Deferasirox effect on renal haemodynamic parameters in patients with transfusion-dependent ß thalassaemia.

Some patients with ß thalassaemia experience non-progressive creatinine increases with deferasirox, mostly within normal limits; the mechanisms involved are not fully elucidated. The effects of deferasirox on renal haemodynamics, including glomerular filtration rate (GFR) and renal plasma flow (RPF), were investigated in a Phase I, open-label study in ß thalassaemia major patients with iron overload. Patients received deferasirox 30 mg/kg/d up to Week 8, followed by a 2-week washout period, and extended treatment up to Week 104 with a 4-week washout period. In the short-term study (n = 11), mean GFR and RPF declined from baseline to Week 8 (mean [%] change:-9·2 [-9·5%] and -105·7 ml/min [-17·8%], respectively). A similar pattern was observed during the long-term study (n = 5); mean GFR and RPF decreased up to Week 52 (-19·1 [-17·7%] and -155·6 ml/min [-26·1%]), with similar change at Week 104 (-18·4 [-17·2%] and -115·9 ml/min [-19·6%]). Measures returned to baseline values after each washout. Serum creatinine and creatinine clearance followed a similar pattern. Effects of deferasirox on renal haemodynamics were mild and reversible for up to 2 years of treatment, with no progressive worsening of renal function over time. www.clinicaltrials.gov: NCT00560820.

Renal complications from bisphosphonate treatment.

PURPOSE OF REVIEW: More than 10 years ago evidence emerged that bisphosphonate therapy especially in malignant bone diseases is associated with renal complications. The nature of renal injury from bisphosphonates has become clearer in recent years. RECENT FINDINGS: Pamidronate can rarely cause (collapsing) focal segmental glomerular sclerosis with the nephrotic syndrome and renal insufficiency. This renal complication has also been observed with other bisphosphonates but only in isolated cases. Other types of renal injury include transient but self-limited rises in creatinine, and, very rarely, acute tubular necrosis causing acute renal failure. The frequency of the latter two complications appears to follow the potency of different bisphosphonates. Although thus far no tubular transport for bisphosphonates has been identified (renal excretion appears to be only by glomerular ultrafiltration), the occurrence of tubular cell injury gives rise for the possibility that these cells can take up bisphosphonates. In patients receiving bisphosphonates monitoring of serum creatinine before and after intravenous (i.v.) dosing or periodically with oral bisphosphonates is advised. SUMMARY: Renal complications with bisphosphonates are rare but creatinine monitoring, especially with i.v. bisphosphonates is strongly advised. The mechanisms by which bisphosphonates can cause renal insufficiency are still elusive and opportunities for research include the discovery of potential mechanisms of tubular cell uptake of bisphosphonates.

Hematopoietic growth factor inducible neurokinin-1 (Gpnmb/Osteoactivin) is a biomarker of progressive renal injury across species.

We sought to find a urinary biomarker for chronic kidney disease and tested hematopoietic growth factor inducible neurokinin-1 (HGFIN, also known as Gpnmb/Osteoactivin) as it was found to be a kidney injury biomarker in microarray studies. Here, we studied whether HGFIN is a marker of kidney disease progression. Its increase in kidney disease was confirmed by real-time PCR after 5/6 nephrectomy, in streptozotocin-induced diabetes, and in patients with chronic kidney disease. In the remnant kidney, HGFIN mRNA increased over time reflecting lesion chronicity. HGFIN was identified in the infarct portion of the remnant kidney in infiltrating hematopoietic interstitial cells, and in distal nephron tubules of the viable remnant kidney expressed de novo with increasing time. In vitro, it localized to cytoplasmic vesicles and cell membranes. Epithelial cells lining distal tubules and sloughed luminal tubule cells of patients expressed HGFIN protein. The urine HGFIN-to-creatinine ratio increased over time after 5/6 nephrectomy; increased in patients with proteinuric and polycystic kidney disease; and remained detectable in urine after prolonged freezer storage. The urine HGFIN-to-creatinine ratio compared favorably with the urine neutrophil gelatinase-associated lipocalin (NGAL)-to-creatinine ratio (both measured by commercial enzyme-linked immunosorbent assays (ELISAs)), and correlated strongly with proteinuria, but weakly with estimated glomerular filtration rate and serum creatinine. Thus, HGFIN may be a biomarker of progressive kidney disease.

Y-box protein-1 is a transcriptional regulator of BMP7.

Bone morphogenetic protein-7 (BMP7) is an endogenous antifibrogenic protein in the kidney which is down regulated in experimental chronic kidney diseases such as obstructive and diabetic nephropathy in parallel with progressively increasing TGFß. In vitro studies were performed in Madin-Darby Canine Kidney (MDCK)-cells to identify transcriptional regulators of BMP7. Experiments with various BMP7 promoter fragments (465-4,267 bp) identify small proximal promoter segments that are transcriptionally activated by high glucose (3.2-fold) but down regulated by TGFß (0.2-fold) compared to normal glucose. Protein binding to these DNA segments is increased by high glucose and decreased by TGFß in a time-dependent, progressive manner. Analysis of BMP7 promoter-binding proteins with liquid chromatography/tandem mass spectrometry (LC/MS/MS) identifies seven unique, partially overlapping peptides, spanning 25% of the amino acid sequence of Y-box protein-1 (YB1). EMSA-Western blot combination experiments confirm that YB1 is a BMP7 promoter-binding protein. YB1 knock-down reduces transcriptional responses to high glucose and TGFß by about one-half, respectively. In addition, high glucose induces but TGFß reduces nuclear translocation of YB1 from the cytoplasm. These studies identify YB1 as a transcriptional activator of BMP7 and helps to explain the progressive decline in renal BMP7 in diabetic nephropathy and other kidney diseases.

Understanding sources of dietary phosphorus in the treatment of patients with chronic kidney disease.

In individuals with chronic kidney disease, high dietary phosphorus (P) burden may worsen hyperparathyroidism and renal osteodystrophy, promote vascular calcification and cardiovascular events, and increase mortality. In addition to the absolute amount of dietary P, its type (organic versus inorganic), source (animal versus plant derived), and ratio to dietary protein may be important. Organic P in such plant foods as seeds and legumes is less bioavailable because of limited gastrointestinal absorption of phytate-based P. Inorganic P is more readily absorbed by intestine, and its presence in processed, preserved, or enhanced foods or soft drinks that contain additives may be underreported and not distinguished from the less readily absorbed organic P in nutrient databases. Hence, P burden from food additives is disproportionately high relative to its dietary content as compared with natural sources that are derived from organic (animal and vegetable) food proteins. Observational and metabolic studies indicate nutritional and longevity benefits of higher protein intake in dialysis patients. This presents challenges to providing appropriate nutrition because protein and P intakes are closely correlated. During dietary counseling of patients with chronic kidney disease, the absolute dietary P content as well as the P-to-protein ratio in foods should be addressed. Foods with the least amount of inorganic P, low P-to-protein ratios, and adequate protein content that are consistent with acceptable palatability and enjoyment to the individual patient should be recommended along with appropriate prescription of P binders. Provision of in-center and monitored meals during hemodialysis treatment sessions in the dialysis clinic may facilitate the achievement of these goals.

Noncanonical TGF-beta pathways, mTORC1 and Abl, in renal interstitial fibrogenesis.

Renal interstitial fibrosis is a major determinant of renal failure in the majority of chronic renal diseases. Transforming growth factor-beta (TGF-beta) is the single most important cytokine promoting renal fibrogenesis. Recent in vitro studies identified novel non-smad TGF-beta targets including p21-activated kinase-2 (PAK2), the abelson nonreceptor tyrosine kinase (c-Abl), and the mammalian target of rapamycin (mTOR) that are activated by TGF-beta in mesenchymal cells, specifically in fibroblasts but less in epithelial cells. In the present studies, we show that non-smad effectors of TGF-beta including PAK2, c-Abl, Akt, tuberin (TSC2), and mTOR are activated in experimental unilateral obstructive nephropathy in rats. Treatment with c-Abl or mTOR inhibitors, imatinib mesylate and rapamycin, respectively, each blocks noncanonical (non-smad) TGF-beta pathways in the kidney in vivo and diminishes the number of interstitial fibroblasts and myofibroblasts as well as the interstitial accumulation of extracellular matrix proteins. These findings indicate that noncanonical TGF-beta pathways are activated during the early and rapid renal fibrogenesis of obstructive nephropathy. Moreover, the current findings suggest that combined inhibition of key regulators of these non-smad TGF-beta pathways even in dose-sparing protocols are effective treatments in renal fibrogenesis.

Diabetes-relevant regulation of cultured blood outgrowth endothelial cells.

Many cell and tissue abnormalities in diabetes mellitus are mediated by auto- and paracrine TGFbeta which is induced by high ambient glucose and glycated proteins. In most cell types TGFbeta reduces cell proliferation and enhances apoptosis which are mediated through the TGFbeta type I receptor, Alk5. In contrast, early diabetic microangiopathy is characterized by endothelial cell proliferation. Endothelial cells are unique in expressing a second TGFbeta type I receptor, Alk1, as well as the co-receptor, endoglin which increases the affinity of the ligand to Alk1. In differentiated blood outgrowth endothelial cells from normal subjects Alk1 and endoglin are constitutively expressed. Incubation with high glucose (HG) and glycated albumin (gAlb) induces Alk5 and raises TGFbeta secretion 3-fold without affecting Alk1 or endoglin levels. This diabetic milieu accelerates cell proliferation, at least in part, through TGFbeta/Alk1-smad1/5 and probably involving VEGF as well as pro-migratory MMP2 downstream of Alk1. In contrast, HG/gAlb also increases caspase-3 activity (suggesting increased apoptosis) in part but not entirely using a TGFbeta/Alk5-smad2/3 pathway. The findings support pleiotropy of TGFbeta in endothelial cells including proliferative effects (through Alk1-smad1/5) and pro-apoptotic signals (through Alk5-smad2/3).

Bone morphogenetic protein-7 (BMP7) in chronic kidney disease.

Bone morphogenetic protein-7 (BMP7) is a member of the BMP-subfamily of perhaps a dozen proteins within the TGFbeta-superfamily of cysteine-knot fold cytokine-growth factors. BMP7 has pivotal functions during renal and eye development. In adult organisms, BMP7 is heavily expressed in kidney, specifically in podocytes, distal tubules and collecting ducts. The activity of BMP7 is reduced by inhibitors including some members of the dan-cerberus group and CTGF but can be enhanced by endoglin and KCP. Renal BMP7 disappears early in fibrogenic renal diseases which may facilitate progression. Exogenous administration of rhBMP7 or transgenic overexpression reduces renal fibrogenesis and apoptosis as well as transdifferentiation of epithelial cells. BMP7 improves maintenance of nephron function and structural integrity. These antifibrogenic activities result from inhibition of the nuclear translocation of TGFbeta-activated smad3 by smad6 downstream of BMP7-activated smad5. Although at present the beneficial effects of BMP7 have only been studied in rodent models of chronic renal diseases, there is promise for therapeutic utility of rhBMP7 or small molecule BMP7 agonists in patients.

Osmotic polyuria: an overlooked mechanism in diabetic nephropathy.

Tubulo-interstitial pathology in diabetic nephropathy is thought to be caused by cell injury that is induced by high ambient glucose levels and increased proportions of glycated proteins. Other mechanistic hypotheses engage glomerular ultrafiltration of proteins and bioactive growth factors and their effects on tubular cells. Some scholars promote tubular ischaemia due to reduced peritubular blood flow as a response to glomerular injury. All of these mechanisms contribute to renal tubulo-interstitial injury in diabetic nephropathy. However, they do not well explain observations that have been made in studies of experimental animals and evaluations of human biopsies showing dilated collecting ducts in early diabetic nephropathy. Dilatation of distal nephron segments is routinely seen in human biopsies or in histological sections from experimental diabetic nephropathy and is reminiscent of similar findings in obstructive nephropathy. Moreover, it is these dilated tubules that are the primary source for pro-inflammatory and pro-fibrogenic cytokines and regulators. Based on this large body of observations from this laboratory and the published literature this narrative develops a novel hypothesis where hyperglycaemic, osmotic polyuria play important contributory roles in the initiation and progression of tubulo-interstitial injury in diabetic nephropathy.

Functional symbiosis between endothelium and epithelial cells in glomeruli.

In some capillary beds, pericytes regulate endothelial growth. Capillaries with high filtration capacity, such as those in renal glomeruli, lack pericytes. Glomerular endothelium lies adjacent to visceral epithelial cells (podocytes) that are anchored to and cover the anti-luminal surface of the basement membrane. We have tested the hypothesis that podocytes can function as endothelial supporting cells. Endothelial cells were outgrown from circulating endothelial progenitors of normal subjects and were extensively characterized. These blood outgrowth endothelial cells (BOECs) expressed endothelial markers, lacked stem cell markers, and expressed the angiopoietin-1 receptor, Tie-2, and the vascular endothelial growth factor (VEGF) receptor, Flk-1. Differentiated podocytes in culture expressed and secreted VEGF, which was upregulated 4.5-fold by high glucose. In complete medium, BOECs formed thin cell-cell connections and multicellular tubes on Matrigel, the in vitro correlate of angiogenesis. This was impaired in deficient media but rescued by co-incubation with Transwell Anopore inserts containing differentiated podocytes. To assess whether VEGF was the major podocyte-derived signal that rescued BOEC angiogenesis, we examined angiogenesis of control and Flk-1-deficient BOECs. Co-incubation with podocytes or addition of recombinant VEGF each rescued angiogenesis in control BOECs, but both failed to support maintenance and angiogenesis in Flk-1-deficient BOECs. Finally, co-culture with podocytes increased BOEC-proliferation. In concert, these findings suggest a model in which glomerular visceral epithelial cells function as pericyte-like endothelial supporting cells. Podocyte-derived VEGF is a required and sufficient regulator of vascular endothelial maintenance, and its upregulation in podocytes by high glucose may be the mechanism for the increased glomerular angiogenesis that is observed in vivo in early diabetic glomerular injury.

BMP7 is a podocyte survival factor and rescues podocytes from diabetic injury.

In early diabetic renal injury, there is podocyte drop-out (but no decrease in the number of other glomerular cells) which is thought to cause glomerular proteinuria and subsequent diabetic glomerular injury. We tested the hypothesis that early diabetic podocyte injury is caused, in part, by downregulation of bone morphogenetic protein-7 (BMP7) and loss of its autocrine function in murine podocytes. High glucose (HG; 25 mM) induces rounding of differentiated podocytes and changes in the distribution of F-actin but without quantitative changes in E-cadherin and the podocyte markers podocin, CD2AP, Neph1, or synaptopodin. HG reduces BMP7 secretion and activity but does not affect BMP receptor levels in murine podocytes. In these cells, BMP7 effectively activates smad5 (but not smad1) and raises p38 phosphorylation [which is also increased by transforming growth factor-beta (TGF-beta)]. HG as well as TGF-beta raise caspase-3 activity, increase apoptosis, and reduce cell survival which is, in part, blocked by BMP7. Knockdown and forced expression studies indicate that smad5 is required as well as sufficient for these actions of BMP7. These findings indicate that BMP7 is a differentiation and survival factor for podocytes, requires smad5, and can reduce diabetic podocyte injury.

Renal bone morphogenetic protein-7 protects against diabetic nephropathy.

Longstanding diabetes causes renal injury with early dropout of podocytes, albuminuria, glomerular and tubulointerstitial fibrosis, and progressive renal failure. The renal pathology seems to be driven, in part, by TGF-beta and is associated with a loss of renal bone morphogenic protein-7 (BMP-7) expression. Here, the hypothesis that maintenance of renal (especially podocyte) BMP-7 by transgenic expression reduces diabetic renal injury was tested. Diabetic mice that expressed the phosphoenolpyruvate carboxykinase promoter-driven BMP-7 transgene and nondiabetic, transgenic mice as well as diabetic and nondiabetic wild-type controls were studied for up to 1 yr. Transgenic expression of BMP-7 in glomerular podocytes and proximal tubules prevents podocyte dropout and reductions in nephrin levels in diabetic mice. Maintenance of BMP-7 also reduces glomerular fibrosis and interstitial collagen accumulation as well as collagen I and fibronectin expression. Diabetic wild-type mice develop progressive albuminuria, which is substantially reduced in transgenic mice. These effects of the BMP-7 transgene occur without changing renal TGF-beta levels. It is concluded that maintenance of renal BMP-7 during the evolution of diabetic nephropathy reduces diabetic renal injury, especially podocyte dropout. The findings also establish a role for endogenous glomerular BMP-7 as an autocrine regulator of podocyte integrity in vivo.

Global safety of coxibs and NSAIDs.

Non-steroidal anti-inflammatory drugs (NSAIDs) and selective cyclooxygenase-2 inhibitors (Coxibs) are commonly used for minor pain treatment and chronically in the management of rheumatoid arthritis and osteoarthritis. Three areas of safety concerns are shared by both groups of drugs: Gastrointestinal complications (upper gastrointestinal bleeding, perforations or obstruction), cardiovascular safety (mainly myocardial infarction) and renal safety (acute renal failure, hypertension and electrolyte abnormalities). The incidence of renal complications may be increased two-fold with NSAIDs or coxibs, and there is no evidence for a major difference between the two groups of drugs. Coxibs are clearly associated with improved gastrointestinal safety compared to NSAIDs, but this benefit is reduced and may be lost completely with concurrent low-dose aspirin use. In contrast, coxibs may be associated with a greater incidence of cardiovascular complications, mainly myocardial infarction, especially in comparison to certain NSAIDs such as naproxen. Thus, coxibs are not generally safer than NSAIDs. Rather, their long-term use should be customized to individual patients and their intrinsic baseline risks and other medications required in their management.

Imatinib mesylate blocks a non-Smad TGF-beta pathway and reduces renal fibrogenesis in vivo.

Transforming growth factor-beta (TGF-beta) is the single most important cytokine promoting renal fibrogenesis. p21-activated kinase-2 (PAK2) and activation of abelson nonreceptor tyrosine kinase (c-abl) have been shown recently to be smad-independent, fibroblast-specific targets downstream of the activated TGF-beta receptor. In the current study we show that in cultured NRK49F-renal fibroblasts (but not in tubular or mesangial cells) TGF-beta similarly activates PAK2 as well as c-abl and induces cell proliferation. Inhibition of the c-abl kinase with imatinib mesylate prevents increased proliferation after TGF-beta addition without affecting PAK2. These in vitro findings were extended to rats with unilateral obstructive nephropathy, a disease model of TGF-beta-driven renal fibrogenesis. In obstructed kidneys, PAK2 and c-abl activity were increased but only c-abl activation was blocked by imatinib. Treatment with imatinib did not prevent renal interstitial infiltration of macrophages or phosphorylation and nuclear translocation of smad2/3 in obstructed kidneys. In contrast, imatinib substantially inhibited an increase in the number of interstitial fibroblasts and myofibroblasts and reduced the expression and interstitial accumulation of collagen type III, collagen type IV and fibronectin. These findings indicate that TGF-beta-induced activation of the nonreceptor c-abl tyrosine kinase regulates fibroblast proliferation and, by this means, is a costimulatory signal in TGF-beta-dependent renal fibrogenesis. Inhibition of c-abl activity with imatinib mesylate ameliorates experimental renal fibrosis in rats.