Rusticyanin Research Articles

Evaluation of Cyc1 protein stability in Acidithiobacillus ferrooxidans bacterium after E121D mutation by molecular dynamics simulation to improve electron transfer.

Cyc1 (Cytochrome c552) is a protein in the electron transport chain of the Acidithiobacillus ferrooxidans (Af) bacteria which obtain their energy from oxidation Fe2+ to Fe3+. The electrons are directed through Cyc2, RCY (rusticyanin), Cyc1 and Cox aa3 proteins to O2. Cyc1 protein consists of two chains, A and B. In the present study, a novel mutation (E121D) in the A chain of Cyc1 protein was selected due to electron receiving from Histidine 143 of RCY. Then, the changes performed in the E121D mutant were evaluated by MD simulations analyzes. Cyc1 and RCY proteins were docked by a Patchdock server. By E121D mutation, the connection between Zn 1388 of chain B and aspartate 121 of chain A weaken. Asp 121 gets farther from Zn 1388. Therefore, the aspartate gets closer to Cu 1156 of the RCY leading to the higher stability of the RCY/Cyc1 complex. Further, an acidic residue (Glu121) becomes a more acidic residue (Asp121) and improves the electron transfer to Cyc1 protein. The results of RMSF analysis showed further ligand flexibility in mutation. This leads to fluctuation of the active site and increases redox potential at the mutation point and the speed of electron transfer. This study also predicts that in all respiratory chain proteins, electrons probably enter the first active site via glutamate and exit histidine in the second active site of each respiratory chain protein.

Electron transfer from cytochrome c to cupredoxins

Electron transfer (ET) through and between proteins is a fundamental biological process. The activation energy for an ET reaction depends upon the Gibbs energy change upon ET (DeltaG(0)) and the reorganization energy. Here, we characterized ET from Pseudomonas aeruginosa cytochrome c(551) (PA) and its designed mutants to cupredoxins, Silene pratensis plastocyanin (PC) and Acidithiobacillus ferrooxidans rusticyanin (RC), through measurement of pseudo-first-order ET rate constants (k(obs)). The influence of the DeltaG (0) value for ET from PA to PC or RC on the k(obs) value was examined using a series of designed PA proteins exhibiting a variety of E (m) values, which afford the DeltaG (0) variation range of 58-399 meV. The plots of the k(obs) values obtained against the DeltaG(0) values for both PA-PC and PA-RC redox pairs could be fitted well with a single Marcus equation. We have shown that the ET activity of cytochrome c can be controlled by tuning the E(m) value of the protein through the substitution of amino acid residues located in hydrophobic-core regions relatively far from the redox center. These findings provide novel insights into the molecular design of cytochrome c, which could be utilized for controlling its ET activity by means of protein engineering.

Molecular Modeling of the Ternary Complex of Rusticyanin-Cytochrome c4-Cytochrome Oxidase: An Insight to Possible H-Bond Mediated Recognition and Electron Transfer Reaction in T.ferrooxidans

The metabolism of Thiobacillus ferrooxidans involves electron transfer from the Fe+2 ions in the extracellular environment to the terminal oxygen in the bacterial cytoplasm through a series of periplasmic proteins like Rusticyanin (RCy), Cytochrome (Cyt c4), and Cytochrome oxidase (CcO). The energy minimization and MD studies reveal the stabilization of the three redox proteins in their ternary complex through the direct and water mediated H-bonds and electrostatic interaction. The surface exposed polar residues of the three proteins, i.e., RCy (His 143, Thr 146, Lys 81, Glu 20), Cyt c4 (Asp 5, 15, 52, Ser 14, Glu 61), and CcO (Asp 135, Glu 126, 140, 142, Thr 177) formed the intermolecular hydrogen bonds and stabilized the ternary complex. The oxygen (Oεl) of Glu 126, 140, and 142 on subunit II of the CcO interact to the exposed side-chain and Ob atoms of the Asp 52 of Cyt c4 and Glu 20 and Leu 12 of RCy. The Asp 135 of subunit II also forms H-bond with the Nε atom of Lys 81 of RCy. The Oεl of Glu 61 of Cyt c4 is also H-bonded to Oγ atom of Thr 177 of CcO. Solvation followed by MD studies of the ternary protein complex revealed the presence of seven water molecules in the interfacial region of the interacting proteins. Three of the seven water molecules (W 79, W 437, and W 606) bridged the three proteins by forming the hydrogen bonded network (with the distances ∼ 2.10–2.95 Å) between the Lys 81 (RCy), Glu 61 (Cyt c4), and Asp 135 (CcO). Another water molecule W 603 was H-bonded to Tyr 122 (CcO) and interconnected the Lys 81 (RCy) and Asp 135 (CcO) through the water molecules W 606 and W 437. The other two water molecules (W 21 and W 455) bridged the RCy to Cyt c4 through H-bonds, whereas the remaining W 76 interconnected the His 53 (Cytc4) to Glu 126 (CcO) with distances ∼ 2.95–3.0 Å.

Modeling Study of Rusticyanin-Cytochrome C4 Complex: An Insight to Possible H-Bond Mediated Recognition and Electron—Transfer Process

Rusticyanin (RCy) mediated transfer of electron to Cytochrome C4 (Cytc4) from the extracellular Fe+2 ion is primarily involved in the Thiobacillus ferrooxidans induced bio-leaching of pyrite ore and also in the metabolism of this acidophilic bacteria. The modeling studies have revealed the two possible mode of RCy-Cytc4 complexation involving nearly the same stabilization energy ∼ −15 × 103 kJ/mol, one through N-terminal Asp 15 and another -C terminal Glu 121 of Cytc4 with the Cu-bonded His 143 of RCy. The Asp 15:His 143 associated complex (DH) of Cytc4-RCy was stabilized by the intermolecular H-bonds of the carboxyl oxygen atoms Oδ1 and Oδ2 of Asp 15 with the Nϵ-atom of His 143 and Ob atoms of Ala 8 and Asp 5 (of Cytc4) with the Thr 146 and Phe 51 (of RCy). But the other Glu 121:His 143 associated complex (EH) of Cytc4-RCy was stabilized by the H-bonding interaction of the oxygen atoms Oϵ1 and Oϵ2 of Glu 121 with the Nϵ and Oγ atoms of His 143 and Thr 146 of RCy. The six water molecules were present in the binding region of the two proteins in the energy minimized autosolvated DH and EH-complexes. The MD studies also revealed the presence of six interacting water molecules at the binding region between the two proteins in both the complexes. Several residues Gly 82 and 84, His 143 (RCy) were participated through the water mediated (W 389, W 430, W 413, W 431, W 373, and W 478) interaction with the Asp 15, Ile 82, and 62, Tyr 63 (Cytc4) in DH complex, whereas in EH complex the Phe 51, Asn 80, Tyr 146 (RCy) residues were observed to interact with Asn 108, Met 120, Glu 121 (of Cytc4) through the water molecules W 507, W 445, W 401, W 446, and W 440. The direct water mediated (W 478) interaction of His 143 (RCy) to Asp 15 (of Cytc4) was observed only in the DH complex but not in EH. These direct and water mediated H-bonding between the two respective proteins and the binding free energy with higher interacting buried surface area of the DH complex compare to other EH complex have indicated an alternative possibility of the electron transfer route through the interaction of His 143 of RCy and the N-terminal Asp 15 of Cytc4.

The Structure of Acidithiobacillus ferrooxidans c4-Cytochrome : A Model for Complex-Induced Electron Transfer Tuning

The study of electron transfer between the copper protein rusticyanin (RCy) and the c 4-cytochrome CYC 41 of the acidophilic bacterium Acidithiobacillus ferrooxidans has evidenced a remarkable decrease of RCy's redox potential upon complex formation. The structure of the CYC 41 obtained at 2.2 Å resolution highlighted a specific glutamate residue (E121) involved in zinc binding as potentially playing a central role in this effect, required for the electron transfer to occur. EPR and stopped-flow experiments confirmed the strong inhibitory effect of divalent cations on CYC 41:RCy complex formation. A docking analysis of the CYC 41 and RCy structure allows us to propose a detailed model for the complex-induced tuning of electron transfer in agreement with our experimental data, which could be representative of other copper proteins involved in electron transfer.

Preparation and characterization of cobalt(II)-substituted rusticyanin

Preparation and characterization of cobalt(II)-substituted rusticyanin