Project description:Notch signaling deficient kidney collecting ducts may serve as a useful resource to identify principal cell lineage and intercalated lineage specific factors since they develop a reduced number of principal cells and an increased number of intercalated cells compared with wild type kidney collecting ducts. We compared RNA from three E18.5 mouse kidneys per group: HoxB7Cre;RBPJf/-;Rosa+/Eyfp (Notch signaling deficient; mutant) versus RBPJf/f;Rosa+/Eyfp (wild type).

Project description:Urinary tract infection (UTI) significantly impacts people with diabetes mellitus. Insulin resistance, the primary abnormality leading to Type 2 diabetes, is defined by inefficient insulin receptor signaling. In the kidney, insulin receptor deletion in intercalated cells increases UTI susceptibility. Here, we use RNA sequencing to profile the transcriptomes of enriched intercalated cell and neighboring principal cell populations from mice with intercalated cell-specific insulin receptor deletion and compare expression profiles to wild-type mice. We also establish unique intercalated cell and principal cell cultures to assess the functional impact of insulin receptor deletion. Transcriptomic analysis and culture models demonstrate intercalated cells with insulin receptor deletion are more susceptible to uropathogenic Escherichia coli infection and have suppressed integrated stress responses. They also show the integrated stress response is necessary to activate NFkB-mediated immune responses. When NFkB is silenced, intercalated cells do not activate innate immune responses, including the production of antimicrobial peptides, which increases infection susceptibility.  

Project description:Intercalated cells are known to be involved in acid-base homeostasis via vacuolar ATPase (H+-ATPase or V-ATPase) expression. Increasing evidence supports an innate immune role for ICs along with their traditional function of pH regulation. In this study, human kidney tissue was enriched for viable intercalated cells then exposed to uropathogenic E. coli versus saline control. Single cell transcriptomics was performed. Six intercalated cell subtypes were identified including hybrid principal-intercalated cells. Cell specific cluster marker gene list generated from this sequencing data was put through ingenuity pathway analysis pipeline which predicted “phagosome maturation” as a key biological pathway that increased in rank following exposure to uropathogenic E. coli in two of the intercalated cell subtypes. Uptake of E. coli and pHrodo coated E. coli BioParticlesTM during live animal intravital microscopy demonstrated that intercalated cell phagocytosis of bacteria was an active process that involved acidification. Taken together, our finding indicate that intercalated cells represent an epithelial cell with characteristics of professional phagocytes like macrophages or neutrophils, which includes the ability to phagocytose E. coli and acidify phagolysosomes.

Project description:Intercalated cells within renal tubules play a vital role in maintaining body acid-base balance through H+ and HCO3- secretion. Disruptions in intercalated cell differentiation or channel activity due to gene mutations can lead to distal renal tubular acidosis (dRTA), yet the precise mechanisms governing this process remain poorly understood. This study identified Foxp1 and its downstream factors as novel essential factors for intercalated cell differentiation, thus shed light on potential underlying mechanisms in some unresolved cases of dRTA.

Project description:Kidneys are essential for acid-base homeostasis, especially when organisms cope with changes in acid or base dietary intake. Because collecting ducts constitute the final site for regulating urine acid-base balance, we undertook to identify the gene network involved in acid-base transport and regulation in the mouse outer medullary collecting duct (OMCD). For this purpose, we combined kidney functional studies and quantitative analysis of gene expression in OMCDs, by transcriptome and candidate gene approaches, during metabolic acidosis. Furthermore, to better delineate the set of genes concerned with acid-base disturbance, the OMCD transcriptome of acidotic mice was both compared to that of normal mice and mice undergoing an adaptative response through potassium depletion. Metabolic acidosis, achieved through a NH4Cl-supplemented diet for 3 days, not only induced acid secretion, but also stimulated the aldosterone and vasopressin systems and triggered cell proliferation. Accordingly, metabolic acidosis increased the expression of genes involved in acid-base transport, sodium transport, water transport and cell proliferation. In particular, more than 25 transcripts encoding proteins involved in urine acidification (subunits of H-ATPase, kidney anion exchanger, chloride channel Clcka, carbonic anhydrase 2, aldolase) were co-regulated during acidosis. We propose that these trancripts cooperating to a same function and co-regulated during acidosis constitute a functional regulon. Keywords: SAGE; Kidney collecting duct; Mouse; Metabolic acidosis; V-ATPase

Project description:Kidneys are essential for acid-base homeostasis, especially when organisms cope with changes in acid or base dietary intake. Because collecting ducts constitute the final site for regulating urine acid-base balance, we undertook to identify the gene network involved in acid-base transport and regulation in the mouse outer medullary collecting duct (OMCD). For this purpose, we combined kidney functional studies and quantitative analysis of gene expression in OMCDs, by transcriptome and candidate gene approaches, during metabolic acidosis. Furthermore, to better delineate the set of genes concerned with acid-base disturbance, the OMCD transcriptome of acidotic mice was both compared to that of normal mice and mice undergoing an adaptative response through potassium depletion. Metabolic acidosis, achieved through a NH4Cl-supplemented diet for 3 days, not only induced acid secretion, but also stimulated the aldosterone and vasopressin systems and triggered cell proliferation. Accordingly, metabolic acidosis increased the expression of genes involved in acid-base transport, sodium transport, water transport and cell proliferation. In particular, more than 25 transcripts encoding proteins involved in urine acidification (subunits of H-ATPase, kidney anion exchanger, chloride channel Clcka, carbonic anhydrase 2, aldolase) were co-regulated during acidosis. We propose that these trancripts cooperating to a same function and co-regulated during acidosis constitute a functional regulon. Keywords: SAGE; Kidney collecting duct; Mouse; Metabolic acidosis; V-ATPase Approximately 650 OMCDs were microdissected, as previously described from collagenase-treated kidneys of 6 mice fed the NH4Cl-supplemented diet for 3 days. 20960 tags were sequenced in the acidosis SAGE library. After withdrawing duplicate ditags and linker sequences, the 19146 tags remaining corresponded to 8847 different tags.This acidosis library is similar in size and diversity to the normal mouse OMCD libraries previously generated (GEO accession number : GSM23478). The tag abundance in the two library was compared and discussed.

Project description:Maximizing the potential of human kidney organoids for drug testing, regenerative medicine and to model development and disease requires addressing cell immaturity, the lack of a branching collecting system and the off target cell types. Here we establish methods to independently generate the two kidney progenitor cell populations – metanephric mesenchyme and ureteric bud. Combining these two progenitor cell types results in organoids with an improved branched collecting system. We also identified the hormones aldosterone and arginine vasopressin as critical to promote maturation of collecting duct cell types. The resulting organoids contain the full range of epithelial cells in the nephron, including principal and intercalated cells. By scRNA-seq, we demonstrate superior proximal tubule maturation and reduced off-target cell populations using this protocol.

Project description:Kidney Intercalated Cells Phagocytose and Acidify Escherichia coli

Project description:Transcriptome analyses reveal plasticity of phenotype with expression of principle and intercalated cell markers in this mouse kidney-derived cell line.

Project description:Analysis of collecting duct response to low NaCl or high NaCl diet at the gene expression level. Results provide insight into transcriptional changes in principal and intercalated cells that occur in response to changes in dietary NaCl.