the
DNA mixture was incubated at room temperature for 15 min and divided
into three 6-cm plates containing 2 ml of medium. These plates were
incubated at 37 °C with 5% CO2. 16 h later, cells
were shocked with 20% glycerol for 2 min, washed with PBS three times,
and incubated with media containing 1 µM dexamethasone (0.5 mM stock prepared in ethanol, Sigma) and 20 µM forskolin (10 mM stock prepared in
ethanol, Sigma) to induce the PEPCK promoter. 48 h
later, cells were washed with PBS, and the CAT activity was measured by
a phase extraction method (28). A mock transfection was carried out
using 12 µg of pGEM3 to make the DNA mixture.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (20K):
[in a new window]
Fig. 1.
Transgenic mice had symptoms indicative of
general liver dysfunction. Alkaline phosphatase
(A), bile acids (B), ALT (C), and AST
(D) levels were determined from mice at ages of P1-P7.
Alk. PTase, alkaline phosphatase; ALT, alanine
transaminase; AST, aspartate transaminase; U/L,
units/liter. Data represent the mean ± S.E. from multiple samples
(Alk. PTase = >35 samples; bile acids, AST, and ALT = >12
samples) with each sample containing sera combined from 3-10 mice.
*, p < 0.001 versus
Non-Txg.
View larger version (12K):
[in a new window]
Fig. 2.
Transgenic mice had defects in the
conjugation and release of bilirubin. Total bilirubin
(A), conjugated bilirubin (Con.) (B),
and unconjugated bilirubin (Uncon.) (C) were
determined from mice at ages of P1-P7. Data represent the mean ± S.E. from 35 samples with each sample containing sera combined from
3-10 mice. *, p < 0.001 versus
Non-Txg.
Comparison of serum biochemical parameters
18 samples with the exception of lipase
(n = 3). Each sample contained combined serum from 3-4
mice. No significant difference was observed in these parameters. SUN,
serum urea nitrogen.
Serum insulin and glucagon levels
-hydroxybutyrate levels were slightly higher in the transgenic mice
than that in the non-transgenic mice; however, the difference was not
statistically significant (Fig. 3B). The presence of
-hydroxybutyrate indicates that the transgenic mice could carry out
-oxidation to produce ketone bodies. Because of the low blood volume
described above, the results of -hydroxybutyrate were derived from
samples with combined sera as detailed in the figure legends. Taken
together, these results indicate that the transgenic mice had a proper
hormonal response to low serum glucose levels (low insulin:glucagon
ratio) and could respond to the hormonal change by mobilizing fat or reduced adipose tissue mass and carrying out -oxidation.
View larger version (40K):
[in a new window]
Fig. 3.
Txg mice had reduced adipose tissue mass but
comparable -hydroxybutyrate levels when
compared with Non-Txg mice. A, transverse sections of
the neck from P7 mice were stained with hematoxylin and eosin.
Dotted lines delineate the adipose tissue, which includes
white adipose tissue and brown adipose tissue. Magnification = ×20. B, serum -hydroxybutyrate levels were determined
from mice at ages of P1-P7. Data represent the mean ± S.E. from
10 samples with each sample containing combined sera from 3-10 mice.
The difference was not statistically significant (p = 0.11).
View larger version (98K):
[in a new window]
Fig. 4.
Glycogenolysis most probably was not affected
in the transgenic mice. Liver sections from Txg and Non-Txg mice
either before birth at embryonic day 18.5 (E18.5) or after
birth at P7 were stained with periodic acid-Schiff reagent. Periodic
acid-Schiff stain (magenta) was strongly positive in livers
of transgenic mice at E18.5 but low at P7, consistent with the
interpretation that they could utilize their glycogen stores (most
probably via glycogenolysis) but not replenish it. Magnification = ×400; bar = 20 µm.
View larger version (36K):
[in a new window]
Fig. 5.
ATF3 bound to the ATF/CRE site on the
PEPCK promoter and repressed the activity of the
PEPCK promoter. A, electrophoretic
mobility shift assay. A radiolabeled DNA fragment containing the
ATF/CRE consensus sequence from the PEPCK promoter was used
for electrophoretic mobility shift assay in the absence (lane
1) or presence of recombinant ATF3 isolated from a vaccinia
expression system (lanes 2-5). Specific antiserum against
ATF3 (Sp, lane 3) or nonspecific antiserum
(NS, lane 4) was added in the supershift
experiment. Lane 5 contains unlabeled competitor DNA at the
molar ratio of 100 relatively to the radiolabeled probe. B,
CAT assay. HepG2 hepatocytes were transfected with a CAT reporter
driven by the PEPCK promoter ( 600 to +69 region) and the
indicated effectors, pCG vector (, the reporter only control),
pCG-ATF3, which encodes ATF3, or pCG-ATF4, which encodes ATF4, a
transcriptional activator (33). Mock transfection with pGEM3 was
carried out to determine the basal CAT activity in the HepG2 extract.
Dexamethasone and forskolin were added as described under
"Experimental Procedures" to increase the promoter activity that
was low in the absence of the treatment (data not shown). The percent
of CAT activity was calculated by subtracting the basal activity and
arbitrarily defining the reporter only control as 100%. Data were the
mean ± S.E. derived from five experiments with duplicate or
triplicate assays in each experiment. *, p < 0.0001 versus reporter only control.
600 to +69 region of the PEPCK
promoter. This region of the PEPCK promoter contains the
ATF/CRE site and has been demonstrated to mediate the up-regulation of
PEPCK gene expression by the cAMP pathway (29, 30, 32). To
address transcriptional repression, we activated the PEPCK
promoter with dexamethasone and forskolin and asked whether ATF3 could
repress the promoter. As shown in Fig. 5B, ATF3 repressed
the PEPCK promoter. However, ATF4, a transactivator that
also binds to the ATF/CRE site (33), further activated the promoter.
Therefore, not all members of the ATF/CREB family could repress the
PEPCK promoter.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
(41). These studies indicate
that the disturbance in transcriptional program impairs liver function
and affects glucose homeostasis. Therefore, our results are consistent
with previous findings. However, our results add a dimension of stress.
Because ATF3 is a stress-inducible gene, our results
indicate that stress signals may affect hepatic functions, at least in
part, by inducing ATF3 and perturbing the normal hepatic
gene expression patterns.
ACKNOWLEDGEMENTS
FOOTNOTES
Present address: CuraGen Corporation, 555 Long Wharf Dr., New
Haven, CT 06511.
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1.
Girard, J. R.,
Cuendet, G. S.,
Marliss, E. B.,
Kervran, A.,
Rieutort, M.,
and Assan, R.
(1973)
J. Clin. Invest.
52,
3190-3200[Medline]
[Order article via Infotrieve]
2.
Girard, J.,
Ferre, P.,
Pegorier, J. P.,
and Duee, P. H.
(1992)
Physiol. Rev.
72,
507-562 3.
Ballard, F. J.,
and Hanson, R. W.
(1967)
Biochem. J.
104,
866-871[Medline]
[Order article via Infotrieve]
4.
McGrane, M. M.,
Yun, J. S.,
Patel, Y. M.,
and Hanson, R. W.
(1992)
Trends Biochem. Sci.
17,
40-44[CrossRef][Medline]
[Order article via Infotrieve]
5.
Stryer, L.
(1995)
Biochemistry
, pp. 569-602, W. H. Freeman and Company, New York
6.
Arias, I. M.,
Boyer, J. L.,
Fausto, N.,
Jakoby, W. B.,
Schachter, D.,
and Shafritz, D. A.
(1994)
The Liver: Biology and Pathobiology
, Raven Press, Ltd., New York
7.
Hai, T.,
and Hartman, M. G.
(2001)
Gene (Amst.)
273,
1-11[CrossRef][Medline]
[Order article via Infotrieve]
8.
Brindle, P. K.,
and Montminy, M. R.
(1992)
Curr. Opin. Genet. Dev.
2,
199-204[CrossRef][Medline]
[Order article via Infotrieve]
9.
Meyer, T. E.,
and Habener, J. F.
(1993)
Endocr. Rev.
14,
269-290[CrossRef][Medline]
[Order article via Infotrieve]
10.
Sassone-Corsi, P.
(1994)
EMBO J.
13,
4717-4728[Medline]
[Order article via Infotrieve]
11.
Hai, T.,
Liu, F.,
Coukos, W. J.,
and Green, M. R.
(1989)
Genes Dev.
3,
2083-2090 12.
Hsu, J.-C.,
Laz, T.,
Mohn, K. L.,
and Taub, R.
(1991)
Proc. Natl. Acad. Sci. U. S. A.
88,
3511-3515 13.
Drysdale, B.-E.,
Howard, D. L.,
and Johnson, R. J.
(1996)
Mol. Immunol.
33,
989-998[CrossRef][Medline]
[Order article via Infotrieve]
14.
Farber, J. M.
(1992)
Mol. Cell. Biol.
12,
1535-1545 15.
Ishiguro, T.,
Nakajima, M.,
Naito, M.,
Muto, T.,
and Tsuruo, T.
(1996)
Cancer Res.
56,
875-879 16.
Hai, T.,
Wolfgang, C. D.,
Marsee, D. K.,
Allen, A. E.,
and Sivaprasad, U.
(1999)
Gene Expr.
7,
321-335[Medline]
[Order article via Infotrieve]
17.
Chen, B. P. C.,
Wolfgang, C. D.,
and Hai, T.
(1996)
Mol. Cell. Biol.
16,
1157-1168[Abstract]
18.
Haber, B. A.,
Mohn, K. L.,
Diamond, R. H.,
and Taub, R.
(1993)
J. Clin. Invest.
91,
1319-1326[Medline]
[Order article via Infotrieve]
19.
Weir, E.,
Chen, Q.,
DeFrances, M. C.,
Bell, A.,
Taub, R.,
and Zarnegar, R.
(1994)
Hepatology
20,
955-960[Medline]
[Order article via Infotrieve]
20.
Tsujino, H.,
Kondo, E.,
Fukuoka, T.,
Dai, Y.,
Tokunaga, A.,
Miki, K.,
Yonenobu, K.,
Ochi, T.,
and Noguchi, K.
(2000)
Mol. Cell. Neurosci.
15,
170-182[CrossRef][Medline]
[Order article via Infotrieve]
21.
Allen-Jennings, A. E.,
Hartman, M. G.,
Kociba, G. J.,
and Hai, T.
(2001)
J. Biol. Chem.
276,
29507-29514 22.
Okamoto, Y.,
Chaves, A.,
Chen, J.,
Kelley, R.,
Jones, K.,
Weed, H. G.,
Gardner, K. L.,
Gangi, L.,
Yamaguchi, M.,
Klomkleaw, W.,
Nakayama, T.,
Hamlin, R. L.,
Carnes, C. A.,
Altschuld, R. A.,
Bauer, J. A.,
and Hai, T.
(2001)
Am. J. Pathol.
159,
639-650 23.
Jacobsson, B.,
Collins, V. P.,
Grimelius, L.,
Pettersson, T.,
Sandstedt, B.,
and Carlstrom, A.
(1989)
J. Histochem. Cytochem.
37,
31-37[Abstract]
24.
Yan, C.,
Costa, R. H.,
Darnell, J. E.,
Chen, J. D.,
and Van Dyke, T. A.
(1990)
EMBO J.
9,
869-878[Medline]
[Order article via Infotrieve]
25.
Wu, H.,
Wade, M.,
Krall, L.,
Grisham, J.,
Xiong, Y.,
and Van Dyke, T.
(1996)
Genes Dev.
10,
245-260 26.
Ye, H.,
Holterman, A. X.,
Yoo, K. W.,
Franks, R. R.,
and Costa, R. H.
(1999)
Mol. Cell. Biol.
19,
8570-8580 27.
Wolfgang, C. D.,
Chen, B. P. C.,
Martindale, J. L.,
Holbrook, N. J.,
and Hai, T.
(1997)
Mol. Cell. Biol.
17,
6700-6707[Abstract]
28.
Ausubel, F. M.,
Brent, R.,
Kingston, R. E.,
Moore, D. D.,
Seidman, J. G.,
Smith, J. A.,
and Struhl, K.
(1993)
Current Protocols in Molecular Biology
, pp. 9.7.5-9.7.6, Greene Publishing Associates and Wiley-Interscience, New York
29.
Quinn, P. G.,
Wong, T. W.,
Magnuson, M. A.,
Shabb, J. B.,
and Granner, D. K.
(1988)
Mol. Cell. Biol.
8,
3467-3475 30.
Short, J. M.,
Wynshaw-Boris, A.,
Short, H. P.,
and Hanson, R. W.
(1986)
J. Biol. Chem.
261,
9721-9726 31.
Chen, B. P. C.,
Liang, G.,
Whelan, J.,
and Hai, T.
(1994)
J. Biol. Chem.
269,
15819-15826 32.
Roesler, W. J.,
Vandenbark, G. R.,
and Hanson, R. W.
(1989)
J. Biol. Chem.
264,
9657-9664 33.
Liang, G.,
and Hai, T.
(1997)
J. Biol. Chem.
272,
24088-24095 34.
Nizielski, S. E.,
Lechner, P. S.,
Croniger, C. M.,
Wang, N.-D.,
Darlington, G. J.,
and Hanson, R. W.
(1996)
J. Nutr.
126,
2697-2708 35.
Granner, D.,
O'Brien, R.,
Imai, E.,
Forest, C.,
Mitchell, J.,
and Lucas, P.
(1991)
Recent Prog. Horm. Res.
47,
319-346[Medline]
[Order article via Infotrieve]
36.
Darlington, G. J.,
Wang, N.,
and Hanson, R. W.
(1995)
Curr. Opin. Genet. Dev.
5,
565-570[CrossRef][Medline]
[Order article via Infotrieve]
37.
Croniger, C.,
Leahy, P.,
Reshef, L.,
and Hanson, R. W.
(1998)
J. Biol. Chem.
273,
31629-31632 38.
Sutherland, C.,
Tebbey, P. W.,
and Granner, D. K.
(1997)
Diabetes
46,
17-22[Abstract]
39.
She, P.,
Shiota, M.,
Shelton, K. D.,
Chalkley, R.,
Postic, C.,
and Magnuson, M. A.
(2000)
Mol. Cell. Biol.
20,
6508-6517 40.
Wang, N. D.,
Finegold, M. J.,
Bradley, A., Ou, C. N.,
Abdelsayed, S. V.,
Wilde, M. D.,
Taylor, L. R.,
Wilson, D. R.,
and Darlington, G. J.
(1995)
Science
269,
1108-1112 41.
Croniger, C. M.,
Millward, C.,
Yang, J.,
Kawai, Y.,
Arinze, I. J.,
Liu, S.,
Mariko,
Harada-Shiba, M.,
Chakravarty, K.,
Friedman, J. E.,
Poli, V.,
and Hanson, R. W.
(2000)
J. Biol. Chem.
276,
629-638
Copyright © 2002 by The American Society for Biochemistry and Molecular Biology, Inc.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati What's this?
This article has been cited by other articles:
|
|
 |
|
  M. T. Flowers, M. P. Keller, Y. Choi, H. Lan, C. Kendziorski, J. M. Ntambi, and A. D. Attie Liver gene expression analysis reveals endoplasmic reticulum stress and metabolic dysfunction in SCD1-deficient mice fed a very low-fat diet Physiol Genomics, May 1, 2008; 33(3): 361 - 372. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 D. Li, X. Yin, E. J. Zmuda, C. C. Wolford, X. Dong, M. F. White, and T. Hai The Repression of IRS2 Gene by ATF3, a Stress-Inducible Gene, Contributes to Pancreatic {beta}-Cell Apoptosis Diabetes, March 1, 2008; 57(3): 635 - 644. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 S. Bandyopadhyay, Y. Wang, R. Zhan, S. K. Pai, M. Watabe, M. Iiizumi, E. Furuta, S. Mohinta, W. Liu, S. Hirota, et al. The Tumor Metastasis Suppressor Gene Drg-1 Down-regulates the Expression of Activating Transcription Factor 3 in Prostate Cancer Cancer Res., December 15, 2006; 66(24): 11983 - 11990. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
H. B. Kim, M. Kong, T. M. Kim, Y. H. Suh, W.-H. Kim, J. H. Lim, J. H. Song, and M. H. Jung NFATc4 and ATF3 Negatively Regulate Adiponectin Gene Expression in 3T3-L1 Adipocytes. Diabetes, May 1, 2006; 55(5): 1342 - 1352. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 D. Lu, C. D. Wolfgang, and T. Hai Activating Transcription Factor 3, a Stress-inducible Gene, Suppresses Ras-stimulated Tumorigenesis J. Biol. Chem., April 14, 2006; 281(15): 10473 - 10481. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
J. S. Huo, R. C. McEachin, T. X. Cui, N. K. Duggal, T. Hai, D. J. States, and J. Schwartz Profiles of Growth Hormone (GH)-regulated Genes Reveal Time-dependent Responses and Identify a Mechanism for Regulation of Activating Transcription Factor 3 By GH J. Biol. Chem., February 17, 2006; 281(7): 4132 - 4141. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 A. B. Keeton, K. D. Bortoff, J. L. Franklin, and J. L. Messina Blockade of Rapid Versus Prolonged Extracellularly Regulated Kinase 1/2 Activation Has Differential Effects on Insulin-Induced Gene Expression Endocrinology, June 1, 2005; 146(6): 2716 - 2725. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 K.-T. Chin, H.-J. Zhou, C.-M. Wong, J. M.-F. Lee, C.-P. Chan, B.-Q. Qiang, J.-G. Yuan, I. O.-l. Ng, and D.-Y. Jin The liver-enriched transcription factor CREB-H is a growth suppressor protein underexpressed in hepatocellular carcinoma Nucleic Acids Res., March 30, 2005; 33(6): 1859 - 1873. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 M. G. Hartman, D. Lu, M.-L. Kim, G. J. Kociba, T. Shukri, J. Buteau, X. Wang, W. L. Frankel, D. Guttridge, M. Prentki, et al. Role for Activating Transcription Factor 3 in Stress-Induced {beta}-Cell Apoptosis Mol. Cell. Biol., July 1, 2004; 24(13): 5721 - 5732. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
H.-Y. Jiang, S. A. Wek, B. C. McGrath, D. Lu, T. Hai, H. P. Harding, X. Wang, D. Ron, D. R. Cavener, and R. C. Wek Activating Transcription Factor 3 Is Integral to the Eukaryotic Initiation Factor 2 Kinase Stress Response Mol. Cell. Biol., February 1, 2004; 24(3): 1365 - 1377. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
J. Wang, Y. Cao, and D. F. Steiner Regulation of Proglucagon Transcription by Activated Transcription Factor (ATF) 3 and a Novel Isoform, ATF3b, through the cAMP-response Element/ATF Site of the Proglucagon Gene Promoter J. Biol. Chem., August 29, 2003; 278(35): 32899 - 32904. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
Y. Olswang, B. Blum, H. Cassuto, H. Cohen, Y. Biberman, R. W. Hanson, and L. Reshef Glucocorticoids Repress Transcription of Phosphoenolpyruvate Carboxykinase (GTP) Gene in Adipocytes by Inhibiting Its C/EBP-mediated Activation J. Biol. Chem., April 4, 2003; 278(15): 12929 - 12936. [Abstract] [Full Text] [PDF]
|
|
| ||
