Chemically based transmissible ER stress protocols are unsuitable to study cell-to-cell UPR transmission

Renal epithelial cells regulate the destructive activity of macrophages and participate in the progression of kidney diseases. Critically, the Unfolded Protein Response (UPR), which is activated in renal epithelial cells in the course of kidney injury, is required for the optimal differentiation and activation of macrophages. Given that macrophages are key regulators of renal inflammation and fibrosis, we suppose that the identification of mediators that are released by renal epithelial cells under Endoplasmic Reticulum (ER) stress and transmitted to macrophages is a critical issue to address. Signals leading to a paracrine transmission of ER stress (TERS) from a donor cell to a recipient cells could be of paramount importance to understand how ER-stressed cells shape the immune microenvironment. Critically, the vast majority of studies that have examined TERS used thaspigargin as an inducer of ER stress in donor cells in cellular models. By using multiple sources of ER stress, we evaluated if human renal epithelial cells undergoing ER stress can transmit the UPR to human monocyte-derived macrophages and if such TERS can modulate the inflammatory profiles of these cells. Our results indicate that carry-over of thapsigargin is a confounding factor in chemically based TERS protocols classically used to induce ER Stress in donor cells. Hence, such protocols are not suitable to study the TERS phenomenon and to identify its mediators. In addition, the absence of TERS transmission in more physiological models of ER stress indicates that cell-to-cell UPR transmission is not a universal feature in cultured cells

Physiology and physiopathology of transepithelial transports of proximal tubule : evidence for a role of the Kir4.2 subunit and analysis of a ClC-5 mutant involved in Dent's disease

Le tubule proximal participe à la diurèse en modifiant la composition de l'ultrafiltrat glomérulaire. Grâce à de nombreux transports transépithéliaux, il le glucose, les acides aminés et les protéines de bas poids moléculaires, ainsi que 80 % des ions HPO42- ou HCO3-, 60 % des ions Na+, Cl-, K+, Ca2+, 75 % de l’eau et 30 % des ions Mg2+ ultrafiltrés.Durant ma thèse, j'ai étudié les rôles physiologiques et physiopathologiques de deux protéines de transport exprimées dans le tubule proximal.Dans le cadre de ma première étude, j'ai évalué in vivo la fonction rénale de souris n'exprimant pas une protéine appelée Kir4.2, dont le rôle est inconnu. Nos résultats montrent que Kir4.2, associée à Kir5.1, forme un canal potassique basolatéral Kir4.2/Kir5.1 dans le tubule proximal. L'absence de Kir4.2 provoque chez la souris une acidose tubulaire proximale isolée, consécutive à une ammoniogénèse altérée. De fait, la perte de fonctionnalité de Kir4.2 pourrait être à l'origine d'acidoses tubulaires proximales isolées familiales idiopathiques.Dans le cadre de ma seconde étude, j'ai analysé in vitro la fonctionnalité d'un mutant pathogène de l'échangeur 2Cl-/H+ ClC-5 impliqué dans la maladie de Dent. Cette maladie, caractérisée par une protéinurie de bas poids moléculaire associées à divers troubles du tubule proximal, serait liée à un défaut d'acidification des endosomes précoces par ClC-5. Toutefois, le mutant de ClC-5 que nous avons étudié, converti en canal chlorure, acidifie autant les endosomes précoces que le ClC-5 sauvage. Surprenants, ces résultats suggèrent que la maladie de Dent puisse être causée par un défaut d'accumulation d'ions chlorure dans l'endosome.The proximal tubule is involved in diuresis by modifying the content of the glomerular ultrafiltrate. Using a variety of transepithelial transports systems, it reabsorbs all ultrafiltrated glucose, amino-acids and low molecular weight proteins, as well as 80% of HPO42- and HCO3- ions, about 60% of Na+, Cl-, K+, and Ca2+ ions, 75% of water and 30% of Mg2+.During this thesis, I determined the physiological and physiopathological roles of two transport proteins present in proximal tubule. Firstly, I evaluated the renal function of mice invalidated for the Kir4.2 protein, whose role was undetermined. Our results show that Kir4.2, in association with Kir5.1, form a Kir4.2/Kir5.1 potassium channel at the basolateral membrane of proximal tubular cells. Furthermore, Kir4.2-null mice exhibit a reduced ammoniagenesis leading to an isolated proximal renal tubular acidosis. This study provides the gene encoding Kir4.2 as a candidate gene for the yet unexplained autosomal dominant isolated proximal renal tubular acidosis.Secondly, I evaluated in vitro the functional consequences of a pathogenic mutation of the 2Cl-/H+ exchanger ClC-5, involved in Dent’s disease. This disease, characterized by a low-molecular-weigth-proteinuria in the context of a general proximal tubule dysfunction, is currently thought to be due to an acidification defect of early endosomes linked to a loss of function of ClC-5. Surprisingly, our results show that ClC-5, converted into a chloride channel by this mutation, indeed acidifies the early endosomes as well as the ClC-5 wild-type. Thus, Dent’s disease may originate from a defect in the accumulation of chloride ions into the early endosomes

Physiologie et physiopathologie des transports transépithéliaux du tubule proximal : mise en évidence du rôle de la sous-unité Kir4.2 et analyse d'un mutant de ClC-5 impliqué dans la maladie de Dent

The proximal tubule is involved in diuresis by modifying the content of the glomerular ultrafiltrate. Using a variety of transepithelial transports systems, it reabsorbs all ultrafiltrated glucose, amino-acids and low molecular weight proteins, as well as 80% of HPO42- and HCO3- ions, about 60% of Na+, Cl-, K+, and Ca2+ ions, 75% of water and 30% of Mg2+.During this thesis, I determined the physiological and physiopathological roles of two transport proteins present in proximal tubule. Firstly, I evaluated the renal function of mice invalidated for the Kir4.2 protein, whose role was undetermined. Our results show that Kir4.2, in association with Kir5.1, form a Kir4.2/Kir5.1 potassium channel at the basolateral membrane of proximal tubular cells. Furthermore, Kir4.2-null mice exhibit a reduced ammoniagenesis leading to an isolated proximal renal tubular acidosis. This study provides the gene encoding Kir4.2 as a candidate gene for the yet unexplained autosomal dominant isolated proximal renal tubular acidosis.Secondly, I evaluated in vitro the functional consequences of a pathogenic mutation of the 2Cl-/H+ exchanger ClC-5, involved in Dent’s disease. This disease, characterized by a low-molecular-weigth-proteinuria in the context of a general proximal tubule dysfunction, is currently thought to be due to an acidification defect of early endosomes linked to a loss of function of ClC-5. Surprisingly, our results show that ClC-5, converted into a chloride channel by this mutation, indeed acidifies the early endosomes as well as the ClC-5 wild-type. Thus, Dent’s disease may originate from a defect in the accumulation of chloride ions into the early endosomes.Le tubule proximal participe à la diurèse en modifiant la composition de l'ultrafiltrat glomérulaire. Grâce à de nombreux transports transépithéliaux, il le glucose, les acides aminés et les protéines de bas poids moléculaires, ainsi que 80 % des ions HPO42- ou HCO3-, 60 % des ions Na+, Cl-, K+, Ca2+, 75 % de l’eau et 30 % des ions Mg2+ ultrafiltrés.Durant ma thèse, j'ai étudié les rôles physiologiques et physiopathologiques de deux protéines de transport exprimées dans le tubule proximal.Dans le cadre de ma première étude, j'ai évalué in vivo la fonction rénale de souris n'exprimant pas une protéine appelée Kir4.2, dont le rôle est inconnu. Nos résultats montrent que Kir4.2, associée à Kir5.1, forme un canal potassique basolatéral Kir4.2/Kir5.1 dans le tubule proximal. L'absence de Kir4.2 provoque chez la souris une acidose tubulaire proximale isolée, consécutive à une ammoniogénèse altérée. De fait, la perte de fonctionnalité de Kir4.2 pourrait être à l'origine d'acidoses tubulaires proximales isolées familiales idiopathiques.Dans le cadre de ma seconde étude, j'ai analysé in vitro la fonctionnalité d'un mutant pathogène de l'échangeur 2Cl-/H+ ClC-5 impliqué dans la maladie de Dent. Cette maladie, caractérisée par une protéinurie de bas poids moléculaire associées à divers troubles du tubule proximal, serait liée à un défaut d'acidification des endosomes précoces par ClC-5. Toutefois, le mutant de ClC-5 que nous avons étudié, converti en canal chlorure, acidifie autant les endosomes précoces que le ClC-5 sauvage. Surprenants, ces résultats suggèrent que la maladie de Dent puisse être causée par un défaut d'accumulation d'ions chlorure dans l'endosome

Rhodnius prolixus smells repellents: Behavioural evidence and test of present and potential compounds inducing repellency in Chagas disease vectors

International audienceInsect repellents are known since many decades ago and constitute a major tool for personal protection against the biting of mosquitoes. Despite their wide use, the understanding of why and how repellents repel is relatively recent. In particular, the question about to what extent insects other than mosquitoes are repulsed by repellents remains open. We developed a series of bioassays aimed to test the performance of well established as well as potential repellent molecules on the Chagas disease vector Rhodnius prolixus. Besides testing their ability to prevent biting, we tested the way in which they act, i.e., by obstructing the detection of attractive odours or by themselves. By using three different experimental protocols (host-biting, open-loop orientation to odours and heat-triggered proboscis extension response) we show that DEET repels bugs both in the presence and in the absence of host-associated odours but only at the highest quantities tested. Piperidine was effective with or without a host and icar-idine only repelled in the absence of a living host. Three other molecules recently proposed as potential repellents due to their affinity to the Ir40a + receptor (which is also activated by DEET) did not evoke significant repellency. Our work provides novel experimental tools and sheds light on the mechanism behind repellency in haematophagous bugs

Diversity of functional alterations of the ClC‐5 exchanger in the region of the proton glutamate in patients with Dent disease 1

International audienceMutations in the CLCN5 gene encoding the 2Cl- /1H+ exchanger ClC-5 are associated with Dent disease 1, an inherited renal disorder characterized by low molecular weight (LMW) proteinuria and hypercalciuria. In the kidney, ClC-5 is mostly localized in proximal tubule cells where it is thought to play a key role in the endocytosis of LMW proteins. Here, we investigated the consequences of eight previously reported pathogenic missense mutations of ClC-5 surrounding the "proton glutamate" that serves as a crucial H+ -binding site for the exchanger. A complete loss of function was observed for a group of mutants that were either retained in the endoplasmic reticulum of HEK293T cells or unstainable at plasma membrane due to proteasomal degradation. In contrast, the currents measured for a second group of mutations in X. laevis oocytes were reduced. Molecular Dynamics simulations performed on a ClC-5 homology model demonstrated that such mutations may alter ClC-5 protonation by interfering with the water pathway. Analysis of clinical data from patients harboring these mutations demonstrated no phenotype/genotype correlation. This study reveals that mutations clustered in a crucial region of ClC-5 have diverse molecular consequences in patients with Dent disease 1, ranging from altered expression to defects in transport. This article is protected by copyright. All rights reserved

Defective bicarbonate reabsorption in Kir4.2 potassium channel deficient mice impairs acid-base balance and ammonia excretion: Kir4.2 and renal ammoniagenesis

International audienceThe kidneys excrete the daily acid load mainly by generating and excreting ammonia but the underlying molecular mechanisms are not fully understood. Here we evaluated the role of the inwardly rectifying potassium channel subunit Kir4.2 (Kcnj15 gene product) in this process. In mice, Kir4.2 was present exclusively at the basolateral membrane of proximal tubular cells and disruption of Kcnj15 caused a hyperchloremic metabolic acidosis associated with a reduced threshold for bicarbonate in the absence of a generalized proximal tubule dysfunction. Urinary ammonium excretion rates in Kcnj15- deleted mice were inappropriate to acidosis under basal and acid-loading conditions, and not related to a failure to acidify urine or a reduced expression of ammonia transporters in the collecting duct. In contrast, the expression of key proteins involved in ammonia metabolism and secretion by proximal cells, namely the glutamine transporter SNAT3, the phosphate-dependent glutaminase and phosphoenolpyruvate carboxykinase enzymes, and the sodium-proton exchanger NHE-3 was inappropriate in Kcnj15-deleted mice. Additionally, Kcnj15 deletion depolarized the proximal cell membrane by decreasing the barium-sensitive component of the potassium conductance and caused an intracellular alkalinization. Thus, the Kir4.2 potassium channel subunit is a newly recognized regulator of proximal ammonia metabolism. The kidney consequences of its loss of function in mice support the proposal for KCNJ15 as a molecular basis for human isolated proximal renal tubular acidosis

The cellular prion protein is a stress protein secreted by renal tubular cells and a urinary marker of kidney injury

International audienceEndoplasmic Reticulum (ER) stress underlies the pathogenesis of numerous kidney diseases. A better care of patients with kidney disease involves the identification and validation of ER stress biomarkers in the early stages of kidney disease. For the first time to our knowledge, we demonstrate that the prion protein PrP C is secreted in a conventional manner by ER-stressed renal epithelial cell under the control of the transcription factor x-box binding protein 1 (XBP1) and can serve as a sensitive urinary biomarker for detecting tubular ER stress. Urinary PrP C elevation occurs in patients with chronic kidney disease. In addition, in patients undergoing cardiac surgery, detectable urine levels of PrP C significantly increase after cardiopulmonary bypass, a condition associated with activation of the IRE1-XBP1 pathway in the kidney. In conclusion, our study has identified PrP C as a novel urinary ER stress biomarker with potential utility in early diagnosis of ongoing acute or chronic kidney injury

A novel CLCN5 pathogenic mutation supports Dent disease with normal endosomal acidification

International audienceDent disease is an X‐linked recessive renal tubular disorder characterized by low‐molecular‐weight proteinuria, hypercalciuria, nephrolithiasis, nephrocalcinosis, and progressive renal failure. Inactivating mutations of CLCN5, the gene encoding the 2Cl−/H+ exchanger ClC‐5, have been reported in patients with Dent disease 1. In vivo studies in mice harboring an artificial mutation in the “gating glutamate” of ClC‐5 (c.632A > C, p.Glu211Ala) and mathematical modeling suggest that endosomal chloride concentration could be an important parameter in endocytosis, rather than acidification as earlier hypothesized. Here, we described a novel pathogenic mutation affecting the “gating glutamate” of ClC‐5 (c.632A>G, p.Glu211Gly) and investigated its molecular consequences. In HEK293T cells, the p.Glu211Gly ClC‐5 mutant displayed unaltered N‐glycosylation and normal plasma membrane and early endosomes localizations. In Xenopus laevis oocytes and HEK293T cells, we found that contrasting with wild‐type ClC‐5, the mutation abolished the outward rectification, the sensitivity to extracellular H+ and converted ClC‐5 into a Cl− channel. Investigation of endosomal acidification in HEK293T cells using the pH‐sensitive pHluorin2 probe showed that the luminal pH of cells expressing a wild‐type or p.Glu211Gly ClC‐5 was not significantly different. Our study further confirms that impaired acidification of endosomes is not the only parameter leading to defective endocytosis in Dent disease 1

Analysis of CLCNKB mutations at dimer‐interface, calcium‐binding site, and pore reveals a variety of functional alterations in ClC‐Kb channel leading to Bartter syndrome

International audiencePathological missense mutations in CLCNKB gene give a wide spectrum of clinical phenotypes in Bartter syndrome type III patients. Molecular analysis of the mutated ClC-Kb channels can be helpful to classify the mutations according to their functional alteration. We investigated the functional consequences of nine mutations in the CLCNKB gene causing Bartter syndrome. We first established that all tested mutations lead to decreased ClC-Kb currents. Combining electrophysiological and biochemical methods in Xenopus laevis oocytes and in MDCKII cells, we identified three classes of mutations. One class is characterized by altered channel trafficking. p.A210V, p.P216L, p.G424R, and p.G437R are totally or partially retained in the endoplasmic reticulum. p.S218N is characterized by reduced channel insertion at the plasma membrane and altered pH-sensitivity; thus, it falls in the second class of mutations. Finally, we found a novel class of functionally inactivated mutants normally present at the plasma membrane. Indeed, we found that p.A204T alters the pH-sensitivity, p.A254V abolishes the calcium-sensitivity. p.G219C and p.G465R are probably partially inactive at the plasma membrane. In conclusion, most pathogenic mutants accumulate partly or totally in intracellular compartments, but some mutants are normally present at the membrane surface and simultaneously show a large range of altered channel gating properties

Renal Function Decline Under Therapy With Small Interfering RNA Silencing ALAS1 for Acute Intermittent Porphyria

International audienceIntroduction: Givosiran is an RNA interference therapeutic designed to block the synthesis of the aminolevulinic acid (ALA) synthase 1 (ALAS1) enzyme in patients with acute intermittent porphyria (AIP). Givosiran may have adverse effects on the kidney.Methods: We performed a descriptive case series of renal function parameters of all the patients who received givosiran in France. Twenty patients receiving givosiran between March 2018 and July 2020 in France were analyzed: 7 patients in the ENVISION trial and 13 patients treated in collaboration with the Centre de Référence Maladies Rares Prophyries.Results: A transient decrease in renal function was observed in all but 2 patients (90%) within the 3 months following givosiran initiation. None of the patients developed acute kidney injury or disease. Patients of the ENVISION cohort were followed for at least 30 months: 2 patients did not experience estimated glomerular filtration rate (eGFR) loss, 3 patients experienced a modest decline in renal function (–3.4 ml/min per 1.73 m2 per year in average), and 2 patients had a clearly abnormal eGFR loss (–5.8 ml/min per 1.73 m2 per year in average). None of the patients had biochemical signs of active tubular or glomerular injury. One patient’s kidney was biopsied without finding any signs of an active kidney disease and with normal ALAS1 tubular expression.Conclusions: Givosiran is associated with a transient moderate increase in serum creatinine (sCr) without sign of kidney injury. A long-term deleterious impact of ALAS1 inhibition on renal function is not excluded. Because AIP promotes chronic kidney disease, it is difficult to separate the long-term effects of givosiran from the natural progression of the renal disease