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Molecular and Cellular Biology, September 2000, p. 6704-6711, Vol. 20, No. 18
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Characterization of the Role of AMP-Activated Protein Kinase in the Regulation of Glucose-Activated Gene Expression Using Constitutively Active and Dominant Negative Forms of the Kinase

Angela Woods,1 Dalila Azzout-Marniche,2 Marc Foretz,2 Silvie C. Stein,1 Patricia Lemarchand,3 Pascal Ferré,2 Fabienne Foufelle,2 and David Carling1,*

Cellular Stress Group, MRC Clinical Sciences Centre, Imperial College School of Medicine, Hammersmith Hospital, London W12 0NN, United Kingdom,1 and U465 INSERM, Centre Biomédical des Cordeliers, F-75270 Paris Cedex 06,2 and U25 INSERM, Faculté de Médecine Necker-Enfants Malades, 75730 Paris Cedex 15,3 France

Received 3 April 2000/Returned for modification 19 May 2000/Accepted 20 June 2000


    ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

In the liver, glucose induces the expression of a number of genes involved in glucose and lipid metabolism, e.g., those encoding L-type pyruvate kinase and fatty acid synthase. Recent evidence has indicated a role for the AMP-activated protein kinase (AMPK) in the inhibition of glucose-activated gene expression in hepatocytes. It remains unclear, however, whether AMPK is involved in the glucose induction of these genes. In order to study further the role of AMPK in regulating gene expression, we have generated two mutant forms of AMPK. One of these (alpha 1312) acts as a constitutively active kinase, while the other (alpha 1DN) acts as a dominant negative inhibitor of endogenous AMPK. We have used adenovirus-mediated gene transfer to express these mutants in primary rat hepatocytes in culture in order to determine their effect on AMPK activity and the transcription of glucose-activated genes. Expression of alpha 1312 increased AMPK activity in hepatocytes and blocked completely the induction of a number of glucose-activated genes in response to 25 mM glucose. This effect is similar to that observed following activation of AMPK by 5-amino-imidazolecarboxamide riboside. Expression of alpha 1DN markedly inhibited both basal and stimulated activity of endogenous AMPK but had no effect on the transcription of glucose-activated genes. Our results suggest that AMPK is involved in the inhibition of glucose-activated gene expression but not in the induction pathway. This study demonstrates that the two mutants we have described will provide valuable tools for studying the wider physiological role of AMPK.


    INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

In the presence of insulin, high levels of glucose stimulate the transcription of a number of genes involved in the conversion of carbohydrates to lipids in the liver (15, 45). In primary rat hepatocytes in culture, the levels of mRNA encoding L-type pyruvate kinase (L-PK), fatty acid synthase (FAS), and spot 14 (S14) increase with increasing concentrations of glucose (5 to 25 mM) (10, 24, 33). The mechanism by which this occurs remains unclear, but metabolism of glucose to glucose-6-phosphate appears to be an essential step in the process (33). In this respect, insulin is required to increase the expression of glucokinase in the liver to allow conversion of glucose to glucose-6-phosphate (15). There is growing evidence to suggest that protein phosphorylation plays an important role in the regulation of glucose-activated gene expression. For example, okadaic acid, an inhibitor of protein phosphatase types 1 and 2A, has been shown to inhibit the glucose stimulation of S14 (40) and FAS (13) gene expression in cultured hepatocytes.

The AMP-activated protein kinase (AMPK) provides a potential candidate for a protein kinase involved in the regulation of glucose-activated genes. A significant clue regarding a possible role for AMPK in the regulation of gene transcription came from the finding that it is structurally and functionally related to the yeast protein kinase complex SNF1 (1, 40, 52). In yeast, the transcription of a number of genes is repressed by high concentrations of glucose (46). The kinase activity of SNF1 is essential for the derepression of these genes in yeast grown under conditions of glucose limitation (3). AMPK and SNF1 both form heterotrimeric complexes consisting of a catalytic subunit and two regulatory subunits. The amino acid sequences of the mammalian AMPK subunits are highly related to their counterparts in the SNF1 complex (1, 32, 40, 51), and the kinases show functional similarities (9, 50, 52). Taken together, these findings led us, and others (31), to speculate that AMPK may be involved in regulating gene transcription in mammals. Evidence that this may be the case came from studies in which AMPK in hepatocytes was activated by incubation with 5-amino-imidazolecarboxamide (AICA) riboside, leading to the inhibition of FAS, L-PK, and S14 gene expression by glucose (13, 31). These results imply that AMPK is involved in the repression of glucose-activated genes. However, AICA riboside is not a specific activator of AMPK (16, 28), and therefore the results obtained in these studies cannot be taken as unequivocal proof that AMPK was mediating this response. Furthermore, neither of these studies provided any information as to whether AMPK was involved in the activation process.

In order to investigate further the role of AMPK in the regulation of glucose-activated gene expression, we have developed two mutant forms of the kinase: one that acts as a constitutively active kinase (alpha 1312) and one that acts as a dominant negative inhibitor (alpha 1DN) of endogenous AMPK. We used adenovirus-mediated gene transfer to express these mutants at high levels in primary rat hepatocytes in culture. Expression of alpha 1312 results in a significant increase in AMPK activity and blocks the glucose activation of the FAS, L-PK, S14, and acetyl coenzyme A (acetyl-CoA) carboxylase (ACC) genes. In contrast, expression of alpha 1DN reduces endogenous AMPK activity by up to 75% but does not have any effect on the transcription of these genes. Taken together, these results point to a role for AMPK in the down-regulation of glucose-activated genes but suggest that it is not involved in their activation. To our knowledge this is the first study to use molecular reagents to modulate AMPK activity in order to determine the effects of the kinase on a downstream pathway. In addition to helping characterize the role of AMPK in the regulation of gene expression, these reagents should provide valuable tools for the further elucidation of the physiological role of AMPK.


    MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Animals. Animal studies were conducted according to French guidelines for the care and use of experimental animals. Female Wistar rats (200 to 300 g) were used for the isolation of hepatocytes.

Isolation and primary culture of rat hepatocytes and adenovirus infection. Hepatocytes were isolated exactly as described previously (13) using the collagenase method. After cell attachment, hepatocytes were cultured for 16 to 18 h in the presence of 5 mM glucose. Hepatocytes were infected with various titers of adenovirus (0 to 100 PFU/cell) and incubated in either 5 mM glucose and 100 nM insulin or 25 mM glucose and 100 nM insulin for up to 90 h, as indicated. The adenoviral infection protocol was carried out as previously described (14). In some cases, at the end of this period, AICA riboside (250 or 500 µM) was added to the media, and the cells were incubated for a further 1 to 4 h, as indicated. Approximately 8 × 106 cells on a 10-cm plate were lysed by the direct addition of 1.5 ml of 5× buffer A to the culture medium (6 ml) to give a final concentration of 50 mM Tris-HCl (pH 7.5), 50 mM NaF, 5 mM sodium pyrophosphate, 1 mM EDTA, 1 mM dithiothreitol, 10% glycerol, and 1% Triton X-100 (buffer A). Cellular debris was removed by centrifugation at 14,000 × g for 10 min at 4°C, and the resulting supernatant (cell lysate) was used for analysis of AMPK activity or Western blotting.

Construction of recombinant adenoviruses. cDNA encoding residues 1 to 312 of alpha 1, containing a mutation that alters threonine 172 to an aspartic acid (T172D) (41), was used to construct the recombinant adenovirus Ad.alpha 1312 as described previously (22). Briefly, the cDNA of alpha 1312 was subcloned into the shuttle vector pAdTrack-CMV. The resultant plasmid was linearized by the restriction endonuclease PmeI and cotransformed with the supercoiled adenoviral vector pAd-Easy1 into Escherichia coli strain BJ5183. Recombinants were selected by kanamycin resistance and screened by restriction endonuclease digestion. The recombinant adenoviral construct was cleaved with PacI and transfected into the packaging cell line HEK293.

cDNA encoding alpha 1, containing a mutation that alters aspartic acid residue 157 to alanine (41), was used to construct Ad.alpha 1DN. The cDNA was subcloned into the EcoRI/XhoI-linearized pDK6 shuttle vector (11) under the control of the cytomegalovirus IE promoter. The pDK6-alpha 1DN plasmid was cotransfected in HEK293 cells together with the ClaI-cut DNA of the E1a- adenovirus vector Ad.gal-nls (36). Recombinant Ad.alpha 1DN plaques were detected by amplification of viral DNA using alpha 1-specific primers, and one clone was further amplified in HEK293 cells. The adenovirus vector Ad.null, in which the expression cassette contains the major late promoter with no exogenous gene, was used as a control (30). Adenoviruses were propagated in HEK293 cells, purified by cesium chloride density centrifugation, and stored as previously described (30).

Antibodies and immunological reagents. An anti-Myc monoclonal antibody (clone 9E10 [12]) was used to detect the recombinant alpha 1 mutant proteins, which both contain the sequence EQKLISEEDL immediately after the initiating methionine residue (41). Sheep antibodies against the rat alpha 1 and alpha 2 subunits (53) and against the rat gamma 1 subunit (4) and rabbit antibodies against the rat beta 1 subunit (51) were produced as described previously. Anti-mouse, anti-rabbit, and anti-sheep antibodies conjugated to horseradish peroxidase and protein A and protein G conjugated to horseradish peroxidase were obtained from Bio-Rad. Protein G-Sepharose was from Sigma.

Immunoprecipitation and AMPK assays. AMPK was immunoprecipitated from 0.5 to 1.5 ml of cell lysate by incubation with either anti-alpha 1, anti-alpha 2, or anti-gamma 1 antibody bound to protein G-Sepharose for 2 h at 4°C. Recombinant alpha 1 proteins were immunoprecipitated from hepatocyte lysates using an anti-Myc (clone 9E10) antibody bound to protein G-Sepharose. Immune complexes were collected by brief centrifugation and washed extensively in buffer A. AMPK activity in the immune complex was determined by phosphorylation of the SAMS (full sequence: HMRSAMSGLHLVKRR) synthetic peptide substrate (53). At the end of the assay period, the immune complex was washed with buffer A to remove unreacted ATP, and proteins within the complex were resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and analyzed by Western blotting.

Western blotting. Samples were boiled in SDS sample buffer, resolved by SDS-PAGE, and transferred to a polyvinylidene difluoride (PVDF) membrane. The membrane was incubated for 1 h at room temperature in 10 mM Tris-HCl (pH 7.4) 0.5 M NaCl, and 0.5% (vol/vol) Tween 20 (TBST) containing 5% (wt/vol) low-fat milk powder. Following a 2-h incubation with primary antibody diluted in TBST containing 5% milk powder, blots were washed extensively with TBST at room temperature. Blots of crude lysates were incubated with the appropriate secondary antibody conjugated to horseradish peroxidase, whereas blots of immune complexes were probed with protein A or protein G conjugated to horseradish peroxidase. After further washing with TBST, the blots were developed using enhanced chemiluminescence (Boehringer Mannheim).

Isolation of total RNA and Northern blot analysis. Total cellular RNAs were extracted from cultured hepatocytes using guanidine thiocyanate (5) and prepared for Northern blot hybridization as previously described (7). Labeling of each cDNA probe with [alpha -32P]dCTP was performed by random priming. cDNA probes for albumin, ACC, FAS, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), L-PK, and S14 were used as previously described (14).

Statistical analysis. Results, expressed as the mean ± the standard error of the mean (SEM), were analyzed using a two-tailed unpaired Student t test.


    RESULTS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Expression of a constitutively active form of AMPK in hepatocytes. In a recent study, Crute et al. reported that truncation of AMPKalpha 1 at residue 312 yielded a polypeptide that no longer associated with the beta  and gamma  subunits but retained significant kinase activity (8). We subsequently showed that mutation of threonine 172 within the alpha  subunit, the major site phosphorylated by AMPK kinase (20), to an aspartic acid residue within this truncated protein prevented its inactivation by protein phosphatases (41). These findings indicated the potential of this mutant to act as a constitutively active kinase. In order to determine the effect of high-level expression of this mutant in primary rat hepatocytes, we constructed a recombinant adenovirus (Ad.alpha 1312). Following infection with Ad.alpha 1312, hepatocyte lysates were analyzed by Western blotting for expression of alpha 1312 and endogenous AMPK subunits. The recombinant alpha 1312 protein contains a Myc epitope tag at the N terminus, allowing detection with an anti-Myc antibody. The mutant protein was just detectable after 18 h with 3 PFU/cell, and the expression increased markedly with time and adenoviral titer (Fig. 1A). Expression of alpha 1312 did not have any significant effect on the amount of endogenous AMPK subunits present in total cell extracts. The antibodies used for detecting the alpha  subunit cross-react with both the alpha 1 and alpha 2 isoforms but do not recognize the truncated alpha 1312 mutant. In order to determine whether the truncated alpha 1312 protein associates in a complex with the beta  and gamma  subunits in hepatocytes, complex formation in anti-gamma or anti-Myc immunoprecipitates was analyzed by Western blotting (Fig. 1B). In immune complexes isolated with an anti-Myc antibody, which immunoprecipitates alpha 1312, the beta  and gamma  subunits were not detected, confirming that this mutant does not associate with the regulatory subunits. In contrast, immune complexes isolated with an anti-gamma antibody, which immunoprecipitates the endogenous AMPK complexes, contained readily detectable levels of both the beta  and gamma  subunits.


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  		FIG. 1.   Expression of alpha 1312 in hepatocytes. (A) Primary rat hepatocytes in culture were infected with Ad.alpha 1312 or Ad.null at either 3 or 30 PFU/cell. Cell lysates from hepatocytes harvested 18 or 24 h postinfection were analyzed by Western blotting for expression of the recombinant alpha 1312 protein (using an anti-Myc antibody) or the endogenous AMPK subunits (using either an anti-alpha antibody which recognizes both alpha 1 and alpha 2 isoforms, but not the truncated alpha 1312 protein, or an anti-beta or anti-gamma antibody). (B) Cell lysates from hepatocytes infected with Ad.alpha 1312 (30 PFU/cell for 24 h) were immunoprecipitated (IP) with either an anti-gamma antibody or an anti-Myc antibody. Immune complexes were resolved by SDS-PAGE, and the presence of the beta  and gamma  subunits was determined by Western blotting. In each case, a representative blot from two independent experiments is shown.

Expression of alpha 1312 resulted in significantly increased levels of AMPK activity present in cell lysates compared to those for control-infected cells (Ad.null). This increase in activity was greater than that detected following treatment of cells with AICA riboside (Fig. 2A). In order to measure the endogenous activity of AMPK, cell lysates were immunoprecipitated with an anti-gamma antibody, which immunoprecipitates native AMPK complexes but not recombinant alpha 1312 (Fig. 2B). Endogenous AMPK activity was unaffected by expression of alpha 1312, whereas the endogenous activity was stimulated approximately sixfold following treatment with 250 µM AICA riboside. Figure 2C shows that AMPK activity in immune complexes isolated using an anti-gamma antibody, i.e., endogenous AMPK, was stimulated four- to fivefold by 200 µM AMP and that the activity of alpha 1312, present in an anti-Myc immune complex, was not dependent on AMP. alpha 1312 activity was resistant to inactivation by treatment with protein phosphatase 2C (data not shown), confirming our previous finding that alpha 1312 is resistant to dephosphorylation (41). These results show that the expressed alpha 1312 protein acts as a constitutively active kinase, significantly increasing AMPK activity within primary rat hepatocytes.


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  		FIG. 2.   Activity of alpha 1312 in hepatocytes. Hepatocytes were grown in the presence of 25 mM glucose and 100 nM insulin and infected with either Ad.null or Ad.alpha 1312 (30 PFU/cell). Twenty-four hours postinfection, hepatocytes were incubated in the presence or absence of 250 µM AICA riboside (AICAR) for 1 h before harvesting. (A) Total activity (endogenous AMPK and expressed alpha 1312) was measured in cell lysates, without prior immunoprecipitation, using the SAMS peptide assay. (B) Endogenous AMPK activity was measured in immune complexes isolated by immunoprecipitation using an anti-gamma antibody bound to protein G-Sepharose. (C) AMPK activity present in either anti-gamma (endogenous) or anti-Myc (expressed alpha 1312) immunoprecipitates was measured in the absence (shaded bars) or presence (open bars) of 0.2 mM AMP. Activities shown are the mean ± the SEM from four experiments (A and B) or the average of two independent experiments assayed in duplicate (C). *** denotes a significant difference from the Ad.null value (P < 0.0005), and ** indicates that P was <0.005. Activities are plotted as picomoles of 32P incorporation/minutes per milliliter of lysate.

Inhibition of glucose-activated gene expression by AMPK. Members of our group and others have previously shown that activation of AMPK by AICA riboside blocks the glucose activation of a number of genes in hepatocytes (13, 31). We therefore determined the effect of expression of alpha 1312 on the transcription of glucose-activated genes. Figure 3 shows a Northern blot analysis of RNA from hepatocytes infected with either Ad.alpha 1312 or Ad.null. The expression of genes encoding FAS, L-PK, S14, and ACC was increased by incubating the cells in 25 mM glucose compared to results obtained with 5 mM glucose (Fig. 3). Consistent with the results of earlier studies, AICA riboside antagonized glucose activation of these genes. At 30 PFU/cell, expression of alpha 1312 almost totally abolished the increase in gene expression by 25 mM glucose, although this effect was far less apparent in cells where the mutant protein was expressed at a low level (3 PFU/cell). The expression of control genes (those for albumin and GAPDH) was not significantly affected by any of the treatments.


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  		FIG. 3.   Expression of alpha 1312 inhibits the transcription of glucose-activated genes in cultured hepatocytes. Hepatocytes were grown in medium containing either 5 mM glucose and 100 nM insulin (G5) or 25 mM glucose and 100 nM insulin (G25) and were infected with Ad.alpha 1312 (3 or 30 PFU/cell) or Ad.null (30 PFU/cell) and incubated for 18 h. At the end of this period, hepatocytes were treated with or without AICA riboside (AICAR) (250 µM) and incubated for 4 h. Total RNA was extracted, electrophoresed on a 1% agarose gel, and subjected to Northern blot analysis using cDNA probes encoding either FAS, L-PK, ACC, S14, albumin, or GAPDH. Blots were washed extensively and exposed to autoradiographic film at -70°C for 1 to 2 days. The blot shown is representative of two independent experiments.

Expression of a dominant negative form of AMPK in hepatocytes. Considering that an increase in AMPK activity, caused either by AICA riboside or by overexpression of alpha 1312, results in the inhibition of transcription of glucose-activated genes, it is tempting to speculate that in hepatocytes, inhibition of AMPK is the mechanism by which glucose induces the expression of these genes. To date, however, no specific inhibitors of AMPK have been reported, and so it has not been possible to test this hypothesis directly. In an attempt to address this problem, we undertook to develop a dominant negative mutant of AMPK, which would allow us to determine directly whether AMPK is involved in the induction of glucose-activated gene expression in hepatocytes.

Aspartate 157 within the alpha  subunit lies in the conserved DFG motif (subdomain VII in protein kinase catalytic subunits), which has been shown to be essential for MgATP binding in all protein kinases (26). Mutation of this residue to alanine, in either alpha 1 or alpha 2, yields an inactive kinase but does not have any effect on the binding of the beta  and gamma  subunits within the complex (41). Since formation of the heterotrimeric complex is essential for AMPK activity, we reasoned that overexpression of the inactive alpha 1 subunit (alpha 1DN) would act as a dominant negative inhibitor by competing with the native alpha  subunit for binding with beta  and gamma . We therefore used adenovirus-mediated gene transfer in primary rat hepatocytes to test this hypothesis.

Infection of primary rat hepatocytes with Ad.alpha 1DN led to the marked expression of the mutant alpha 1 subunit, detected by Western blotting of cell lysates using an anti-alpha 1 antibody, which was dependent on the adenoviral titer used for infection (Fig. 4A). Endogenous alpha 1 in control-infected cells (Ad.null) was barely detectable due to the low sensitivity of this antibody. Western blot analysis of immune complexes isolated using an anti-gamma antibody showed that as the expression of alpha 1DN increased, there was a concomitant decrease in the amount of alpha 2 present in AMPK complexes (Fig. 4B). In contrast, the levels of the beta  and gamma  subunits remained constant. These results imply that alpha 1DN competes with the native alpha  subunits for the binding of the beta  and gamma  subunits. Western blot analysis of the total level of AMPK subunits present in cell lysates following a time course of alpha 1DN expression showed that increasing expression of the inactive alpha 1 subunit had no significant effect on the expression of the endogenous beta  and gamma  subunits. Interestingly, however, the expression of alpha 2 decreased markedly with time after infection (Fig. 4C). These results suggest that as the endogenous alpha 2 subunit (and presumably the endogenous alpha 1 subunit) is displaced from the complex, it becomes relatively unstable and is removed from the cell.


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  		FIG. 4.   Expression of alpha 1DN in hepatocytes. (A) Hepatocytes in culture were infected with varying titers of Ad.alpha 1DN or Ad.null. Twenty-four hours after infection, cell lysates were resolved by SDS-PAGE, transferred to a PVDF membrane, and probed with an anti-alpha 1 antibody. The alpha 1-specific antibody used for detection recognizes both the endogenous alpha 1 subunit and the recombinant alpha 1 mutant protein. (B) Hepatocytes were infected with Ad.alpha 1DN (10 PFU/cell), and at varying times after infection, AMPK complexes were isolated by immunoprecipitation (IP) with an anti-gamma antibody. Proteins within the immune complex were resolved by SDS-PAGE, transferred to a PVDF membrane, and probed with either alpha 2-, beta -, or gamma -specific antibodies. A control lane shows the expression of the subunits in an immune complex isolated from hepatocytes infected for 90 h with Ad.null (10 PFU/cell). (C) Hepatocytes were infected with either Ad.alpha 1DN (10 PFU/cell) or Ad.null (10 PFU/cell). At various times after infection, total protein in cell lysates was analyzed for expression of alpha 1 and the endogenous alpha 2, beta , and gamma  subunits, using subunit-specific AMPK antibodies. In each case, a representative blot from two independent experiments is shown.

Effect of inactive alpha 1 on AMPK activity in hepatocytes. Hepatocytes that had been preincubated with AICA riboside to activate AMPK were used to study the effect of expression of alpha 1DN on AMPK activity. Using an anti-gamma antibody, which immunoprecipitates both the alpha 1 and alpha 2 isoforms (38), there was a decrease in kinase activity following expression of alpha 1DN. The degree of inhibition correlated with increasing expression of alpha 1DN (Fig. 5A). At 100 PFU/cell, there was approximately 70 to 75% inhibition of the AICA riboside-stimulated AMPK activity. Similar results were obtained after measuring AMPK activity in crude cell lysates or in a partially purified polyethylene glycol fraction of the kinase (data not shown). At titers of Ad.alpha 1DN that were greater than 100 PFU/cell, the hepatocytes became unviable. Virtually identical results were obtained when AMPK was immunoprecipitated with an alpha 2-specific antibody (Fig. 5B). We were not able to measure the effect on endogenous alpha 1 activity directly due to competition of the immunoprecipitating alpha 1-specific antibody by the high levels of recombinant alpha 1 subunit. Previously, however, it has been shown that alpha 1 and alpha 2 contribute almost equally to total AMPK activity in rat liver (38, 53). Since the total activity of AMPK falls by the same amount as the alpha 2-specific activity, our results imply that expression of alpha 1DN inhibits both alpha 1- and alpha 2-containing complexes to a similar extent. Expression of alpha 1DN also led to a decrease in AMPK activity of up to 60% in hepatocytes that had not been incubated with AICA riboside, i.e., under conditions which would reflect basal AMPK activity (Fig. 5C).


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  		FIG. 5.   Expression of alpha 1DN inhibits AMPK activity. (A and B) Hepatocytes were infected with varying titers of Ad.alpha 1DN or Ad.null. Forty-four hours after infection, AICA riboside (500 µM) was added to the culture medium, and the hepatocytes were incubated for a further 1 h. AMPK complexes were isolated from cell lysates by immunoprecipitation (IP) with either an anti-gamma antibody (A) or an anti-alpha 2 antibody (B). Activity present in the immune complexes was measured by phosphorylation of the SAMS peptide. For panel C, hepatocytes were infected with either Ad.alpha 1DN (10 PFU/cell) or Ad.null (10 PFU/cell) in the absence of AICA riboside. At various times postinfection, AMPK activity present in immune complexes isolated using an anti-gamma antibody was determined as described above. In each case, results are plotted as a percentage of the activity present in hepatocytes infected with Ad.null and are the mean ± the SEM of four independent experiments. *** denotes a significant difference from the Ad.null value (P < 0.0005), and ** indicates that P was <0.005.

Effect of inhibition of AMPK on glucose-activated gene expression. In order to determine whether AMPK plays a role in the induction of glucose-activated gene expression, we examined the effect of inhibiting AMPK by expression of alpha 1DN. The expression of glucose-activated genes in hepatocytes grown in 5 mM glucose is very low but increases with increasing glucose concentrations (13). Figure 6A shows that there was no increase in the mRNA levels of FAS, L-PK, or S14 following expression of alpha 1DN in hepatocytes grown in 5 mM glucose, even though basal AMPK activity was reduced by up to 60% under these conditions. In contrast, however, the level of FAS mRNA was markedly increased by 25 mM glucose in hepatocytes maintained under these conditions (Fig. 6B). These results indicate that partial inhibition of AMPK is not sufficient for induction of glucose-activated gene expression in hepatocytes.


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  		FIG. 6.   Overexpression of alpha 1DN has no effect on the transcription of glucose-activated genes. (A) Hepatocytes were incubated in the presence of 5 mM glucose and 100 nM insulin (G5) for 18 h before infection with either Ad.alpha 1DN (10 PFU/cell) or Ad.null (10 PFU/cell). At various times after infection, total RNA was extracted from the cells and subjected to Northern blotting with cDNA probes encoding either FAS, L-PK, ACC, S14, or albumin. Blots were washed extensively and exposed to autoradiographic film at -70°C for 1 to 2 days. (B) Northern blot analysis of RNA isolated from hepatocytes 90 h after infection with Ad.null (10 PFU/cell) cultured in medium containing 100 nM insulin and either 5 mM glucose (G5) or 25 mM glucose (G25). In each case, a representative blot from at least four independent experiments is shown.

Effect of glucose concentration on endogenous AMPK activity. A caveat to our finding that inhibition of AMPK has no effect on the induction of gene expression in response to glucose is that we were unable to inhibit AMPK activity completely. It remained possible, therefore, that high concentrations of glucose could activate gene expression by inhibiting AMPK activity to a greater extent than we have observed using the dominant negative approach. In order to test this, we measured AMPK activity present in anti-alpha 1 and anti-alpha 2 immune complexes that were isolated from hepatocytes incubated in the presence of 100 nM insulin with either 5 mM glucose or 25 mM glucose. Although in every case AMPK activity was very low, we were unable to detect any significant reduction in the activity of either alpha 1 or alpha 2 complexes from hepatocytes incubated in 25 mM glucose compared to results with 5 mM glucose (Fig. 7). This result rules out the possibility that high concentrations of glucose activate gene expression in hepatocytes by directly inhibiting AMPK.


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  		FIG. 7.   Effect of extracellular glucose concentration on AMPK activity in hepatocytes. Hepatocytes were cultured overnight in medium containing 5 mM glucose and 100 nM insulin (G5). Medium was removed, and fresh G5 medium or medium containing 25 mM glucose and 100 nM insulin (G25) was added. Hepatocytes were harvested following incubation for a further 1 or 6 h. AMPK activity present in immune complexes isolated using either an anti-alpha 1 (shaded bars) or anti-alpha 2 (hatched bars) antibody was determined by phosphorylation of the SAMS peptide. Activities are plotted as a percentage of AMPK activity present in hepatocytes maintained in G5 and are the mean ± the SEM of three experiments. The 100% value for the activity in G5 is indicated by the dashed line.


    DISCUSSION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

AMPK was originally identified through its phosphorylation and inhibition of key enzymes involved in biosynthetic pathways, such as ACC (fatty acid synthesis) and 3-hydroxy-3-methylglutaryl CoA reductase (isoprenoid and cholesterol biosynthesis) (18). It has now become clear that AMPK plays a much wider role in cellular regulation, e.g., in the regulation of fatty acid oxidation in the liver (34, 48, 49) and muscles (29, 47), in the activation of glucose uptake in muscles (21), and in the inhibition of glucose-activated gene expression in the liver (13, 31). Virtually all of the studies examining the physiological role of AMPK have involved experiments using AICA riboside to activate the kinase. AICA riboside is a cell-permeative compound which is phosphorylated within the cell by adenosine kinase to form AICA ribotide, or ZMP (37), which mimics the effect of AMP on activation of AMPK (6, 43, 44). A limitation when using AICA riboside to study the function of AMPK is that its effects are not restricted to activation of AMPK (16, 28), while in some cell types, e.g., cardiomyocytes, ZMP does not accumulate to high levels (25). Results obtained with AICA riboside, therefore, should be interpreted with caution and treated only as preliminary evidence for the involvement of AMPK in a particular pathway.

Convincing evidence of a role for AMPK in a particular cellular pathway could be gained by using alternative methods for modulating AMPK activity within the cell. Until now, however, there have been no reports of other well-characterized activators or inhibitors of AMPK. In order to address this issue, we have developed a constitutively active form of AMPK to increase activity and a dominant negative mutant of AMPK to decrease activity. To determine the use of these reagents as molecular tools to study the function of AMPK, we chose to investigate the effects of their overexpression on the transcription of glucose-activated genes. In the present study, we used primary rat hepatocytes in culture, a system which has been used extensively as a model for studying glucose-activated gene expression (15, 45), coupled with adenovirus-mediated gene transfer. Using this approach, we were able to express high levels of both alpha 1312, the constitutively active form of AMPK, and alpha 1DN, the dominant negative form. At 30 PFU/cell, the activity contributed by alpha 1312 in hepatocyte lysates was greater than that of endogenous AMPK following stimulation by AICA riboside. Expression of alpha 1312 blocked the induction of four glucose-responsive genes (FAS, L-PK, ACC, and S14) but had no effect on the expression of control genes (albumin and GAPDH), which are not induced by glucose.

In the liver, insulin acts indirectly in stimulating glucose-activated gene expression by inducing glucokinase expression (15, 45). In the present study, insulin (100 nM) was included throughout the incubation of the hepatocytes, and the concentration of glucose was varied between 5 and 25 mM. We are unable to distinguish, therefore, among the inhibitory effects of AMPK in a glucose pathway, an insulin pathway, or both. In addition, it is possible that the effect of overexpression of alpha 1312 on gene expression is due to its mimicking a closely related kinase rather than being the direct consequence of AMPK activity. However, the effect of alpha 1312 is similar to that observed following stimulation of AMPK with AICA riboside, providing strong evidence that AMPK per se inhibits glucose-activated gene expression. To our knowledge this is the first study to use a constitutively active form of AMPK to alter a cellular response.

Having obtained convincing evidence that AMPK inhibits glucose-activated gene expression, we investigated next whether AMPK could also be involved in the glucose activation pathway. Expression of alpha 1DN in hepatocytes led to a marked decrease in AMPK activity. The magnitude of this effect was the same regardless of whether anti-gamma or anti-alpha 2 antibodies were used to immunoprecipitate AMPK. In liver, the anti-gamma antibody immunoprecipitates complexes containing both the alpha 1 and alpha 2 isoforms (38), implying that the activities of the alpha 1 and alpha 2 isoforms are reduced to a similar extent by expression of inactive alpha 1. The most likely explanation for the reduction in AMPK activity is that alpha 1DN competes with the endogenous alpha  subunit for the binding of the beta  and gamma  subunits. It is possible that the unassociated alpha  subunit is subject to an increased turnover rate and is depleted from the cell. Consistent with this hypothesis are the results of a previous study which showed that the turnover rate of alpha 1 in transiently transfected COS cells is decreased by coexpression of the beta  and gamma  subunits (8). Alternatively, it is possible that the decrease in alpha 2 expression is due to feedback inhibition of alpha 2 caused by overexpression of the alpha 1DN protein. Further experiments will be required to address this issue.

Since an increase in AMPK activity inhibits glucose-activated gene transcription, it follows that a decrease in AMPK activity could stimulate gene transcription. This does not appear to be the case, since inhibition of AMPK activity by more than 50% in hepatocytes grown in 5 mM glucose had no detectable effect on the expression of any of the glucose-activated genes we examined. In a recent study, alpha 2-containing complexes, but not alpha 1 complexes, were shown to be present within the nucleus (38). This result suggests that the effect of AMPK on gene expression may be mediated specifically by alpha 2-containing complexes. However, we found that expression of alpha 1DN inhibited both alpha 1 and alpha 2 complexes to the same extent, arguing against this scenario. Expression of alpha 1DN did not completely abolish AMPK activity, and it remained feasible that high concentrations of glucose could reduce activity by a greater amount than the dominant negative inhibitor. However, we were unable to detect any decrease in the activity of endogenous AMPK in cultured hepatocytes after changing the glucose concentration in the medium from 5 to 25 mM. In contrast, the expression of glucose-activated genes is significantly increased under these conditions. Taken together, these results rule out the possibility that glucose exerts its effects on gene expression by directly inhibiting AMPK.

In a previous study, Salt et al. observed a correlation between AMPK activity and extracellular glucose concentration in cell lines derived from pancreatic beta  cells (39). In this case, however, AMPK activity was only increased by very low concentrations of glucose (below 1 mM). This is reminiscent of the activation of SNF1 in yeast following removal of glucose from the medium (50, 52). The increase in AMPK activity upon glucose removal in beta  cells correlated with an increase in both the ADP/ATP ratio and AMP/ATP ratio. Increasing the glucose concentration above 10 mM had no obvious effect on either AMPK activity or the ratio of ADP to ATP or AMP to ATP (39). The results obtained with pancreatic beta  cell lines are consistent with our finding for hepatocytes that AMPK is not inhibited by high concentrations of glucose.

A specific role of AMPK in the inhibition of glucose-activated gene expression, rather than in the induction process, is compatible with the idea that AMPK acts as a low-energy sensor within the cell (16, 17). Under optimal conditions the AMP/ATP ratio is maintained at a level below that required to lead to activation of AMPK. Consistent with this is the finding that the basal activity of AMPK isolated from hepatocytes grown in the presence of 5 mM glucose is very low. Many stress conditions lead to depletion of ATP and a concomitant rise in the ratio of AMP to ATP, resulting in activation of AMPK (19). In the case of glucose-activated gene expression, activation of AMPK would inhibit transcription, an energy-utilizing pathway, thereby conserving the energy within the cell. It is less clear whether any physiological conditions would lead to inhibition of basal AMPK activity. From our current understanding of the regulation of AMPK, inhibition of basal activity would require a decrease in the AMP/ATP ratio, although it is possible that some other, unrelated process could be involved. However, we have not been able to measure any reduction of basal AMPK activity in hepatocytes, and others have failed to detect significant inhibition of AMPK in pancreatic beta  cell lines (39), by high levels of glucose. Based on these findings, we propose that activation of AMPK is a physiologically relevant process, whereas a reduction of basal AMPK activity is unlikely to occur in vivo.

Comparing the role of AMPK in inhibiting glucose-activated gene expression with the role of SNF1 in yeast reveals some intriguing details. SNF1 is activated in the presence of low glucose levels (derepressing conditions). Although the metabolic signal leading to activation remains enigmatic, it is analogous to the activation of AMPK following a rise in the AMP/ATP ratio. Once activated, SNF1 switches on transcription of glucose-repressed genes, such as SUC2, the gene coding for invertase (2, 3). This is the mirror image of the situation for AMPK, which switches off transcription of glucose-activated genes. With high glucose levels (glucose-repressing conditions), SNF1 is maintained in an inactive state and does not appear to play a role in the glucose induction pathway (27), analogous to the situation with AMPK. It is possible that the repressive role of AMPK in gene expression is not limited to glucose-activated genes but is a more global response. Inhibition of gene expression following a fall in the energy status of the cell would prevent further utilization of ATP, which would be beneficial to the cell. To date we have identified only genes which are inactivated by AMPK. Could AMPK also be involved in activation of gene transcription, as is the case for SNF1 in yeast? In a recent paper, Holmes et al. reported that chronic activation of AMPK by subcutaneous injection of AICA riboside over a 5-day period increased the expression of GLUT4 as well as the total activity of hexokinase in the skeletal muscle (23). The GLUT4 gene provides a particularly attractive candidate for activation by AMPK, since previous studies have shown that GLUT4 mRNA is increased by exercise training (35). It will be interesting, therefore, to determine whether AMPK is involved in the activation of GLUT4 gene expression in muscles.

The results reported here describe the expression of mutant forms of AMPK that act either as a constitutively active kinase or as a dominant negative inhibitor of endogenous AMPK in primary cells. The constitutively active form of AMPK provides a specific way to increase AMPK activity. Previously, AICA riboside has often been used to activate AMPK. However, as has been noted by others, AICA riboside is not a specific activator of AMPK and therefore should not be used in isolation to identify downstream targets of AMPK (16, 28). In addition to describing a more specific method for increasing AMPK activity, we also describe a specific inhibitor of AMPK, the alpha 1DN mutant. Using these reagents, we have been able to obtain convincing evidence that AMPK is involved in inhibiting expression of glucose-activated genes but does not play a role in their induction. It will be possible to use adenovirus-mediated gene transfer to express these mutants in cultured cells and in vivo in order to alter AMPK activity. These mutants will provide valuable tools for studying the wider physiological role of AMPK.


    ACKNOWLEDGMENTS

This study was supported by the Medical Research Council (MRC), London (D.C.), the Algerian state (D.A.-M.), and the Centre National de la Recherche Scientifique (P.F.). Part of this work was funded by an Intermediate Research Fellowship from the British Heart Foundation (A.W.) and from a European Union FAIR contract (97/3011). S.C.S. was supported by an MRC-CASE Ph.D. studentship (in collaboration with AstraZeneca Pharmaceuticals).

A.W. and D.A.-M. contributed equally to this study.


    FOOTNOTES

* Corresponding author. Mailing address: Cellular Stress Group, MRC Clinical Sciences Centre, Imperial College School of Medicine, Hammersmith Hospital, DuCane Road, London W12 0NN, United Kingdom. Phone: 44 (0)20 8383 4313. Fax: 44 (0)20 8383 2028. E-mail: dcarling{at}csc.mrc.ac.uk.


    REFERENCES
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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