Hormone formation in the isolated fragment 1-171 of human thyroglobulin involves the couple tyrosine 5 and tyrosine 130.

The 22 kDa fragment (Asn1-Met171) purified from iodine-poor human thyroglobulin (hTg) is capable by itself to synthesize thyroxine at Tyr5, the preferential hormonogenic acceptor site of the protein, after iodination in vitro. To identify the corresponding donor site in this model we studied the fate of the six Tyr residues present in the 22 kDa peptide after in vitro hormone synthesis. Structural studies of the tyrosyl peptides showed that Tyr5 was the only thyroxine-forming site, the other tyrosines (29, 89, 97 and 107) were noniodinated and Tyr130 was recovered in alanine form after CNBH4 treatment of the Tyr130-containing peptide. Taking into account that alanine could arise from aminoreduced pyruvate species, these results showed that in the 22 kDa fragment (1) hormone formation involves the couple Tyr5 (acceptor)-Tyr130 (donor), and (2) dehydroalanine, the resultant product of donor tyrosine after hormone synthesis, has evolved in pyruvoyl form. To test whether Tyr130 could also act as donor in hTg hormone synthesis, the 22 kDa peptide was isolated from hTg iodinated under conditions leading to iodotyrosine formation followed or not by hormone formation and the tyrosyl peptides were analyzed. After hTg iodination and before coupling (i.e. hormone synthesis) only Tyr5 and Tyr130 were recovered in iodotyrosine form; after coupling thyroxine was found at Tyr5 whereas Tyr130 disappeared. Taken together these results, correlated with the previously reported cleavage of hTg chain at Tyr130 occurring during in vivo hormone synthesis, support the theory that the couple Tyr5 (acceptor)-Tyr130 (donor) would be the preferential hormonogenic site in human Tg.

Hormone synthesis in human thyroglobulin: possible cleavage of the polypeptide chain at the tyrosine donor site.

At moderate iodination levels (20 iodine atoms/mol) human thyroglobulin (hTg) produces after reduction a hormone-rich peptide of 26 kDa which contains the preferential hormonogenic 'acceptor' tyrosine (Tyr 5) of the protein. The site of cleavage of the hTg chain was demonstrated by analysis of the 26 kDa tryptic hydrolysis products. It consistently yielded the peptide Gln-82-Val-129 which consequently made it possible to localize the hTg chain cleavage at tyrosine residue 130. Evidence for tyrosine involvement in hTg cleavage during thyroid hormone formation supports the hypothesis that peptide bond cleavage would occur at the 'donor' tyrosine residue and suggests that tyrosine 130 would be the donor site reacting with the major hormone-forming acceptor site (Tyr 5) of hTg.

Characterization of a hormonogenic domain from human thyroglobulin.

A polypeptide domain of molecular mass near 22 kDa was purified from CNBr-digest of iodine poor human thyroglobulin (hTgb). This fragment represents the N-terminal part of the hTgb molecule and consequently contains the preferential hormonogenic tyrosine 'acceptor' of the protein. This fragment could correspond to the non-iodinated and unreduced form of the thyroxinyl-containing 26 kDa peptide previously purified from reduced and iodinated hTgb. This 22 kDa fragment is capable by itself, i.e. independently of the remaining hTgb molecule, of synthesizing thyroxine with a high efficiency after in vitro iodination. Its study should constitute a valuable way to identify at least one of the hormonogenic tyrosine 'donor' residues of hTgb.

Amino acid sequence and disulfide bridges of subunit III, a defective endopeptidase present in the bovine pancreatic 6 S procarboxypeptidase A complex.

The sequence of the 240 amino acids and the position of the five S-S bridges of subunit III of the bovine pancreatic 6 S procarboxypeptidase A complex have been determined thus confirming its phylogenetic filiation with the pancreatic serine endopeptidase group. The subunit contains at equivalent positions all the elements of the catalytic site of these enzymes. The elements of a binding pocket very similar to that of porcine elastase I are also present in the protein thus accounting for its zymogen-like activity. The most obvious difference is the absence in the subunit of the two strongly hydrophobic amino acids (16 and 17 in the chymotrypsinogen numbering), which are known to participate in the stabilization of a fully functional binding pocket in active endopeptidases. Four of the five disulfide bridges of subunit III are homologous with those common to all pancreatic endopeptidases. In contrast the fifth bridge forms a very small loop of only four amino acids, which is not encountered in active endopeptidases. Other potentially lethal modifications in the structure of the subunit are not excluded.