[59] Lobster muscle transpeptidase. Proteolytic Enzymes. Elsevier; 1970. pp. 765-70. [DOI: 10.1016/0076-6879(70)19064-1]

Signature Ions in MS/MS Spectra for Dansyl-Aminohexyl-QQIV Adducts on Lysine

Bacterial transglutaminase was used to label human plasma proteins with fluorescent tags. Protein lysines were modified with dansyl-epsilon-aminohexyl-Gln-Gln-Ile-Val-OH (dansylQQIV), while protein glutamines were modified with dansyl cadaverine. Labeled proteins included human butyrylcholinesterase, apolipoprotein A-1, haptoglobin, haptoglobin-related protein, immunoglobulin heavy chain, and hemopexin. Tryptic peptides were analyzed by LC-MS/MS on an Orbitrap Fusion Lumos mass spectrometer. Modified residues were identified in Protein Prospector and Proteome Discoverer searches of mass spectrometry data. The MS/MS fragmentation spectra from dansylQQIV-modified peptides gave intense peaks at 475.2015, 364.1691, 347.1426, 234.0585, and 170.0965 m/z. These signature ions are useful markers for identifying modified peptides. Human butyrylcholinesterase retained full activity following modification by dansylQQIV or dansyl cadaverine.

Crystal structure of red sea bream transglutaminase

The crystal structure of the tissue-type transglutaminase from red sea bream liver (fish-derived transglutaminase, FTG) has been determined at 2.5-A resolution using the molecular replacement method, based on the crystal structure of human blood coagulation factor XIII, which is a transglutaminase zymogen. The model contains 666 residues of a total of 695 residues, 382 water molecules, and 1 sulfate ion. FTG consists of four domains, and its overall and active site structures are similar to those of human factor XIII. However, significant structural differences are observed in both the acyl donor and acyl acceptor binding sites, which account for the difference in substrate preferences. The active site of the enzyme is inaccessible to the solvent, because the catalytic Cys-272 hydrogen-bonds to Tyr-515, which is thought to be displaced upon acyl donor binding to FTG. It is postulated that the binding of an inappropriate substrate to FTG would lead to inactivation of the enzyme because of the formation of a new disulfide bridge between Cys-272 and the adjacent Cys-333 immediately after the displacement of Tyr-515. Considering the mutational studies previously reported on the tissue-type transglutaminases, we propose that Cys-333 and Tyr-515 are important in strictly controlling the enzymatic activity of FTG.

A new transglutaminase-like from the ascidian Ciona intestinalis

A cDNA clone encoding a transglutaminase (TGase) was isolated from a cDNA library prepared from the larval stage of Ciona intestinalis. The cDNA sequence has an open reading frame encoding a protein of 696 amino acids and is about 36% identical to 11 other TGase sequences. In addition, the critical residues thought to form the catalytic center are conserved. The Ciona TGase (CiTGase) has an extension of 39 amino acids in the NH2-terminal region similar to that reported for keratinocyte TGases. A phylogenetic analysis among other types of TGases demonstrated that CiTGase represents a new type of the enzyme.

Tissue-type transglutaminase from red sea bream (Pagrus major). Sequence analysis of the cDNA and functional expression in Escherichia coli

A cDNA clone encoding a tissue-type transglutaminase (TGase) was isolated from a cDNA library prepared from the liver of red sea bream (Pagrus major). The cDNA sequence had an open reading frame coding for a protein of 695 amino acids and showed 43% identity to the sequence of guinea pig liver TGase, revealing a relatively low overall similarity. However, the 25-amino-acid sequence containing the putative active site (Cys272) of the enzyme was completely conserved between the two species, and was also identical to the corresponding regions of human and bovine endothelial cell TGases. In addition, the critical residues (His332 and Asp355) thought to form the catalytic-center triad together with Cys272, were found in the highly conserved region. The red sea bream TGase had an extension of 11 amino acids in the C-terminal region and some differences in the N-terminal region when compared with guinea pig TGase. From the cloned cDNA, a semi-synthetic TGase gene suitable for overexpression in Escherichia coli was constructed (pTTG2-22). At a reduced temperature (28 degrees C), E. coli cells transformed with pTTG2-22 could produce soluble TGase which exhibited catalytic activity in the presence of calcium. E. coli extracts containing the recombinant red sea bream TGase induced gelation of actomyosin solutions, accompanied by a significant increase of epsilon-(gamma-glutamyl)lysine bonds, which are predominantly derived from the cross-linking of myosin heavy chains. These results indicate that this fish TGase should be useful for further analysis of TGase structure/function relationships and that it could also be employed to enhance the viscoelastic properties of proteinaceous materials.