Respiratory complex II acting as a homeostatic regulatory sensor.

The succinate-ubiquinone oxidoreductase (SQR) complex connects two of the cell's most vital energy-producing metabolic processes: the tricarboxylic acid cycle and the electron transport chain. Hence, the SQR complex is essential in cell metabolism, and its malfunction leads to the progression of multiple metabolic disorders and other diseases, such as cancer. In the current study, we calculated the electron tunneling (ET) pathways between the different redox systems in the SQR complex, including the SQR ligands and the distant heme redox center, using the broken-symmetry semi-empirical ZINDO method.

Respiratory Complex III: A Bioengine with a Ligand-Triggered Electron-Tunneling Gating Mechanism.

Respiratory complex III (a.k.a.

Computational Modeling for the Oxidation Reactions of the Cysteine Residues with the Superoxide and the Organic Radical Species.

The current computational study analyzes the oxidation reactions of the superoxide and hydroxyl radicals with cysteine residues due to their importance as natural targets to neutralize the harmful reactive oxygen species. Due to the high reactivity of the hydroxyl radicals with the surrounding environment, we also studied the oxidation reactions of organic radicals with cysteine. In addition, we explored the different reaction pathways between cysteine and the superoxide radicals in both anionic and protonated forms.

Respiratory complex I: Bottleneck at the entrance of quinone site requires conformational change for its opening.

The structure of the entire respiratory complex I is now known at reasonably high resolution for many species - bacteria, yeast, and several mammals, including human. The structure reveals an almost 30 angstrom tunnel-like chamber for ubiquinone binding in the core part of the enzyme, at the joint between the membrane and hydrophilic arms of the enzyme. Here we characterize the geometric bottleneck forming the entrance of the quinone reaction chamber.

Mutations in Cause Metabolic Reprogramming and Disruption of the Electron Transfer.

Complex I (CI) is the first enzyme of the mitochondrial respiratory chain and couples the electron transfer with proton pumping. Mutations in genes encoding CI subunits can frequently cause inborn metabolic errors. We applied proteome and metabolome profiling of patient-derived cells harboring pathogenic mutations in two distinct CI genes to elucidate underlying pathomechanisms on the molecular level.

Concerted Two-Electron Reduction of Ubiquinone in Respiratory Complex I.

Respiratory complex I catalyzes two-electron/two-proton reduction of a ubiquinone (Q) substrate bound at its Q-binding pocket; upon reduction, ubiquinole carries electrons further down the electron transport chain. The mechanism of this two-electron transfer reaction is poorly understood. Here we consider a hypothetical scheme in which two electrons transfer together with two protons in a concerted fashion.

Polarizable Embedding for Excited-State Reactions: Dynamically Weighted Polarizable QM/MM.

Recent interest in polarizable embedding methods for electronic excited states has so far been focused on optical absorption and emission spectra calculations. To explore the suitability of these methods for excited-state reactions, we constructed a simple molecular system with an electronic crossing coupled to a polarizable species: the triatomic LiFBe. We found that current polarizable QM/MM methods inadequately describe the potential energy surfaces in this system, particularly close to the electronic crossing, so we developed a new polarizable embedding method called dynamically weighted polarizable QM/MM.

Electron tunneling in proteins program.

We developed a unique integrated software package (called Electron Tunneling in Proteins Program or ETP) which provides an environment with different capabilities such as tunneling current calculation, semi-empirical quantum mechanical calculation, and molecular modeling simulation for calculation and analysis of electron transfer reactions in proteins. ETP program is developed as a cross-platform client-server program in which all the different calculations are conducted at the server side while only the client terminal displays the resulting calculation outputs in the different supported representations. ETP program is integrated with a set of well-known computational software packages including Gaussian, BALLVIEW, Dowser, pKip, and APBS.

Novel Inhibitors for a Novel Binding Site in Respiratory Complex III.

A new binding site and potential novel inhibitors of the respiratory complex III are described. The site is located at the opposite side of the enzyme with respect to ubiquinol binding site (Qo site), and distinctly different from both Qo and Qi sites (hence designated as Non-Q binding site, NQ). NQ site binding pocket extends up close to Phe90 residue, an internal switch (LH switch) that regulates electron transfer between heme bL and heme bH of the low potential redox chain.

Internal switches modulating electron tunneling currents in respiratory complex III.

In different X-ray crystal structures of bc1 complex, some of the key residues of electron tunneling pathways are observed in different conformations; here we examine their relative importance in modulating electron transfer and propose their possible gating function in the Q-cycle. The study includes inter-monomeric electron transfer; here we provide atomistic details of the reaction, and discuss the possible roles of inter-monomeric electronic communication in bc(1) complex. Binding of natural ligands or inhibitors leads to local conformational changes which propagate through protein and control the conformation of key residues involved in the electron tunneling pathways.

Quantum Calculations of Electron Tunneling in Respiratory Complex III.

The most detailed and comprehensive to date study of electron transfer reactions in the respiratory complex III of aerobic cells, also known as bc1 complex, is reported. In the framework of the tunneling current theory, electron tunneling rates and atomistic tunneling pathways between different redox centers were investigated for all electron transfer reactions comprising different stages of the proton-motive Q-cycle. The calculations reveal that complex III is a smart nanomachine, which under certain conditions undergoes conformational changes gating electron transfer, or channeling electrons to specific pathways.

Transition Flux Formula for the Electronic Coupling Matrix Element.

The transition flux formula for the coupling matrix element of long-distance electron transfer reactions is discussed. Here we present a new derivation which is based on the Golden Rule approach. The electronic Franck-Condon factor that appears in the multielectronic formulation of the coupling element is discussed using the concept of tunneling time.