Miriam Zacchia

Upregulation of apical sodium-chloride cotransporter and basolateral chloride channels is responsible for the maintenance of salt-sensitive hypertension

We investigated which of the NaCl transporters are involved in the maintenance of salt-sensitive hypertension. Milan hypertensive (MHS) rats were studied 3 mo after birth. In MHS, compared with normotensive strain (MNS), mRNA abundance, quantified by competitive PCR on isolated tubules, was unchanged, both for Na+/H+ isoform 3 (NHE3) and Na+-K+-2Cl- (NKCC2), but higher (119%, n = 5, P < 0.005) for Na+-Cl- (NCC) in distal convoluted tubules (DCT). These results were confirmed by Western blots, which revealed: 1) unchanged NHE3 in the cortex and NKCC2 in the outer medulla; 2) a significant increase (52%, n = 6, P < 0.001) of NCC in the cortex; 3) alpha- and beta-sodium channels [epithelial Na+ channel (ENaC)] unaffected in renal cortex and slightly reduced in the outer medulla, while gamma-ENaC remained unchanged. Pendrin protein expression was unaffected. The role of NCC was reinforced by immunocytochemical studies showing increased NCC on the apical membrane of DCT cells of MHS animals, and by clearance experiments demonstrating a larger sensitivity (P < 0.001) to bendroflumethiazide in MHS rats. Kidney-specific chloride channels (ClC-K) were studied by Western blot experiments on renal cortex and by patch-clamp studies on primary culture of DCT dissected from MNS and MHS animals. Electrophysiological characteristics of ClC-K channels were unchanged in MHS rats, but the number of active channels in a patch was 0.60 +/- 0.21 (n = 35) in MNS rats and 2.17 +/- 0.59 (n = 23) in MHS rats (P < 0.05). The data indicate that, in salt-sensitive hypertension, there is a strong upregulation, both of NCC and ClC-K along the DCT, which explains the persistence of hypertension.

The role of the kidney in salt-sensitive hypertension

Primary hypertension is one of the leading risk factors for cardiovascular disease. Although the pathogenesis is not completely understood, an imbalance of sodium and chloride homeostasis seems to be relevant both in the induction and in the maintenance of salt-sensitive hypertension. Besides individual renal phenotypes, salt intake is one of the most important environmental determinants of this condition. The Milan hypertensive strain (MHS) of rats is an interesting model to investigate the molecular mechanisms underling the development of salt-sensitive hypertension. In young MHS rats, hypertension is anticipated by a phase of increased salt reabsorption localized along the medullary thick ascending limb associated with the up-regulation of the apical sodium−potassium−chloride cotransporter (NKCC2). Later, the frank hypertensive status of adult MHS rats is accompanied by the activation of the luminal and basal lateral transporters of sodium chloride (NaCl) in the distal convoluted tubule (DCT). Several lines of evidence have proven the key role of DCT in the maintenance of hypertension in MHS rats; more importantly, hypertensive patients carrying a mutation of α-adducin (resembling the MHS model) have a high sensitivity to thiazides, suggesting that the Na+–Cl− cotransporter also plays a pivotal role in humans.

A fate-mapping approach reveals the composite origin of the connecting tubule and alerts on “single-cell”-specific KO model of the distal nephron

The distal nephron is a heterogeneous part of the nephron composed by six different cell types, forming the epithelium of the distal convoluted (DCT), connecting, and collecting duct. To dissect the function of these cells, knockout models specific for their unique cell marker have been created. However, since this part of the nephron develops at the border between the ureteric bud and the metanephric mesenchyme, the specificity of the single cell markers has been recently questioned. Here, by mapping the fate of the aquaporin 2 (AQP2) and Na+-Cl- cotransporter (NCC)-positive cells using transgenic mouse lines expressing the yellow fluorescent protein fluorescent marker, we showed that the origin of the distal nephron is extremely composite. Indeed, AQP2-expressing precursor results give rise not only to the principal cells, but also to some of the A- and B-type intercalated cells and even to cells of the DCT. On the other hand, some principal cells and B-type intercalated cells can develop from NCC-expressing precursors. In conclusion, these results demonstrate that the origin of different cell types in the distal nephron is not as clearly defined as originally thought. Importantly, they highlight the fact that knocking out a gene encoding for a selective functional marker in the adult does not guarantee cell specificity during the overall kidney development. Tools allowing not only cell-specific but also time-controlled recombination will be useful in this sense.

Renal phenotype in Bardet-Biedl syndrome: a combined defect of urinary concentration and dilution is associated with defective urinary AQP2 and UMOD excretion

The renal phenotype in Bardet-Biedl syndrome (BBS) is highly variable. The present study describes renal findings in 41 BBS patients and analyzes the pathogenesis of hyposthenuria, the most common renal dysfunction. Five of 41 patients (12%) showed an estimated glomerular filtration rate < 60 ml·min-1·1.73 m-2 Urine protein and urine albumin-to-creatinine ratio were over 200 and 30 mg/g in 9/24 and 7/23 patients, respectively. Four of 41 patients showed no renal anomalies on ultrasound. Twenty of 34 patients had hyposthenuria in the absence of renal insufficiency. In all 8 of the hyposthenuric patients studied, dDAVP failed to elevate urine osmolality (Uosm), suggesting a nephrogenic origin. Interestingly, water loading (WL) did not result in a significant reduction of Uosm, indicating combined concentrating and diluting defects. dDAVP infusion induced a significant increase of plasma Factor VIII and von Willebrand Factor levels, supporting normal function of the type 2 vasopressin receptor at least in endothelial cells. While urinary aquaporin 2 (u-AQP2) abundance was not different between patients and controls at baseline, the dDAVP-induced increased u-AQP2 and the WL-induced reduction of u-AQP2 were blunted in patients with a combined concentrating and diluting defect, suggesting a potential role of AQP2 in the defective regulation of water absorption. Urine Uromodulin excretion was reduced in all hyposthenuric patients, suggesting a thick ascending limb defect. Interestingly, renal Na, Cl, Ca, but not K handling was impaired after acute WL but not at basal. In summary, BBS patients show combined urinary concentration and dilution defects; a thick ascending limb and collecting duct tubulopathy may underlie impaired water handling.

The importance of uromodulin as regulator of salt reabsorption along the thick ascending limb

Uromodulin (UMOD), also named Tamm Horsfall protein, is the most abundant protein secreted in the urine under normal conditions. It was purified the first time in 1950 and since then considerable efforts have highlighted its importance in human pathophysiology. However, its precise biological functions still remain elusive. The clinical interest in UMOD derives from the evidence that UMOD genetic mutations result in tubulointerstitial nephropathies currently known as UMODassociated kidney disease (UAKD), rare genetic disorders characterized by hyperuricaemia, gout and a progressive decline of renal function [1]. In addition, UMOD has been proposed to modulate water and electrolyte homeostasis by acting on the main transporters expressed along the thick ascending limb (TAL) and the early distal convoluted tubule. The precursor undergoes extensive post-translational modifications through the endoplasmic reticulum (ER) and the Golgi apparatus, and ultimately it is targeted to the apical membrane [2]. From the luminal site, it is cleaved by an unknown protease and then released into the tubular fluid. The exact mechanism linking UMOD mutations to renal concentrating defect has not been fully characterized. It has been suggested that the filamentous gel-like structure of the extracellular domain may serve as a barrier to water permeability [3]. In vitro and in vivo studies have recently demonstrated that UMOD modulates the function of the Na-K-2Cl (NKCC2) co-transporter [4] and the renal outer medullary potassium (ROMK) channel [5] (Figure 1). UMOD-deficient mice showed normal electrolyte balance at basal and urine concentrating defect after water deprivation [6]. Impaired urine concentration was coupled with a compensatory up-regulation of distal Na transporters, including the Na-Cl co-transporter (NCC), suggesting indirectly an impaired function of the TAL. Immunostaining analysis revealed the absence of any difference in NKCC2 protein abundance on the apical membrane between knockout (KO) and wild-type (WT) mice, but an increased sub-apical immunoreactivity, with overall increased NKCC2 protein abundance compared with WT [4]. It is possible that an impaired protein degradation, in the absence of UMOD, resulted in NKCC2 accumulation. However, the same study demonstrated that phospho-NKCC2 levels, a marker of NKCC2 activity, were lower in KO than WT mice, and intraperitoneal injection of frusemide resulted in attenuated natriuretic and cloruretic responses, further supporting the hypothesis of reduced NKCC2 activity in the absence of UMOD. Consistent with these findings, in vitro NKCC2 phosphorylation was enhanced in the presence of UMOD, indicating that also in cultured cells UMOD promoted NKCC2 activity. This hypothesis has been further corroborated by recent observations linking salt-sensitive hypertension with a genetic UMOD variant leading to an increased UMOD synthesis and secretion in humans [7]. Transgenic mice expressing this genetic variant resembled human features, showing salt-sensitive hypertension. This finding correlated with the up-regulation of NKCC2, with increased protein phosphorylation via the STE20/SPS1-related proline/alanine-rich kinase (SPAK) and the down-regulation of the negative regulator kidney-specific KS-SPAK. Besides NKCC2, UMOD has been shown to modulate also the activity of ROMK. Renigunta et al. [5] have shown that UMOD co-localized with ROMK in a protein lysate from mice, while in oocytes, co-expression of UMOD and ROMK resulted in increased current amplitude, associated with an increased surface ROMK abundance. Patients suffering from UAKD commonly do manifest a defect in urine concentrating ability even before the decline of the GFR [8]. The mechanism by which UMOD mutations lead to urine concentrating defect in humans remains to be better elucidated. In this issue of NDT, Labriola et al. [9] show original data exploring the tubular function of a patient suffering UAKD during the early phase of the disease.

Knockdown of the BBS10 Gene Product Affects Apical Targeting of AQP2 in Renal Cells: A Possible Explanation for the Polyuria Associated with Bardet-Biedl Syndrome

Objective: Bardet-Biedl syndrome (BBS) is a rare genetic disorder whose clinical features include renal abnormalities, which ranges from renal malformations to renal failure. Polyuria and iso-hyposthenuria are common renal dysfunctions in BBS patients even in the presence of normal GFR. The mechanism underlying this defect is unknown and no genotype-phenotype correlation has yet been reported. Here we report four BBS patients showing different renal phenotypes: one had polyuria with hyposthenuria associated with mutation of BBS10, while three patients with normal urineconcentrating ability had mutations in BBS1. Methods: We measured aquaporin 2 (AQP2) urinary excretions in BBS patients and studied the possible role of BBS1 and BBS10 on AQP2 trafficking in a mouse cortical collecting duct cell line. Results: We found that the BBS1-mutated patients showed a significant increase of water channel AQP2 urine excretion in antidiuresis. In contrast, the BBS10-mutated patient showed no difference in AQP2 excretion in antidiuresis and after an acute water load. In mouse kidney cortical collecting duct MCD4 cells, knockdown of BBS10, but not of BBS1, prevented the forskolin-dependent trafficking of AQP2 to the apical membrane, and induced the mis-trafficking to the basolateral membrane. Interestingly, BBS10 knockdown was associated with a dramatic reduction of tubulin acetylation without loss of cell polarity. Conclusions: Therefore, the effect of BBS10 knockdown in vitro is consistent with the hyposthenuria observed in the patient with mutation of BBS10. This correlation between renal phenotype and genotype indicates that BBS10, but not BBS1, might control the trafficking of AQP2 and therefore plays a key role in the renal concentrating mechanism.

Vitamin-D status and mineral metabolism in two ethnic populations with sarcoidosis

Vitamin-D insufficiency and sarcoidosis are more common and severe in African Americans (AA) than Caucasians. In sarcoidosis, substrate-dependent extrarenal 1,25-dihydroxyvitamin-D (1,25-(OH)2D) production is thought to contribute to hypercalciuria and hypercalcemia, and vitamin-D repletion is often avoided. However, the anti-inflammatory properties of vitamin-D may also be beneficial. We prospectively examined serum vitamin-D levels, calcium balance, and the effects of vitamin-D repletion in 86 AA and Caucasian patients with biopsy-proven active sarcoidosis from the USA (US) and Italy (IT) in university-affiliated outpatient clinics. Clinical features, pulmonary function, and calciotropic hormones were measured. 16 patients with vitamin-D deficiency and normal serum ionized calcium (Ca2+) were treated with oral ergocalciferol (50,000 IU/week) for 12 weeks. Baseline mineral parameters were similar in US (93% AA) and IT (95% Caucasian) patients irrespective of glucocorticoid treatment. Pulmonary dysfunction was less pronounced in IT patients. Nephrolithiasis (in 11% US, 17% IT patients) was associated with higher urinary calcium excretion. Vitamin-D deficiency was not more prevalent in patients compared to the respective general populations. As serum 25-hydroxyvitamin-D (25-OHD) rose postrepletion, serum 1,25-(OH)2D, γ-globulins, and the previously elevated angiotensin converting enzyme (ACE) levels declined. Asymptomatic reversible increases in Ca2+ or urinary calcium/creatinine (Ca/Cr) developed in three patients during repletion. In conclusion, Caucasian and AA patients show similar calcium and vitamin D profiles. The higher prevalence of hypercalciuria and nephrolithiasis in sarcoidosis is unrelated to endogenous vitamin-D levels. Vitamin-D repletion in sarcoidosis is generally safe, although calcium balance should be monitored. A hypothesis that 25-OHD repletion suppresses granulomatous immune activity is provided.

Integration of Proteomics and Metabolomics in Exploring Genetic and Rare Metabolic Diseases

Background: Inherited metabolic disorders or inborn errors of metabolism are caused by deficiency of enzymatic activities in the catabolism of amino acids, carbohydrates, or lipids. These disorders include aminoacidopathies, urea cycle defects, organic acidemias, defects of oxidation of fatty acids, and lysosomal storage diseases. Inborn errors of metabolism constitute a significant proportion of genetic diseases, particularly in children; however, they are individually rare. Clinical phenotypes are very variable, some of them remain asymptomatic, others manifest metabolic decompensation in neonatal age, and others encompass mental retardation at later age. The clinical manifestation of these disorders can involve different organs and/or systems. Some disorders are easily managed if promptly diagnosed and treated, whereas in other cases neither diet, vitamin therapy, nor transplantation appears to prevent multi-organ impairment. Summary: Here, we discuss the principal challenges of metabolomics and proteomics in inherited metabolic disorders. We review the recent developments in mass spectrometry-based proteomic and metabolomic strategies. Mass spectrometry has become the most widely used platform in proteomics and metabolomics because of its ability to analyze a wide range of molecules, its optimal dynamic range, and great sensitivity. The fast measurement of a broad spectrum of metabolites in various body fluids, also collected in small samples like dried blood spots, have been facilitated by the use of mass spectrometry-based techniques. These approaches have enabled the timely diagnosis of inherited metabolic disorders, thereby facilitating early therapeutic intervention. Due to its analytical features, proteomics is suited for the basic investigation of inborn errors of metabolism. Modern approaches enable detailed functional characterization of the pathogenic biochemical processes, as achieved by quantification of proteins and identification of their regulatory chemical modifications. Key Message: Mass spectrometry-based “omics” approaches most frequently used to study the molecular mechanisms underlying inherited metabolic disorders pathophysiology are described.

Urine Proteomics Revealed a Significant Correlation Between Urine-Fibronectin Abundance and Estimated-GFR Decline in Patients with Bardet-Biedl Syndrome

Background:/Aims: Renal disease is a common cause of morbidity in patients with Bardet-Biedl syndrome (BBS), however the severity of kidney dysfunction is highly variable. To date, there is little information on the pathogenesis, the risk and predictor factors for poor renal outcome in this setting. The present study aims to analyze the spectrum of urinary proteins in BBS patients, in order to potentially identify 1) disease-specific proteomic profiles that may differentiate the patients from normal subjects; 2) urinary markers of renal dysfunction. Methods: Fourteen individuals (7 males and 7 females) with a clinical diagnosis of BBS have been selected in this study. A pool of 10 aged-matched males and 10 aged-matched females have been used as controls for proteomic analysis. The glomerular filtration rate (eGFR) has been estimated using the CKD-EPI formula. Variability of eGFR has been retrospectively assessed calculating average annual eGFR decline (ΔeGFR) in a mean follow-up period of 4 years (3-7). Results: 42 proteins were significantly over- or under-represented in BBS patients compared with controls; the majority of these proteins are involved in fibrosis, cell adhesion and extracellular matrix organization. Statistic studies revealed a significant correlation between urine fibronectin (u-FN) (r2=0.28; p<0.05), CD44 antigen (r2 =0.35; p<0.03) and lysosomal alfa glucosidase ( r20.27; p<0.05) abundance with the eGFR. In addition, u-FN (r2 =0.2389; p<0.05) was significantly correlated with ΔeGFR. Conclusion: The present study demonstrates that urine proteome of BBS patients differs from that of normal subjects; in addition, kidney dysfunction correlated with urine abundance of known markers of renal fibrosis.