Biophysical properties of normal and diseased renal glomeruli

Wyss, Hans M.; Henderson, Joel M.; Byfield, Fitzroy J.; Bruggeman, Leslie A.; Ding, Yaxian; Huang, Changcheng; Suh, Jung Hee; Franke, Thomas; Mele, Elisa; Pollak, Martin R.; Miner, Jeffrey H.; Janmey, Paul A.; Weitz, David A.; Miller, R. Tyler

doi:10.1152/ajpcell.00438.2010

Cited by 96 publications

(91 citation statements)

References 44 publications

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“…This distribution corresponds to the domains of highest cholesterol content in podocytes on the basis of earlier freeze-fracture studies (43). The glomerular capillary is a relatively high-pressure microvascular bed, and its walls are unusually rigid (4,70). For this reason, podocyte foot processes will be exposed to continuous highfrequency mechanical stimuli originating from the cardiac cycle, as well as slower fluctuations associated with myogenic autoregulatory responses and tubuloglomerular feedback (19).…”

Section: Discussionmentioning

confidence: 87%

Opposing effects of podocin on the gating of podocyte TRPC6 channels evoked by membrane stretch or diacylglycerol

Anderson

Kim

Hagmann

et al. 2013

American Journal of Physiology-Cell Physiology

120

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Anderson M, Kim EY, Hagmann H, Benzing T, Dryer SE. Opposing effects of podocin on the gating of podocyte TRPC6 channels evoked by membrane stretch or diacylglycerol. Am J Physiol Cell Physiol 305: C276 -C289, 2013. First published May 8, 2013 doi:10.1152/ajpcell.00095.2013.-Gain-of-function mutations in the transient receptor potential (TRP) cation channel subfamily C member 6 (TRPC6) gene and mutations in the NPHS2 gene encoding podocin result in nephrotic syndromes. The purpose of this study was to determine the functional significance of biochemical interactions between these proteins. We observed that gating of TRPC6 channels in podocytes is markedly mechanosensitive and can be activated by hyposmotic stretch or indentation of the plasma membrane. Stretch activation of cationic currents was blocked by small interfering RNA knockdown of TRPC6, as well as by SKF-96365 or micromolar La 3ϩ . Stretch activation of podocyte TRPC6 persisted in the presence of inhibitors of phospholipase C (U-73122) and phospholipase A 2 (ONO-RS-082). Robust stretch responses also persisted when recording electrodes contained guanosine 5=-O-(2-thiodiphosphate) at concentrations that completely suppressed responses to ANG II. Stretch responses were enhanced by cytochalasin D but were abolished by the peptide GsMTx4, suggesting that forces are transmitted to the channels through the plasma membrane. Podocin and TRPC6 interact at their respective COOH termini. Knockdown of podocin markedly increased stretch-evoked activation of TRPC6 but nearly abolished TRPC6 activation evoked by a diacylglycerol analog. These data suggest that podocin acts as a switch to determine the preferred mode of TRPC6 activation. They also suggest that podocin deficiencies will result in Ca 2ϩ overload in foot processes, as with gain-of-function mutations in the TRPC6 gene. Finally, they suggest that mechanical activation of TRP family channels and the preferred mode of TRP channel activation may depend on whether members of the stomatin/ prohibitin family of hairpin loop proteins are present.podocyte; glomerular filtration; TRPC6; slit diaphragm; podocyte; mechanosensitive PODOCYTES ARE HIGHLY DIFFERENTIATED multipolar cells that cover the external surface of glomerular capillaries and form an essential component of the kidney ultrafiltration apparatus (46). Primary processes extend from the podocyte cell body and ramify extensively as they wrap around the glomerular capillary. Specialized structures known as foot processes normally emanate at regular spatial intervals from the major processes of podocytes and attach to the surface of the glomerular basement membrane. Connections between interdigitating foot processes, known as slit diaphragms (SDs), are formed by trans-interactions of specialized transmembrane adhesion molecules (26). The interacting extracellular domains of SD proteins form a porous matrix (65) that provides a pathway for convective flow and diffusion of water and small solutes into Bowman's space (7). SDs may have multiple roles, as the...

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Section: Discussionmentioning

confidence: 87%

Opposing effects of podocin on the gating of podocyte TRPC6 channels evoked by membrane stretch or diacylglycerol

Anderson

Kim

Hagmann

et al. 2013

American Journal of Physiology-Cell Physiology

120

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“…For example, it was shown that conditionally immortalized glomerular podocytes from a mouse model of HIVassociated nephropathy (HIVAN) are substantially softer than normal podocytes (by 25%), as assessed by atomic force microscopy (AFM) and microaspiration (Tandon et al, 2006). At a stage of the disease that showed no detectable pathological changes, the glomeruli from these mice were 30% softer than normal glomeruli (1.5 kPa compared with 2.5 kPa, as measured by AFM) (Wyss et al, 2011). Glomeruli and podocytes in other disease models are also significantly softer than normal cells, indicating that the increased mechanical deformability of podocytes and glomeruli might be a common feature of a number of renal diseases.…”

Section: Renal Glomerular Diseasementioning

confidence: 99%

Mechanisms of mechanical signaling in development and disease

Janmey

Miller

2011

Journal of Cell Science

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408

332

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SummaryThe responses of cells to chemical signals are relatively well characterized and understood. Cells also respond to mechanical signals in the form of externally applied force and forces generated by cell-matrix and cell-cell contacts. Many features of cell function that are generally considered to be under the control of chemical stimuli, such as motility, proliferation, differentiation and survival, can also be altered by changes in the stiffness of the substrate to which the cells are adhered, even when their chemical environment remains unchanged. Many examples from clinical and whole animal studies have shown that changes in tissue stiffness are related to specific disease characteristics and that efforts to restore normal tissue mechanics have the potential to reverse or prevent cell dysfunction and disease. How cells detect stiffness is largely unknown, but the cellular structures that measure stiffness and the general principles by which they work are beginning to be revealed. This Commentary highlights selected recent reports of mechanical signaling during disease development, discusses open questions regarding the physical mechanisms by which cells sense stiffness, and examines the relationship between studies in vitro on flat substrates and the more complex three-dimensional setting in vivo.

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“…Because the moduli of reconstituted actin networks are highly sensitive to cross-linker affinity and concentration (1,2,19), we hypothesized that changes in actin cross-linking will also significantly impact the total force and work exerted by an active cell on its environment. However, the effect of this mutation, or variable cross-linking in general, on the dynamics and forces of cells is largely unknown (20). Understanding how cross-linker binder affinity changes force generation will provide essential insight into how cells modulate their mechanics, and exert forces on their surrounding environment.…”

mentioning

confidence: 99%

Alpha-actinin binding kinetics modulate cellular dynamics and force generation

Ehrlicher

Krishnan

Guo

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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The actin cytoskeleton is a key element of cell structure and movement whose properties are determined by a host of accessory proteins. Actin cross-linking proteins create a connected network from individual actin filaments, and though the mechanical effects of cross-linker binding affinity on actin networks have been investigated in reconstituted systems, their impact on cellular forces is unknown. Here we show that the binding affinity of the actin crosslinker α-actinin 4 (ACTN4) in cells modulates cytoplasmic mobility, cellular movement, and traction forces. Using fluorescence recovery after photobleaching, we show that an ACTN4 mutation that causes human kidney disease roughly triples the wild-type binding affinity of ACTN4 to F-actin in cells, increasing the dissociation time from 29 ± 13 to 86 ± 29 s. This increased affinity creates a less dynamic cytoplasm, as demonstrated by reduced intracellular microsphere movement, and an approximate halving of cell speed. Surprisingly, these less motile cells generate larger forces. Using traction force microscopy, we show that increased binding affinity of ACTN4 increases the average contractile stress (from 1.8 ± 0.7 to 4.7 ± 0.5 kPa), and the average strain energy (0.4 ± 0.2 to 2.1 ± 0.4 pJ). We speculate that these changes may be explained by an increased solid-like nature of the cytoskeleton, where myosin activity is more partitioned into tension and less is dissipated through filament sliding. These findings demonstrate the impact of cross-linker point mutations on cell dynamics and forces, and suggest mechanisms by which such physical defects lead to human disease.Alpha-actinin | actin | kidney disease | cell mechanics | traction force M ovement, morphology, and force production are essential aspects of animal life. At the cellular level, these mechanics are largely determined by the actin cytoskeleton-a network of actin filaments connected by cross-linkers to create a 3D biopolymer frame. These cross-linkers are not permanent, but bind transiently. Studies using reconstituted proteins show that when these cross-linkers are attached to and connect multiple filaments, they create a network that behaves like a weak elastic solid. When cross-links unbind, actin filaments are free to slide past one another, producing a network that behaves more like a viscous fluid (1, 2). This dynamic cross-linking makes the actin network a viscoelastic material that is solid-like on short timescales such as seconds, yet fluid-like on longer timescales such as minutes (3, 4).The timescale of the transition from solid to fluid-like behavior in reconstituted actin networks is set by the duration of cross-linking, which is in turn set by cross-linker dissociation rate, K off (1, 5, 6). The ability for an actin network to move between solid and fluid-like states may be an essential mechanism to balance mechanical and structural integrity of an elastic solid with adaptability and movement (1, 7-9). Despite this clear physical role of actin cross-linking in reconstituted network mechan...

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Biophysical properties of normal and diseased renal glomeruli

Cited by 96 publications

References 44 publications

Opposing effects of podocin on the gating of podocyte TRPC6 channels evoked by membrane stretch or diacylglycerol

Opposing effects of podocin on the gating of podocyte TRPC6 channels evoked by membrane stretch or diacylglycerol

Mechanisms of mechanical signaling in development and disease

Alpha-actinin binding kinetics modulate cellular dynamics and force generation

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