Actinidain-hydrolyzed Type I Collagen Reveals a Crucial Amino Acid Sequence in Fibril Formation

We investigated the ability of type I collagen telopeptides to bind neighboring collagen molecules, which is thought to be the initial event in fibrillogenesis. Limited hydrolysis by actinidain protease produced monomeric collagen, which consisted almost entirely of α1 and α2 chains. As seen with ultrahigh resolution scanning electron microscopy, actinidain-hydrolyzed collagen exhibited unique self-assembly, as if at an intermediate stage, and formed a novel suprastructure characterized by poor fibrillogenesis. Then, the N- and C-terminal sequences of chicken type I collagen hydrolyzed by actinidain or pepsin were determined by Edman degradation and de novo sequence analysis with matrix-assisted laser desorption ionization-tandem time-of-flight mass spectrometry, respectively. In the C-telopeptide region of the α1 chain, pepsin cleaved between Asp¹⁰³⁵ and Phe¹⁰³⁶, and actinidain between Gly¹⁰³² and Gly¹⁰³³. Thus, the actinidain-hydrolyzed α1 chain is shorter at the C terminus by three residues, Gly¹⁰³³, Phe¹⁰³⁴, and Asp¹⁰³⁵. In the α2 chain, both proteases cleaved between Glu¹⁰³⁰ and Val¹⁰³¹. We demonstrated that a synthetic nonapeptide mimicking the α1 C-terminal sequence including GFD weakly inhibited the self-assembly of pepsin-hydrolyzed collagen, whereas it remarkably accelerated that of actinidain-hydrolyzed collagen. We conclude that the specific GFD sequence of the C-telopeptide of the α1 chain plays a crucial role in stipulating collagen suprastructure and in subsequent fibril formation.