Degradation-Suppressed Cocoonase for Investigating the Propeptide-Mediated Activation Mechanism

• Published in: Molecules (Basel, Switzerland) Vol. 27; no. 22; p. 8063
• Main Authors: Sakata, Nana, Ogata, Ayumi, Takegawa, Mai, Murakami, Yuri, Nishimura, Misaki, Miyazawa, Mitsuhiro, Hagiwara, Teruki, Shimamoto, Shigeru, Hidaka, Yuji
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 20.11.2022; MDPI
• Subjects: Amino Acid Sequence; Casein; Catalytic activity; Degradation; Electronics industry; Enzymatic activity; enzyme; Enzyme activity; Enzymes; Folding; Gene mutations; Investigations; Mutation; Peptides; Point Mutation; Proenzymes; propeptide; Protein Folding; Protein Precursors; Protein structure; Proteins; Residues; Spectrometry; trypsin; zymogen; Japan; enzyme; zymogen; trypsin; propeptide; folding
• ISSN: 1420-3049; 1420-3049
• DOI: 10.3390/molecules27228063

Cocoonase is folded in the form of a zymogen precursor protein (prococoonase) with the assistance of the propeptide region. To investigate the role of the propeptide sequence on the disulfide-coupled folding of cocoonase and prococoonase, the amino acid residues at the degradation sites during the refolding and auto-processing reactions were determined by mass spectrometric analyses and were mutated to suppress the numerous degradation reactions that occur during the reactions. In addition, the Lys residue at the propeptide region was also mutated to estimate whether the entire sequence is absolutely required for the activation of cocoonase. Finally, a degradation-suppressed [K8D,K63G,K131G,K133A]-proCCN protein was prepared and was found to refold readily without significant degradation. The results of an enzyme assay using casein or Bz-Arg-OEt suggested that the mutations had no significant effect on either the enzyme activity or the protein conformation. Thus, we, herein, provide the non-degradative cocoonase protein to investigate the propeptide-mediated protein folding of the molecule. We also examined the catalytic residues using the degradation-suppressed cocoonase. The point mutations at the putative catalytic residues in cocoonase resulted in the loss of catalytic activity without any secondary structural changes, indicating that the mutated residues play a role in the catalytic activity of this enzyme.