Role of Thr199 residue in human β-carbonic anhydrase-II pH-dependent activity elucidated by microsecond simulation analysis

Carbonic anhydrases catalyze the reversible hydration of carbon dioxide to form bicarbonate, a reaction required for many functions such as carbon assimilation, pH acid-base homeostasis, respiration and photosynthesis via a zinc-hydroxide mechanism for carbon dioxide hydration. In earlier studies, it was revealed that Carbonic anhydrases are inactive at pH 7.5 and active at pH 8.4. This steep pH dependence for its activity led us to design this work to understand its mode of action at atomic level detail. In our microsecond simulation based analysis, it was revealed that the interaction between Glu106 and Thr199 plays a critically important role in its activity. Thr199 co-ordinated loop movement was observed to be acting as a lid, with 'open' and 'close' mechanism for substrate entry to the core of the catalytic site, where Zn-ion resides and executes its carbon dioxide hydration mechanism. On the other hand, decline in the total secondary structural elements percentage in the protein was observed in correspondence to the pH condition change. The alpha-helices between Thr125-Gly145 and Val150-Lys170 residues were especially noticed to be losing their structural integrity responsible for formation of dimer and tetramers. In conclusion, our analysis showed that the interaction between Glu106 and Thr199 is crucial for maintaining the structural integrity of the Thr199 coordinated loop, responsible for allowing substrate towards the catalytic site. Communicated by Ramaswamy H. Sarma

Automated summary

Carbonic anhydrases play important roles in various functions such as carbon assimilation, pH regulation, respiration, and photosynthesis. This study investigates the atomic level details of the enzyme's mode of action and reveals that the interaction between Glu106 and Thr199 is crucial for its activity. Additionally, the protein's secondary structure elements decrease with changes in pH conditions.