A Multi-layered Quantitative In Vivo Expression Atlas of the Podocyte Unravels Kidney Disease Candidate Genes

Rinschen, Markus M.; Gödel, Markus; Grahammer, Florian; Zschiedrich, Stefan; Helmstädter, Martin; Kretz, Oliver; Zarei, Mostafa; Braun, Daniela A.; Dittrich, S; Pahmeyer, Caroline; Schröder, Patricia; Teetzen, Carolin; Gee, Heon Yung; Daouk, Ghaleb H.; Pöhl, Martin; Kuhn, Elisa; Schermer, Bernhard; Küttner, Victoria; Boerries, Melanie; Busch, Hauke; Schiffer, Mario; Bergmann, Carsten; Krüger, Marcus; Hildebrandt, Friedhelm; Dengjel, Jörn; Benzing, Thomas; Huber, Tobias B.

doi:10.1016/j.celrep.2018.04.059

Cited by 93 publications

(93 citation statements)

References 83 publications

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“…15 In this context, podocyte loss represents the major culprit for the development for glomerular diseases. 16 Podocytes were identified using histone-mediated nuclear expression of enhanced green fluorescent protein (eGFP) (Figure 2a). Total numbers of eGFP þ podocytes were quantified in intact using a combination of in vivo metabolic labeling and 3D morphometry ( Figure 2b).…”

Section: Podocyte Loss In Crescentic Nephritismentioning

confidence: 99%

Novel 3D analysis using optical tissue clearing documents the evolution of murine rapidly progressive glomerulonephritis

Puelles

Fleck

Ortz

et al. 2019

Kidney International

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Recent developments in optical tissue clearing have been difficult to apply for the morphometric analysis of organs with high cellular content and small functional structures, such as the kidney. Here, we establish combinations of genetic and immuno-labelling for single cell identification, tissue clearing and subsequent de-clarification for histoimmunopathology and transmission electron microscopy. Using advanced light microscopy and computational analyses, we investigated a murine model of crescentic nephritis, an inflammatory kidney disease typified by immune-mediated damage to glomeruli leading to the formation of hypercellular lesions and the rapid loss of kidney function induced by nephrotoxic serum. Results show a graded susceptibility of the glomeruli, significant podocyte loss and capillary injury. These effects are associated with activation of parietal epithelial cells and formation of glomerular lesions that may evolve and obstruct the kidney tubule, thereby explaining the loss of kidney function. Thus, our work provides new highthroughput endpoints for the analysis of complex tissues with single-cell resolution.

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Section: Podocyte Loss In Crescentic Nephritismentioning

confidence: 99%

Novel 3D analysis using optical tissue clearing documents the evolution of murine rapidly progressive glomerulonephritis

Puelles

Fleck

Ortz

et al. 2019

Kidney International

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“…Then proteins were reduced and alkylated as described above. Proteins were digested using a protease in-solution digestion protocol with a modified SP3 protocol (Hohne et al, 2018;Hughes et al, 2019) (50000 cells), or in solution digestion (Rinschen et al, 2018a). For all digestion steps, trypsin was used.…”

Section: Sample Preparation and Mass Spectrometry Analysismentioning

confidence: 99%

“…Further, only podocytes are isolated from one mouse, the other glomerular cells being indistinguishable through the expression of tdTomato. Additionally, the substantial expression of a foreign fluorescent protein within glomerular cells (up to 6%) (Rinschen et al, 2018a) could induce inevitable biochemical artefacts, depending on the biological system evaluated (for example protein degradation systems). These limitations are particularly important in diseases with altered glomerular composition such as podocyte loss or mesangial expansion.…”

Section: Introductionmentioning

confidence: 99%

Tripartite separation of glomerular cell-types and proteomes from reporter-free mice

Hatje

Rinschen

Wedekind

et al. 2020

Preprint

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Purpose: The kidney glomerulus comprises a syncytium of podocytes, mesangial and endothelial cells, which jointly determine glomerular filtration barrier function, and thereby kidney and cardiovascular health. The understanding of this intricate functional unit and its intracellular communication beyond the transcriptome requires bulk isolation of these cell-types from glomeruli for subsequent biochemical investigations. Therefore, we developed a globally applicable tripartite isolation method for murine mesangial and endothelial cells and podocytes (timMEP). Methods: Glomerular cells were separated via a novel FACS-sort depending on a cell-specific antibody labeling in wildtype mice or based on a combination of transgenic fluorescent protein expression and antibody labeling in mT/mG mice. The purity of isolated cell-types was validated by qPCR and immunoblot. The proteome of podocytes, mesangial and endothelial cells was determined and compared between species, ages and gender of wildtype and mT/mG mice. The method was also applied to the podocyte-targeting immunologic injury model of THSD7A-associated membranous glomerulonephritis. Results: TimMEP enabled protein-biochemical analyses of podocytes, mesangial and endothelial cells derived from a single reporter free mouse. Proteomic analyses allowed the first characterization of podocyte, endothelial and mesangial proteomes of individual mice. Marker proteins for mesangial and endothelial proteins were determined, and protein-based interaction and intraglomerular cell communication networks were elucidated. Interestingly, analyses revealed significant cell-type specific proteome differences between mouse strains, artefacts induced by reporters, and alterations depending on gender and age. Within the glomerulus, timMEP resolved a fine-tuned initial stress response exclusively in podocytes after exposure to anti-THSD7A antibodies, which was not detectable using conventional analyses in whole glomeruli. Conclusion: Globally applicable timMEP abolishes the need for costly, time- and animal- consuming breeding of mice to glomerular cell-type reporters. TimMEP enables glomerular cell-type resolved investigations at the transcriptional and protein biochemical level in health and disease, while avoiding reporter-based artefacts, paving the way towards the comprehensive and systematic characterization of glomerular cell-type biology.

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“…76 First applications of deep proteomics include detailed characterization of human and mouse podocytes 77 that led to the discovery of FARP1, a previously unrecognized podocytespecific protein with a potential role in proteinuric kidney disease. 77 An ongoing area of research focuses on posttranslational protein modifications in glomerular tissue. In particular, large-scale phosphoproteomes, 78 integrated with genomic information, can be used to predict clinically relevant phosphorylation sites.…”

Section: Proteomics and Metabolomicsmentioning

confidence: 99%

Big science and big data in nephrology

Sáez-Rodríguez

Rinschen

Floege

et al. 2019

Kidney International

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A Multi-layered Quantitative In Vivo Expression Atlas of the Podocyte Unravels Kidney Disease Candidate Genes

Cited by 93 publications

References 83 publications

Novel 3D analysis using optical tissue clearing documents the evolution of murine rapidly progressive glomerulonephritis

Novel 3D analysis using optical tissue clearing documents the evolution of murine rapidly progressive glomerulonephritis

Tripartite separation of glomerular cell-types and proteomes from reporter-free mice

Big science and big data in nephrology

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