A flexible, multilayered protein scaffold maintains the slit in between glomerular podocytes
Florian Grahammer, Christoph Wigge, Christoph Schell, Oliver Kretz, Jaakko Patrakka, Simon Schneider, Martin Klose, Julia Kind, Sebastian J. Arnold, Anja Habermann, Ricarda Bräuniger, Markus M. Rinschen, Linus Völker, Andreas Bregenzer, Dennis Rubbenstroth, Melanie Boerries, Dontscho Kerjaschki, Jeffrey H. Miner, Gerd Walz, Thomas Benzing, Alessia Fornoni, Achilleas S. Frangakis, Tobias B. Huber
Florian Grahammer, Christoph Wigge, Christoph Schell, Oliver Kretz, Jaakko Patrakka, Simon Schneider, Martin Klose, Julia Kind, Sebastian J. Arnold, Anja Habermann, Ricarda Bräuniger, Markus M. Rinschen, Linus Völker, Andreas Bregenzer, Dennis Rubbenstroth, Melanie Boerries, Dontscho Kerjaschki, Jeffrey H. Miner, Gerd Walz, Thomas Benzing, Alessia Fornoni, Achilleas S. Frangakis, Tobias B. Huber
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Research Article Nephrology

A flexible, multilayered protein scaffold maintains the slit in between glomerular podocytes

Abstract

Vertebrate life critically depends on renal filtration and excretion of low molecular weight waste products. This process is controlled by a specialized cell-cell contact between podocyte foot processes: the slit diaphragm (SD). Using a comprehensive set of targeted KO mice of key SD molecules, we provided genetic, functional, and high-resolution ultrastructural data highlighting a concept of a flexible, dynamic, and multilayered architecture of the SD. Our data indicate that the mammalian SD is composed of NEPHRIN and NEPH1 molecules, while NEPH2 and NEPH3 do not participate in podocyte intercellular junction formation. Unexpectedly, homo- and heteromeric NEPHRIN/NEPH1 complexes are rarely observed. Instead, single NEPH1 molecules appear to form the lower part of the junction close to the glomerular basement membrane with a width of 23 nm, while single NEPHRIN molecules form an adjacent junction more apically with a width of 45 nm. In both cases, the molecules are quasiperiodically spaced 7 nm apart. These structural findings, in combination with the flexibility inherent to the repetitive Ig folds of NEPHRIN and NEPH1, indicate that the SD likely represents a highly dynamic cell-cell contact that forms an adjustable, nonclogging barrier within the renal filtration apparatus.

Authors

Florian Grahammer, Christoph Wigge, Christoph Schell, Oliver Kretz, Jaakko Patrakka, Simon Schneider, Martin Klose, Julia Kind, Sebastian J. Arnold, Anja Habermann, Ricarda Bräuniger, Markus M. Rinschen, Linus Völker, Andreas Bregenzer, Dennis Rubbenstroth, Melanie Boerries, Dontscho Kerjaschki, Jeffrey H. Miner, Gerd Walz, Thomas Benzing, Alessia Fornoni, Achilleas S. Frangakis, Tobias B. Huber

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Figure 2

NEPHRIN and NEPH1 can form rudimentary SDs independently of each other.

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NEPHRIN and NEPH1 can form rudimentary SDs independently of each other. ...
(AC and EG) In contrast to control mice, Nphs1–/– mice had protein-filled proximal tubular cells, broadened primary (PP) and shortened secondary foot processes (FP), and what appeared to be tight junctional cell-cell contacts between effaced foot processes. Yellow arrows represent SDs slit diaphragms; yellow squares represent tight junctions. (IK) Neph1–/– mice appeared to have misdirected foot processes but, at least at early stages of glomerular maturation, were able to form SD-like junctions. (D, H, and L) Immunoreactivity for NEPH1 was largely maintained in Nphs1–/–, as was staining intensity for NEPHRIN in Neph1–/–. (MO) Further evaluation of Nphs1-deficient glomeruli demonstrated thin and short strand-like junctions between incompletely effaced foot processes that showed NEPH1 immunoreactivity. (PR) Similarly, in Neph1–/– mice, we detected SD-like junctions that often appeared dislocated apically and had NEPHRIN immunoreactivity. (S and T) In tissue from human CNS patients with remaining open slits, SD-like junctions could be visualized, showing immunoreactivity for NEPH1.