Project description:Adult Stem Cell (ASC )-derived organoids are 3D epithelial structures that recapitulate essential aspects of their organ of origin. We have developed conditions for the long-term growth of primary kidney tubular epithelial organoids (‘tubuloids’). Cultures can be established from mouse and human kidney tissue, as well as from urine and can be expanded for at least 20 passages (> 6 months). The structures retain a normal number of chromosomes. Human tubuloids represent proximal as well as distal nephron segments, as evidenced by gene expression, immunofluorescence and tubular functional analyses. BK virus infection of tubuloids recapitulates in vivo phenomena. "Tumoroids" can be established from Wilms nephroblastoma. Kidney tubuloids from urine from a subject with Cystic Fibrosis (CF) allows ex vivo assessment of treatment efficacy. Finally, tubuloids cultured on microfluidic organ-on-a-chip plates adopt a tubular conformation and display active (trans-)epithelial transport function. Adult kidney-derived epithelial tubuloids allow studies of hereditary, infectious and malignant kidney disease in a personalized fashion.

Project description:Adult Stem Cell (ASC )-derived organoids are 3D epithelial structures that recapitulate essential aspects of their organ of origin. We have developed conditions for the long-term growth of primary kidney tubular epithelial organoids (‘tubuloids’). Cultures can be established from mouse and human kidney tissue, as well as from urine and can be expanded for at least 20 passages (> 6 months). The structures retain a normal number of chromosomes. Human tubuloids represent proximal as well as distal nephron segments, as evidenced by gene expression, immunofluorescence and tubular functional analyses. BK virus infection of tubuloids recapitulates in vivo phenomena. "Tumoroids" can be established from Wilms nephroblastoma. Kidney tubuloids from urine from a subject with Cystic Fibrosis (CF) allows ex vivo assessment of treatment efficacy. Finally, tubuloids cultured on microfluidic organ-on-a-chip plates adopt a tubular conformation and display active (trans-)epithelial transport function. Adult kidney-derived epithelial tubuloids allow studies of hereditary, infectious and malignant kidney disease in a personalized fashion.

Project description:Acute kidney injury (AKI) is a severe clinical syndrome with high morbidity and mortality, yet its pathogenesis remains incompletely understood, and effective therapeutic strategies are still lacking. In this study, we observed significant upregulation of N-acetyltransferase 10 (NAT10) in the tubular epithelial cells of Cisplatin-induced AKI. Lentivirus-mediated knockdown of NAT10 or treatment with NAT10 inhibitor Remodelin, ameliorated Cisplatin-induced renal dysfunction and tubular injury. Importantly, NAT10 inhibition markedly attenuated cellular senescence in Cisplatin-induced AKI, as evidenced by reduced senescence-associated β-galactosidase (SA-β-gal) activity, downregulation of senescence markers (p53, p21, and γ-H2A.X), and decreased levels of senescence-associated secretory phenotype (SASP) factors (IL-1β, IL-6, and TNF-α). Mechanistically, co-immunoprecipitation assay suggested that NAT10 interacted with DDX17 to regulate its expression. Knockdown or inhibition of NAT10 reduced the protein expression of DDX17 in Cisplatin-injured kidneys. While silencing DDX17 could inhibit Cisplatin-induced senescence in HK-2 cells. Furthermore, we demonstrated that the effects of NAT10 on Cisplatin-induced tubular injury and senescence was dependent on DDX17. Our study revealed a novel mechanism by which NAT10 promoted Cisplatin-induced renal tubular cell senescence via DDX17 upregulation, suggesting that targeting the NAT10/DDX17 signaling axis may offer a potential therapeutic strategy for AKI.

Project description:Tubuloids are adult stem cell-based kidney organoids with promising application in kidney disease modelling and drug screening. However, tubuloids still present limited transepithelial transport capacity, which is essential for the kidney’s function. The extracellular vesicles (EVs) are cell-derived vesicular structures known to regulate several cellular processes, including development and maturation. This study explores the potential of EVs derived from renal cells to support tubuloid functional maturation by increasing the levels of organic anion transport 1 (OAT1), a protein involved in renal waste handling.

Project description:This study reports the cellular self-organization of primary human renal proximal tubule epithelial cells (RPTECs) around a minimal Matrigel scaffold to produce basal-in and apical-out proximal tubule organoids (tubuloids). These tubuloids are produced and maintained in hanging drop cultures for 90+ days, the longest such culture of any kind reported to date. The tubuloids upregulate maturity markers, such as aquaporin-1 (AQP1) and megalin (LRP2), and exhibit less mesenchymal and proliferation markers, such as vimentin and Ki67, compared to 2D cultures. They also experience changes over time as revealed by a comparison of gene expression patterns of cells in 2D culture and in day 31 and day 67 tubuloids. Gene expression analysis and immunohistochemistry reveal an increase in the expression of megalin, an endocytic receptor that can directly bind and uptake protein or potentially assist protein uptake. The tubuloids, including day 90 tubuloids, uptake fluorescent albumin and reveal punctate fluorescent patterns, suggesting functional endocytic uptake through these receptors. Furthermore, the tubuloids release kidney injury molecule-1 (KIM-1), a common biomarker for kidney injury, when exposed to albumin in both dose- and time-dependent manners. While this study focuses on potential applications for modeling proteinuric kidney disease, the tubuloids may have broad utility for studies where apical proximal tubule cell access is required.

Project description:Adult kidney organoids have been described as strictly tubular epithelial and termed tubuloids. While the cellular origin of tubuloids has remained elusive, here we report that they originate from a distinct CD24+ epithelial subpopulation. Long-term-cultured CD24+-derived tubuloids represent a functional human kidney tubule. We show that kidney tubuloids can be used to model the most common inherited kidney disease, namely autosomal dominant polycystic kidney disease (ADPKD), reconstituting the phenotypic hallmark of this disease with cyst formation. Single-cell RNA sequencing of CRISPR/Cas9 gene-edited PKD1 and PKD2 knockout tubuloids and human ADPKD and control tissue show similarities in upregulation of disease-driving genes. Furthermore, in a proof of concept, we demonstrate that tolvaptan, the only approved drug for ADPKD, shows a significant effect on cyst size in tubuloids but no effect in a pluripotent-stem-cell-derived model. Thus, tubuloids derive from a tubular epithelial subpopulation and represent an advanced model for ADPKD disease modeling.

Project description:Human Kidney Tubuloids Model of Repeated Cisplatin-induced Cellular Senescence and Fibrosis for Drug Screening

Project description:Kidney organoids can be generated from commercially available human induced pluripotent stem cells (iPSC). They are amenable for genetic manipulation and useful for modelling development and early-onset genetic diseases. However, iPSC-derived kidney organoids lack longevity to model chronic stressors associated with chronic kidney disease. Adult epithelial kidney organoids (tubuloids) derived from nephrectomies or from renal cells suspended in urine can be passaged, expanded and cryopreserved, offering avenues to model epithelial injury and repair over longer timeframes. However, patient-derived organoids face regulatory barriers in their utilization. To leverage the benefits of both models, we establish a new protocol to generate tubuloids from iPSC-derived kidney organoids (iTubuloids). Kidney organoids were produced from iPSCs by directed differentiation then dissociated and cultured under adult organoid culture conditions. Epithelial organoids formed in less than 3 days from three distinct iPSC lines, each of which have been passaged > 12 times. Comparative analysis of gene expression profiles with RNA sequencing suggested that adult-derived tubuloids better represented the collecting duct, and iTubuloids showed increased expression of proximal and some distal markers. However, expression of proximal tubule markers was higher in iPSC-derived kidney organoids than any tubuloid model. We then evaluated the capacity of iTubuloids to model repetitive kidney injury and found exacerbation of the response and signs of failed repair as the injured progressed. Our study affirms capacity to extend the lifespan of epithelial cell types from short-lived iPSC-derived kidney organoids and reveal a need to optimise nephron cell identities in the tubuloid culture.

Project description:Acute kidney injury (AKI) is a frequent and challenging clinical condition associated with high morbidity and mortality. In AKI, renal tubular epithelial cells (TECs) are a primary site of damage, and recovery from AKI depends on TEC plasticity. However, the molecular mechanisms underlying adaptation and maladaptation of TECs in AKI remain largely unclear. Here, our analyses of mouse kidney tubuloids showed that TEC injury resulted in activation of the glucocortiocoid receptor by endogenous glucocorticoids, which aggravated tubular damage. The detrimental effect of endogenous glucocorticoids on injured TECs was exacerbated by the administration of the widely clinically used synthetic glucocorticoid, dexamethasone, as indicated by experiments in mouse kidney tubuloids. Mechanistically, studies in mouse tubuloids demonstrated that glucocorticoid receptor signaling in injured TECs orchestrated a maladaptive transcriptional program to hinder DNA repair and to amplify injury-induced DNA double-strand break formation, as well as to dampen mTOR activity and mitochondrial bioenergetics. This study identifies glucocortiocoid receptor activation as a mechanism of epithelial maladaptation, which is functionally important for acute kidney injury.

Project description:Acute kidney injury (AKI) is a frequent and challenging clinical condition associated with high morbidity and mortality. In AKI, renal tubular epithelial cells (TECs) are a primary site of damage, and recovery from AKI depends on TEC plasticity. However, the molecular mechanisms underlying adaptation and maladaptation of TECs in AKI remain largely unclear. Here, our analyses of mouse kidney tubuloids showed that TEC injury resulted in activation of the glucocortiocoid receptor by endogenous glucocorticoids, which aggravated tubular damage. The detrimental effect of endogenous glucocorticoids on injured TECs was exacerbated by the administration of the widely clinically used synthetic glucocorticoid, dexamethasone, as indicated by experiments in mouse kidney tubuloids. Mechanistically, studies in mouse tubuloids demonstrated that glucocorticoid receptor signaling in injured TECs orchestrated a maladaptive transcriptional program to hinder DNA repair and to amplify injury-induced DNA double-strand break formation, as well as to dampen mTOR activity and mitochondrial bioenergetics. This study identifies glucocortiocoid receptor activation as a mechanism of epithelial maladaptation, which is functionally important for acute kidney injury.