Unfolding intermediates in the triple helix to coil transition of bovine type XI collagen and human type V collagens alpha 1(2) alpha 2 and alpha 1 alpha 2 alpha 3.

The thermal triple helix to coil transitions of two human type V collagens (alpha 1(2) alpha 2 and alpha 1 alpha 2 alpha 3) and bovine type XI collagen differ from those of the interstitial collagens type I, II, and III by the presence of unfolding intermediates. The total transition enthalpy of these collagens is comparable to the transition enthalpy of the interstitial collagens with values of 17.9 kJ/mol tripeptide units for type XI collagen, 22.9 kJ/mol for type V (alpha 1(2) alpha 2), and 18.5 kJ/mol for type V (alpha 1 alpha 2 alpha 3). It is shown by optical rotatory dispersion and differential scanning calorimetry that complex transition curves with stable intermediates exist. Type XI collagen has two main transitions at 38.5 and 41.5 degrees C and a smaller transition at 40.1 degrees C. Type V (alpha 1(2) alpha 2) shows two main transitions at 38.2 and 42.9 degrees C and two smaller transitions at 40.1 and 41.3 degrees C. Compared to these two collagens type V (alpha 1 alpha 2 alpha 3) unfolds at a lower temperature with two main transitions at 36.4 and 38.1 degrees C and two minor transitions at 40.5 and 42.9 degrees C. The intermediates present at different temperatures are characterized by resistance to trypsin digestion, length measurements of the resistant fragments after rotary shadowing, and amino-terminal sequencing. One of the intermediate peptides has been identified as belonging to the alpha 2 type V chain, starting at position 430 and being about 380 residues long. (The residue numbering begins with the first residue of the first amino-terminal tripeptide unit of the main triple helix. The alpha 2(XI) chain was assumed to be the same length as the alpha 1(XI). One intermediate was identified from the alpha 2(XI) chain and with starting position at residue 495, and three from the alpha 3(XI) with starting positions at residues 519, 585, and 618.