Lysine-specific histone demethylase 1a regulates nephron development and long-term transcriptional programming
Nicola Wanner, Julia Keller, Nastassia Liaukouskaya, Geoffroy Andrieux, Sandra D. Laufer, Manuel Rogg, Tillmann Bork, Wei Liang, Fabian Braun, Fabian Haas, Milagros N. Wong, Victor G. Puelles, Sydney E. Gies, Charlotte Meyer, Melanie Boerries, Martin Helmstädter, Oliver Kretz, Iris Hild, Eric Metzger, Roland Schüle, Wibke Bechtel-Walz, Tobias B. Huber
Nicola Wanner, Julia Keller, Nastassia Liaukouskaya, Geoffroy Andrieux, Sandra D. Laufer, Manuel Rogg, Tillmann Bork, Wei Liang, Fabian Braun, Fabian Haas, Milagros N. Wong, Victor G. Puelles, Sydney E. Gies, Charlotte Meyer, Melanie Boerries, Martin Helmstädter, Oliver Kretz, Iris Hild, Eric Metzger, Roland Schüle, Wibke Bechtel-Walz, Tobias B. Huber
View: Text | PDF
Research Article Development Nephrology

Lysine-specific histone demethylase 1a regulates nephron development and long-term transcriptional programming

Abstract

Low nephron endowment constitutes a risk factor for hypertension and renal disease. Epigenetic regulation is crucial for nephron progenitor cell differentiation, affecting nephron number and renal function. The role of many epigenetic modulators, such as Lysine-specific histone demethylase 1a (LSD1 or KDM1A), remains unclear. We used Kdm1a-KO mice to demonstrate that Kdm1a depletion in nephron progenitor cells results in reduced kidney size in neonates and led to glomerulosclerosis, proteinuria, and renal cysts in adults. Notably, Kdm1a deletion in podocytes or tubular cells did not replicate these effects. CRISPR/Cas9-mediated KDM1A deletion in human kidney organoids caused cyst formation and altered gene expression, with snRNA-seq revealing downregulation of podocyte genes and upregulation of metabolic genes. The presence of noncoding RNAs indicated roles in cell proliferation. Our study reveals the critical role of Kdm1a function in nephron development and highlights its affect on transcriptional programming for long-term renal function and susceptibility to cyst formation.

Authors

Nicola Wanner, Julia Keller, Nastassia Liaukouskaya, Geoffroy Andrieux, Sandra D. Laufer, Manuel Rogg, Tillmann Bork, Wei Liang, Fabian Braun, Fabian Haas, Milagros N. Wong, Victor G. Puelles, Sydney E. Gies, Charlotte Meyer, Melanie Boerries, Martin Helmstädter, Oliver Kretz, Iris Hild, Eric Metzger, Roland Schüle, Wibke Bechtel-Walz, Tobias B. Huber

×

Figure 2

Conditional depletion of KDM1A leads to mild proteinuria and kidney hypoplasia at birth.

Options: View larger image (or click on image) Download as PowerPoint
Conditional depletion of KDM1A leads to mild proteinuria and kidney hypo...
(A) Schematic of conditional Kdm1a-KO mouse model. (B) Macroscopic view of WT and KO kidneys (scale bar: 5 mm). (C and D) Periodic Acid Schiff staining of histological sections of WT and KO kidneys shows no structural changes upon conditional Kdm1a ablation (scale bars: 300 μm in C and 30 μm in D). (E) Transmission electron microscopy of WT and KO kidney displays slight abnormalities in foot process formation. Scale bar: 1 μm. (F) Kidney weight-to-body weight ratio shows reduction of kidney size (wt, n = 14; het, n = 6; ko, n = 8). (G) Albumin/creatinine ratio shows an increase in proteinuria in KO animals compared with WT and HET animals. (H) Blood urea levels are unaltered. One-way ANOVA with Dunnett’s correction for multiple comparisons. (I) Glomeruli per volume do not differ compared with HET and KO kidneys at p0. Unpaired 2-tailed Student’s t test. (J) Representative images from z stacks of optically cleared kidneys at p0. Scale bar: 100 μm. (K) Scanning electron microscopy images from 21-day-old kidneys show slightly irregular foot process effacements in KO kidneys. Scale bar: 2 μm. *P < 0.01. **P < 0.05.