Residue Mutations in [Fe-Fe]-hydrogenase Impedes O(2) Binding: A QM/MM Investigation.

نویسندگان

  • Daniela Dogaru
  • Stefan Motiu
  • Valentin Gogonea
چکیده

[Fe-Fe]-hydrogenases are enzymes that reversibly catalyze the reaction of protons and electrons to molecular hydrogen, which occurs in anaerobic media. In living systems, [Fe-Fe]-hydrogenases are mostly used for H(2) production. The [Fe-Fe]-hydrogenase H-cluster is the active site, which contains two iron atoms. The latest theoretical investigations1,2 advocate that the structure of di-iron air inhibited species are either Fe(p) (II)-Fe(d) (II)-O-H(-), or Fe(p) (II)-Fe(d) (II)-O-O-H, thus O(2) has to be prevented from binding to Fe(d) in all di-iron subcluster oxidation states in order to retain a catalytically active enzyme. By performing residue mutations on [Fe-Fe]-hydrogenases, we were able to weaken O(2) binding to distal iron (Fe(d)) of Desulfovibrio desulfuricans hydrogenase (DdH). Individual residue deletions were carried out in the 8 A apoenzyme layer radial outward from Fe(d) to determine what residue substitutions should be made to weaken O(2) binding. Residue deletions and substitutions were performed for three di-iron subcluster oxidation states, Fe(p) (II)-Fe(d) (II), Fe(p) (II)-Fe(d) (I), and Fe(p) (I)-Fe(d) (I) of [Fe-Fe]-hydrogenase. Two deletions (DeltaThr(152) and DeltaSer(202)) were found most effective in weakening O(2) binding to Fe(d) in Fe(p) (II)-Fe(d) (I) hydrogenase (DeltaG(QM/MM) = +5.4 kcal/mol). An increase in Gibbs' energy (+2.2 kcal/mol and +4.4 kcal/mol) has also been found for Fe(p) (II)-Fe(d) (II), and Fe(p) (I)-Fe(d) (I) hydrogenase respectively. pi-backdonation considerations for frontier molecular orbital and geometrical analysis corroborate the Gibbs's energy results.

برای دانلود متن کامل این مقاله و بیش از 32 میلیون مقاله دیگر ابتدا ثبت نام کنید

ثبت نام

اگر عضو سایت هستید لطفا وارد حساب کاربری خود شوید

منابع مشابه

On the Convergence of QM/MM Energies.

We have studied the convergence of QM/MM calculations with respect to the size of the QM system. We study a proton transfer between a first-sphere cysteine ligand and a second-sphere histidine group in [Ni,Fe] hydrogenase and use a 446-atom model of the protein, treated purely with QM methods as a reference. We have tested 12 different ways to redistribute charges close to the junctions (to avo...

متن کامل

Mechanistic and physiological implications of the interplay among iron-sulfur clusters in [FeFe]-hydrogenases. A QM/MM perspective.

Key stereoelectronic properties of Desulfovibrio desulfuricans [FeFe]-hydrogenase (DdH) were investigated by quantum mechanical description of its complete inorganic core, which includes a Fe(6)S(6) active site (the H-cluster), as well as two ancillary Fe(4)S(4) assemblies (the F and F' clusters). The partially oxidized, active-ready form of DdH is able to efficiently bind dihydrogen, thus star...

متن کامل

A double-QM/MM method for investigating donor-acceptor electron-transfer reactions in solution.

We developed a double-quantum mechanical/molecular mechanical (d-QM/MM) method for investigation of full outer-sphere electron transfer (ET) processes between a donor and an acceptor (DA) in condensed matter. In the d-QM/MM method, which employs the novel concept of multiple QM regions, one can easily specify the number of electrons, spin states and appropriate exchange-correlation treatment in...

متن کامل

Accurate Reaction Energies in Proteins Obtained by Combining QM/MM and Large QM Calculations.

We here suggest and test a new method to obtain stable energies in proteins for charge-neutral reactions by running large quantum mechanical (QM) calculations on structures obtained by combined QM and molecular mechanics (QM/MM) geometry optimization on several snapshots from molecular dynamics simulations. As a test case, we use a proton transfer between a metal-bound cysteine residue and a se...

متن کامل

Why is the oxidation state of iron crucial for the activity of heme-dependent aldoxime dehydratase? A QM/MM study.

Aldoxime dehydratase is a heme-containing enzyme that utilizes the ferrous rather than the ferric ion to catalyze the synthesis of nitriles by dehydration of the substrate. We report a theoretical study of this enzyme aimed at elucidating its catalytic mechanism and understanding this oxidation state preference (Fe(2+) versus Fe(3+)). The uncatalyzed dehydration reaction was modeled by includin...

متن کامل

ذخیره در منابع من


  با ذخیره ی این منبع در منابع من، دسترسی به آن را برای استفاده های بعدی آسان تر کنید

برای دانلود متن کامل این مقاله و بیش از 32 میلیون مقاله دیگر ابتدا ثبت نام کنید

ثبت نام

اگر عضو سایت هستید لطفا وارد حساب کاربری خود شوید

عنوان ژورنال:
  • International journal of quantum chemistry

دوره 110 9  شماره 

صفحات  -

تاریخ انتشار 2009