(Received for publication, February 3, 1997, and in revised form, March 4, 1997)
From the Department of Molecular Physiology and
Biophysics, Vanderbilt University Medical School, Nashville, Tennessee
37232 and the § Department of Genetics, University of
Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104
Glucose-6-phosphatase (G6Pase) catalyzes the
final step in the gluconeogenic and glycogenolytic pathways. The
transcription of the gene encoding the catalytic subunit of G6Pase is
stimulated by glucocorticoids, whereas insulin strongly inhibits both
basal G6Pase gene transcription and the stimulatory effect of
glucocorticoids. To identify the insulin response sequence (IRS) in the
G6Pase promoter through which insulin mediates its action, we have
analyzed the effect of insulin on the basal expression of mouse
G6Pase-chloramphenicol acetyltransferase (CAT) fusion genes transiently
expressed in hepatoma cells. Deletion of the G6Pase promoter sequence
between 271 and
199 partially reduces the inhibitory effect of
insulin, whereas deletion of additional sequence between
198 and
159 completely abolishes the insulin response. The presence of this multicomponent IRS may explain why insulin potently inhibits basal G6Pase-CAT expression. The G6Pase promoter region between
198 and
159 contains an IRS, since it can confer an inhibitory effect of
insulin on the expression of a heterologous fusion gene. This region
contains three copies of the T(G/A)TTTTG sequence, which is the core
motif of the phosphoenolpyruvate carboxykinase (PEPCK) gene IRS. This
suggests that a coordinate increase in both G6Pase and PEPCK gene
transcription is likely to contribute to the increased hepatic glucose
production characteristic of patients with
non-insulin-dependent diabetes mellitus.
While insulin has long been known to modulate intracellular metabolism by altering the activity or intracellular location of various enzymes, it is only more recently that the regulation of gene transcription by insulin has been recognized as a major action of this hormone (1). cis-Acting elements that mediate the action of insulin on gene transcription, referred to as an insulin response sequences or elements (IRSs/IREs),1 have been identified in a number of genes but, unlike cAMP (2, 3), which regulates gene transcription predominantly through one cis-acting element, it is already apparent that a single consensus IRS does not exist (1). Instead, most of the sequences identified to date appear unique, a situation that resembles that for phorbol esters that regulate gene transcription through at least eight distinct consensus sequences (4).
Non-insulin-dependent diabetes mellitus (NIDDM) is characterized by defects in insulin secretion, peripheral glucose utilization, and hepatic glucose production (HGP) (5). The ability of insulin to stimulate peripheral glucose utilization and repress HGP in patients with NIDDM is reduced, a phenomenon known as insulin resistance (5). Various investigators have speculated that an alteration in the insulin-regulated expression of specific genes, a consequence of insulin resistance, may contribute to the pathophysiology of this disease (1, 5, 6). The gene encoding the glucose-6-phosphatase (G6Pase) catalytic subunit (7) is one such candidate, since it catalyzes the final step in the gluconeogenic pathway, the conversion of glucose-6-phosphate to glucose (8). The activity (9, 10) and mRNA level (10-12) of the G6Pase catalytic subunit is increased in diabetic animals, and this contributes to increased fasting HGP (13). Experiments in FAO rat hepatoma cells (14) and primary hepatocytes (15) have shown that insulin treatment reduces both basal and glucocorticoid-induced G6Pase mRNA levels. Since the increased fasting HGP characteristic of NIDDM may be explained, in part, by an increase in G6Pase gene expression resulting from a loss of insulin repression, it is of interest to determine the mechanism whereby insulin normally inhibits G6Pase gene expression. This manuscript describes the identification of a potent IRS in the G6Pase promoter.
[-32P]dATP (>3000 Ci
mmol
1) and [3H]acetic acid, sodium salt
(>10 Ci mmol
1) were obtained from Amersham Corp. and
ICN, respectively. Insulin was purchased from Collaborative
Bioproducts. All other chemicals were of the highest grade
available.
DNA
manipulations were accomplished by standard techniques (16). A mouse
liver genomic library (129SV, Lambda FIX II vector) (Stratagene)
was screened with a probe encoding the rat glucose-6-phosphatase cDNA open reading frame (EcoRI/HindIII
fragment) (12). DNA from positive clones was digested with
NotI and EcoRI, and DNA restriction fragments
were separated by agarose gel electrophoresis, transferred to a
nitrocellulose membrane, and sequentially hybridized with the rat
glucose-6-phosphatase open reading frame cDNA probe and an
oligonucleotide spanning nucleotides 25-47 of exon 1 of the published
genomic sequence of the mouse glucose-6-phosphatase gene (17)
(5
-GCTTGGACTCACTGCACGGGCTC-3
). A 2.015-kilobase pair
NotI/EcoRI restriction fragment of the genomic
clone hybridized with both probes and corresponded to the
EcoRI fragment spanning exon 1 of the published restriction
digest map (17). NotI/EcoRI-digested genomic DNA
was ligated into Bluescript SK+ at the EcoRI site and
transformed into JM109 bacteria. Transformants were screened for the
presence of the 2.1-kilobase pair genomic DNA EcoRI
fragment, and the presence of the correct insert was confirmed by
Southern blot analysis with the 5
exon I probe described above. The
EcoRI genomic fragment was sequenced with a ABI PRISM
automated sequencer and contained 751 bp of 5
-flanking region, exon 1 (311 bp) and 952 bp of the first intron.
The orientation of all subcloned DNA
fragments was determined by restriction enzyme analysis and confirmed
by DNA sequencing using the U. S. Biochemical Corp. Sequenase kit. A
fragment of the mouse G6Pase promoter from 751 to +66, relative to
the transcription start site, was ligated into the polylinker of the
pCAT(An) expression vector, a generous gift from Dr. Howard Towle (18).
A series of truncated G6Pase-CAT fusion genes was generated by either
restriction enzyme digestion or polymerase chain reaction, using
standard techniques (16), with the 5
end points shown in Fig. 2. All promoter fragments generated by polymerase chain reaction were completely sequenced to ensure the absence of polymerase errors, whereas promoter fragments generated by restriction enzyme digestion were only sequenced to confirm the 5
end points.
Plasmid TKC-VI, kindly provided by Dr. Thomas Sudhof (19), contains the
herpes simplex virus thymidine kinase (TK) promoter ligated to the CAT
gene. The TK promoter sequence extends from 480 to +51 and contains a
BamHI linker between positions
40 and
35 (Fig.
3B). Various double-stranded oligonucleotides representing the G6Pase promoter sequence between
197 and
159 (Fig.
3A) were synthesized with BamHI-compatible ends
using a Perceptive Biosystems Nucleic Acid Synthesis System and were
cloned in either orientation into BamHI-cleaved TKC-VI by
standard techniques (16). All plasmid constructs were purified by
centrifugation twice through cesium chloride gradients (16).
Cell Culture and Transient Transfection
(a) Rat
H4IIE hepatoma cells were grown to 40-70% confluence in T150 flasks
in -modified Eagle's medium containing 2% (v/v) fetal calf serum,
3% (v/v) newborn calf serum, and 5% (v/v) calf serum and were then
transiently transfected in solution using the calcium phosphate-DNA
co-precipitation method as described previously (20). Where appropriate
(Fig. 1), an expression vector (5 µg) encoding the glucocorticoid
receptor, a generous gift from Dr. Keith Yamamoto (21), was
co-transfected with the reporter gene construct (15 µg).
(b) Human HepG2 cells were grown to 40-70% confluence in
T150 flasks in Dulbecco's modified Eagle's medium containing 2.5% (v/v) newborn calf serum and 2.5% (v/v) fetal calf serum and 5% (v/v)
NuSerum IV (Collaborative Research, Inc.) and were then transiently
transfected in solution using the calcium phosphate-DNA co-precipitation method as described previously (22). Expression vectors encoding -galactosidase (2.5 µg) and/or the insulin
receptor (5 µg), a generous gift from Dr. Jonathan Whittaker (23),
were co-transfected with the reporter gene construct (15 µg).
CAT and -galactosidase
assays were performed exactly as described previously (24). Since
-galactosidase is very poorly expressed in H4IIE cells (20, 22), CAT
activity was corrected for the protein concentration in the cell
lysate, as measured by the Pierce BCA assay, and each plasmid construct
was transfected multiple times. CAT activity expressed in HepG2 cells
was either corrected for the protein concentration in the cell lysate
or
-galactosidase activity. Both methods gave similar results
(Fig.2B).
To study the molecular mechanism whereby
insulin inhibits G6Pase gene expression, the promoter of the mouse
G6Pase gene was isolated (see "Experimental Procedures"). The start
site for mouse G6Pase gene transcription, previously reported by Shelly
et al. (17), is 1 bp 3 of that reported for the human gene
(25) but 5 bp 5
of that reported for the rat G6Pase gene (15).
A fragment of the mouse G6Pase promoter from 751 to +66, relative to
the transcription start site was ligated into the pCAT(An) expression
vector (18) and the resulting construct transiently transfected into
H4IIE cells. Fig. 1A shows that the hormonal regulation of this fusion gene construct mimics that of the endogenous rat G6Pase gene in FAO cells (14) and primary hepatocytes (15) as well
as a human G6Pase-CAT fusion gene expressed in H4IIE cells (25). Thus,
dexamethasone stimulates mouse G6Pase-CAT expression, but this effect
is blocked by insulin. This pattern of regulation is similar to that
seen with a PEPCK-CAT reporter gene containing the promoter region from
468 to +69 (Fig. 1A; Ref. 24).
Insulin also inhibits the basal expression of the endogenous rat G6Pase and PEPCK genes in hepatoma cells (14, 26, 27). However, insulin represses only dexamethasone-stimulated, not basal PEPCK-CAT expression, following either transient (Fig. 1B) or stable (26) transfection. By contrast, insulin strongly represses both the dexamethasone-stimulated and the basal expression of a transiently transfected mouse G6Pase-CAT fusion gene (Fig. 1B). The reason for this discrepancy with respect to PEPCK regulation is unknown. However, as a consequence of this loss of appropriate basal regulation of PEPCK-CAT fusion gene expression, the identification of an IRS in the PEPCK promoter has proved to be a difficult problem (1). This is because of the need to elevate basal PEPCK-CAT expression, using dexamethasone or cAMP, to be able to study the negative effect of insulin (26). The potential co-localization of positive cis-acting elements required for the effects of dexamethasone and cAMP with negative IRSs has made the interpretation of such experiments difficult (1).
Deletion of the G6Pase Promoter Sequence betweenWe sought to make use of the observation that insulin
inhibits basal G6Pase-CAT expression to define a region of the promoter required for this action of insulin. The ability of insulin to inhibit
the basal expression of a series of 5-truncated G6Pase-CAT fusion
genes was analyzed by transient transfection of HepG2 cells (Fig.
2). Although the magnitude of the insulin effect is
greater in H4IIE cells (Fig. 1), basal G6Pase-CAT expression is higher in HepG2 cells (data not shown). In these experiments, an expression vector for the insulin receptor was co-transfected with the G6Pase-CAT fusion gene, since this has been shown to enhance the regulation of
gene transcription by insulin in cases where the number of endogenous
receptors is low (28). Fig. 2A shows that deletion of the
G6Pase promoter sequence between
271 and
199 (Region A) partially
reduces the inhibitory effect of insulin, whereas deletion of
additional sequence between
198 and
159 (Region B) completely
abolishes the remaining effect of insulin on G6Pase-CAT fusion gene
expression. These results are not explained by a loss of basal
G6Pase-CAT expression (Fig. 2B). The simplest
interpretations of these data are that either (i) Regions A and B each
contain an independent IRS, or (ii) only Region B contains an IRS
whereas Region A acts as an accessory element that enhances the action of a single IRS located in Region B. The latter is a common phenomenon in cAMP- and glucocorticoid-regulated gene transcription (29), but this
arrangement would be entirely novel with respect to insulin action on
gene transcription (1).
To determine whether Region B of the G6Pase promoter
is sufficient to mediate an effect of insulin on transcription,
double-stranded oligonucleotides representing this sequence (Fig.
3A) were synthesized and ligated into the
BamHI site of the heterologous TKC-VI vector (19). This
vector has previously been used to define an inhibitory sterol-responsive element in the low density lipoprotein receptor gene
promoter (19) and an inhibitory IRS in the PEPCK promoter (30). Insulin
has little effect on CAT expression directed by the basic TKC-VI vector
(Fig. 3B) but ligation of the wild-type G6Pase sequence from
position 197 to
159 into the BamHI site of TKC-VI
conferred an insulin-dependent, orientation-independent, inhibition of CAT expression following transient transfection of H4IIE
cells (Fig. 3B).
This region of the G6Pase promoter contains three copies of the
sequence T(G/A)TTT(T/G)(G/T) (Fig. 3A). The IRSs identified in the PEPCK, tyrosine aminotransferase (TAT) and apolipoprotein CIII
(ApoCIII) promoters all contain this same motif, whereas the IRS in the
insulin-like growth factor binding protein-1 (IGFBP-1) promoter has two
copies of this motif arranged as an inverted palindrome (20, 30-34).
Like G6Pase, insulin also inhibits the transcription of these other
genes. A mutational analysis of this motif has shown that mutation of
the "G/A" to "C" abolishes the effect of insulin (20). To
determine whether this same motif mediates the effect of insulin
through the 197 to
159 G6Pase promoter region, a double-stranded
oligomer that represents this G6Pase sequence, but in which all three
of the putative IRS motifs have been mutated, was also synthesized
(Fig. 3A). When this oligonucleotide was ligated into the
BamHI site of the TKC-VI vector, the resulting construct was
no longer able to mediate an effect of insulin on reporter gene
expression (Fig. 3B).
These results suggest that the G6Pase promoter region between 197 and
159 contains an IRS and that insulin inhibits the transcription of
the G6Pase gene, at least in part, through the same IRS and,
presumably, the same trans-acting factor that mediates the
effect of insulin on transcription of the PEPCK, TAT, IGFBP-1, and
ApoCIII genes. Several proteins have been identified that bind this
IRS, including members of the C/EBP (22) and HNF-3 (20, 31, 35)
transcription factor families. However, in no case does the binding of
one of these proteins correlate with the effect of insulin (20).
Instead, it has been hypothesized that an unidentified factor mediates
the negative effect of insulin through this element, perhaps by
interfering with the binding of HNF-3 (1).
The mouse G6Pase promoter sequence between 197 and
159 (Region B;
Fig. 2) is perfectly conserved in the rat G6Pase promoter (Fig.
3A; Ref. 15) and, with the exception of one base pair, also
conserved in the human G6Pase promoter (Fig. 3A; Ref. 25). By contrast, the mouse G6Pase promoter sequence between
271 and
199
(Region A; Fig. 2) is only partially conserved between mouse and human.
In addition, this region contains no homology with either Region B or
any of the known IRSs in other genes (1). Additional experimentation
will be required to determine whether Region A contains an independent
IRS or simply enhances the action of the IRS in Region B.
The expression of insulin-regulated genes would be expected to change in patients with NIDDM as a consequence of insulin resistance (1, 5, 6). In fact, since insulin normally inhibits G6Pase and PEPCK gene transcription, the overexpression of these genes, as a consequence of insulin resistance, may in part explain the increased rate of gluconeogenesis, and HGP that is the major cause of fasting hyperglycemia in NIDDM (36). Indeed, the activity of the hepatic "glucose cycle," between G6Pase and glucokinase, is altered in both patients with NIDDM (37) and in animal models of diabetes (13), and overexpression of the PEPCK gene in H4IIE cells (38) and transgenic mice (39) does result in unrestrained HGP.
Although the evidence currently only supports a secondary role for altered insulin-regulated gene expression in NIDDM, the first example of a disease state resulting from a primary defect in insulin-regulated gene transcription has recently been elucidated. Thus, hepatic ApoCIII gene transcription is normally inhibited by insulin (40), but some patients with hypertriglyceridemia have a mutation in the ApoCIII IRS that abolishes the ability of insulin to suppress ApoCIII gene transcription (32). Experiments in transgenic mice demonstrated that the resulting overexpression of ApoCIII is sufficient to cause hypertriglyceridemia (41). We have previously postulated that a similar mutation in the PEPCK IRS could contribute to increased HGP (1, 6). However, a recent study failed to detect such mutations in a population of human subjects with NIDDM (42). Moreover, a defect in insulin-regulated PEPCK gene transcription, while it could explain the increase in HGP could not, by itself, explain hepatic insulin resistance. Nevertheless, changes in gene expression are likely to play a major role in the pathophysiology of NIDDM as suggested by the recent identification of mutations in the transcription factors HNF-1 and HNF-4, resulting in a form of NIDDM called maturity-onset diabetes of the young (43, 44).
In summary, this paper describes the identification of a multicomponent IRS in the mouse G6Pase promoter. Future studies will focus on the identification of the cis-acting elements that mediate the stimulatory effect of glucocorticoids and cAMP on G6Pase transcription with the ultimate aim of understanding how insulin signaling through the G6Pase IRS blocks this induction.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U91573[GenBank].
We thank Daryl Granner, Howard Towle, Keith Yamamoto, and Jonathan Whittaker for generous gifts of the PEPCK-CAT, pCAT(An), glucocorticoid receptor, and insulin receptor expression vector plasmids, respectively. We also thank Cathy Caldwell for providing the H4IIE and HepG2 cell lines.