Matrix Biology Plus (Feb 2021)

A glycine substitution in the collagenous domain of Col4a3 in mice recapitulates late onset Alport syndrome

  • Christoforos Odiatis,
  • Isavella Savva,
  • Myrtani Pieri,
  • Pavlos Ioannou,
  • Petros Petrou,
  • Gregory Papagregoriou,
  • Kyriaki Antoniadou,
  • Neoklis Makrides,
  • Charalambos Stefanou,
  • Danica Galešić Ljubanović,
  • Georgios Nikolaou,
  • Dorin-Bogdan Borza,
  • Kostas Stylianou,
  • Oliver Gross,
  • Constantinos Deltas

Journal volume & issue
Vol. 9
p. 100053

Abstract

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Alport syndrome (AS) is a severe inherited glomerulopathy caused by mutations in the genes encoding the α-chains of type-IV collagen, the most abundant component of the extracellular glomerular basement membrane (GBM). Currently most AS mouse models are knockout models for one of the collagen-IV genes. In contrast, about half of AS patients have missense mutations, with single aminoacid substitutions of glycine being the most common. The only mouse model for AS with a homozygous knockin missense mutation, Col4a3-p.Gly1332Glu, was partly described before by our group. Here, a detailed in-depth description of the same mouse is presented, along with another compound heterozygous mouse that carries the glycine substitution in trans with a knockout allele. Both mice recapitulate essential features of AS, including shorten lifespan by 30–35%, increased proteinuria, increased serum urea and creatinine, pathognomonic alternate GBM thinning and thickening, and podocyte foot process effacement. Notably, glomeruli and tubuli respond differently to mutant collagen-IV protomers, with reduced expression in tubules but apparently normal in glomeruli. However, equally important is the fact that in the glomeruli the mutant α3-chain as well as the normal α4/α5 chains seem to undergo a cleavage at, or near the point of the mutation, possibly by the metalloproteinase MMP-9, producing a 35 kDa C-terminal fragment. These mouse models represent a good tool for better understanding the spectrum of molecular mechanisms governing collagen-IV nephropathies and could be used for pre-clinical studies aimed at better treatments for AS.

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