Abstract
Type VII collagen (C7) is a major component of anchoring fibrils, structures that mediate epidermal-dermal adherence. Mutations in gene COL7A1 encoding for C7 cause dystrophic epidermolysis bullosa (DEB), a genetic mechano-bullous disease. The biological consequences of specific COL7A1 mutations and the molecular mechanisms leading to DEB clinical phenotypes are unknown. In an attempt to establish genotype-phenotype relationships, we generated four individual substitution mutations that have been associated with recessive DEB, G2049E, R2063W, G2569R, and G2575R, and purified the recombinant mutant proteins. All mutant proteins were synthesized and secreted as a 290-kDa mutant C7 alpha chain at levels similar to wild type C7. The G2569R and G2575R glycine substitution mutations resulted in mutant C7 with increased sensitivity to protease degradation and decreased ability to form trimers. Limited proteolytic digestion of mutant G2049E and R2063W proteins yielded aberrant fragments and a triple helix with reduced stability. These two mutations next to the 39-amino acid helical interruption hinge region caused local destabilization of the triple-helix that exposed an additional highly sensitive proteolytic site within the region of the mutation. Our functional studies demonstrated that C7 is a potent pro-motility matrix for skin human keratinocyte migration and that this activity resides within the triple helical domain. Furthermore, G2049E and R2063W mutations reduced the ability of C7 to support fibroblast adhesion and keratinocyte migration. We conclude that known recessive DEB C7 mutations perturb critical functions of the C7 molecule and likely contribute to the clinical phenotypes of DEB patients.
Highlights
C7 is a homotrimer composed of three identical ␣ chains
We demonstrated that two mutations, G2049E and R2063W, next to the 39-amino acid helical interruption hinge region caused local destabilization of the triple helix and reduced the C7 ability to support cell adhesion and migration, whereas the other two G2569R and G2575R glycine substitution mutations interfered with molecular stability and triple helical assembly of C7
Analysis of the purified mutant collagens by SDS-PAGE revealed the presence of a single band corresponding to the ␣ chain of C7, indicating that the mutant collagens were secreted from cells as intact proteins (Fig. 2B)
Summary
C7, type VII collagen; NC1 and NC2, amino- and carboxyl-terminal noncollagenous domain, respectively, of type VII collagen; DEB, dystrophic epidermolysis bullosa; RDEB, recessive DEB; TH, triple helical; ECM, extracellular matrix; P, protease. Characterization of Type VII Collagen Mutants catalyze the antiparallel dimer formation of the procollagen C7 [17] It is important for the integrity of the basement membrane zone that anchoring fibrils have the correct structure. Despite a growing number of known collagen mutations, the biological consequences of specific COL7A1 mutations and the molecular mechanisms leading to DEB clinical phenotypes are unknown. We used an efficient eukaryotic recombinant approach to engineer and generate four C7 mutant molecules (G2049E, R2063W, G2569R, and G2575R) in sufficient quantities for biological characterization and functional analysis These four mutations are associated with severe, mutilating Hallopeau-Siemens type of recessive DEB and result in significant pathological changes in the number and morphology of anchoring fibrils [25,26,27,28]. We demonstrated that two mutations, G2049E and R2063W, next to the 39-amino acid helical interruption hinge region caused local destabilization of the triple helix and reduced the C7 ability to support cell adhesion and migration, whereas the other two G2569R and G2575R glycine substitution mutations interfered with molecular stability and triple helical assembly of C7
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