Smitted through the basement membrane protein receptor integrins, we evaluated integrin mRNA and protein expression in Alport glomeruli. Compared to wild-type, there were significant increases in Itga3 and Itgb1 mRNAs in Alport, and integrin a1 and a3 protein immunofluorescence signals were increased as well. We speculate that the Alport GBM lacking collagen a3a4a5(IV) caused changes in integrin expression/distribution, which directly and/or indirectly altered the organization of the podocyte IF cytoskeleton, affecting cell shape and possibly signal transduction and gene transcription. Alterna-Vimentin and Integrins in Alport GlomeruliFigure 4. Integrin a1 protein is upregulated in the mesangium of Alport glomeruli. A : Fresh frozen kidney sections from 4 week old Alport mice were labeled with a combination of hamster anti-integrin a1 and rat anti-laminin b1 IgGs, followed by the appropriate species-specific Alexa Fluor secondary antibody. Anti-integrin a1 labeling (A, Itga1) is restricted to the mesangial layer, marked by anti-laminin b1 staining (B, Lamb1), and overlap of staining is shown in C (merge). D : Representative fluorescence micrographs are shown of anti-integrin a1 labeling of wild-type (D, wt), or Alport (E) mouse glomeruli. ASP2215 chemical information glomerular fluorescence intensities were averaged for n = 3 mice of each genotype, wildtype (wt, blue) or Alport (red), and integrin a1 signals were significantly greater in Alport. * p = 0.01. doi:10.1371/journal.pone.GLPG0187 site 0050745.gtively, increases in vimentin availability and/or distribution within the podocyte may have affected podocyte expression and/or turnover of integrins, as discussed further below. Dysregulation of integrins and podocyte IFs may therefore be key pathogenic components of glomerular Alport disease. IFs are thin, ,10 nm diameter, intracellular filaments and are one of three interconnected cytoskeletal systems found within cells (the other two being actin microfilaments and tubulin-based microtubules) [27]. Depending upon the cell type, IFs are composed of as many as ,70 evolutionarily related proteins including acidic and neutral based keratins (epithelial cells), desmin (muscle), vimentin (mesenchymal cells), and neurofilaments (neurons), although heteropolymers can exist as well. Originally believed to be a static network that provided cells a method to resist deformation and mechanical stress, IFs are now known to be highly dynamic, motile elements, that extend from the cytoplasm into the nucleoplasm. Cytoplasmic intermediate filament proteins exist as aggregates or particles, short filaments called “squiggles,” and long fibrils [27,28]. All have the capacity to shorten and elongate bidirectionally through their association with molecular 15900046 motors such as kinesin and dynein. In general, cytoplasmic IFs provide biomechanical integrity to cells but they also participate in cell signaling cascades, help regulate delivery and compartmentalization of stress-activated kinases, and they are active in cell-matrix adhesion and directional migration [27,28]. The intranuclear network of IFs are composed of polymers of lamin A, B1 and B2, C and other lamin isoforms. The IFnucleoskeleton provides a structural framework that facilitates DNA repair, replication, transcription and modulates the architecture of chromatin [27?9]. Among the many different IF proteins, vimentin is one of the best characterized [30]. Like other IF family members, vimentin contains a central, a helical rod domain and v.Smitted through the basement membrane protein receptor integrins, we evaluated integrin mRNA and protein expression in Alport glomeruli. Compared to wild-type, there were significant increases in Itga3 and Itgb1 mRNAs in Alport, and integrin a1 and a3 protein immunofluorescence signals were increased as well. We speculate that the Alport GBM lacking collagen a3a4a5(IV) caused changes in integrin expression/distribution, which directly and/or indirectly altered the organization of the podocyte IF cytoskeleton, affecting cell shape and possibly signal transduction and gene transcription. Alterna-Vimentin and Integrins in Alport GlomeruliFigure 4. Integrin a1 protein is upregulated in the mesangium of Alport glomeruli. A : Fresh frozen kidney sections from 4 week old Alport mice were labeled with a combination of hamster anti-integrin a1 and rat anti-laminin b1 IgGs, followed by the appropriate species-specific Alexa Fluor secondary antibody. Anti-integrin a1 labeling (A, Itga1) is restricted to the mesangial layer, marked by anti-laminin b1 staining (B, Lamb1), and overlap of staining is shown in C (merge). D : Representative fluorescence micrographs are shown of anti-integrin a1 labeling of wild-type (D, wt), or Alport (E) mouse glomeruli. Glomerular fluorescence intensities were averaged for n = 3 mice of each genotype, wildtype (wt, blue) or Alport (red), and integrin a1 signals were significantly greater in Alport. * p = 0.01. doi:10.1371/journal.pone.0050745.gtively, increases in vimentin availability and/or distribution within the podocyte may have affected podocyte expression and/or turnover of integrins, as discussed further below. Dysregulation of integrins and podocyte IFs may therefore be key pathogenic components of glomerular Alport disease. IFs are thin, ,10 nm diameter, intracellular filaments and are one of three interconnected cytoskeletal systems found within cells (the other two being actin microfilaments and tubulin-based microtubules) [27]. Depending upon the cell type, IFs are composed of as many as ,70 evolutionarily related proteins including acidic and neutral based keratins (epithelial cells), desmin (muscle), vimentin (mesenchymal cells), and neurofilaments (neurons), although heteropolymers can exist as well. Originally believed to be a static network that provided cells a method to resist deformation and mechanical stress, IFs are now known to be highly dynamic, motile elements, that extend from the cytoplasm into the nucleoplasm. Cytoplasmic intermediate filament proteins exist as aggregates or particles, short filaments called “squiggles,” and long fibrils [27,28]. All have the capacity to shorten and elongate bidirectionally through their association with molecular 15900046 motors such as kinesin and dynein. In general, cytoplasmic IFs provide biomechanical integrity to cells but they also participate in cell signaling cascades, help regulate delivery and compartmentalization of stress-activated kinases, and they are active in cell-matrix adhesion and directional migration [27,28]. The intranuclear network of IFs are composed of polymers of lamin A, B1 and B2, C and other lamin isoforms. The IFnucleoskeleton provides a structural framework that facilitates DNA repair, replication, transcription and modulates the architecture of chromatin [27?9]. Among the many different IF proteins, vimentin is one of the best characterized [30]. Like other IF family members, vimentin contains a central, a helical rod domain and v.