Departments of 1 Biology and Biochemistry and 2 Pharmacy and Pharmacology, University of Bath, Bath BA2 7AY, United Kingdom
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ABSTRACT |
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Abnormalities in intracellular pH regulation have been proposed to be important in type 2 diabetes and the associated cardiomyopathy and hypertension. We have therefore investigated the dependence of insulin-stimulated glucose transport on cytosolic pH in cardiomyocytes. Insulin treatment of cardiomyocytes resulted in a marked alkalinization of the cytoplasm as measured using carboxy-semi-napthorhodofluor-1. The alkalinizing effect of insulin was blocked by treatment with either cariporide (which inhibits the Na+/H+ exchanger) or by bafilomycin A1 (which inhibits H+-ATPase activity). After treatments with cariporide or bafilomycin A1, insulin stimulation of insulin receptor and insulin receptor substrate-1 phosphorylation and Akt activity were normal. In contrast, glucose transport activity and the levels of functional GLUT4 at the plasma membrane (detected using an exofacial photolabel) were reduced by ~50%. Immunocytochemical analysis revealed that insulin treatment caused a translocation of the GLUT4 from perinuclear structures and increased its co-localization with cell surface syntaxin 4. However, neither cariporide nor bafilomycin A1 treatment reduced the translocation of immunodetectable GLUT4 to the sarcolemma region of the cell. It is therefore hypothesized that insulin-stimulated cytosol alkalinization facilitates the final stages of translocation and incorporation of fully functional GLUT4 at the surface-limiting membrane.
GLUT4 translocation; cytosolic pH; cariporide; bafilomycin A1
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INTRODUCTION |
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IN ADDITION TO ITS EFFECTS on glucose transport activity and glycolysis, insulin plays an important role in H+ balance. Stimulation of cells by insulin causes an increase in intracellular pH in adipocytes (6, 30), 3T3-L1 cells (23), muscle (12, 22), and liver (32). Conversely, cytosol acidification has been implicated in pathophysiological processes related to insulin action, including hypertension and type 2 diabetes (24, 25, 36, 45). Cytosolic pH regulation is of particular importance for physiological and pathophysiological processes in cardiomyocytes because of the susceptibility of these cells to changes in pH during osmotic shock and contraction and under anoxic/ischemic conditions (1, 2). A cocktail of glucose, insulin, and potassium is known to have beneficial effects on the ischemic heart (1, 7, 19). Cardiomyopathy is associated with type 2 diabetes and contributes significantly to cardiovascular disease morbidity and mortality in diabetic patients, especially those with coexistent hypertension (45). It is therefore of importance to unravel the interdependence of cardiomyocyte pH and insulin action in these cells.
It has been suggested that part of insulin's effect on cytosol alkalinization is mediated by activation of Na+/H+ exchange (10, 18, 41). We have examined here whether inhibition of the Na+/H+ exchanger with cariporide can antagonize the effects of insulin on cytosolic pH and glucose transport activity. To examine more widely whether other cell acidification processes may antagonize the alkalinizing effects of insulin, we have examined the effects of bafilomycin A1, an inhibitor of H+-ATPases (50). Both cariporide and bafilomycin A1 were found to markedly reduce insulin-stimulated glucose transport activity.
Insulin stimulation of glucose transport activity is a multistep process involving a convergence of signaling steps on the process of GLUT4 vesicle translocation from its intracellular storage compartment and subsequent docking and fusion of these vesicles with the plasma membrane (17, 40, 44). To measure GLUT4 translocation, subcellular fractionation techniques are often used. However, this technique was found to be unreliable in cardiomyocytes, particularly when only small samples of cell material were available. We have therefore used an immunocytochemical approach to examine changes in insulin-stimulated GLUT4 translocation. Intracellular GLUT4 has been localized to tubulovesicular structures by confocal microscopy in fat cells, skeletal muscle, and heart tissue (28, 29, 34), and this technique therefore provides us a means of examining the effects of pH perturbation on GLUT4 translocation in small-scale preparations of cardiomyocytes. To examine the extent to which treatments that induce cytosol acidification lead to altered cell surface exposure of translocated GLUT4, we have used a photolabeling technique. This utilizes an impermeant photoaffinity label (26). The studies described suggest that the cytosol acidification effects of cariporide and bafilomycin A1 antagonize the final stages of insertion of fully functional GLUT4 at the sarcolemma membrane.
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MATERIALS AND METHODS |
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Cardiomyocyte isolation.
Cardiomyocytes from adult male Wistar rats (260-280 g) were
prepared by collagenase digestion (type II, from Worthington
Biochemical) by use of a method adapted from those previously described
(9, 14) but with the inclusion of 20 mM inosine in the
final cell suspension. Cell suspensions were adjusted to 10%
cytocrit in Krebs-Ringer-HEPES (KRH) buffer (in mM: 6 KCl, 1 Na2HPO4, 0.2 NaH2PO4,
1.4 MgSO4, 1 CaCl2, 128 NaCl, 10 HEPES, 20 inosine, pH 7.4) with 2% fatty acid-free BSA (Roche Molecular
Biochemicals). Freshly isolated rat cardiomyocytes in 2% BSA-KRH
buffer were maintained for 10 min at 37°C (with continuous gassing
with O2) in the presence and absence of cariporide (20 µM) or bafilomycin A1 (100 nM). Cells were then stimulated with 30 nM
insulin, where appropriate, for 30 min at 37°C. In some experiments,
cells were prepared in KRH buffer and transferred to a
Krebs-Henseleit-bicarbonate (KHB) buffer (in mM: 4.7 KCl, 1.2 KH2PO4, 25 NaHCO3, 118.5 NaCl, 2.5 CaCl2, 1.2 MgSO4, 5 HEPES) and continuously
gassed with 95% O2-5% CO2 to pH 7.4 throughout the treatments.
Confocal microscopic measurement of cardiomyocyte pH. For measurements of cytosolic pH, 0.5 ml per condition of 10% cytocrit cell suspensions was loaded with 10 µm of (5/6-)carboxy-semi-napthorhodofluor-1 (carboxy-SNARF-1). This was added as the acetoxymethyl ester (Molecular Probes) for 30 min at 37°C after the preincubation period. Intracellular pH was measured essentially as described (49). Three to six cells from each experiment were analyzed using a Zeiss LSM-510 inverted confocal microscope. Carboxy-SNARF-1 was excited at 488 nm, and the mean of the ratios of the fluorescence emission intensities at >615 nm and 560-615 nm was compared with an in situ calibration curve obtained by use of the ionophore nigericin (49).
Insulin signaling. For determination of the extent of phosphorylation of the insulin receptor and insulin receptor substrate-1 (IRS-1), 1-ml aliquots of cardiomyocytes (10% cytocrit) were centrifuged and the pellets lysed in a buffer containing 1% Triton X-100 and 10% glycerol in 50 mM HEPES, pH 7.0, 150 mM NaCl, and 1 mM EGTA, with the phosphatase inhibitors 100 mM NaF, 10 mM NaPPi, 1 mM Na3VO4, and the protease inhibitors antipain, pepstatin A, and leupeptin (each at 1 µg/ml) and 100 µM 4-(2-aminoethyl)benzenesulfonyl fluoride. Lysates were subjected to precipitation using anti-phosphotyrosine agarose (Sigma), and then the precipitates were resolved by SDS-PAGE and Western blotted using monoclonal anti-insulin receptor antibody (C19, Santa Cruz) and polyclonal anti-IRS-1 (Upstate), as previously described (35). For determination of the extent of Akt phosphorylation, cardiomyocytes were directly lysed in SDS-PAGE sample buffer. Thirty-microgram samples were resolved on gels and Western blotted using anti-phospho-373-Akt (New England Biolabs). In each case, signals were detected by enhanced chemiluminescence (ECL) and quantified using an Optichem Detector with associated software (Ultra Violet Products).
Glucose transport activity. Nine hundred-microliter aliquots of cardiomyocyte suspensions at 10% cytocrit in 2% BSA-KRH buffer were maintained at 37°C and continuously gassed with O2. The transport assay was initiated by the addition of 2-deoxy-D-glucose [100 µM final concentration, containing 0.5 µCi of 2-deoxy-D-[3H]glucose (Amersham Pharmacia Biotech)]. Where indicated, the KRH buffer was replaced by KHB buffer. Sugar uptake was terminated after 10 min by transferring the cell suspension to microfuge tubes containing 400 µM phloretin in KRH buffer. Background activity was determined by addition of cells to tubes that contained 2-deoxy-D-glucose premixed with 400 µM phloretin. The samples were quickly mixed and immediately centrifuged at 3,500 g for 1 min. The supernatants were removed, and the cells were washed three times with 1 ml of KRH buffer containing 400 µM phloretin. Cells were lysed with 1 ml of ice-cold 0.1 M NaOH, and aliquots were taken for determination of radioactivity and protein levels.
Photolabeling of cell surface glucose transporters. Basal and insulin-stimulated cardiomyocytes (1 ml per condition of cell suspension at 10% cytocrit) were transferred to 35-mm-diameter polystyrene dishes cooled at 18°C to slow transporter recycling, and 4,4-O-[2-[ 2-[2-[2-[2-[6-(biotinylamino) hexanolyl]amino]ethoxy]exoxy]ethoxy]-4-(1-azi-2,2,2-trifluoroethyl)benzoyl]amino-1,3-propanediyl bis-D-mannose (Bio-LC-ATB-BMPA; 500 µM final concentration) (26) was added to the samples. Cells were irradiated at a wavelength of 300-350 nm for 1 min in a Rayonet RPR-100 photoreactor. After irradiation, cells were transferred to 15-ml tubes and washed once with 15 ml of KRH buffer and twice with 15 ml of HES buffer [20 mM HEPES, pH 7.2, 1 mM EDTA, and 255 mM sucrose plus protease inhibitors: 1 µg/ml each leupeptin, aprotonin, pepstatin A, and antipain and 100 µM 4-(2-aminoethyl)benzenesulfonyl fluoride] at 18°C. After the final wash, the cell pellets were resuspended in 500 µl of HES buffer and homogenized. The homogenized samples were then processed by solubilization in 2% Thesit detergent. Protein concentration was measured and adjusted, and then streptavidin-agarose precipitation was carried out as described (26, 49). Proteins eluted from the streptavidin beads were resolved on 10% SDS-PAGE gels, transferred to nitrocellulose, and blotted with anti-GLUT4 COOH-terminal peptide antibody. Signals were detected by ECL and were quantified using an Optichem Detector with associated software.
GLUT4 immunofluorescence microscopy. Cardiomyocyte morphology was fixed by incubation with 4% (wt/vol) paraformaldehyde in PBS buffer, pH 7.2. The cells were then incubated in permeabilization buffer [0.1% saponin, 1% (wt/vol) BSA, 3% (vol/vol) goat serum (Sigma) in PBS buffer, pH 7.2] for 45 min. For co-localization of GLUT4 and syntaxin 4, a 1:500 dilution of rabbit anti-syntaxin 4 serum (raised against GST-syntaxin 4 cytosolic domain) was added with 2 µg/ml of anti-GLUT4 1F8 monoclonal antibody. Alexa Fluor 568 anti-mouse IgG (4 µg/ml) and Alexa Fluor 488 rabbit IgG (4 µg/ml; Molecular Probes) were used as secondary antibodies. After these treatments, the cells were washed again and mounted onto a glass coverslip with Vectashield mounting medium. Cardiomyocytes were imaged using a Zeiss confocal scanning microscope LSM-510 equipped with a 63 × 1.4 NA oil immersion objective and by dual-laser excitation at 458-488 and 543 nm. Images were processed using the Zeiss LSM-510 and Adobe Photoshop 6 software.
Statistics. Results are presented as means ± SE. Unpaired two-tailed Student's t-tests were used for reagent effects compared with insulin treatment alone (except for the photolabeling experiments, when paired comparisons were made), and P values are presented on the figures.
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RESULTS |
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Insulin-induced alkalinization in cardiomyocytes and reversal by
cariporide and bafilomycin A1.
To measure insulin-induced changes in cytosolic pH, we used
carboxy-SNARF-1 (Fig. 1A). The
fluorescence signal of this reagent changes to longer wavelengths as
intracellular pH rises. Such changes were quantified using a
calibration curve in which nigericin was used to equilibrate cytosolic
pH with a range of pH standard solutions. There was a significant rise
in red fluorescence (Fig. 1A) and associated cytosolic pH
(Fig. 1B) when cardiomyocytes were treated with insulin.
Inhibition of sodium/proton exchange by use of cariporide blocked this
effect and maintained intracellular pH at basal levels (or slightly
below). Likewise, bafilomycin A1 was found to block the alkalinizing
effects of insulin on cytosolic pH.
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Effects of cariporide and bafilomycin A1 on insulin signaling.
To examine the possibility that the pharmacological treatments might
alter GLUT4 activity through a reduction in insulin-signaling activity,
we examined the extents of phosphorylation of the insulin receptor,
IRS-1, and Akt (Fig. 2A). The
treatments did not reduce the phosphorylation of these early signaling
intermediates (Fig. 2B).
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Glucose transport in cardiomyocytes treated with cariporide or with
bafilomycin A1.
To determine whether inhibition of Na+/H+
exchange and/or H+-ATPase activities affects glucose
transport activity, the uptake of 2-deoxy-D-glucose was
analyzed. Treatment with cariporide slightly increased basal transport
activity. In agreement with previous findings (8, 13),
insulin increased glucose transport activity nearly fivefold above the
rates measured in basal cells (Fig. 3A). Treatment with 20 µM
cariporide before the addition of insulin resulted in a marked
inhibition of insulin-stimulated glucose transport by 40-50%
(Fig. 3). Treatment with 0.1 µM bafilomycin A1 before the addition of
insulin also resulted in a marked inhibition of insulin-stimulated
glucose transport by nearly 60% (Fig. 3A). The combined
effect of cariporide and bafilomycin A1 was no greater than with either
reagent alone. Similar effects of cariporide and bafilomycin A1 were
obtained when a bicarbonate-containing buffer was used (Fig.
3B) instead of a bicarbonate-free buffer (Fig.
3A). However, it was found that the insulin-stimulated
transport activity was somewhat smaller in the bicarbonate buffer when
this response was directly compared with that in the bicarbonate-free buffer. We have used a bicarbonate-free buffer for most of the experiments described here because it stabilizes, but amplifies, intracellular pH changes when compared with the more physiological bicarbonate-containing buffer systems.
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Effects of cariporide and bafilomycin A1 on cell surface levels of
GLUT4.
To determine whether there was a correlation between the prevention of
insulin-induced cytosolic alkalinization produced by cariporide and
bafilomycin A1 and the effects of these reagents on insulin-stimulated
exposure of GLUT4 at the cell surface, the cell-impermeant photolabel
Bio-LC-ATB-BMPA was employed. This photolabel tags transporters
accessible at the cell surface with biotin. Cells were treated with
cariporide or with bafilomycin A1 in the presence or absence of insulin
and then irradiated in the presence of the photolabel. Biotin-tagged
transporters were separated from untagged GLUT4 on streptavidin beads
and Western blotted with antibodies against GLUT4 (Fig.
5A). GLUT4 at the cell surface
increased following insulin stimulation nearly fivefold over basal
levels (Fig. 5B). However, in the presence of cariporide or
bafilomycin A1, this effect was attenuated by 50%. There was a
small increase in the cell surface labeling of basal cells after the
treatment with cariporide. No change in the total amount of GLUT4 was
detected in detergent-solubilized supernatants, indicating that
1) an equal amount of protein had been incubated with the streptavidin beads and 2) neither cariporide nor bafilomycin
A1 has a significant effect on the total amount of GLUT4 in
cardiomyocytes.
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Distribution of GLUT4 revealed by confocal microscopy. Several studies have indicated that insulin may regulate GLUT4 translocation at both the level of release from its storage compartment and the level of the plasma membrane where translocated vesicles dock and fuse (17, 40, 44). To examine whether the effects of cytosolic acidification were mediated at either of these sites, the subcellular distribution of GLUT4 was analyzed by confocal microscopy.
Syntaxin 4 is primarily localized at the cell surface in insulin-responsive tissues, including muscle (21). Therefore, to analyze the effects on translocation to the cell surface, we carried out co-localization studies in which both GLUT4 and syntaxin 4 were examined. Secondary antibodies coupled to either Alexa Fluor 568 anti-mouse IgG (4 µg/ml) or Alexa Fluor 488 anti-rabbit IgG (4 µg/ml) were used to detect GLUT4 and syntaxin 4 antibodies as red and green signals, respectively (Fig. 6A). There was a high concentration of immunodetectable GLUT4 in the perinuclear area and between the two cell nuclei (in cases where 2 nuclei per cell were observed). GLUT4 was also found in lines that radiated out laterally to the cell surface. The GLUT4 in these locations is likely to be associated with the T-tubule system that lies between the myosin fibers.
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DISCUSSION |
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We have found that insulin treatment can lead to alkalinization of cardiomyocyte cytosol and that this effect can be blocked by treatment with either cariporide or bafilomycin A1. The neutralization effects induced by cariporide or bafilomycin A1 were accompanied by reductions in glucose transport activity and exposure of GLUT4 at the cell surface as detected by photolabeling. In contrast, confocal microscopy revealed that the effects of insulin on release of GLUT4 from its storage compartment were not reversed by these treatments. Instead, the gross distribution of GLUT4 appeared to be indistinguishable from that observed with insulin treatment alone, and in both cases an intense fluorescent signal from GLUT4 was evident around the cell periphery. Therefore, approximately one-half of the transporters that are present in the surface membrane appear to be nonfunctional. These findings are equivalent to those observed when isoproterenol is used to counterregulate the effects of insulin in adipose cells. Isoproterenol treatment of adipocytes leads to a reduction in insulin-stimulated glucose transport activity but does not reduce the total levels of insulin-stimulated translocation of GLUT4 from intracellular compartments (48). Instead, it leads to a slowing of the rate of cell surface exposure of GLUT4, with a consequent accumulation in the plasma membrane of nonfunctional GLUT4 (11, 49). The counterregulatory effects of isoproterenol in adipocytes are also dependent on its ability to prevent the alkalinization of cytosolic pH that occurs during insulin treatment (49).
The basis of the inhibitory effect of cariporide on insulin-stimulated glucose transport activity is likely to be through its inhibitory action on Na+/H+ exchange activity. The effects of cariporide were most evident in a nominally bicarbonate-free buffer system. However, they are likely to be of pathophysiological significance, as bicarbonate buffering will be compromised during ischemia. Under ischemia, the cytosolic buffering of the metabolic acid load will be more dependent on the Na+/H+ exchanger and the known stimulatory effects of insulin on the Na+/H+ exchanger (41), and the inhibitory effects of cariporide on this protein (39, 43) will be particularly important under these conditions.
The bafilomycin A1 effect on vesicle alkalinization may be due to inhibition of the H+-ATPase within intracellular vesicle membranes. However, it has previously been demonstrated that H+-ATPase is present in the plasma membrane of macrophages (16, 47) and that its inhibition leads to cytosol acidification. The H+-ATPase present in the plasma membrane appears to be particularly responsive to bafilomycin A1 (47). The plasma membrane levels of the H+-ATPase are increased by peroxyvanadate stimulation of granulocytes (3) and following chemotactic peptide and PKC activation of neutrophils (31), and in these cases the activation leads to increased cytosol alkalinization, which is antagonized by bafilomycin A1. However, there is no evidence that insulin can regulate H+-ATPase activity, and the antagonistic effects of bafilomycin A1 on insulin-stimulated GLUT4 activity may be an indirect consequence of the cytosol acidification induced by the reagent, which counteracts the cell-alkalinizing effects of insulin. The data presented do suggest that both the H+-ATPase and the Na+/H+ exchanger can contribute to cytosolic pH maintenance, particularly when bicarbonate exchangers are inactive, as inhibition of either of these systems can reverse insulin's effect on cytosol alkalinity.
Cariporide treatment of basal cells slightly increased transport activity and the levels of photolabeled and immunodetectable GLUT4 at the cell surface. However, no consistent increase in basal transport or GLUT4 translocation was found following bafilomycin A1 treatment. Treatment of 3T3-L1 cells with the H+-ATPase inhibitor bafilomycin A1 has been reported to induce the translocation of GLUT4 to the cell surface in the basal state (4). In this 3T3-L1 cell study, GLUT4 translocation was analyzed by Western blotting of membrane fractions, and any effect of bafilomycin A1 on transport activity was not reported. Any effects of cariporide or bafilomycin A1 on basal cardiomyocytes were slight compared with the stimulatory effect of insulin. More importantly, these treatments resulted in a substantial inhibition of insulin-stimulated glucose transport activity. Although somewhat contrasting effects are observed in 3T3-L1 adipocytes and in cardiomyocytes, the data collectively suggest that pH-dependent trafficking steps occur in both cell types. There may be a balance between pH effects at sequential steps in trafficking. For example, acidification may increase GLUT4 vesicle budding and release from its perinuclear storage compartment, with a consequent increase in basal GLUT4 at the cell surface, but this acidification may reduce GLUT4 vesicle fusion at the surface membrane. The net result would then be dependent on both of these steps. The balance may vary in different cells with different intracellular pH-buffering mechanisms.
There was no additivity in the inhibitory effects of a combination of cariporide and bafilomycin A1 on insulin-stimulated glucose transport activity. This suggests that, although they perturb intracellular pH by different mechanisms, they operate to reduce the proportion of functional GLUT4 exposed at the cell surface via a common mechanism. This common mechanism may be a cytosolic pH-dependent perturbation of the GLUT4 vesicle fusion step at the plasma membrane, which could account for the nonfunctional GLUT4 that accumulates at the cell surface. The transmembrane segment of the vacuolar H+-ATPase has recently been shown to be a key component required for vesicle fusion in yeast (33). This protein is involved in formation of a fusion pore and completion of the membrane fusion steps initially facilitated by formation of a SNARE complex (33). In addition, pH-dependent fusion steps are known to be involved in virus-induced fusion involving hemagluttinin (46). Thus the actions of cariporide and bafilomycin A1 may be to slow the transition into the plasma membrane of GLUT4 from occluded vesicles. The postulated links between pH and the molecules involved in fusion are speculative at present but suggest that examination of the details of such links may be important for future investigation of GLUT4 trafficking.
Recently, it has been demonstrated that incubation of cardiomyocytes
under normoxic conditions with an extracellular buffer of pH values
below (but not above) 6.8 leads to reduced insulin signaling at the
level of tyrosine phosphorylation of the insulin receptor and IRS-1
with a consequent decreased activation of Akt (1). Similar
decreases in signaling occur in ischemia and after treatment
with amiloride plus ouabain, conditions that decrease intracellular pH
to 6.4 (1). In our studies, the blocking of insulin-induced alkalinization by cariporide or bafilomycin A1 treatments led to maintenance of cytosolic pH at basal levels of
6.8-7.0. Under the relatively mild conditions of cytosol
acidification induced in our study, we find no reduction in early
signaling steps. We find that a full translocation of immunodetectable
GLUT4 to the cell periphery occurs when the insulin-induced cytosol alkalinization is neutralized, and this suggests that signaling to the
initial translocation step is intact.
Our studies suggest that insulin's cytosol-alkalinizing effect could be critical in the mechanism of cardioprotective glucose-insulin-potassium therapy (particularly in early stages of ischemia, when the therapy is considered to be most effective). Cariporide is cardioprotective during reperfusion after ischemia. This effect is attributed to inhibition of sodium influx via the Na+/H+ exchanger, with a consequent reduction in Na+/Ca2+ exchange activity and calcium overload (20, 37, 42). Cardioprotective interventions, therefore, include the cell-alkalinizing insulin therapy during ischemia and the cell-acidifying cariporide therapy during reperfusion. There is clearly a complex interplay and balance of pH maintenance and cation fluxes in these therapies, which may be most effective at different stages of cardiac failure and recovery.
The pH dependence of the final step of GLUT4 translocation may be critical to pathophysiological conditions such as type 2 diabetes. Recent evidence suggests that defects in insulin-stimulated glucose transport may occur quite distally to insulin-signaling processes (15, 27). The stimulatory effect of hypoxia on glucose transport is also defective in type 2 diabetic patients. This suggests that a defect may lie beyond the point of convergence of the insulin- and hypoxia-mediated signaling pathways (38). A range of physiological processes that are dependent on ionic fluxes across muscle membranes may impinge upon mechanisms that maintain cytosolic pH and may easily become disturbed and lead to insulin resistance. Likewise, a range of ion flux regulatory processes may be stimulated by insulin and result in alkalinization of the cytoplasm. The data presented in this study indicate that the Na+/H+ exchanger and the H+-ATPase are both critical components of cytosolic pH homeostasis and that their inhibition leads to neutralization of insulin-stimulated cytosol alkalinization and, consequently, impaired insulin-stimulated glucose transport.
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ACKNOWLEDGEMENTS |
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We are grateful to Dr. Juergen Eckel for help in setting up the cardiomyocyte preparation. We also thank the European Community (COST action B5) for a travel grant to A. Gillingham to visit Dr. Eckel's laboratory.
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FOOTNOTES |
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* These authors contributed equally to this work.
This work was supported by grants from the Medical Research Council (UK) and Diabetes UK.
Address for reprint requests and other correspondence: G. D. Holman, Dept of Biology and Biochemistry, Univ. of Bath, Bath BA2 7AY, UK (E-mail: g.d.holman{at}bath.ac.uk).
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.
August 13, 2002;10.1152/ajpendo.00341.2002
Received 31 July 2002; accepted in final form 12 August 2002.
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