Intravital imaging of podocyte calcium in glomerular injury and disease
James L. Burford, … , Stuart J. Shankland, János Peti-Peterdi
James L. Burford, … , Stuart J. Shankland, János Peti-Peterdi
Published April 8, 2014
Citation Information: J Clin Invest. 2014;124(5):2050-2058. https://doi.org/10.1172/JCI71702.
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Technical Advance Nephrology

Intravital imaging of podocyte calcium in glomerular injury and disease

Abstract

Intracellular calcium ([Ca2+]i) signaling mediates physiological and pathological processes in multiple organs, including the renal podocyte; however, in vivo podocyte [Ca2+]i dynamics are not fully understood. Here we developed an imaging approach that uses multiphoton microscopy (MPM) to directly visualize podocyte [Ca2+]i dynamics within the intact kidneys of live mice expressing a fluorescent calcium indicator only in these cells. [Ca2+]i was at a low steady-state level in control podocytes, while Ang II infusion caused a minor elevation. Experimental focal podocyte injury triggered a robust and sustained elevation of podocyte [Ca2+]i around the injury site and promoted cell-to-cell propagating podocyte [Ca2+]i waves along capillary loops. [Ca2+]i wave propagation was ameliorated by inhibitors of purinergic [Ca2+]i signaling as well as in animals lacking the P2Y2 purinergic receptor. Increased podocyte [Ca2+]i resulted in contraction of the glomerular tuft and increased capillary albumin permeability. In preclinical models of renal fibrosis and glomerulosclerosis, high podocyte [Ca2+]i correlated with increased cell motility. Our findings provide a visual demonstration of the in vivo importance of podocyte [Ca2+]i in glomerular pathology and suggest that purinergic [Ca2+]i signaling is a robust and key pathogenic mechanism in podocyte injury. This in vivo imaging approach will allow future detailed investigation of the molecular and cellular mechanisms of glomerular disease in the intact living kidney.

Authors

James L. Burford, Karie Villanueva, Lisa Lam, Anne Riquier-Brison, Matthias J. Hackl, Jeffrey Pippin, Stuart J. Shankland, János Peti-Peterdi

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Figure 3

Quantitative MPM imaging of the effects of increased podocyte [Ca2+]i on glomerular function in vivo.

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Quantitative MPM imaging of the effects of increased podocyte [Ca2+]i on...
(A and B) Representative MPM images of an intact (G1) and an adjacent laser-injured glomerulus (G2; arrow denotes injury site) from an intact Pod-GCaMP3 mouse kidney before (A) and during (B) the podocyte [Ca2+]i wave. In B, increased GCaMP3 fluorescence (green) indicates increased podocyte [Ca2+]i, whereas increased red fluorescence in the Bowman’s space (arrowheads) indicates concomitant leakage of plasma albumin–Alexa Fluor 594 in the injured glomerulus, but not the adjacent intact glomerulus. Scale bar: 20 μm. (C) Dynamics of the elevations in GCaMP3 (measured in the glomerular tuft) and albumin–Alexa Fluor 594 (measured in the Bowman’s space) F/F0 during the podocyte [Ca2+]i wave in the same preparation as in A and B. (D) Albumin leakage into the Bowman’s space during podocyte [Ca2+]i wave propagation and the effects of purinergic receptor blockade with suramin. Suramin infusion (n = 6 glomeruli from n = 3 mice) significantly reduced the magnitude of the peak increase in Bowman’s space albumin–Alexa Fluor 594 Fmax/F0 compared with control (n = 16 glomeruli from n = 9 mice). Data represent mean ± SEM. (E) Size of the glomerular tuft area before and at the peak of the podocyte [Ca2+]i wave (n = 18 glomeruli from n = 9 mice each). Mean ± SEM is shown in red. *P < 0.05 vs. respective control.