Abstract
Tandem mass spectrometry was applied to tissues from targeted mutant mouse models to explore the collagen substrate specificities of individual members of the prolyl 3-hydroxylase (P3H) gene family. Previous studies revealed that P3h1 preferentially 3-hydroxylates proline at a single site in collagen type I chains, whereas P3h2 is responsible for 3-hydroxylating multiple proline sites in collagen types I, II, IV, and V. In screening for collagen substrate sites for the remaining members of the vertebrate P3H family, P3h3 and Sc65 knock-out mice revealed a common lysine under-hydroxylation effect at helical domain cross-linking sites in skin, bone, tendon, aorta, and cornea. No effect on prolyl 3-hydroxylation was evident on screening the spectrum of known 3-hydroxyproline sites from all major tissue collagen types. However, collagen type I extracted from both Sc65-/- and P3h3-/- skin revealed the same abnormal chain pattern on SDS-PAGE with an overabundance of a γ112 cross-linked trimer. The latter proved to be from native molecules that had intramolecular aldol cross-links at each end. The lysine under-hydroxylation was shown to alter the divalent aldimine cross-link chemistry of mutant skin collagen. Furthermore, the ratio of mature HP/LP cross-links in bone of both P3h3-/- and Sc65-/- mice was reversed compared with wild type, consistent with the level of lysine under-hydroxylation seen in individual chains at cross-linking sites. The effect on cross-linking lysines was quantitatively very similar to that previously observed in EDS VIA human and Plod1-/- mouse tissues, suggesting that P3H3 and/or SC65 mutations may cause as yet undefined EDS variants.
Highlights
The present phenocopied effects on collagen lysine hydroxylation can best be explained if Sc65 and P3H3 form a complex in the ER that is required to facilitate access of LH1 to substrate lysine residues on newly made collagen chains
Type V collagen from null mouse skin and aorta exhibited a decrease in hydroxylation/glycosylation at Lys-87 compared with WT; no change was detected in type V collagen from null-bone versus WT bone
We proposed an interaction complex that at least transiently involves LH1, CypB, SC65, and P3H3 [21]
Summary
The present phenocopied effects on collagen lysine hydroxylation can best be explained if Sc65 and P3H3 form a complex in the ER that is required to facilitate access of LH1 to substrate lysine residues on newly made collagen chains. Summary of posttranslational variances in linear cross-linking lysine 87 from type V collagens Modifications on lysine 87 from both ␣-chains of type V collagen in WT, Sc65Ϫ/Ϫ, and P3h3Ϫ/Ϫ mice were measured using mass spectrometry in skin and bone. Severe under-hydroxylation of lysine residues at triple-helical domain cross-linking sites for skin, tendon, cornea, and aorta.
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