MMOD-induced structural changes of hydroxylase in soluble methane monooxygenase.
Hanseong KimSojin AnYeo Reum ParkHara JangHeeseon YooSang Ho ParkSeung Jae LeeUhn-Soo ChoPublished in: Science advances (2019)
Soluble methane monooxygenase in methanotrophs converts methane to methanol under ambient conditions. The maximum catalytic activity of hydroxylase (MMOH) is achieved through the interplay of its regulatory protein (MMOB) and reductase. An additional auxiliary protein, MMOD, functions as an inhibitor of MMOH; however, its inhibitory mechanism remains unknown. Here, we report the crystal structure of the MMOH-MMOD complex from Methylosinus sporium strain 5 (2.6 Å). Its structure illustrates that MMOD associates with the canyon region of MMOH where MMOB binds. Although MMOD and MMOB recognize the same binding site, each binding component triggers different conformational changes toward MMOH, which then respectively lead to the inhibition and activation of MMOH. Particularly, MMOD binding perturbs the di-iron geometry by inducing two major MMOH conformational changes, i.e., MMOH β subunit disorganization and subsequent His147 dissociation with Fe1 coordination. Furthermore, 1,6-hexanediol, a mimic of the products of sMMO, reveals the substrate access route.
Keyphrases
- anaerobic digestion
- carbon dioxide
- binding protein
- molecular dynamics
- molecular dynamics simulations
- single molecule
- protein protein
- amino acid
- air pollution
- particulate matter
- transcription factor
- high glucose
- dna binding
- diabetic rats
- small molecule
- pseudomonas aeruginosa
- cystic fibrosis
- biofilm formation
- protein kinase