Involvement of the protein kinase C substrate, SSeCKS, in the actin-based stellate morphology of mesangial cells.

Activation of protein kinase C is a key signal transduction event in mesangial cell dedifferentiation and proliferation, yet little is known about downstream substrates or their roles in normal or diseased glomeruli. SSeCKS, a novel protein kinase C substrate originally isolated as a src-suppressed negative mitogenic regulator in fibroblasts, controls actin-based cytoskeletal architecture and scaffolds key signaling kinases such as protein kinase C and protein kinase A. Based on the morphologic similarity between SSeCKS-overexpressing fibroblasts and stellate mesangial cells, we hypothesized that SSeCKS might play a role in mesangial cell morphology in a protein kinase C-dependent manner. Immunoblotting, in situ staining and northern blotting detected abundant expression of SSeCKS in human and rodent mesangial cells and glomerular parietal cells but not in renal tubular epithelia. Immunofluorescence analysis showed enrichment of SSeCKS in mesangial cell podosomes and along a cytoskeletal network distinct from F-actin. Activation of protein kinase C by phorbol ester resulted in a rapid serine phosphorylation of SSeCKS and its subsequent translocation to perinuclear sites, coincident with the retraction of stellate processes. These effects were blocked by concentrations of bis-indolylmaleimide that selectively inhibit protein kinase C. Finally, ablation of SSeCKS expression using retroviral anti-sense vectors induced (1) an elongated, fibroblastic cell morphology, (2) production of thick, longitudinal stress fibers and (3) repositioning of vinculin-associated focal complexes away from the cell edges. These data suggest a role for SSeCKS as a downstream mediator of protein kinase C-controlled, actin-based mesangial cell cytoskeletal architecture.

Cathepsin K: isolation and characterization of the murine cDNA and genomic sequence, the homologue of the human pycnodysostosis gene.

Cathepsin K(EC 3.4.22.38) is a lysosomal cysteine protease that is strongly implicated in bone resorption. The human cathepsin K gene is highly expressed in osteoclasts and gene mutations cause pycnodysostosis, an autosomal recessive skeletal dysplasia. To investigate the evolutionary relatedness of cathepsin K across species, the mouse cathepsin K gene was isolated. A mouse heart cDNA clone, pMCatKl, contained the 3' untranslated region, mature enzyme coding sequence, and most of the propeptide. The remainder of the gene was amplified from mouse melanocyte RNA using 5' rapid amplification of cDNA ends. The gene contained a 990-bp open reading frame, predicting a 329-amino-acid prepropolypeptide. The structure of the protein included a 15-amino-acid presignal, a 99-amino-acid proregion, and a 215-amino-acid mature enzyme. Two potential N-glycosylation sites were identified, one in the proregion and one in the mature enzyme. The 5' untranslated region was 135 bp. The 3' untranslated region was 470 bp including a 9-bp poly(A) tract and contained two polyadenylation signals. The mouse cathepsin K nucleotide and amino acid sequences were highly conserved with the human, rabbit, and chicken homologues across the proregion and mature enzyme. The mouse cathepsin K gene was isolated from an V129 genomic library, and characterization of its genomic structure and intron sizes revealed exons with the initiation ATG in exon 2 and termination TGA in exon 8, a genomic organization that was highly conserved with its human homologue. The availability of the mouse cathepsin K cDNA and genomic sequences will facilitate generation of a mouse model of cathepsin K deficiency by gene targeting.