Fragility of foot process morphology in kidney podocytes arises from chaotic spatial propagation of cytoskeletal instability

Kidney podocytes’ function depends on fingerlike projections (foot processes) that interdigitate with those from neighboring cells to form the glomerular filtration barrier. The integrity of the barrier depends on spatial control of dynamics of actin cytoskeleton in the foot processes. We determined how imbalances in regulation of actin cytoskeletal dynamics could result in pathological morphology. We obtained 3-D electron microscopy images of podocytes and used quantitative features to build dynamical models to investigate how regulation of actin dynamics within foot processes controls local morphology. We find that imbalances in regulation of actin bundling lead to chaotic spatial patterns that could impair the foot process morphology. Simulation results are consistent with experimental observations for cytoskeletal reconfiguration through dysregulated RhoA or Rac1, and they predict compensatory mechanisms for biochemical stability. We conclude that podocyte morphology, optimized for filtration, is intrinsically fragile, whereby local transient biochemical imbalances may lead to permanent morphological changes associated with pathophysiology

Abstract P1075: Igf-1 Signaling And Nuclear Localization Of Pdgfralpha Tyrosine Kinase Activity Control The Fibrotic Response Of Mesenchymal Stromal Cells To Myocardial Ischemia

Background and Hypothesis: The role of mesenchymal stromal cells expressing the platelet-derived growth factor alpha (PDGFRα + MSCs) has been associated with fibro-adipogenic pathologies. Based on our previous data in regenerating skeletal muscle and the data herein described, we hypothesized that specific and distinct mesenchymal stromal cells exist in the heart, which will retain regenerative capacities by modulating the spatiotemporal distribution of the PDGFRα tyrosine kinase activity and the re-expression of specific regenerative molecules. Methods: Myocardial ischemia/reperfusion (I/R) was induced in mice with standard procedures and in compliance with the regulations of the NIH and the local institutional animal care. Results: Confocal imaging and immunophenotyping analyses showed that cardiac PDGFRα + MSCs exist as two distinct sub-populations expressing markers of specialized and differentiated cells, such as endothelial (60.3%±7.9% expressing CD31) and cardiomyocyte cell-cell anchoring markers (89%± 0.6% of population expressing desmocollin 2/3), while also retaining the expression of mesenchymal markers. Importantly, whereas PDGFRα + MSCs organized in vessel-like structures expressing CD31 during the acute phase after I/R, they transitioned into myofibroblast-like cells in ischemic subacute conditions. Identifying the mechanisms regulating PDGFRα + MSCs dual function remains a critical roadblock. In addressing this gap, we discovered that the transition to myofibroblast-like cells was associated to nuclear shuttling of PDGFRα C-terminal tyrosine kinase domain and ligand-dependent increased nuclear area, suggesting receptor-mediated activation of chromatin remodeling. Furthermore, we discovered that therapeutic re-expression of downregulated paracrine factors, such as the IGF-1Ea splice variant, correlated with long-term organization of PDGFRα + /CD31 + in small capillaries, overcoming the late ischemic transition to fibrotic cells. Conclusions: Taken together, these data suggest that by modulating PDGFRα intracellular shuttling or altering the expression of regenerating genes, may therapeutically direct PDGFRα + MSCs duality to reduce fibrosis, while harnessing their beneficial properties

Atomic force microscope elastography reveals phenotypic differences in alveolar cell stiffness

To understand the connection between alveolar mechanics and key biochemical events such as surfactant secretion, one first needs to characterize the underlying mechanical properties of the lung parenchyma and its cellular constituents. In this study, the mechanics of three major cell types from the neonatal rat lung were studied; primary alveolar type I (AT1) and type II (AT2) epithelial cells and lung fibroblasts were isolated using enzymatic digestion. Atomic force microscopy indentation was used to map the three-dimensional distribution of apparent depth-dependent pointwise elastic modulus. Histograms of apparent modulus data from all three cell types indicated non-Gaussian distributions that were highly skewed and appeared multimodal for AT2 cells and fibroblasts. Nuclear stiffness in all three cell types was similar (2.5 ± 1.0 kPa in AT1 vs. 3.1 ± 1.5 kPa in AT2 vs. 3.3 ± 0.8 kPa in fibroblasts; n = 10 each), whereas cytoplasmic moduli were significantly higher in fibroblasts and AT2 cells (6.0 ± 2.3 and 4.7 ± 2.9 kPa vs. 2.5 ± 1.2 kPa). In both epithelial cell types, actin was arranged in sparse clusters, whereas prominent actin stress fibers were observed in lung fibroblasts. No systematic difference in actin or microtubule organization was noted between AT1 and AT2 cells. Atomic force microscope elastography, combined with live-cell fluorescence imaging, revealed that the stiffer measurements in AT2 cells often colocalized with lamellar bodies. These findings partially explain reported heterogeneity of alveolar cell deformation during in situ lung inflation and provide needed data for better understanding of how mechanical stretch influences surfactant release

Decoding Information in Cell Shape

SummaryShape is an indicator of cell health. But how is the information in shape decoded? We hypothesize that decoding occurs by modulation of signaling through changes in plasma membrane curvature. Using analytical approaches and numerical simulations, we studied how elongation of cell shape affects plasma membrane signaling. Mathematical analyses reveal transient accumulation of activated receptors at regions of higher curvature with increasing cell eccentricity. This distribution of activated receptors is periodic, following the Mathieu function, and it arises from local imbalance between reaction and diffusion of soluble ligands and receptors in the plane of the membrane. Numerical simulations show that transient microdomains of activated receptors amplify signals to downstream protein kinases. For growth factor receptor pathways, increasing cell eccentricity elevates the levels of activated cytoplasmic Src and nuclear MAPK1,2. These predictions were experimentally validated by changing cellular eccentricity, showing that shape is a locus of retrievable information storage in cells

Fragility of foot process morphology in kidney podocytes arises from chaotic spatial propagation of cytoskeletal instability.

Kidney podocytes' function depends on fingerlike projections (foot processes) that interdigitate with those from neighboring cells to form the glomerular filtration barrier. The integrity of the barrier depends on spatial control of dynamics of actin cytoskeleton in the foot processes. We determined how imbalances in regulation of actin cytoskeletal dynamics could result in pathological morphology. We obtained 3-D electron microscopy images of podocytes and used quantitative features to build dynamical models to investigate how regulation of actin dynamics within foot processes controls local morphology. We find that imbalances in regulation of actin bundling lead to chaotic spatial patterns that could impair the foot process morphology. Simulation results are consistent with experimental observations for cytoskeletal reconfiguration through dysregulated RhoA or Rac1, and they predict compensatory mechanisms for biochemical stability. We conclude that podocyte morphology, optimized for filtration, is intrinsically fragile, whereby local transient biochemical imbalances may lead to permanent morphological changes associated with pathophysiology

Processed and Reconstructed SBEM Imaging Data for Podocytes

This data package contains the segmented binary images (Level 1) and the Gaussian-smoothened reconstructed volumes (Level 2) of individual rat kidney podocytes that were used to create our dynamical models. Images have 11 nm/pixel in-plane (XY)-resolution and 210 nm out-of-plane (Z)-resolution. Reconstructed volumes all use a single coordinate system. Technical details of segmentation and reconstruction are provided in the Supplementary Information file associated with the manuscript