Alessandra Mingione

Decreased transcriptional activity of calcium-sensing receptor gene promoter 1 is associated with calcium nephrolithiasis

BACKGROUND CaSR gene is a candidate for calcium nephrolithiasis. Single-nucleotide polymorphisms (SNPs) encompassing its regulatory region were associated with calcium nephrolithiasis. AIMS We tested SNPs in the CaSR gene regulatory region associated with calcium nephrolithiasis and their effects in kidney. SUBJECTS AND METHODS One hundred sixty-seven idiopathic calcium stone formers and 214 healthy controls were genotyped for four CaSR gene SNPs identified by bioinformatics analysis as modifying transcription factor binding sites. Strontium excretion after an oral load was tested in 55 stone formers. Transcriptional activity induced by variant alleles at CaSR gene promoters was compared by luciferase reporter gene assay in HEK-293 and HKC-8 cells. CaSR and claudin-14 mRNA levels were measured by real-time PCR in 107 normal kidney medulla samples and compared in patients with different CaSR genotype. RESULTS Only rs6776158 (A>G), located in the promoter 1, was associated with nephrolithiasis. Its minor G allele was more frequent in stone formers than controls (37.8% vs 26.4%, P = .001). A reduced strontium excretion was observed in GG homozygous stone formers. Luciferase fluorescent activity was lower in cells transfected with the promoter 1 including G allele at rs6776158 than cells transfected with the A allele. CaSR mRNA levels were lower in kidney medulla samples from homozygous carriers for the G allele at rs6776158 than carriers for the A allele. Claudin-14 mRNA levels were also lower in GG homozygous subjects. CONCLUSIONS Minor allele at rs6776158 may predispose to calcium stones by decreasing transcriptional activity of the CaSR gene promoter 1 and CaSR expression in kidney tubules.

Idiopathic calcium nephrolithiasis: A review of pathogenic mechanisms in the light of genetic studies

Background: Calcium nephrolithiasis is a multifactorial disease with a polygenic milieu. Association studies identified genetic polymorphisms potentially implicated in the pathogenesis of calcium nephrolithiasis. The present article reviews the mechanisms of calcium stone formation and the potential contribution of gene polymorphisms to lithogenic mechanisms. Summary: Endoscopy observations suggested that precipitation of calcium-oxalate on the Randalls plaque at the papilla surface may cause idiopathic calcium-oxalate stones. The Randalls plaque is a hydroxyapatite deposit in the interstitium of the kidney medulla, which resembles a soft tissue calcification. Conversely, calcium-phosphate stones may develop from crystalline deposits located at the tip of the Bellini duct. Polymorphisms of eleven genes have been associated with stones in genome-wide association studies and replicated candidate-gene association studies: VDR, SLC34A1, SLC34A4, CLDN14, and CaSR genes coding for proteins regulating tubular phosphate and calcium reabsorption; CaSR, MGP, OPN, PLAU, and UMOD genes coding for proteins preventing calcium salt precipitation; AQP1 gene coding for a water channel in the proximal tubule. The renal activity of the last gene, DGKH, is unknown. Polymorphisms in these genes may predispose to calcium-oxalate and -phosphate stones by increasing the risk of calcium-phosphate precipitation in the tubular fluid. Key Messages: Genetic findings suggest that tubular fluid supersaturation with respect to calcium and phosphate predisposes to calcium-oxalate stones by triggering cellular mechanisms that lead to the Randalls plaque formation.

Dietary style and acid load in an Italian population of calcium kidney stone formers

BACKGROUND AND AIMS Animal protein intake may cause an acid load that predisposes individuals to stones by influencing calcium and citrate excretion. These associations were not confirmed in recent studies. Therefore the present study was aimed to compare acid load of diet in stone formers and controls. METHODS AND RESULTS Participants to the study were 157 consecutive calcium stone formers and 144 controls. Diet was analyzed in these subjects using a software that evaluated nutrient intake from a three-day food intake diary. This software also estimated the potential renal acid load (PRAL, mEq/day). Twenty-four-hour urine excretion of ions and citrate was measured in stone formers. Stone former diet had lower intake of glucose, fructose, potassium and fiber and higher PRAL in comparison with controls. The multinomial logistic regression analysis showed that stone risk decreased in association with the middle and the highest tertiles of fiber intake and increased in association with the highest tertile of PRAL. The linear multiple regression analysis showed that calcium excretion was associated with the sodium excretion and that citrate excretion was associated with the PRAL and animal protein intake in stone formers. CONCLUSION Our findings suggest that stone formers may undergo a greater dietary acid load sustained by a low vegetable intake and base provision. Dietary acid load does not appear as the main determinant of calcium excretion, but may promote stone risk by decreasing citrate excretion. Sodium intake may predispose to stones by stimulating calcium excretion.

High parathyroid hormone concentration in tenofovir-treated patients are due to inhibition of calcium-sensing receptor activity

Bone health impairment is a common finding in HIV-infected patients on antiretroviral treatment. High serum parathyroid hormone (PTH) concentration in patients on antiretroviral treatment containing tenofovir disoproxil fumarate (TDF) has been reported. Hyperparathyroidism was not always sustained by a reduction in vitamin D concentration. We thus hypothesized a direct inhibitory effect of TDF on the Calcium-sensing receptor (CaSR), leading to hyperparathyroidism. Human embryonic kidney cells were transfected with CASR wild-type gene or mutated in different sites (N124K, T1051G, C788T, T888M). Cells were grown in standard conditions and the activity of CaSR was assessed after stimulation with CaCl2 with and without TDF (100 nM-1 μM). We evaluated by western blot phospho-p44/42 ERK expression levels as a marker of CaSR activity. In silico structure models were obtained for wild-type and N124K mutant. Molecular docking with TDF was also evaluated. The stimulation by CaCl2 and TDF 100 nM led to a decrease of 55% of CaSR activity (P < 0.001), whereas the stimulation by CaCl2 and TDF 1 μM reduced the activity by 68% (P < 0.001). The decreased CaSR activity was comparable to that observed from known CASR gene inactivating mutations (T1051G, C788T), which inhibit the receptor activity by 56% and 78%, respectively. The TDF inhibits the CaSR activity carrying a gain of function mutation in the intracellular domain (T888M), but it does not influence the activity of the receptor carrying the N124K activating mutation. Our data show that TDF is able to inhibit the activity of CaSR in a dose-dependent manner. Hyperparathyroidism observed in TDF-treated patients may be therefore promoted by the direct effect of the drug on CaSR.

Autosomal dominant hypocalcemia due to a truncation in the C-tail of the calcium-sensing receptor.

Autosomal Dominant Hypocalcemia (ADH) is an endocrine disorder due to activating mutations of the calcium-sensing receptor (CASR) gene. We report on a young boy who presented low serum calcium with hypercalciuria, hyperphosphatemia and low serum concentration of parathyroid hormone, not accompanied by classic clinical signs of hypocalcemia. Treatment with calcitriol and calcium did not normalize serum calcium and renal calcium excretion. The use of thiazide diuretics slightly reduced calciuria. Despite high calcium excretion, no signs of nephrocalcinosis were detected. The patient had a prolonged Q-T interval at ECG, which did not normalize during treatment. PCR amplification of CASR coding sequence and direct sequencing of PCR products. showed a novel heterozygous deletion of a cytosine (c.2682delC), responsible for a frameshift (p.S895Pfs*44) and a premature stop codon resulting in a truncation of the CaSRs C-tail. Functional studies indicated increased activity of mutant receptor compared to the wild-type.

Filamin A is reduced and contributes to the CASR sensitivity in human parathyroid tumors

Parathyroid tumors display reduced sensitivity to extracellular calcium ([Ca2+]o). [Ca2+]o activates calcium-sensing receptor (CASR), which interacts with the scaffold protein filamin A (FLNA). The study aimed to investigate: (1) the FLNA expression in human parathyroid tumors, (2) its effects on the CASR mRNA and protein expression, and (3) on ERK signaling activation, (4) the effect of the carboxy-terminal CASR variants and (5) of the treatment with the CASR agonist R568 on FLNA-mediated ERK phosphorylation in HEK293 cells. Full-length FLNA immunostaining was variably reduced in parathyroid tumors. Immunofluorescence showed that FLNA localized in membrane and cytoplasm and co-localized with CASR in parathyroid adenomas (PAds)-derived cells. Cleaved C-terminus FLNA fragment could also be detected in PAds nuclear protein fractions. In HEK293 cells transfected with 990R-CASR or 990G-CASR variants, silencing of endogenous FLNA reduced CASR mRNA levels and total and membrane-associated CASR proteins. In agreement, FLNA mRNA levels positively correlated with CASR expression in a series of 74 PAds; however, any significant correlation with primary hyperparathyroidism severity could be detected and FLNA transcript levels did not differ between PAds harboring 990R or 990G CASR variants. R568 treatment was efficient in restoring 990R-CASR and 990G-CASR sensitivity to [Ca2+]o in the absence of FLNA. In conclusion, FLNA is downregulated in parathyroid tumors and parallels the CASR expression levels. Loss of FLNA reduces CASR mRNA and protein expression levels and the CASR-induced ERK phosphorylation. FLNA is involved in receptor expression, membrane localization and ERK signaling activation of both 990R and 990G CASR variants.

The sialyl-glycolipid SSEA4 marks a subpopulation of chemotherapy resistant breast cancer cells with mesenchymal features

Triple negative breast cancer (TNBC) is an aggressive breast cancer subtype associated with high risk of early relapse and metastasis [1]. At the moment chemotherapy remains the main option for systemic therapy of TNBC patients but complete remission occurs only in 20% of the patients [2]. In order to identify biomarker for chemotherapy-resistant TNBC cells, we performed a cell surface marker screen in 4 TNBC patient-derived xenograft (PDX) models that respond well to adriamycin/cyclophosphamide-based (A/C) chemotherapy but fail to reach complete pathological response. We used multi-parameter flow cytometry to screen the expression of 45 cell surface markers during the course of chemotherapy. We identified the sialyl-glycolipid SSEA4 as a marker of chemotherapy-resistant cancer cells in all four models. In addition, 3 out of 4 TNBC PDXs showed higher percentage of SSEA4-positive cells compared to all A/C-sensitive TNBC PDXs analysed. Gene expression comparison between SSEA4-positive and SSEA4-negative tumor cells from 3 TNBC PDXs highlighted an overexpression of mesenchymal-associated genes and a deregulation of drug resistance pathway-associated genes and miRNAs in SSEA4+ breast cancer cells. In addition, high expression of ST3 beta-galactoside alpha-2,3-sialyltransferase 2 (ST3Gal2), the enzyme catalyzing the last step of SSEA4 synthesis, was found associated with poor outcome in ER-, PR- breast cancer patients treated with chemotherapy (p < 0.01, HR 3.08). Thus, we propose SSEA4 as a novel marker of mesenchymal and chemoresistant breast cancer cells, and ST3GAL2 expression as a predictive marker for chemoresistance associated with poor outcome in breast cancer patients.

Position Statement from ADA/AACE/EASD/TES in Response to a Recently Published Letter to the Editor in The Lancet and an Editorial Addressing the Israeli-Palestinian Fighting in Gaza

Derek LeRoith, MD, PhD, Editor in Chief, Endocrine Practice R. Mack Harrell , MD, President, American Association of Clinical Endocrinologists George Grunberger, MD, President Elect, American Association of Clinical Endocrinologists Leonard Wartofsky, MD, Editor in Chief, The Journal of Clinical Endocrinology and Metabolism Andrea C. Gore, PhD, Editor in Chief, Endocrinology Margaret Wierman, MD, Acting Editor in Chief, Endocrine Reviews Stephen R. Hammes, MD, PhD, Editor in Chief, Molecular Endocrinology Carol A. Lange, PhD, Editor in Chief, Hormones and Cancer Richard J. Santen, MD, President, Endocrine Society George L. Bakris, MD, Editor in Chief, American Journal of Nephrology

Update on the calcium-sensing receptor

The cells of the human body have a receptor that is sensitive to extracellular calcium [calcium-sensing receptor (CaSR)] and whose tissue expression is decreased in patients with chronic kidney disease. The CaSR plays a key role both in the regulation of PTH secretion by parathyroid cells, as well as in calcium tubular reabsorption by renal tubular cells. Recent biochemical and cellular studies found that this receptor has peculiar functional characteristics. Furthermore, pharmacological research has brought to the marker agonists for CaSR (calcimimetics) that today are used for treating secondary hyperparathyroidism and may have an effect on cardiovascular and bone diseases in patients with chronic kidney disease. With regard to the latter, the EVOLVE and ADVANCE trials were dedicated to understanding the role of cinacalcet, a calcimimetic drug, in the prevention of vascular calcification and cardiovascular events in patients with chronic kidney disease. Research in this field has thus opened promising perspectives for the treatment of chronic kidney disease.