Abstract
Aims/hypothesis
Peroxisome proliferator-activated receptor (PPAR) γ agonists are used increasingly in the treatment of type 2 diabetes. In the context of renal disease, PPARγ agonists reduce microalbuminuria in diabetic nephropathy; however, the mechanisms underlying this effect are unknown. Glomerular podocytes are newly characterised insulin-sensitive cells and there is good evidence that they are targeted in diabetic nephropathy. In this study we investigated the functional and molecular effects of the PPARγ agonist rosiglitazone on human podocytes.
Methods
Conditionally immortalised human podocytes were cultured with rosiglitazone and functional effects were measured with glucose-uptake assays. The effect of rosiglitazone on glucose uptake was also measured in 3T3-L1 adipocytes, nephrin-deficient podocytes, human glomerular endothelial cells, proximal tubular cells and podocytes treated with the NEFA palmitate. The role of the glucose transporter GLUT1 was investigated with immunofluorescence and small interfering RNA knockdown and the plasma membrane expression of GLUT1 was determined with bis-mannose photolabelling.
Results
Rosiglitazone significantly increased glucose uptake in wild-type podocytes and this was associated with translocation of GLUT1 to the plasma membrane. This effect was blocked with GLUT1 small interfering RNA. Nephrin-deficient podocytes, glomerular endothelial cells and proximal tubular cells did not increase glucose uptake in response to either insulin or rosiglitazone. Furthermore, rosiglitazone significantly increased basal and insulin-stimulated glucose uptake when podocytes were treated with the NEFA palmitate.
Conclusions/interpretation
In conclusion, rosiglitazone has a direct and protective effect on glucose uptake in wild-type human podocytes. This represents a novel mechanism by which PPARγ agonists may improve podocyte function in diabetic nephropathy.
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Introduction
The peroxisome proliferator-activated receptors (PPARs) are a family of nuclear receptors which were first described in 1990 [1]. There are three subtypes (α, β/δ and γ) with diverse roles in cellular metabolism [2] and equally diverse associations with disease states [3]. PPAR agonists are used therapeutically and the thiazolidinedione group of PPARγ agonists have made an important contribution to the treatment of type 2 diabetes over the past 10 years [4, 5]. A recent international clinical trial demonstrated that rosiglitazone in combination with lifestyle changes significantly reduced the risk of developing type 2 diabetes in susceptible individuals [6].
In the context of renal disease, PPARγ agonists have been shown to reduce microalbuminuria in patients with diabetic nephropathy [7–10], although the mechanisms for this are not fully understood. Regulation of renal filtration occurs at the level of the glomerular filtration barrier, which is comprised of endothelial cells, podocytes and an intervening glomerular basement membrane. In diabetic nephropathy there is disruption to this barrier with the consequent loss of protein into the urine. An early marker of this state is microalbuminuria. There is now good evidence that glomerular podocytes are directly targeted in diabetic nephropathy with loss of podocytes into the urine [11] and reduced production of the key podocyte protein nephrin [12]. These phenomena may be mechanisms that lead to disruption of the glomerular filtration barrier and to disease progression in diabetic nephropathy.
The clinical observations that PPARγ agonists reduce microalbuminuria in diabetic nephropathy indicate that these agents have direct effects at the level of the glomerular filtration barrier. Indeed, there is evidence of direct effects of these agents on podocytes. It has been shown that nephrin is upregulated in podocytes in response to PPARγ agonists [13] and that this effect occurs via direct action of the peroxisome proliferator response elements on the nephrin promoter. Furthermore, PPARγ agonists reduce podocyte apoptosis [14] and have been shown to be protective against the progression to glomerulosclerosis [14, 15] that is a feature of advanced diabetic nephropathy. More recently, the PPARγ agonist rosiglitazone was shown to prevent diabetic nephropathy in a mouse model of diabetes [16] and this was associated with a reduction in markers of oxidative injury. Together these findings indicate that PPARγ agonists have diverse effects on podocyte function; additional investigation is required to further define the pathways involved.
We have recently reported that human glomerular podocytes are insulin-sensitive cells and are able to rapidly transport glucose using the glucose transporters GLUT4 and GLUT1 [17]. In addition, we have shown that this effect depends on the production of nephrin, which is required for GLUT1 translocation, in podocytes, [18]. These observations demonstrate that insulin sensitivity in podocytes is uniquely controlled at a molecular level. We hypothesise that, in insulin-resistant states such as type 2 diabetes, the insulin sensitivity of podocytes is disrupted leading to adverse effects on podocyte function that predispose to nephropathy.
In this study we investigated the effect of rosiglitazone on podocyte glucose uptake and insulin sensitivity. We investigated the roles of the glucose transporter GLUT1 and the key podocyte protein nephrin. To relate these studies to a disease state, we used the NEFA palmitate to induce insulin resistance in podocytes.
Methods
Materials
Cell culture plastics were from Greiner (Stonehouse, UK). All reagents were from Sigma (Poole, UK) unless otherwise stated.
Cell lines
Several conditionally immortalised human cell lines were used. These were derived by incorporating a temperature-sensitive SV40 gene, which enables cells to proliferate at the permissive temperature (33°C) and to differentiate at the non-permissive temperature (37°C). The characteristics of the wild-type human podocyte cell line have been reported [19]. The cells have additionally been transfected with a telomerase construct [20]. A podocyte cell line derived from a patient with Fin Major nephrin mutation was used and the characteristics of these podocytes have also been reported previously [17, 19, 21]. Cells were cultured for 14 days at the non-permissive temperature (37°C) in RPMI 1640 medium with glutamine (R-8758; Sigma, St Louis, MO, USA) supplemented with 10% (vol./vol.) FCS (Life Technologies, Grand Island, NY, USA) and insulin transferrin sodium selenite (Sigma I-1184; 1% [vol./vol.]). Conditionally immortalised human glomerular endothelial cells were also used. The characteristics of these cells have been reported elsewhere [22]. In addition, murine 3T3-L1 fibroblast clones were obtained from LGC Promochem (Teddington, UK). They were differentiated to adipocytes as previously described [23]. Finally, an immortalised human proximal tubular epithelial cell line (HK2) was used [24].
Stimulation of cells
Cells were stimulated for 24–48 h with rosiglitazone (donated by GlaxoSmithKline). Rosiglitazone was dissolved in DMSO, 5 mg in 1 ml, and added to RPMI to give a final concentration of 10 μmol/l and 0.01% (vol./vol.) DMSO. The vehicle control for rosiglitazone was RPMI with 0.01% (vol./vol.) DMSO (termed vehicle). The dose of rosiglitazone was taken from previously published studies of cells in vitro [25, 26]. For palmitate treatment, podocytes were stimulated for 24 h with 750 μmol/l palmitate. The preparation of media containing palmitate was based on a previously published method [27]. Briefly, 20% fatty-acid-free BSA was heated to 37°C before the addition of palmitate dissolved in ethanol. The solution was heated to 37°C until clear and diluted with RPMI to give a final concentration of 5% (wt/vol.) BSA, 750 μmol/l palmitate and 1% (vol./vol.) ethanol. Solutions were filter sterilised and, if required, rosiglitazone was added before cells were incubated in appropriate solutions. The control for palmitate was 5% (wt/vol.) BSA and 1% (vol./vol.) ethanol (termed BSA). The dose of palmitate was based on previously published studies [27, 28]
2-Deoxyglucose uptake assay
The methods used were as previously reported [17]. Briefly, cells in six-well plates were pre-incubated accordingly before being serum starved in medium containing the required treatment for 2 h. For the final 15 min, cells were incubated in pre-warmed Krebs–Ringer phosphate buffer after washing three times in PBS. Where appropriate, cells were then treated with insulin (100 nmol/l) for 15 min at 37°C. Glucose uptake was quantified by exposing the cells to 2-deoxy-d-[3H]glucose at a concentration of 50 μmol/l (37 kBq/ml) for 5 min. At the end of this incubation, the cells were washed rapidly three times in ice-cold PBS and lysed in 0.5 ml of PBS containing 1% (vol./vol.) Triton X-100. The cell-associated β emissions were then determined by liquid-scintillation counting. All experiments were carried out in triplicate.
GLUT1 small interfering RNA transfection
As previously reported [17], a combination of two sequences was used with the following sense target sequences: CCAAGAGUGUGCUAAAGAAUU and CAUCGUGGCUGAACUCUUCUU. In addition, a non-specific control small interfering RNA (siRNA) sequence was used (Dharmacon, Lafayette, CO, USA). Cells were transfected using Lipofectamine 2000 (Invitrogen, Paisley, UK). Lipofectamine and siRNA were separately diluted in serum-free RPMI and the two solutions were combined and allowed to stand for 30 min before being added to cells in normal culture conditions. The final concentration of siRNA was 60 nmol/l. After 48 h, cells were serum starved for 2 h for 2-deoxyglucose-uptake experiments.
Bis-mannose photolabelling
Bis-mannose labelling is a method whereby bis-labelled mannose is covalently linked to cell-surface glucose transporters which can then be detected and quantified by western blotting. This method was performed as previously described [17, 29], but with some modifications. Briefly, stimulated podocytes were incubated with and without 100 nmol/l insulin for 12 min and then incubated for a further 3 min in the presence of 200 μmol/l PEG-biotincap-ATB-BMPA (Toronto Research Chemical, Toronto, ON, Canada). Cells were then irradiated for 1 min in a CL-1000M crosslinker (UVP, Cambridge, UK) using 302 nm wavelength lamps. Cell protein concentration was quantified using an assay based on the bicinchoninic acid assay (Pierce, Rockford, IL, USA) and protein was extracted for western blotting.
Western blotting
For whole-cell lysates, cells were washed twice with ice-cold PBS and then scraped into ice-cold NP40 extraction buffer (50 mmol/l Tris/HCl, pH 7.5, containing 1 mmol/l EDTA, 120 mmol/l NaCl, 50 mmol/l NaF, 1 mmol/l benzamidine, 1% (vol./vol.) NP40, 1 μmol/l microcystin, 7.2 mmol/l 2-mercaptoethanol, 5 mmol/l orthovanadate and 1 μl/ml protease inhibitor cocktail (Sigma)). Cell extracts were centrifuged at 10000 g for 10 min at 4°C and the supernatant fractions were saved. Whole-cell membrane fractions were prepared as previously described [30] with the final membrane pellet being resuspended in NP40 extraction buffer. SDS PAGE using 7.5% (wt/vol.) acrylamide gels was performed and protein was transferred onto polyvinylidene fluoride membranes (Millipore, Billerica, MA, USA). Membranes were blocked with 5% (wt/vol.) BSA and then incubated with the following primary antibodies: rabbit anti-PPARγ (Santa Cruz SC-7196; Santa Cruz Biotechnology, Santa Cruz, CA, USA), rabbit polyclonal anti-GLUT1 (a kind gift from G. Holman, Bath University, Bath, UK) and anti-nephrin antibody 50A9 (a kind gift from K. Tryggvason, Karolinska Institute, Stockholm, Sweden). Secondary horseradish-peroxidase-conjugated antibodies (Amersham Biosciences, Little Chalfont, UK) were used and luminescence was created with Femto Supersignal luminal (Pierce) before imaging in a ChemiDoc-it imaging system (UV Products, Cambridge, UK).
Immunofluorescence
Immunofluorescence of cells was performed using a modified protocol as previously described [19]. Podocytes on cover slips were stimulated accordingly, washed with ice-cold PBS and then fixed with 2% (vol./vol.) paraformaldehyde. Cells were permeabilised and blocked with 0.1% (vol./vol.) saponin and 3% (wt/vol.) BSA in PBS. They were incubated with anti-GLUT1 (a kind gift from G. Holman, Bath University, UK) and FITC secondary antibody in the blocking solution. Cells were imaged using an inverted fluorescence microscope (AF6000LX; Leica Microsystems, Mannheim, Germany). GLUT1 images of wild-type podocytes were scored by two independent blinded observers who scored at least 100 cells per condition for cytoplasmic or peripheral localisation.
Statistical analysis
ANOVA was performed for glucose-uptake assays and densitometry and the groups were compared with a post hoc Bonferroni multiple comparison test. For the GLUT1 scoring an unpaired t test was used. GraphPad Prism, Version 4.00, was used for analysis (GraphPad Software, San Diego, CA, USA). Significance was deemed to occur at p < 0.05. The standard error of the mean is shown for all experiments.
Results
Production of PPARγ in cultured podocytes
Production of PPARγ was confirmed by western blotting in proliferating and differentiated podocytes (Fig. 1).
Rosiglitazone increased glucose uptake in podocytes and adipocytes
Rosiglitazone significantly increased basal and insulin-stimulated glucose uptake in podocytes (Fig. 2a). This effect was greatest at 48 h and at this time point the increase in basal glucose uptake was equivalent in magnitude to the glucose uptake seen with insulin stimulation. Basal glucose uptake in 3T3-L1 adipocytes was also significantly increased at 24 h following rosiglitazone treatment (Fig. 2b) though this increase was of a lesser magnitude than that in podocytes. In these adipocytes, insulin-stimulated glucose uptake in adipocytes was also enhanced by rosiglitazone, as previously reported [31]. Rosiglitazone did not increase basal glucose uptake in either human glomerular endothelial cells (Fig. 3a) or human proximal tubular (HK2) cells (Fig. 3b) after 24 h.
The increased glucose uptake in podocytes treated with rosiglitazone was abolished with GLUT1 siRNA
GLUT1 is the predominant glucose transporter responsible for glucose uptake under basal conditions in podocytes. We previously used GLUT1-specific siRNA and demonstrated GLUT1 knockdown in differentiated podocytes by western blotting at 48 h with no change in GLUT4 production [17]. In this study the increased basal glucose uptake that occurred in podocytes with rosiglitazone was significantly reduced with GLUT1 siRNA (Fig. 4). Vehicle-treated cells also demonstrated reduced basal glucose uptake following GLUT1 siRNA, consistent with GLUT 1 being the principal transporter for basal uptake. GLUT1 siRNA altered insulin-stimulated glucose uptake in both vehicle- and rosiglitazone-treated cells compared with controls. In the same experiment, rosiglitazone significantly increased basal glucose uptake in podocytes treated with and without control GLUT1 siRNA. These findings support a GLUT1-dependent mechanism for the increased glucose uptake seen in podocytes treated with rosiglitazone.
Nephrin-deficient podocytes did not demonstrate increased glucose uptake with rosiglitazone
We proceeded to investigate the functional role of nephrin. Nephrin is a key component of the podocyte slit diaphragm protein complex. In keeping with our previous findings [18], we found in this study that nephrin-deficient podocytes derived from a patient with a Fin Major nephrin mutation did not increase glucose uptake in response to insulin (Fig. 5a). Furthermore, we found that rosiglitazone did not increase glucose uptake in nephrin-deficient podocytes.
Nephrin production was unchanged in wild-type podocytes treated with rosiglitazone
The production of nephrin therefore appears critical for the increased glucose uptake observed in podocytes treated with rosiglitazone. However, we found there was no difference in nephrin production in wild-type podocytes treated with rosiglitazone for 24–48 h (Fig. 5b) and this is in keeping with results from a recent in vivo study [16].
Rosiglitazone increased the translocation of GLUT1 to the plasma membrane in wild-type podocytes
We further examined the role of GLUT1. Podocytes treated with rosiglitazone for 48 h had increased peripheral localisation of GLUT1 on immunostaining compared with vehicle-treated cells (Fig. 6). By comparison, GLUT1 translocation to the plasma membrane was reduced in nephrin-deficient podocytes. This finding is consistent with our previously published data demonstrating that nephrin-deficient podocytes were unable to translocate GLUT1 to the plasma membrane following insulin stimulation [18].
In addition, we found that membrane fractions from wild-type podocytes treated with rosiglitazone demonstrated increased GLUT1 compared with cytoplasmic fractions and vehicle-treated controls (Fig. 7a). To further validate these findings an assay of functional glucose transporters was used. Bis-mannose photolabelling of cell surface glucose transporters demonstrated increased GLUT1 at the plasma membrane in podocytes treated with rosiglitazone (Fig. 7b). There was no difference in the total cellular GLUT1 production between vehicle- and rosiglitazone-treated podocytes (Fig. 7C) and this is in keeping with findings from other studies [16, 32].
Rosiglitazone increased glucose uptake in podocytes treated with palmitate
Palmitate is the predominant circulating saturated fatty acid and it is increased in insulin-resistant states such as type 2 diabetes [33]. We used palmitate to induce insulin resistance in podocytes. Treatment of podocytes with palmitate for 24 h resulted in blocking of insulin-stimulated glucose uptake by comparison with control cells (Fig. 8). When podocytes were co-treated for 24 h with palmitate and rosiglitazone both basal and insulin-stimulated glucose uptake were significantly increased, although the increase in insulin-stimulated glucose uptake was not equal to that in control cells. The effect of rosiglitazone on increasing basal glucose uptake was, therefore, preserved in podocytes treated with palmitate and this led to a corresponding increase in insulin-stimulated glucose uptake. This may represent a mechanism by which rosiglitazone preserves podocyte function in insulin-resistant states.
Discussion
The role PPARγ agonists may play in the prevention and treatment of renal disease is emerging. These agents have recognised insulin-sensitising properties and therefore have an important role in the treatment of type 2 diabetes and insulin resistance. The reduction in microalbuminuria observed in patients with type 2 diabetes treated with PPARγ agonists raises important questions about the potential mechanisms by which these agents work.
The importance of podocytes in maintaining the integrity of the glomerular filtration barrier was encapsulated by the discovery of the key podocyte protein, nephrin, in 1998. Mutations in NPHS1, which encodes nephrin, result in congenital nephrotic syndrome of the Finnish type [34]. Since the discovery of nephrin, a number of genes have been found to be mutated in human nephrotic syndromes or animal models and these discoveries have provided significant insights into disease mechanisms [35].
This study reports a direct functional effect of rosiglitazone on podocytes. After treatment for 48 h, rosiglitazone significantly increased basal glucose uptake and this effect has been observed in other insulin-sensitive cells [31]. This effect was not seen in glomerular endothelial cells suggesting that, at this functional level, rosiglitazone is having an effect on one component of the glomerular filtration barrier. As rosiglitazone had an insulin-sensitising effect in podocytes and adipocytes, the role of the glucose transporter GLUT1 was investigated as a potential mechanism for the observed increase in both basal and insulin-stimulated glucose uptake.
GLUT1 is the predominant basal glucose transporter and we have previously reported GLUT1 production in podocytes, as well as a role for GLUT1 in insulin-mediated glucose transport [17]. Using GLUT1 siRNA it was possible to block the increase in glucose uptake in podocytes treated with rosiglitazone. The increase in glucose uptake was not abolished completely, which may be explained by incomplete knockdown or by the contribution of other glucose transporters. We have demonstrated the presence of GLUT2 in podocytes (M. A. Saleem, unpublished data) and GLUT8 has also been reported to have high levels of production in the kidney [36].
In support of these functional findings, we found increased peripherally localised and membrane-associated GLUT1. Furthermore, there was increased cell-surface expression of GLUT1 associated with rosiglitazone treatment whereas total cellular GLUT1 was unchanged. Increased production of GLUT1 has been associated with diabetic nephropathy, although this may not be a feature of early disease or animal models [16]. In line with our findings, a study reported increased membrane production of GLUT1 in adipocytes following incubation with rosiglitazone without a change in total GLUT1 [32].
In our study, the role of nephrin was investigated with nephrin-deficient podocytes derived from a patient with a Fin Major nephrin mutation. The increased basal glucose uptake seen with wild-type podocytes treated with rosiglitazone was absent in nephrin-deficient cells and in addition these cells did not respond to insulin as previously reported [18]. Furthermore, there was limited peripheral localisation of GLUT1 in nephrin-deficient podocytes following treatment with rosiglitazone.
These findings indicate a critical role for nephrin in mediating the increased glucose uptake in podocytes treated with rosiglitazone. Nephrin has also been associated with diabetic nephropathy, with reduced nephrin levels in human biopsies from patients with diabetes and proteinuria [12]. It has been proposed that this contributes to the development of nephropathy. Therefore, restoration of nephrin production could be a mechanism to reduce glomerular filtration barrier dysfunction in proteinuric states, such as diabetic nephropathy. Indeed pioglitazone, which has been shown to reduce microalbuminuria in diabetic nephropathy [7], has also been shown to restore nephrin mRNA and protein levels in a Heymann nephritis model [13]. This study also demonstrated that pioglitazone regulates the expression of the gene encoding nephrin.
In our study, 48 h incubation with rosiglitazone did not increase the production of nephrin in wild-type podocytes. This may have been due to the duration of rosiglitazone treatment or to normal regulation of nephrin production. It is plausible that nephrin production is maintained within limits for sufficiency. Our finding is also in keeping with a recent study that did not demonstrate changes in glomerular nephrin, GLUT1 and Neph1 (also known as Kirrel) expression in diabetic mice following either 10 or 20 weeks of rosiglitazone treatment [16].
Finally, to draw analogy to a disease state, we used the saturated NEFA palmitate. This blocked insulin-stimulated glucose uptake in wild-type podocytes but did not block the effect of rosiglitazone on podocyte glucose uptake. There was a significant increase in basal glucose uptake in cells co-treated with palmitate and rosiglitazone compared with palmitate alone and this was associated with a corresponding increase in insulin-stimulated glucose uptake.
We have also demonstrated that palmitate interrupts the insulin signalling pathway leading to GLUT4 translocation [37] and we propose that this mechanism is involved in the development of nephropathy in insulin-resistant states. Since the effect of rosiglitazone was preserved in cells treated with palmitate, we suggest that is a means by which PPARγ agonists are protective in nephropathy associated with insulin resistance.
In addition to our study, other studies have reported direct effects of PPARγ agonists on podocytes. Pioglitazone was shown to be protective in a puromycin aminonucleoside (PAN) model of podocyte injury by reducing podocyte apoptosis [14]. Furthermore, the related in vivo study demonstrated a reduction in glomerulosclerosis in PAN-injured rats following treatment with pioglitazone [15]. PPARγ agonists, therefore, have diverse effects on podocyte function and it will be important to further define the pathways involved.
In conclusion, we have shown a direct functional effect of rosiglitazone on podocytes and we have demonstrated that the mechanism occurs via an effect on GLUT1 trafficking. Although we have not demonstrated the mechanism of GLUT1 translocation in this study, we have previously shown that it is dependent upon nephrin and actin in podocytes [18]. We propose that podocytes have a high metabolic demand and as such they require a ready supply of energy substrates. Insulin-resistant states such as type 2 diabetes may adversely affect this substrate provision. Clinically, PPARγ agonists confer renal protection and the functional effect that we have observed may be involved in the mechanism of protection. If PPARγ agonists are protective against progression of renal disease across the spectrum of insulin resistance [38, 39], there are potentially more applications for this group of drugs. The effect of these drugs in reducing the progression of renal disease requires further investigation.
Abbreviations
- PAN:
-
Puromycin aminonucleoside
- PPAR:
-
Peroxisome proliferator-activated receptor
- siRNA:
-
Small interfering RNA
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Acknowledgements
R. Lennon was funded by the Wellcome Trust for this work. A. Singh was funded by Kidney Research UK. R. J. Coward is funded by the Medical Research Council. Additional funding was received from the Nephrotic Syndrome Trust and we thank North Bristol NHS Trust for funding which also supported this work. We also thank M. A. Sabin and J. P. Shield for their advice regarding palmitate stimulation.
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The authors declare that there is no duality of interest associated with this manuscript.
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Lennon, R., Welsh, G.I., Singh, A. et al. Rosiglitazone enhances glucose uptake in glomerular podocytes using the glucose transporter GLUT1. Diabetologia 52, 1944–1952 (2009). https://doi.org/10.1007/s00125-009-1423-7
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DOI: https://doi.org/10.1007/s00125-009-1423-7