This Article Extract Full Text (PDF) All Versions of this Article: 48/4/519    most recent 01.HYP.0000240331.32352.0cv1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Giunti, S. Articles by Cooper, M. E. Search for Related Content PubMed PubMed Citation Articles by Giunti, S. Articles by Cooper, M. E. Related Collections Animal models of human disease Type 1 diabetes Type 2 diabetes

(Hypertension. 2006;48:519.)
© 2006 American Heart Association, Inc.

Brief Reviews

Mechanisms of Diabetic Nephropathy

Role of Hypertension

From the Danielle Alberti Memorial Center for Diabetic Complications, Diabetes and Metabolism Division, Baker Heart Research Institute, Melbourne, Australia.

Correspondence to Mark Cooper, Baker Medical Research Institute, 75 Commercial Rd, Prahran VIC 3181, Melbourne, Australia. E-mail mark.cooper{at}baker.edu.au

	Introduction

Top Introduction Impact of Hypertension on... Genetic Susceptibility,... The Role of Glomerular... Role of ACE2 Interaction Between the... References

 
Diabetic nephropathy is a major microvascular complication of diabetes, representing the leading cause of end-stage renal disease in the Western world, and a major cause of morbidity and mortality in both type 1 and type 2 diabetic subjects. Clinical hallmarks of diabetic nephropathy include a progressive increase in urinary albumin excretion and a decline in glomerular filtration rate (GFR), which occur in association with an increase in blood pressure, ultimately leading to end-stage renal failure.¹ These renal functional changes develop as a consequence of structural abnormalities, including glomerular basement membrane thickening, mesangial expansion with extracellular matrix accumulation, changes in glomerular epithelial cells (podocytes), including a decrease in number and/or density, podocyte foot process broadening and effacement, glomerulosclerosis, and tubulointerstitial fibrosis.

Diabetic nephropathy occurs only in a minority of subjects with either type 1 or type 2 diabetes and seems to result from the interaction between genetic susceptibility and environmental insults, primarily metabolic and hemodynamic in origin. Over the last decade, the cellular and molecular mechanisms by which these insults translate to structural and functional abnormalities leading to diabetic nephropathy have been increasingly delineated. In particular, it has been determined that both metabolic and hemodynamic stimuli lead to the activation of key intracellular signaling pathways and transcription factors, thus triggering the production/release of cytokines, chemokines, and growth factors, which mediate and/or amplify renal damage.

In the present review, we summarize molecular and cellular mechanisms that seem to be responsible for hypertension-induced renal injury in diabetes, with particular focus on the role of increased intracapillary glomerular pressure, more recently discovered components of the renin–angiotensin system (RAS), such as angiotensin-converting enzyme (ACE) 2, and the increasing knowledge that has been gained emphasizing cross-talk between metabolic and hemodynamic pathways in amplifying diabetes-related renal injury.

	Impact of Hypertension on Diabetic Nephropathy

Top Introduction Impact of Hypertension on... Genetic Susceptibility,... The Role of Glomerular... Role of ACE2 Interaction Between the... References

 
The relationship between hypertension and poor vascular outcomes, including progression of renal disease, is unequivocal and independent of other confounding factors. The impact of hypertension on outcomes is exponential rather than linear.

A sustained reduction in blood pressure seems to be currently the most important single intervention to slow progressive nephropathy in type 1 and type 2 diabetes. Long-term follow-up studies of initially normotensive diabetic subjects without renal disease demonstrate a blood pressure–dependent decline in GFR with blood pressure levels within the reference range.² Patients with a blood pressure corresponding to <130/80 mm Hg rarely develop microalbuminuria and show an annual decline in GFR close to the age-matched normal population. Diabetic patients with a blood pressure between 130/80 and 140/90 mm Hg have a greater decline in GFR, with 30% of patients developing associated microalbuminuria or proteinuria over the subsequent 12 to 15 years.

In microalbuminuric and proteinuric type 1 and 2 diabetic patients, numerous studies have demonstrated that treatment of hypertension, irrespective of the agent used, produces a beneficial effect on albuminuria.³ Aggressive targets for blood pressure control in diabetic patients have been shown to result in reduced development and retardation in the progression of incipient and overt nephropathy, as well as decreasing macrovascular events.⁴

	Genetic Susceptibility, Hypertension, and Diabetic Nephropathy

Top Introduction Impact of Hypertension on... Genetic Susceptibility,... The Role of Glomerular... Role of ACE2 Interaction Between the... References

 
The finding that diabetic nephropathy occurs only in a subset of subjects with either type 1 or type 2 diabetes and tends to cluster in families is consistent with the hypothesis of a role of genetic susceptibility in the development of this complication. The observation that subjects with diabetic nephropathy and their first-degree relatives are characterized by higher frequency of hypertension has led to the postulate that susceptibility to develop nephropathy in the setting of diabetes might be influenced by an inherited predisposition to essential hypertension.^5,6

A number of candidate genes for diabetic nephropathy involved in blood pressure regulation have been studied with controversial results mainly ascribed to the small size of the studies and the heterogeneity of the populations examined. Because of the central role of the RAS in the initiation and progression of diabetic nephropathy and the use of agents that interrupt the RAS in this condition, particular interest has been addressed to genes encoding for various components of this system. A number of studies have focused on the role of the ACE gene insertion/deletion (I/D) polymorphism, with a recent meta-analysis, including 14 727 subjects from 47 studies, supporting the association between the ACE gene I/D polymorphism and diabetic nephropathy.⁷ Specifically, the risk of diabetic nephropathy seems to be reduced in both type 1 and type 2 diabetic white subjects and, most markedly, in type 2 diabetic Asian subjects with the II genotype.⁷ Furthermore, current literature suggests that the ACE D/D genotype predicts poor renal response to ACE inhibitors and to agents that do not block the RAS in subjects with diabetic nephropathy.⁸

Other genes that have been implicated in the development of diabetic nephropathy include the D3S1308 marker located in the angiotensin II type 1 (AT₁) receptor region^9,10 and genes linked to sodium homeostasis, such as the SLC12A3 (solute carrier family 12 member [sodium/chloride]) gene.^11–13 Furthermore, other genes linked to the RAS, such as the AT₁ receptor,^9,10 as well as other vasoactive hormones, such as endothelin,⁹ urotensin II,⁹ and atrial natriuretic peptides,⁹ have been examined, although results in this area have generally been negative.

As outlined previously, it is currently suggested that diabetic nephropathy occurs as a result of the interaction between genetic and environmental factors. This concept does not diminish the importance of the study of specific genetic polymorphisms, which might allow for identification of groups with high risk of developing diabetic nephropathy, thus providing novel therapeutic targets or individualized treatment strategies⁸ for both the prevention and treatment of this complication.¹⁴

	The Role of Glomerular Capillary Hypertension

Top Introduction Impact of Hypertension on... Genetic Susceptibility,... The Role of Glomerular... Role of ACE2 Interaction Between the... References

 
Classical renal micropuncture studies performed >20 years ago suggested that glomerular hypertension, as seen in experimental diabetes even in the setting of a normal systemic blood pressure, was central to the initiation and progression of diabetic nephropathy.¹⁵ Diabetes amplifies the deleterious effects of blood pressure within the glomerulus by inducing impairment in the autoregulation of the glomerular microcirculation. This consists of vasodilatation of both the afferent and the efferent arteriole, with a more pronounced effect on the afferent arteriole, thus resulting in an increase in intraglomerular capillary pressure.¹⁵ A number of observations suggest a role for glomerular capillary hypertension in the pathogenesis of diabetes-associated kidney disease. Glomerular structural abnormalities reminiscent of diabetic nephropathy have been observed in various forms of progressive renal disease characterized by increases in intraglomerular capillary pressure.^16–18 Furthermore, strategies that increase glomerular capillary pressure, including contralateral renal arterial clipping¹⁹ and ablation of the contralateral kidney,²⁰ enhance the severity of glomerular lesions in diabetic rats.¹⁷ In addition, prevention of glomerular capillary hypertension via either ACE inhibition or low protein diets has been shown to be renoprotective in experimental diabetes.^17,21 Indeed, the efficacy of ACE inhibitors in retarding the progression of diabetic nephropathy has been considered to partly occur as a result of their hemodynamic effect, specifically decreasing glomerular capillary pressure through a vasodilatory effect on the glomerular efferent arteriole.²²

Because of the elastic properties of the glomeruli, changes in glomerular capillary pressure are paralleled by changes in overall glomerular volume.^23,24 These changes in volume are mild in physiological states and become significantly amplified in conditions characterized by impaired autoregulation, including diabetes.²⁴ Cyclic changes in glomerular volume lead to recurrent episodes of stretch and relaxation of all of the glomerular structural components,^23,24 including mesangial cells²⁴ and podocytes.²⁵ The cellular and molecular mechanisms by which glomerular capillary hypertension leads to changes that promote glomerulosclerosis in these cell types have been explored and partly delineated only in recent years using the in vitro model of mechanical stretch.

Mesangial cells, when exposed to continuous cycles of stretch/relaxation, alter their morphology. Specifically, these cells change from their normal stellate to a straplike appearance, aligning with their long axis perpendicular to the direction of stress.²⁶ This leads to enhanced proliferation²⁶ and increased production of extracellular matrix components. This prosclerotic effect of stretch occurs partly as a result of increases in gene and/or protein expression of extracellular matrix components, such as collagen I,^26–28 III,^26,27 and IV,^27,28 fibronectin,^27,28 and laminin.^27,28 This effect is proportional to the degree of stretch, with the greatest increase at the periphery of the culture dish at the point of greatest deformation.^27,28 Furthermore, this accumulation of extracellular matrix, which occurs as a result of mechanical stretch, is markedly enhanced in a milieu with a high glucose concentration.²⁹

Mechanical stretch may promote extracellular matrix accumulation in cultured mesangial cells, not only by increasing synthesis of extracellular matrix components, but also by decreasing the activity of degradative enzymes.²⁷ Furthermore, mechanical stretch induces both gene^27,30 and protein³⁰ expression of transforming growth factor (TGF)-ß1, a potent prosclerotic cytokine and a well-known mediator of extracellular matrix accumulation in diabetic nephropathy.³¹ In addition, stretch enhances both gene and protein expression of the TGF-ß receptors I and II.³² Therefore, mechanical stretch influences TGF-ß activity by several mechanisms including altering mRNA levels and secretion, activation of the molecule itself, and increasing expression of 2 key TGF-ß receptors.³² However, the relative importance of TGF-ß1 expression in mediating extracellular matrix deposition in this context remains controversial. Indeed, a previous study suggested that it was unlikely that the increase in gene expression of extracellular matrix proteins by mechanical stretch was secondary to increased production of TGF-ß1.²⁷ By contrast, other studies have demonstrated an important role of mechanical stretch-induced TGF-ß1 as a mediator of extracellular matrix deposition in mesangial cells.^33,34 In particular, it has been suggested that stretch induces fibronectin via a biphasic signaling pathway.³⁴ Specifically, stretch, via the intracellular signaling molecule protein kinase C, causes early activation of p38 mitogen-activated protein kinase, which induces TGF-ß1 and fibronectin production.³⁴ In turn, TGF-ß1 maintains a late phase of p38 mitogen-activated protein kinase activation, which perpetuates fibronectin production.³⁴ Mechanical stretch has also been shown to induce gene expression but not protein secretion of connective tissue growth factor, a downstream mediator of TGF-ß1 signaling.³⁵

Therefore, mechanical stretch in mesangial cells results in increased extracellular matrix production directly, via the release of prosclerotic cytokines, and via decreases in extracellular matrix degradation. Interestingly, it seems that only stretch-simulating pathological conditions (10% elongation) are necessary to induce cytokine or matrix production, because a physiological degree of stretch (4% elongation) does not result in these effects.³⁴ Mechanical stretch may also induce extracellular matrix deposition by interacting with specific metabolic, hemodynamic, and inflammatory pathways. Specifically, stretch amplifies the effects of glucose and angiotensin II (Ang II) and enhances the expression of the chemokine monocyte chemoattractant protein-1 (MCP-1)³⁶ and the adhesion molecule intercellular adhesion molecule-1 (ICAM-1).³⁷

Mechanical stretch in mesangial cells upregulates protein expression of the facilitative glucose transporter (GLUT)-1, as well as basal glucose transport through a TGF-ß1–dependent mechanism.³⁸ The importance of GLUT-1 per se is suggested by studies where specific GLUT-1 overexpression in mesangial cells in a normal glucose medium leads to excess extracellular matrix production.^38,39 Therefore, mechanical stretch-induced GLUT-1 expression may represent a mechanism whereby mechanical forces interact with glucose-mediated pathways in the pathogenesis of the glomerular injury.³⁸ This concept is further strengthened by the in vivo observation where an 80% increase in GLUT-1 expression was observed in hypertensive Dahl salt-sensitive rats, a model of systemic hypertension accompanied by glomerular hypertension and injury, but not in similarly hypertensive spontaneously hypertensive rats that do not have a concomitant increase in intraglomerular pressure.³⁸

The powerful vasoconstrictor and trophic hormone Ang II is a central mediator of renal damage in diabetes. In mesangial cells, it produces effects similar to those seen with mechanical stretch, including cell hypertrophy and hyperplasia, accumulation of extracellular matrix, and production of cytokines, chemokines, and growth factors, such as TGF-ß1, connective tissue growth factor, interleukin-6, MCP-1, and vascular endothelial growth factor (VEGF). The existence of an interaction between Ang II and mechanical stretch in cultured mesangial cells has been reported by Gruden et al.⁴⁰ Both Ang II⁴⁰ and mechanical stretch^40,41 can independently induce the production of VEGF. Furthermore, pre-exposure to mechanical stretch results in upregulation of the AT₁ receptor (AT1R) subtype, which, in turn, translates to an enhanced cellular response to Ang II. Specifically, Ang II and stretch confer additive effects on VEGF production,⁴⁰ a potent promoter of vascular permeability, which specifically in this cell type induces proliferation⁴² and enhances collagen synthesis.⁴³

Mechanical stretch may also trigger an inflammatory response in mesangial cells. Indeed, stretch induces both gene expression and protein secretion of MCP-1³⁶ and reduces both gene and protein expression of CC chemokine receptor 2,⁴⁴ the cognate MCP-1 receptor. MCP-1 secretion paralleled by CC chemokine receptor 2 downregulation is a common pattern of response to known inducers of MCP-1, as reported previously in mesangial cells exposed to high glucose⁴⁵ and in monocytes exposed to tumor necrosis factor-,⁴⁶ lipopolysaccharides,⁴⁷ and interferon-.⁴⁸ It has been postulated that at sites of inflammation, this response, by enhancing local MCP-1 availability, favors recruitment of monocytes.⁴⁹ Accordingly, stretch-induced MCP-1 significantly enhances the ability of mesangial cells to attract monocytes.³⁶ Furthermore, both stretch^37,44 and MCP-1⁴⁴ independently induce ICAM-1 expression, which, in turn, significantly enhances phagocytic leukocyte adhesion to mesangial cells.^37,44 This physical interaction is a key event in the amplification of the inflammatory cascade⁵⁰ and may contribute to glomerular injury by inducing the release of cytotoxic reactive oxygen species.⁵¹

These proinflammatory effects of mechanical stretch provide a further mechanism by which glomerular capillary hypertension may exert deleterious effects in diabetic glomerulopathy. Indeed, glomerular infiltration of macrophages has been histologically demonstrated in renal biopsies from patients with diabetic nephropathy,⁵² with both MCP-1 and ICAM-1 having been implicated in the pathogenesis of diabetic nephropathy. Specifically, both proteins are overexpressed in the glomeruli from diabetic animals.^53,54 Furthermore, there is amelioration of both proteinuria and glomerular histological damage in both ICAM-1⁵⁵ and MCP-1⁵⁶ knockout mice in the setting of concomitant diabetes. The mechanisms described above by which mechanical stretch may contribute to mesangial cells extracellular matrix deposition are summarized in Figure 1.

View larger version (16K): [in this window] [in a new window]   Figure 1. Schematic representation of mechanisms whereby stretch may induce extracellular matrix (ECM) deposition in mesangial cells.

As mentioned previously, diabetic nephropathy is characterized by additional structural abnormalities and, in particular, a decrease in the number and/or density of podocytes. These epithelial cells play a major role in the synthesis of matrix proteins of the glomerular basement membrane, in the maintenance of glomerular barrier function, and in counteracting capillary wall distension.^57,58 Therefore, podocytes are constantly exposed to mechanical stress.²⁵ Furthermore, these cells are very sensitive to mechanical force,^25,59 which, specifically, reduces the size of the cell bodies of the podocyte and induces a reversible reorganization of the actin cytoskeleton consisting of a disappearance in transverse stress fibers and formation of radial stress fibers connected to an actin-rich center.⁵⁹ It has been suggested that podocytes assume a state of intermediate adhesion as a strategy to avoid mechanical damage.²⁵ However, this state of intermediate adhesion may ultimately be maladaptive, because reduced adhesion may lead to progressive podocyte loss, with these cells detaching more readily from the glomerulus.²⁵

Mechanical stretch may favor a decrease in podocyte number through several mechanisms, including effects on proliferation, apoptosis, and cell adhesion to the basement membrane (Figure 2). Stretching podocytes in vitro reduces proliferation by decreasing the expression of positive cell cycle regulatory proteins and by increasing the expression of cyclin-dependent kinase inhibitors.⁵⁷ In addition, mechanical stretch has been shown to induce Secreted Protein Acidic and Rich in Cysteine, a matricellular protein mediating cell–matrix interactions, which diminishes proliferative capacity in various tissue systems.^60,61 It has been postulated that this induction of secreted protein acidic and rich in cysteine may lead to a progressive reduction in podocyte number, potentially via a TGF-ß1–dependent mechanism.⁶⁰ Furthermore, podocyte exposure to mechanical stretch results in the activation of a local tissue angiotensin system, consisting of increased production of Ang II and increased expression of the AT1R, which ultimately leads to an increase in podocyte apoptosis.⁶² Interestingly, stretch-induced apoptosis is not completely abrogated by Ang II blockade, suggesting that mechanical stretch may also induce apoptosis via non-Ang II–dependent pathways.⁶² A potential mediator could be TGF-ß1, of which the gene expression is induced by mechanical stretch in podocytes.⁶² Indeed, this growth factor has been reported to induce podocyte apoptosis,⁶⁰ although the relative importance of TGF-ß1 in explaining podocyte depletion in diabetes remains to be fully clarified. Other than the proapoptotic effect, Ang II in podocytes results in effects that may be relevant for extracellular matrix production and alteration of the permselectivity of the glomerular filtration barrier. Specifically, Ang II enhances production of 3(IV) collagen via TGF-ß and VEGF signaling⁶³ and downregulates nephrin expression⁶⁴ in podocytes. Nephrin is a protein specifically localized to the slit pore diaphragm of the podocyte and is implicated in the pathogenesis of proteinuria. Indeed, nephrin downregulation may be closely linked to the pathogenesis of diabetic nephropathy. A decrease in expression of nephrin occurs in vitro in podocytes exposed to glucose-modified proteins known as advanced glycation end products (AGEs)⁶⁴ and in vivo in streptozotocin-induced diabetic rats^65,66 and human diabetic nephropathy.^64,67 Furthermore, in both experimental^65,66 and human⁶⁷ diabetes, this depletion in renal nephrin expression is prevented by RAS blockade. Although Ang II has been reported to promote extracellular matrix accumulation and nephrin downregulation in podocytes, it remains to be determined whether stretch via an Ang II–dependent pathway has similar effects in these glomerular epithelial cells.

View larger version (11K): [in this window] [in a new window]   Figure 2. Schematic representation of mechanisms whereby stretch may lead to a decrease in podocyte number. SPARC indicates secreted protein acidic and rich in cysteine; CDK, cyclin-dependent kinases; GBM, glomerular basement membrane.

Finally, mechanical stretch may interfere with podocyte adhesion to the glomerular basement membrane. The integrin 3ß1 is an adhesion molecule, which is primarily involved in podocyte adhesion to the glomerular basement membrane.⁶⁸ The expression of 3ß1integrin is reduced in vitro in podocytes exposed to high glucose and in vivo in podocytes not only from streptozotocin-induced diabetic rats but also in patients with diabetic nephropathy.⁶⁸ Preliminary evidence suggests that mechanical stretch may reduce both the expression of the integrin 3ß1 and podocyte adhesion to an extracellular matrix substrate,⁶⁹ providing a mechanism whereby glomerular capillary hypertension may favor the detachment of podocytes from the glomerular basement membrane. Overall, these mechanisms of stretch-induced podocyte abnormalities may provide a key explanation for progressive podocyte loss and glomerulosclerosis in diseases associated with glomerular capillary hypertension, including diabetic nephropathy.⁶²

	Role of ACE2

Top Introduction Impact of Hypertension on... Genetic Susceptibility,... The Role of Glomerular... Role of ACE2 Interaction Between the... References

 
A major role for the local RAS in the development and progression of diabetic nephropathy has been clearly demonstrated and reviewed elsewhere⁷⁰ and is beyond the scope of this review. Here, we would like to focus on a new component of the RAS, ACE2, a homologue of ACE, which may be relevant in various pathophysiological states, including hypertension,^71–74 cardiovascular disease,^74,75 and diabetic nephropathy,^75–77 thus representing a novel treatment target for these conditions.^78,79

ACE2 is part of the enzymatic cascade of the RAS. Specifically, it seems to act as a negative regulator of the RAS, counterbalancing the function of ACE,⁷⁵ thus promoting vasodilation. Indeed, it is implicated in the conversion of Ang I to Ang (1-9) and in the degradation of Ang II to Ang (1-7), a peptide that has been postulated to counteract the potentially detrimental actions of Ang II via the AT1R, resulting in vasodilator, natriuretic, and antiproliferative effects.^75,80 Furthermore, ACE2 is involved in cleavage of other vasoactive peptides, such as apelin, neurotensin, kinetensin, and des-Arg bradykinin.⁷⁵

ACE2 is highly expressed in a variety of tissues, although its distribution is much less widespread than ACE. Such sites of ACE2 expression include the heart and kidney. In the kidney, ACE2 has a distribution similar to ACE with major localization in renal tubules.^76,77

Both ACE2 gene and protein expression are downregulated in the kidneys in experimental models of hypertension⁷⁴ and in streptozotocin-induced diabetic Sprague–Dawley rats after 24 weeks of diabetes.⁷⁶ It is not yet known whether this reduction in ACE2 is of pathophysiological significance, but it has been postulated that renal ACE2 deficiency as occurs in long-term diabetes leads to a local increase in tubular Ang II, which, in turn, may promote tubulointerstitial fibrosis.⁷⁶ Interestingly, ACE inhibition seems to prevent the diabetes-associated decreases in renal ACE2 expression, suggesting that ACE inhibition may confer some of its renoprotective effects via modulation of ACE2 expression.⁷⁶

Although ACE2 expression seems to be downregulated in diabetes-associated kidney disease, there is evidence suggesting that ACE2 expression is increased in early phases of diabetes in the absence of renal injury. Indeed, protein expression of ACE2 is increased in renal cortical tubules of diabetic db/db mice, a model of type 2 diabetes, after 3 to 4 weeks of diabetes, when renal complications have not as yet developed.⁷⁷ Furthermore, in the same model, the increase in ACE2 expression was paralleled by a decrease in ACE protein expression,⁷⁷ and it has been postulated that this combination may provide renoprotection by attenuating Ang II accumulation and increasing Ang 1-7 formation.⁷⁷ The finding of increased ACE2 protein expression in renal cortical tubules from young mice prone to type 2 diabetes (db/db mice) does not exclude the possibility of a later reduction in ACE2 during the course of the disease as nephropathy develops.⁷⁷ Indeed, older ACE2 knockout mice develop glomerulosclerosis that resembles to a certain extent diabetic nephropathy.⁷⁵ Thus, it would now be of interest to specifically examine various models of ACE2 deficiency and excess in the context of diabetes.

	Interaction Between the Hemodynamic and Metabolic Pathways

Top Introduction Impact of Hypertension on... Genetic Susceptibility,... The Role of Glomerular... Role of ACE2 Interaction Between the... References

 
There is increasing evidence that the hemodynamic and metabolic pathways, rather than acting independently, are functionally linked in diabetic nephropathy. As outlined earlier, glucose, per se, amplifies the effects of blood pressure within the glomerulus by inducing impairment in the autoregulation of the glomerular microcirculation. On the other hand, glomerular capillary hypertension enhances GLUT-1 expression with a concomitant increase in intracellular glucose accumulation, amplifying the deleterious effects of glucose and its metabolites within the kidney.³⁸ Therefore, in diabetes, both metabolic and hemodynamic factors interact to modify the glomerular microcirculation, creating an environment conducive to progressive glomerular injury.

Patients with poor glycemic control show a greater reduction in intrarenal vascular resistance after blockade of the RAS than that seen in subjects with good metabolic control,^81,82 suggesting that the activity of the intrarenal RAS may be influenced by metabolic factors.⁸² How glucose, per se, induces injury in the kidney remains an area of active investigation, with various pathways having been identified, including promotion of mitochondrial superoxide production⁸³ and enhanced generation of AGEs. These AGEs occur as a result of a series of biochemical reactions involving glucose attaching to proteins, lipids, and nucleic acids. In vitro and in vivo studies have characterized functional interactions between these AGEs and the RAS. In vitro, in mesangial cells, AGE-mediated reactive oxygen species generation via an AGE receptor known as Receptor for Advanced Glycation End products (RAGE) induces autocrine production of Ang II, which results in activation of TGF-ß-Smad signaling, cell hypertrophy, and fibronectin synthesis.⁸⁴ In vivo, in streptozotocin-induced diabetic Sprague–Dawley rats, renal AGE accumulation is attenuated to a similar degree by both an ACE inhibitor and an AGE formation inhibitor.⁸⁵ Furthermore, in Sprague–Dawley rats, infusion of AGE-modified rat serum albumin results in a significant increase in renal expression of various components of the vasoconstrictor arm of the RAS.⁸² This is associated with tubular and glomerular hypertrophy and AGE accumulation, which can be antagonized by the AT1R blocker valsartan. In the same model, an infusion of Ang II increases both serum and renal accumulation of AGEs and advanced oxidation products and induces renal hypertrophy that can be antagonized by an inhibitor of AGE formation, pyridoxamine.⁸²

Overall, these in vitro and in vivo observations demonstrate the existence of a functional interaction between AGEs and the RAS. Furthermore, the in vivo findings demonstrate that both pathways and their structural effects may be partly blocked by inhibitors of the other pathway, reinforcing the concept of the potential use of combination therapy in a diabetic context.⁸² Indeed, in studies performed in diabetic spontaneously hypertensive rats, monotherapy with either the ACE inhibitor perindopril or the inhibitor of AGE formation aminoguanidine attenuated development of albuminuria in this model, with the combination even more effective than the individual agents.⁶⁶ It remains to be determined as to the clinical translatability of these experimental findings, although the situation with respect to the RAS has generally indicated that positive findings in rodents with agents that interrupt the RAS would translate to humans. For example, the exciting initial findings observed in diabetic rats in response to ACE inhibitors and, subsequently, AT1R antagonists were ultimately translated to the clinic in both type 1 and type 2 diabetes. Therefore, with the widespread use of agents that interrupt the RAS as first-line treatment in diabetic patients at risk or with nephropathy, further studies of new renoprotective therapies will now need to be performed in the context of concomitant ACE inhibitor or AT1R antagonist treatment.

	Acknowledgments

 
Disclosures

None.

Received May 31, 2006; first decision June 17, 2006; accepted August 2, 2006.

	References

Top Introduction Impact of Hypertension on... Genetic Susceptibility,... The Role of Glomerular... Role of ACE2 Interaction Between the... References

 
1. Cooper ME. Pathogenesis, prevention, and treatment of diabetic nephropathy. Lancet. 1998; 352: 213–219.[CrossRef][Medline] [Order article via Infotrieve]

2. Ravid M, Savin H, Jutrin I, Bental T, Katz B, Lishner M. Long-term stabilizing effect of angiotensin-converting enzyme inhibition on plasma creatinine and on proteinuria in normotensive type II diabetic patients. Ann Intern Med. 1993; 118: 577–581.[Abstract/Free Full Text]

3. Mogensen CE. Microalbuminuria and hypertension with focus on type 1 and type 2 diabetes. J Intern Med. 2003; 254: 45–66.[CrossRef][Medline] [Order article via Infotrieve]

4. Schrier RW, Estacio RO, Esler A, Mehler P. Effects of aggressive blood pressure control in normotensive type 2 diabetic patients on albuminuria, retinopathy and strokes. Kidney Int. 2002; 61: 1086–1097.[CrossRef][Medline] [Order article via Infotrieve]

5. Viberti GC, Earle K. Predisposition to essential hypertension and the development of diabetic nephropathy. J Am Soc Nephrol. 1992; 3: S27–S33.[Abstract]

6. Viberti G. Why do we have to invoke genetic susceptibility for diabetic nephropathy? Kidney Int. 1999; 55: 2526–2527.[CrossRef][Medline] [Order article via Infotrieve]

7. Ng DP, Tai BC, Koh D, Tan KW, Chia KS. Angiotensin-I converting enzyme insertion/deletion polymorphism and its association with diabetic nephropathy: a meta-analysis of studies reported between 1994 and 2004 and comprising 14,727 subjects. Diabetologia. 2005; 48: 1008–1016.[CrossRef][Medline] [Order article via Infotrieve]

8. Jacobsen PK, Tarnow L, Parving HH. Time to consider ACE insertion/deletion genotypes and individual renoprotective treatment in diabetic nephropathy? Kidney Int. 2006; 69: 1293–1295.[CrossRef][Medline] [Order article via Infotrieve]

9. Ewens KG, George RA, Sharma K, Ziyadeh FN, Spielman RS. Assessment of 115 candidate genes for diabetic nephropathy by transmission/disequilibrium test. Diabetes. 2005; 54: 3305–3318.[Abstract/Free Full Text]

10. Moczulski DK, Rogus JJ, Antonellis A, Warram JH, Krolewski AS. Major susceptibility locus for nephropathy in type 1 diabetes on chromosome 3q: results of novel discordant sib-pair analysis. Diabetes. 1998; 47: 1164–1169.[Abstract]

11. Nishiyama K, Tanaka Y, Nakajima K, Mokubo A, Atsumi Y, Matsuoka K, Watada H, Hirose T, Nomiyama T, Maeda S, Kawamori R. Polymorphism of the solute carrier family 12 (sodium/chloride transporters) member 3, SLC12A3, gene at exon 23 (+78G/A: Arg913Gln) is associated with elevation of urinary albumin excretion in Japanese patients with type 2 diabetes: a 10-year longitudinal study. Diabetologia. 2005; 48: 1335–1338.[CrossRef][Medline] [Order article via Infotrieve]

12. Tanaka N, Babazono T, Saito S, Sekine A, Tsunoda T, Haneda M, Tanaka Y, Fujioka T, Kaku K, Kawamori R, Kikkawa R, Iwamoto Y, Nakamura Y, Maeda S. Association of solute carrier family 12 (sodium/chloride) member 3 with diabetic nephropathy, identified by genome-wide analyses of single nucleotide polymorphisms. Diabetes. 2003; 52: 2848–2853.[Abstract/Free Full Text]

13. Kim JH, Shin HD, Park BL, Moon MK, Cho YM, Hwang YH, Oh KW, Kim SY, Lee HK, Ahn C, Park KS. SLC12A3 (solute carrier family 12 member [sodium/chloride] 3) polymorphisms are associated with end-stage renal disease in diabetic nephropathy. Diabetes. 2006; 55: 843–848.[Abstract/Free Full Text]

14. Thomas MC. Inherited susceptibility to diabetic nephropathy. In: Boner G, Cooper ME, eds. Management of Diabetic Nephropathy. London, United Kingdom: Martin Dunitz Ltd; 2003: 61–73.

15. Hostetter TH, Rennke HG, Brenner BM. The case for intrarenal hypertension in the initiation and progression of diabetic and other glomerulopathies. Am J Med. 1982; 72: 375–380.[CrossRef][Medline] [Order article via Infotrieve]

16. Olson JL, Hostetter TH, Rennke HG, Brenner BM, Venkatachalam MA. Altered glomerular permselectivity and progressive sclerosis following extreme ablation of renal mass. Kidney Int. 1982; 22: 112–126.[Medline] [Order article via Infotrieve]

17. Zatz R, Meyer TW, Rennke HG, Brenner BM. Predominance of hemodynamic rather than metabolic factors in the pathogenesis of diabetic glomerulopathy. Proc Natl Acad Sci U S A. 1985; 82: 5963–5967.[Abstract/Free Full Text]

18. Dworkin LD, Hostetter TH, Rennke HG, Brenner BM. Hemodynamic basis for glomerular injury in rats with desoxycorticosterone-salt hypertension. J Clin Invest. 1984; 73: 1448–1461.[Medline] [Order article via Infotrieve]

19. Mauer SM, Steffes MW, Azar S, Sandberg SK, Brown DM. The effects of Goldblatt hypertension on development of the glomerular lesions of diabetes mellitus in the rat. Diabetes. 1978; 27: 738–744.[Abstract]

20. Steffes MW, Brown DM, Mauer SM. Diabetic glomerulopathy following unilateral nephrectomy in the rat. Diabetes. 1978; 27: 35–41.[Abstract]

21. Zatz R, Dunn BR, Meyer TW, Anderson S, Rennke HG, Brenner BM. Prevention of diabetic glomerulopathy by pharmacological amelioration of glomerular capillary hypertension. J Clin Invest. 1986; 77: 1925–1930.[Medline] [Order article via Infotrieve]

22. Bernadet-Monrozies P, Rostaing L, Kamar N, Durand D. The effect of angiotensin-converting enzyme inhibitors on the progression of chronic renal failure. Presse Med. 2002; 31: 1714–1720.[Medline] [Order article via Infotrieve]

23. Cortes P, Zhao X, Riser BL, Narins RG. Regulation of glomerular volume in normal and partially nephrectomized rats. Am J Physiol. 1996; 270: F356–F370.[Medline] [Order article via Infotrieve]

24. Cortes P, Riser BL, Yee J, Narins RG. Mechanical strain of glomerular mesangial cells in the pathogenesis of glomerulosclerosis: Clinical implications. Nephrol Dial Transplant. 1999; 14: 1351–1354.[Free Full Text]

25. Endlich N, Endlich K. Stretch, tension and adhesion- Adaptive mechanisms of the actin cytoskeleton in podocytes. Eur J Cell Biol. 2006; 85: 229–234.[CrossRef][Medline] [Order article via Infotrieve]

26. Harris RC, Haralson MA, Badr KF. Continuous stretch-relaxation in culture alters rat mesangial cell morphology, growth characteristics, and metabolic activity. Lab Invest. 1992; 66: 548–554.[Medline] [Order article via Infotrieve]

27. Yasuda T, Kondo S, Homma T, Harris RC. Regulation of extracellular matrix by mechanical stress in rat glomerular mesangial cells. J Clin Invest. 1996; 98: 1991–2000.[Medline] [Order article via Infotrieve]

28. Riser BL, Cortes P, Zhao X, Bernstein J, Dumler F, Narins RG. Intraglomerular pressure and mesangial stretching stimulate extracellular matrix formation in the rat. J Clin Invest. 1992; 90: 1932–1943.[Medline] [Order article via Infotrieve]

29. Cortes P, Zhao X, Riser BL, Narins RG. Role of glomerular mechanical strain in the pathogenesis of diabetic nephropathy. Kidney Int. 1997; 51: 57–68.[Medline] [Order article via Infotrieve]

30. Riser BL, Cortes P, Heilig C, Grondin J, Ladson-Wofford S, Patterson D, Narins RG. Cyclic stretching force selectively up-regulates transforming growth factor-beta isoforms in cultured rat mesangial cells. Am J Pathol. 1996; 148: 1915–1923.[Abstract]

31. Ziyadeh FN, Sharma K, Ericksen M, Wolf G. Stimulation of collagen gene expression and protein synthesis in murine mesangial cells by high glucose is mediated by autocrine activation of transforming growth factor-beta. J Clin Invest. 1994; 93: 536–542.[Medline] [Order article via Infotrieve]

32. Riser BL, Ladson-Wofford S, Sharba A, Cortes P, Drake K, Guerin CJ, Yee J, Choi ME, Segarini PR, Narins RG. TGF-beta receptor expression and binding in rat mesangial cells: modulation by glucose and cyclic mechanical strain. Kidney Int. 1999; 56: 428–439.[CrossRef][Medline] [Order article via Infotrieve]

33. Hirakata M, Kaname S, Chung UG, Joki N, Hori Y, Noda M, Takuwa Y, Okazaki T, Fujita T, Katoh T, Kurokawa K. Tyrosine kinase dependent expression of TGF-beta induced by stretch in mesangial cells. Kidney Int. 1997; 51: 1028–1036.[Medline] [Order article via Infotrieve]

34. Gruden G, Zonca S, Hayward A, Thomas S, Maestrini S, Gnudi L, Viberti GC. Mechanical stretch-induced fibronectin and transforming growth factor-beta1 production in human mesangial cells is p38 mitogen-activated protein kinase-dependent. Diabetes. 2000; 49: 655–661.[Abstract]

35. Riser BL, Cortes P. Connective tissue growth factor and its regulation: a new element in diabetic glomerulosclerosis. Ren Fail. 2001; 23: 459–470.[CrossRef][Medline] [Order article via Infotrieve]

36. Gruden G, Setti G, Hayward A, Sugden D, Duggan S, Burt D, Buckingham RE, Gnudi L, Viberti G. Mechanical stretch induces monocyte chemoattractant activity via an NF-kappaB-dependent monocyte chemoattractant protein-1-mediated pathway in human mesangial cells: inhibition by rosiglitazone. J Am Soc Nephrol. 2005; 16: 688–696.[Abstract/Free Full Text]

37. Riser BL, Varani J, Cortes P, Yee J, Dame M, Sharba AK. Cyclic stretching of mesangial cells up-regulates intercellular adhesion molecule-1 and leukocyte adherence: A possible new mechanism for glomerulosclerosis. Am J Pathol. 2001; 158: 11–17.[Abstract/Free Full Text]

38. Gnudi L, Viberti G, Raij L, Rodriguez V, Burt D, Cortes P, Hartley B, Thomas S, Maestrini S, Gruden G. GLUT-1 overexpression: link between hemodynamic and metabolic factors in glomerular injury? Hypertension. 2003; 42: 19–24.[Abstract/Free Full Text]

39. Heilig CW, Concepcion LA, Riser BL, Freytag SO, Zhu M, Cortes P. Overexpression of glucose transporters in rat mesangial cells cultured in a normal glucose milieu mimics the diabetic phenotype. J Clin Invest. 1995; 96: 1802–1814.[Medline] [Order article via Infotrieve]

40. Gruden G, Thomas S, Burt D, Zhou W, Chusney G, Gnudi L, Viberti G. Interaction of angiotensin II and mechanical stretch on vascular endothelial growth factor production by human mesangial cells. J Am Soc Nephrol. 1999; 10: 730–737.[Abstract/Free Full Text]

41. Gruden G, Thomas S, Burt D, Lane S, Chusney G, Sacks S, Viberti G. Mechanical stretch induces vascular permeability factor in human mesangial cells: mechanisms of signal transduction. Proc Natl Acad Sci U S A. 1997; 94: 12112–12116.[Abstract/Free Full Text]

42. Thomas S, Vanuystel J, Gruden G, Rodriguez V, Burt D, Gnudi L, Hartley B, Viberti G. Vascular endothelial growth factor receptors in human mesangium in vitro and in glomerular disease. J Am Soc Nephrol. 2000; 11: 1236–1243.[Abstract/Free Full Text]

43. Amemiya T, Sasamura H, Mifune M, Kitamura Y, Hirahashi J, Hayashi M, Saruta T. Vascular endothelial growth factor activates MAP kinase and enhances collagen synthesis in human mesangial cells. Kidney Int. 1999; 56: 2055–2063.[CrossRef][Medline] [Order article via Infotrieve]

44. Giunti S, Pinach S, Arnaldi L, Viberti G, Perin PC, Camussi G, Gruden G. The MCP-1/CCR2 system has direct proinflammatory effects in human mesangial cells. Kidney Int. 2006; 69: 856–863.[CrossRef][Medline] [Order article via Infotrieve]

45. Janssen U, Sowa E, Marchand P, Floege J, Phillips AO, Radeke HH. Differential expression of MCP-1 and its receptor CCR2 in glucose primed human mesangial cells. Nephron. 2002; 92: 797–806.[CrossRef][Medline] [Order article via Infotrieve]

46. Weber C, Draude G, Weber KS, Wubert J, Lorenz RL, Weber PC. Downregulation by tumor necrosis factor-alpha of monocyte CCR2 expression and monocyte chemotactic protein-1-induced transendothelial migration is antagonized by oxidized low-density lipoprotein: a potential mechanism of monocyte retention in atherosclerotic lesions. Atherosclerosis. 1999; 145: 115–123.[CrossRef][Medline] [Order article via Infotrieve]

47. Xu L, Khandaker MH, Barlic J, Ran L, Borja ML, Madrenas J, Rahimpour R, Chen K, Mitchell G, Tan CM, DeVries M, Feldman RD, Kelvin DJ. Identification of a novel mechanism for endotoxin-mediated down-modulation of CC chemokine receptor expression. Eur J Immunol. 2000; 30: 227–235.[CrossRef][Medline] [Order article via Infotrieve]

48. Penton-Rol G, Polentarutti N, Luini W, Borsatti A, Mancinelli R, Sica A, Sozzani S, Mantovani A. Selective inhibition of expression of the chemokine receptor CCR2 in human monocytes by IFN-gamma. J Immunol. 1998; 160: 3869–3873.[Abstract/Free Full Text]

49. Sica A, Saccani A, Bottazzi B, Bernasconi S, Allavena P, Gaetano B, Fei F, LaRosa G, Scotton C, Balkwill F, Mantovani A. Defective expression of the monocyte chemotactic protein-1 receptor CCR2 in macrophages associated with human ovarian carcinoma. J Immunol. 2000; 164: 733–738.[Abstract/Free Full Text]

50. Kuroiwa T, Lee EG, Danning CL, Illei GG, McInnes IB, Boumpas DT. CD40 ligand-activated human monocytes amplify glomerular inflammatory responses through soluble and cell-to-cell contact-dependent mechanisms. J Immunol. 1999; 163: 2168–2175.[Abstract/Free Full Text]

51. Mene P, Pugliese F, Cinotti GA. Adhesion of U-937 monocytes induces cytotoxic damage and subsequent proliferation of cultured human mesangial cells. Kidney Int. 1996; 50: 417–423.[Medline] [Order article via Infotrieve]

52. Furuta T, Saito T, Ootaka T, Soma J, Obara K, Abe K, Yoshinaga K. The role of macrophages in diabetic glomerulosclerosis. Am J Kidney Dis. 1993; 21: 480–485.[Medline] [Order article via Infotrieve]

53. Sassy-Prigent C, Heudes D, Mandet C, Belair MF, Michel O, Perdereau B, Bariety J, Bruneval P. Early glomerular macrophage recruitment in streptozotocin-induced diabetic rats. Diabetes. 2000; 49: 466–475.[Abstract]

54. Sugimoto H, Shikata K, Hirata K, Akiyama K, Matsuda M, Kushiro M, Shikata Y, Miyatake N, Miyasaka M, Makino H. Increased expression of intercellular adhesion molecule-1 (ICAM-1) in diabetic rat glomeruli: glomerular hyperfiltration is a potential mechanism of ICAM-1 upregulation. Diabetes. 1997; 46: 2075–2081.[Abstract]

55. Okada S, Shikata K, Matsuda M, Ogawa D, Usui H, Kido Y, Nagase R, Wada J, Shikata Y, Makino H. Intercellular adhesion molecule-1-deficient mice are resistant against renal injury after induction of diabetes. Diabetes. 2003; 52: 2586–2593.[Abstract/Free Full Text]

56. Chow FY, Nikolic-Paterson DJ, Ozols E, Atkins RC, Rollin BJ, Tesch GH. Monocyte chemoattractant protein-1 promotes the development of diabetic renal injury in streptozotocin-treated mice. Kidney Int. 2006; 69: 73–80.[CrossRef][Medline] [Order article via Infotrieve]

57. Petermann AT, Hiromura K, Blonski M, Pippin J, Monkawa T, Durvasula R, Couser WG, Shankland SJ. Mechanical stress reduces podocyte proliferation in vitro. Kidney Int. 2002; 61: 40–50.[CrossRef][Medline] [Order article via Infotrieve]

58. Kriz W, Hackenthal E, Nobiling R, Sakai T, Elger M, Hahnel B. A role for podocytes to counteract capillary wall distension. Kidney Int. 1994; 45: 369–376.[Medline] [Order article via Infotrieve]

59. Endlich N, Kress KR, Reiser J, Uttenweiler D, Kriz W, Mundel P, Endlich K. Podocytes respond to mechanical stress in vitro. J Am Soc Nephrol. 2001; 12: 413–422.[Abstract/Free Full Text]

60. Durvasula RV, Shankland SJ. Mechanical strain increases SPARC levels in podocytes: Implications for glomerulosclerosis. Am J Physiol Renal Physiol. 2005; 289: F577–F584.[Abstract/Free Full Text]

61. Brekken RA, Sage EH. SPARC, a matricellular protein: At the crossroads of cell-matrix communication. Matrix Biol. 2001; 19: 816–827.[Medline] [Order article via Infotrieve]

62. Durvasula RV, Petermann AT, Hiromura K, Blonski M, Pippin J, Mundel P, Pichler R, Griffin S, Couser WG, Shankland SJ. Activation of a local tissue angiotensin system in podocytes by mechanical strain. Kidney Int. 2004; 65: 30–39.[CrossRef][Medline] [Order article via Infotrieve]

63. Chen S, Lee JS, Iglesias-de la Cruz MC, Wang A, Izquierdo-Lahuerta A, Gandhi NK, Danesh FR, Wolf G, Ziyadeh FN. Angiotensin II stimulates alpha3(IV) collagen production in mouse podocytes via TGF-beta and VEGF signalling: Implications for diabetic glomerulopathy. Nephrol Dial Transplant. 2005; 20: 1320–1328.[Abstract/Free Full Text]

64. Doublier S, Salvidio G, Lupia E, Ruotsalainen V, Verzola D, Deferrari G, Camussi G. Nephrin expression is reduced in human diabetic nephropathy: Evidence for a distinct role for glycated albumin and angiotensin II. Diabetes. 2003; 52: 1023–1030.[Abstract/Free Full Text]

65. Bonnet F, Cooper ME, Kawachi H, Allen TJ, Boner G, Cao Z. Irbesartan normalises the deficiency in glomerular nephrin expression in a model of diabetes and hypertension. Diabetologia. 2001; 44: 874–877.[CrossRef][Medline] [Order article via Infotrieve]

66. Davis BJ, Forbes JM, Thomas MC, Jerums G, Burns WC, Kawachi H, Allen TJ, Cooper ME. Superior renoprotective effects of combination therapy with ACE and AGE inhibition in the diabetic spontaneously hypertensive rat. Diabetologia. 2004; 47: 89–97.[CrossRef][Medline] [Order article via Infotrieve]

67. Langham RG, Kelly DJ, Cox AJ, Thomson NM, Holthofer H, Zaoui P, Pinel N, Cordonnier DJ, Gilbert RE. Proteinuria and the expression of the podocyte slit diaphragm protein, nephrin, in diabetic nephropathy: effects of angiotensin converting enzyme inhibition. Diabetologia. 2002; 45: 1572–1576.[CrossRef][Medline] [Order article via Infotrieve]

68. Chen HC, Chen CA, Guh JY, Chang JM, Shin SJ, Lai YH. Altering expression of alpha3beta1 integrin on podocytes of human and rats with diabetes. Life Sci. 2000; 67: 2345–2353.[CrossRef][Medline] [Order article via Infotrieve]

69. Dessapt CBM, Hayward A, Viberti G, Gnudi L. TGF-ß1 and mechanical stretch reduce murine podocyte adhesion to extracellular matrix substrate and modulate ß1 integrin expression/maturation in vitro. Diabetologia. 2005; 48 (Suppl 1): A28(abstract).

70. Cooper ME. The role of the renin-angiotensin-aldosterone system in diabetes and its vascular complications. Am J Hypertens. 2004; 17: 16S–20S;quiz A12–14.

71. Diez-Freire C, Vazquez J, Correa de Adjounian MF, Ferrari MF, Yuan L, Silver X, Torres R, Raizada MK. ACE2 gene transfer attenuates hypertension linked pathophysiological changes in the SHR. Physiol Genomics. 2006. Available at: http://physiolgenomics.physiology.org/cgi/reprint/00312.2005v1.pdf. Accessed July 18, 2006.

72. Zhong J, Yan Z, Liu D, Ni Y, Zhao Z, Zhu S, Tepel M, Zhu Z. Association of angiotensin-converting enzyme 2 gene A/G polymorphism and elevated blood pressure in Chinese patients with metabolic syndrome. J Lab Clin Med. 2006; 147: 91–95.[CrossRef][Medline] [Order article via Infotrieve]

73. Yagil Y, Yagil C. Hypothesis: ACE2 modulates blood pressure in the mammalian organism. Hypertension. 2003; 41: 871–873.[Free Full Text]

74. Crackower MA, Sarao R, Oudit GY, Yagil C, Kozieradzki I, Scanga SE, Oliveira-dos-Santos AJ, da Costa J, Zhang L, Pei Y, Scholey J, Ferrario CM, Manoukian AS, Chappell MC, Backx PH, Yagil Y, Penninger JM. Angiotensin-converting enzyme 2 is an essential regulator of heart function. Nature. 2002; 417: 822–828.[CrossRef][Medline] [Order article via Infotrieve]

75. Danilczyk U, Penninger JM. Angiotensin-converting enzyme II in the heart and the kidney. Circ Res. 2006; 98: 463–471.[Abstract/Free Full Text]

76. Tikellis C, Johnston CI, Forbes JM, Burns WC, Burrell LM, Risvanis J, Cooper ME. Characterization of renal angiotensin-converting enzyme 2 in diabetic nephropathy. Hypertension. 2003; 41: 392–397.[Abstract/Free Full Text]

77. Ye M, Wysocki J, Naaz P, Salabat MR, LaPointe MS, Batlle D. Increased ACE 2 and decreased ACE protein in renal tubules from diabetic mice: a renoprotective combination? Hypertension. 2004; 43: 1120–1125.[Abstract/Free Full Text]

78. Katovich MJ, Grobe JL, Huentelman M, Raizada MK. Angiotensin-converting enzyme 2 as a novel target for gene therapy for hypertension. Exp Physiol. 2005; 90: 299–305.[Abstract/Free Full Text]

79. Der Sarkissian S, Huentelman MJ, Stewart J, Katovich MJ, Raizada MK. ACE2: a novel therapeutic target for cardiovascular diseases. Prog Biophys Mol Biol. 2006; 91: 163–198.[CrossRef][Medline] [Order article via Infotrieve]

80. Ferrario CM. Commentary on Tikellis et al: there is more to discover about angiotensin-converting enzyme. Hypertension. 2003; 41: 390–391.[Free Full Text]

81. Taniwaki H, Ishimura E, Kawagishi T, Matsumoto N, Hosoi M, Emoto M, Shoji T, Shoji S, Nakatani T, Inaba M, Nishizawa Y. Intrarenal hemodynamic changes after captopril test in patients with type 2 diabetes: a duplex Doppler sonography study. Diabetes Care. 2003; 26: 132–137.[Abstract/Free Full Text]

82. Thomas MC, Tikellis C, Burns WM, Bialkowski K, Cao Z, Coughlan MT, Jandeleit-Dahm K, Cooper ME, Forbes JM. Interactions between renin angiotensin system and advanced glycation in the kidney. J Am Soc Nephrol. 2005; 16: 2976–2984.[Abstract/Free Full Text]

83. Brownlee M. Biochemistry and molecular cell biology of diabetic complications. Nature. 2001; 414: 813–820.[CrossRef][Medline] [Order article via Infotrieve]

84. Fukami K, Ueda S, Yamagishi S, Kato S, Inagaki Y, Takeuchi M, Motomiya Y, Bucala R, Iida S, Tamaki K, Imaizumi T, Cooper ME, Okuda S. AGEs activate mesangial TGF-beta-Smad signaling via an angiotensin II type I receptor interaction. Kidney Int. 2004; 66: 2137–2147.[CrossRef][Medline] [Order article via Infotrieve]

85. Forbes JM, Cooper ME, Thallas V, Burns WC, Thomas MC, Brammar GC, Lee F, Grant SL, Burrell LA, Jerums G, Osicka TM. Reduction of the accumulation of advanced glycation end products by ACE inhibition in experimental diabetic nephropathy. Diabetes. 2002; 51: 3274–3282.[Abstract/Free Full Text]

This article has been cited by other articles:

				J. H. Garman, S. Mulroney, M. Manigrasso, E. Flynn, and C. Maric Omega-3 fatty acid rich diet prevents diabetic renal disease Am J Physiol Renal Physiol, February 1, 2009; 296(2): F306 - F316. [Abstract] [Full Text] [PDF]

				P. D. B. Ribaldo, D. S. Souza, S. K. Biswas, K. Block, J. M. Lopes de Faria, and J. B. Lopes de Faria Green tea (Camellia sinensis) Attenuates Nephropathy by Downregulating Nox4 NADPH Oxidase in Diabetic Spontaneously Hypertensive Rats J. Nutr., January 1, 2009; 139(1): 96 - 100. [Abstract] [Full Text] [PDF]

				Y. S. Kanwar, J. Wada, L. Sun, P. Xie, E. I. Wallner, S. Chen, S. Chugh, and F. R. Danesh Diabetic Nephropathy: Mechanisms of Renal Disease Progression Experimental Biology and Medicine, January 1, 2008; 233(1): 4 - 11. [Abstract] [Full Text] [PDF]

				N. K. Sweitzer, M. Shenoy, J. H. Stein, S. Keles, M. Palta, T. LeCaire, and G. F. Mitchell Increases in Central Aortic Impedance Precede Alterations in Arterial Stiffness Measures in Type 1 Diabetes Diabetes Care, November 1, 2007; 30(11): 2886 - 2891. [Abstract] [Full Text] [PDF]

				J.-S. Huang, L.-Y. Chuang, J.-Y. Guh, Y.-J. Huang, and M.-S. Hsu Antioxidants attenuate high glucose-induced hypertrophic growth in renal tubular epithelial cells Am J Physiol Renal Physiol, October 1, 2007; 293(4): F1072 - F1082. [Abstract] [Full Text] [PDF]

				Y. Kanetsuna, K. Takahashi, M. Nagata, M. A. Gannon, M. D. Breyer, R. C. Harris, and T. Takahashi Deficiency of Endothelial Nitric-Oxide Synthase Confers Susceptibility to Diabetic Nephropathy in Nephropathy-Resistant Inbred Mice Am. J. Pathol., May 1, 2007; 170(5): 1473 - 1484. [Abstract] [Full Text] [PDF]

This Article Extract Full Text (PDF) All Versions of this Article: 48/4/519    most recent 01.HYP.0000240331.32352.0cv1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Giunti, S. Articles by Cooper, M. E. Search for Related Content PubMed PubMed Citation Articles by Giunti, S. Articles by Cooper, M. E. Related Collections Animal models of human disease Type 1 diabetes Type 2 diabetes