Intravital imaging reveals glomerular capillary distension and endothelial and immune cell activation early in Alport syndrome
Georgina Gyarmati, Urvi Nikhil Shroff, Audrey Izuhara, Xiaogang Hou, Stefano Da Sacco, Sargis Sedrakyan, Kevin V. Lemley, Kerstin Amann, Laura Perin, János Peti-Peterdi
Georgina Gyarmati, Urvi Nikhil Shroff, Audrey Izuhara, Xiaogang Hou, Stefano Da Sacco, Sargis Sedrakyan, Kevin V. Lemley, Kerstin Amann, Laura Perin, János Peti-Peterdi
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Research Article Nephrology

Intravital imaging reveals glomerular capillary distension and endothelial and immune cell activation early in Alport syndrome

Abstract

Alport syndrome (AS) is a genetic disorder caused by mutations in type IV collagen that lead to defective glomerular basement membrane, glomerular filtration barrier (GFB) damage, and progressive chronic kidney disease. While the genetic basis of AS is well known, the molecular and cellular mechanistic details of disease pathogenesis have been elusive, hindering the development of mechanism-based therapies. Here, we performed intravital multiphoton imaging of the local kidney tissue microenvironment in a X-linked AS mouse model to directly visualize the major drivers of AS pathology. Severely distended glomerular capillaries and aneurysms were found accompanied by numerous microthrombi, increased glomerular endothelial surface layer (glycocalyx) and immune cell homing, GFB albumin leakage, glomerulosclerosis, and interstitial fibrosis by 5 months of age, with an intermediate phenotype at 2 months. Renal histology in mouse or patient tissues largely failed to detect capillary aberrations. Treatment of AS mice with hyaluronidase or the ACE inhibitor enalapril reduced the excess glomerular endothelial glycocalyx and blocked immune cell homing and GFB albumin leakage. This study identified central roles of glomerular mechanical forces and endothelial and immune cell activation early in AS, which could be therapeutically targeted to reduce mechanical strain and local tissue inflammation and improve kidney function.

Authors

Georgina Gyarmati, Urvi Nikhil Shroff, Audrey Izuhara, Xiaogang Hou, Stefano Da Sacco, Sargis Sedrakyan, Kevin V. Lemley, Kerstin Amann, Laura Perin, János Peti-Peterdi

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Figure 3

Time-lapse in vivo MPM imaging of the effects of hyaluronidase and ACEi treatment in late-stage AS mice.

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Time-lapse in vivo MPM imaging of the effects of hyaluronidase and ACEi ...
(A–H) Acute hyaluronidase (H) treatment in control (A and C) and late-stage AS mice (B and D). Plasma was labeled with albumin–Alexa Fluor 680 (gray), glycocalyx with FITC-WGA lectin (green; linear pattern), and immune cells with anti-CD44–Alexa Fluor 488 antibodies (green; round cell pattern). (A–D) Projection 5-minute time-lapse images (overlay of plasma albumin, gray; glycocalyx and immune cell labeling, green; tissue autofluorescence, orange; insets show glycocalyx and CD44+ cells separately) of the glomerular microenvironment before (A and B) and within 1 hour of i.v. H (50 U) injection (C and D) in control (A and C) and late-stage AS (B and D). Note the high glomerular capillary albumin intensity in late-stage AS mice and its reductions after H treatment (B and D), indicating improved blood flow (flow of nonfluorescent red blood cells [RBC] rather than only the highly fluorescent plasma; Supplemental Video 1). (E–H) Summary of the effects of H treatment in control and late-stage AS mice on GEC glycocalyx thickness (E), CD44+ cell number per glomerulus (F), glomerular capillary blood flow (RBC velocity; G), and glomerular albumin leakage (albumin GSC; H). (I–O) Chronic treatment with H, ACEi, or control PBS for 1 week in late-stage AS mice. Projection 5-minute time-lapse images, as in A–D (insets show glycocalyx (green) and CD44+ cells (red) separately), in control vehicle (PBS) (I), H (J), and ACEi treatment groups (K). (L–O) Summary of the effects of control PBS, H, or ACEi treatment on GEC glycocalyx thickness (L), CD44+ cell number per glomerulus (M), glomerular capillary blood flow (N), and albuminuria (albumin/creatinine ratio [ACR]; O). Data are shown as the mean ± SEM. **P < 0.01, ***P < 0.001, ****P < 0.0001, using 1-way ANOVA followed by Tukey’s or Šidák’s multiple-comparison test. Scale bar: 50 μm. Data points represent the average of multiple measurements/mouse (O) or from 2 glomeruli/mouse (E–N); n = 5–6 mice in each group.