Injury-induced actin cytoskeleton reorganization in podocytes revealed by super-resolution microscopy
Hani Y. Suleiman, … , Andrey S. Shaw, Jeffrey H. Miner
Hani Y. Suleiman, … , Andrey S. Shaw, Jeffrey H. Miner
Published August 17, 2017
Citation Information: JCI Insight. 2017;2(16):e94137. https://doi.org/10.1172/jci.insight.94137.
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Research Article Cell biology Nephrology

Injury-induced actin cytoskeleton reorganization in podocytes revealed by super-resolution microscopy

Abstract

The architectural integrity of tissues requires complex interactions, both between cells and between cells and the extracellular matrix. Fundamental to cell and tissue homeostasis are the specific mechanical forces conveyed by the actomyosin cytoskeleton. Here we used super-resolution imaging methods to visualize the actin cytoskeleton in the kidney glomerulus, an organized collection of capillaries that filters the blood to make the primary urine. Our analysis of both mouse and human glomeruli reveals a network of myosin IIA–containing contractile actin cables within podocyte cell bodies and major processes at the outer aspects of the glomerular tuft. These likely exert force on an underlying network of myosin IIA–negative, noncontractile actin fibers present within podocyte foot processes that function to both anchor the cells to the glomerular basement membrane and stabilize the slit diaphragm against the pressure of fluid flow. After injuries that disrupt the kidney filtration barrier and cause foot process effacement, the podocyte’s contractile actomyosin network relocates to the basolateral surface of the cell, manifesting as sarcomere-like structures juxtaposed to the basement membrane. Our findings suggest a new model of the podocyte actin cytoskeleton in health and disease and suggest the existence of novel mechanisms that regulate podocyte architecture.

Authors

Hani Y. Suleiman, Robyn Roth, Sanjay Jain, John E. Heuser, Andrey S. Shaw, Jeffrey H. Miner

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Figure 2

STORM imaging of myosin IIA’s distribution in podocytes in healthy and diseased conditions.

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STORM imaging of myosin IIA’s distribution in podocytes in healthy and d...
(A) Triple-color STORM overview image of a WT glomerulus shows myosin IIA’s (blue) absence from foot processes in comparison with synaptopodin (red) and integrin β1 (green) labeling along the capillary wall. (B and C) Higher magnification images of the boxed area in A show that myosin IIA is present in the podocyte cell body and the primary processes (arrows in B) but not in the foot processes that contain synaptopodin (arrowheads in C). Note the transition between the foot processes and the primary processes (arrows in C). Synaptopodin patches were observed at the periphery of the podocyte cell body and primary processes (arrowheads in B). (DI) Staining for actin (D and G), myosin IIA (E and H), and synaptopodin (F and I). (DF) Confocal slices of the glomerular surface show the podocytes’ thick actin cables positive for myosin IIA and negative for synaptopodin (arrows). Note the diffracted en face image of the capillary wall stained positive for actin and synaptopodin and very little myosin IIA (arrowheads). The differential interference contrast (DIC) overlay image (F) shows the shadow of magnetic beads (4 μm) used to isolate glomeruli. (GI) Deep confocal imaging shows the capillary wall (small arrows) positive for phalloidin (G) and synaptopodin (I) but negative for myosin IIA (H). Note the myosin IIA–positive mesangial cell inside the capillary borders (H). Scale bars: 200 nm (AC) and 2,000 nm (DI). Ca, capillary; Me, mesangial cell.