Isoform switching of type IV collagen is developmentally arrested in X-linked Alport syndrome leading to increased susceptibility of renal basement membranes to endoproteolysis.

Kalluri R, Shield CF, Todd P, Hudson BG, Neilson EG
J Clin Invest. 1997 99 (10): 2470-8

PMID: 9153291 · PMCID: PMC508088 · DOI:10.1172/JCI119431

Normal glomerular capillaries filter plasma through a basement membrane (GBM) rich in alpha3(IV), alpha4(IV), and alpha5(IV) chains of type IV collagen. We now show that these latter isoforms are absent biochemically from the glomeruli in patients with X-linked Alport syndrome (XAS). Their GBM instead retain a fetal distribution of alpha1(IV) and alpha2(IV) isoforms because they fail to developmentally switch their alpha-chain use. The anomalous persistence of these fetal isoforms of type IV collagen in the GBM in XAS also confers an unexpected increase in susceptibility to proteolytic attack by collagenases and cathepsins. The incorporation of cysteine-rich alpha3(IV), alpha4(IV), and alpha5(IV) chains into specialized basement membranes like the GBM may have normally evolved to protectively enhance their resistance to proteolytic degradation at the site of glomerular filtration. The relative absence of these potentially protective collagen IV isoforms in GBM from XAS may explain the progressive basement membrane splitting and increased damage as these kidneys deteriorate.

MeSH Terms (20)

Basement Membrane Cathepsin B Cathepsin G Cathepsins Chromatography, Ion Exchange Collagen Collagenases Embryonic and Fetal Development Endopeptidases Gene Expression Regulation, Developmental Humans Kidney Kidney Cortex Kidney Glomerulus Male Nephritis, Hereditary Pancreatic Elastase Reference Values Serine Endopeptidases X Chromosome

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