Computationally guided bioengineering of the active site, substrate access pathway, and water channels of thermostable cytochrome P450, CYP175A1, for catalyzing the alkane hydroxylation reaction.

Understanding structure-function relationships in proteins is pivotal in their development as industrial biocatalysts. In this regard, rational engineering of protein active site access pathways and various tunnels and channels plays a central role in designing competent enzymes with high stability and enhanced efficiency. Here, we report the rational evolution of a thermostable cytochrome P450, CYP175A1, to catalyze the C-H activation reaction of longer-chain alkanes. A strategy combining computational tools with experiments has shown that the substrate scope and enzymatic activity can be enhanced by rational engineering of certain important channels such as the substrate entry and water channels along with the active site of the enzyme. The evolved enzymes showed an improved catalytic rate for hexadecane hydroxylation with high regioselectivity. The Q67L/Y68F mutation showed binding of the substrate in the active site, water channel mutation L80F/V220T showed improved catalytic activity through the peroxide shunt pathway and substrate entry channel mutation W269F/I270A showed better substrate accessibility to the active pocket. All-atom MD simulations provided the rationale for the inactivity of the wild-type CYP175A1 for hexadecane hydroxylation and predicted the above hot-spot residues to enhance the activity. The reaction mechanism was studied by QM/MM calculations for enzyme-substrate complexes and reaction intermediates. Detailed thermal and thermodynamic stability of all the mutants were analyzed and the results showed that the evolved enzymes were thermally stable. The present strategy showed promising results, and insights gained from this work can be applied to the general enzymatic system to expand substrate scope and improve catalytic activity.

Enhanced Substrate Specificity of Thermostable Cytochrome P450 CYP175A1 by Site Saturation Mutation on Tyrosine 68.

Thermostable cytochrome P450 (CYP175A1) cloned from Thermus thermophilus shows mid-point unfolding temperature (Tm) of 88 °C (361 K) along with high thermodynamic stability making it a potential industrially viable biocatalyst. Molecular docking analyses, and structural superposition with steroidogenic and fatty acid metabolizing cytochrome P450 s suggested that the tyrosine 68 may have important role in binding as well as metabolism of substrates by the enzyme. Site-saturation mutation of the tyrosine 68 residue was carried out and several unique mutations were obtained that were properly folded and showed high thermostability. We investigated the effects of variation of the single residue, Tyr68 at the substrate binding pocket of the enzyme on the substrate specificity of CYP175A1. Screening of the mutant colonies of CYP175A1 obtained after saturation mutagenesis of Tyr68 using saturated fatty acid, myristic acid and poly unsaturated fatty acids showed that the Y68K had notable binding and catalytic activity for mono-oxygenation of the saturated fatty acid (myristic acid), which had no major detectable binding affinity towards the WT enzyme. The Y68R mutant of CYP175A1, on the other hand was found to selectively bind and catalyse reaction of cholesterol. The wild type as well as both the mutants of the enzyme however bind poly unsaturated fatty acids. The results thus show that saturation mutation of a single amino acid at the substrate binding pocket of the thermostable cytochrome P450 could induce sufficient changes in the substrate binding pocket of the enzyme that can efficiently change substrate specificity of the enzyme.

Controlled Uptake of an Iridium Complex inside Engineered apo-Ferritin Nanocages: Study of Structure and Catalysis.

The effect of the mutation at the core of the ferritin nanocage (apo-rHLFr) on the uptake of IrCp* has been investigated by structural and spectroscopic methods. Site-specific mutations of two polar residues viz., Asp38 and Arg52 were investigated. The uptake of IrCp* was increased by about 1.5-fold on mutation of Arg52 by His compared to the wild-type variant, while mutation of Asp38 by His had no effect on the uptake. All the variants of the Ir-embedded ferritin cages remained as stable as the wild-type analogue. These hybrid bio-nanocages of ferritin were found to efficiently catalyze transfer hydrogenation of various substituted acetophenones forming the corresponding chiral alcohols with up to 88 % conversion and 70 % enantioselectivity. An electron-withdrawing substituent on the reactant enhanced the Turnover frequency of the reaction. Molecular docking analyses suggested that the substrate binds in different orientations at the active site in different mutants of the nanocage.