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  • 1.
    Engelmark Cassimjee, Karim
    et al.
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Manta, Bianca
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Himo, Fahmi
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    A quantum chemical study of the ω-transaminase reaction mechanism2015Ingår i: Organic and biomolecular chemistry, ISSN 1477-0520, E-ISSN 1477-0539, Vol. 13, nr 31, s. 8453-8464Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    ω-Transaminases are valuable tools in biocatalysis due to their stereospecificity and their broad substrate range. In the present study, the reaction mechanism of Chromobacterium violaceum ω-transaminase is investigated by means of density functional theory calculations. A large active site model is designed based on the recent X-ray crystal structure. The detailed energy profile for the half-transamination of (S)-1-phenylethylamine to acetophenone is calculated and the involved transition states and intermediates are characterized. The model suggests that the amino substrate forms an external aldimine with the coenzyme pyridoxal-5′-phosphate (PLP), through geminal diamine intermediates. The external aldimine is then deprotonated in the rate-determining step, forming a planar quinonoid intermediate. A ketimine is then formed, after which a hemiaminal is produced by the addition of water. Subsequently, the ketone product is obtained together with pyridoxamine-5′-phosphate (PMP). In the studied half-transamination reaction the ketone product is kinetically favored. The mechanism presented here will be valuable to enhance rational and semi-rational design of engineered enzyme variants in the development of ω-transaminase chemistry.

  • 2.
    Manta, Bianca
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Quantum Chemical Studies of Enzymatic Reaction Mechanisms: Investigations of Cytosine Deaminase and ω-Transaminase2014Licentiatavhandling, sammanläggning (Övrigt vetenskapligt)
    Abstract [en]

    In this thesis, density functional theory is used to study the reaction mechanisms of two dierent enzymes. Quantum chemical cluster models of the active sites were designed using available crystal structures. In this approach only the active site residues are considered and the effects of the surroundings are accounted for by a coordinate-locking scheme and a polarizable continuum model.

    The enzymes studied are cytosine deaminase (CDA) from Escherichia coli and ω-transaminase from Chromobacterium violaceum (Cv-ωTA). CDA is a zinc-dependentenzyme that catalyzes the hydrolytic deamination of cytosine into uracil and ammonia. Cv-ωTA carries out the interchange of amino and keto groups by utilizing the cofactor pyridoxal-5’-phosphate (PLP). The calculations provide optimized geometries and energies of transition states and intermediates, which are analyzed and used to construct a potential energy prole for the reaction and to identify the rate-limiting step. Each theoretical investigation provides a detailed description of the catalytic mechanism and establishes the roleof important active site residues.

    In the rst study (Paper I), it was found that a glutamate and an aspartate residue assist in the proton transfer events throughout the reaction. In the second study (Paper II), it was found that the lysine residue, which in the holo enzyme binds the cofactor PLP, assists in several proton transfer events once it has been replaced by the amino substrate. It was also found that the water substrate can be utilized as a proton shuttle before it is consumed at a later stage in the reaction mechanism.

    Apart from the detailed chemical insight, the results in this thesis confirmthat density functional theory together with cluster models of active sites is a very useful approach for studying diverse enzymatic reaction mechanisms.

  • 3.
    Manta, Bianca
    et al.
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Engelmark Cassimjee, Karim
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Himo, Fahmi
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Quantum Chemical Study of Dual-Substrate Recognition in ω-Transaminase2017Ingår i: ACS Omega, E-ISSN 2470-1343, Vol. 2, nr 3, s. 890-898Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    ω-Transaminases are attractive biocatalysts for the production of chiral amines. These enzymes usually have a broad substrate range. Their substrates include hydrophobic amines as well as amino acids, a feature referred to as dual-substrate recognition. In the present study, the reaction mechanism for the half-transamination of L-alanine to pyruvate in (S)-selective Chromobacterium violaceum ω-transaminase is investigated using density functional theory calculations. The role of a flexible arginine residue, Arg416, in the dual-substrate recognition is investigated by employing two active-site models, one including this residue and one lacking it. The results of this study are compared to those of the mechanism of the conversion of (S)-1-phenylethylamine to acetophenone. The calculations suggest that the deaminations of amino acids and hydrophobic amines follow essentially the same mechanism, but the energetics of the reactions differ significantly. It is shown that the amine is kinetically favored in the half-transamination of L-alanine/pyruvate, whereas the ketone is kinetically favored in the half-transamination of (S)-1-phenylethylamine/acetophenone. The calculations further support the proposal that the arginine residue facilitates the dual-substrate recognition by functioning as an arginine switch, where the side chain is positioned inside or outside of the active site depending on the substrate. Arg416 participates in the binding of L-alanine by forming a salt bridge to the carboxylate moiety, whereas the conversion of (S)-1-phenylethylamine is feasible in the absence of Arg416, which here represents the case in which the side chain of Arg416 is positioned outside of the active site.

  • 4.
    Manta, Bianca
    et al.
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Himo, Fahmi
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Insights from Quantum Chemical Calculations into Active Site Structure and Reaction Mechanism of Manganese-Dependent Dinitrogenase Reductase-Activating GlycohydrolaseManuskript (preprint) (Övrigt vetenskapligt)
  • 5.
    Manta, Bianca
    et al.
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Raushel, Frank M.
    Himo, Fahmi
    Stockholms universitet, Naturvetenskapliga fakulteten, Institutionen för organisk kemi.
    Reaction Mechanism of Zinc-Dependent Cytosine Deaminase from Escherichia coli: A Quantum-Chemical Study2014Ingår i: Journal of Physical Chemistry B, ISSN 1520-6106, E-ISSN 1520-5207, Vol. 118, nr 21, s. 5644-5652Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    The reaction mechanism of cytosine deaminase from Escherichia coli is studied using density functional theory. This zinc-dependent enzyme catalyzes the deamination of cytosine to form uracil and ammonia. The calculations give a detailed description of the catalytic mechanism and establish the role of important active-site residues. It is shown that Glu217 is essential for the initial deprotonation of the metal-bound water nucleophile and the subsequent protonation of the substrate. It is also demonstrated that His246 is unlikely to function as a proton shuttle in the nucleophile activation step, as previously proposed. The steps that follow are nucleophilic attack by the metal-bound hydroxide, protonation of the leaving group assisted by Asp313, and C-N bond cleavage. The calculated overall barrier is in good agreement with the experimental findings. Finally, the calculations reproduce the experimentally determined inverse solvent deuterium isotope effect, which further corroborates the suggested reaction mechanism.

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