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Unraveling Biological Energy Catalysis: Multi-Scale Simulations of Respiratory Complex I
Stockholm University, Faculty of Science, Department of Biochemistry and Biophysics.ORCID iD: 0000-0003-1868-2022
2024 (English)Doctoral thesis, comprehensive summary (Other academic)
Abstract [en]

Cellular function is powered by mitochondria through an energy conversion process known as oxidative phosphorylation. Central to this process is respiratory complex I, an enzyme that couples NADH oxidation with ubiquinone reduction and the pumping of protons across the inner mitochondrial membrane. In this thesis, the mechanistic principles of complex I were investigated using multi-scale simulations, including atomistic molecular dynamics simulations and hybrid quantum/classical mechanics (QM/MM) calculations. We found that complex I drives quinone reduction and proton pumping through a network of buried charged residues. These residues couple protonation changes to conformational shifts, electrostatic interactions, and modulations of the hydration dynamics. Additionally, we expanded the applicability of QM/MM to long-range protonation dynamics by developing a novel sampling scheme. This scheme combines advanced sampling methods with a general reaction coordinate to provide a quantitative description of hydration dynamics and conformational changes during proton transfer reactions, which are indispensable for understanding the function of the respiratory enzymes. We further investigated the molecular details of how and why respiratory complexes cluster together to form supercomplexes. Our findings indicate that membrane proteins alter the membrane properties and introduce strain, which could drive the formation of these assemblies. The combined mechanistic findings of this thesis enhance our understanding of respiratory complex I and supercomplexes and their underlying proton transfer reactions, conformational changes, and enzymatic activity.

Place, publisher, year, edition, pages
Stockholm: Department of Biochemistry and Biophysics, Stockholm University , 2024. , p. 68
Keywords [en]
Bioenergetics, Multi-scale Simulations, Proton Transfer, Respiration, Respiratory Complex I, Supercomplex
National Category
Biophysics Theoretical Chemistry
Research subject
Biophysics
Identifiers
URN: urn:nbn:se:su:diva-231869ISBN: 978-91-8014-867-2 (print)ISBN: 978-91-8014-868-9 (electronic)OAI: oai:DiVA.org:su-231869DiVA, id: diva2:1883615
Public defence
2024-09-23, Hörsal 7, hus D, Frescativägen 10 and online via zoom, public link is available at the department website, Stockholm, 09:00 (English)
Opponent
Supervisors
Available from: 2024-08-29 Created: 2024-07-11 Last updated: 2024-08-27Bibliographically approved
List of papers
1. Functional Water Wires Catalyze Long-Range Proton Pumping in the Mammalian Respiratory Complex I
Open this publication in new window or tab >>Functional Water Wires Catalyze Long-Range Proton Pumping in the Mammalian Respiratory Complex I
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2020 (English)In: Journal of the American Chemical Society, ISSN 0002-7863, E-ISSN 1520-5126, Vol. 142, no 52, p. 21758-21766Article in journal (Refereed) Published
Abstract [en]

The respiratory complex I is a gigantic (1 MDa) redox-driven proton pump that reduces the ubiquinone pool and generates proton motive force to power ATP synthesis in mitochondria. Despite resolved molecular structures and biochemical characterization of the enzyme from multiple organisms, its long-range (similar to 300 A) proton-coupled electron transfer (PCET) mechanism remains unsolved. We employ here microsecond molecular dynamics simulations to probe the dynamics of the mammalian complex I in combination with hybrid quantum/classical (QM/MM) free energy calculations to explore how proton pumping reactions are triggered within its 200 A wide membrane domain. Our simulations predict extensive hydration dynamics of the antiporter-like subunits in complex I that enable lateral proton transfer reactions on a microsecond time scale. We further show how the coupling between conserved ion pairs and charged residues modulate the proton transfer dynamics, and how transmembrane helices and gating residues control the hydration process. Our findings suggest that the mammalian complex I pumps protons by tightly linked conformational and electrostatic coupling principles.

National Category
Chemical Sciences
Identifiers
urn:nbn:se:su:diva-191236 (URN)10.1021/jacs.0c09209 (DOI)000605189000020 ()33325238 (PubMedID)
Available from: 2021-03-24 Created: 2021-03-24 Last updated: 2024-08-21Bibliographically approved
2. Quinone Catalysis Modulates Proton Transfer Reactions in the Membrane Domain of Respiratory Complex I
Open this publication in new window or tab >>Quinone Catalysis Modulates Proton Transfer Reactions in the Membrane Domain of Respiratory Complex I
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2023 (English)In: Journal of the American Chemical Society, ISSN 0002-7863, E-ISSN 1520-5126, Vol. 145, no 31, p. 17075-17086Article in journal (Refereed) Published
Abstract [en]

Complex I is a redox-driven proton pump that drives electron transport chains and powers oxidative phosphorylation across all domains of life. Yet, despite recently resolved structures from multiple organisms, it still remains unclear how the redox reactions in Complex I trigger proton pumping up to 200 Å away from the active site. Here, we show that the proton-coupled electron transfer reactions during quinone reduction drive long-range conformational changes of conserved loops and trans-membrane (TM) helices in the membrane domain of Complex I from Yarrowia lipolytica. We find that the conformational switching triggers a π → α transition in a TM helix (TM3ND6) and establishes a proton pathway between the quinone chamber and the antiporter-like subunits, responsible for proton pumping. Our large-scale (>20 μs) atomistic molecular dynamics (MD) simulations in combination with quantum/classical (QM/MM) free energy calculations show that the helix transition controls the barrier for proton transfer reactions by wetting transitions and electrostatic effects. The conformational switching is enabled by re-arrangements of ion pairs that propagate from the quinone binding site to the membrane domain via an extended network of conserved residues. We find that these redox-driven changes create a conserved coupling network within the Complex I superfamily, with point mutations leading to drastic activity changes and mitochondrial disorders. On a general level, our findings illustrate how catalysis controls large-scale protein conformational changes and enables ion transport across biological membranes. 

National Category
Biophysics Theoretical Chemistry
Identifiers
urn:nbn:se:su:diva-220977 (URN)10.1021/jacs.3c03086 (DOI)001035678200001 ()37490414 (PubMedID)2-s2.0-85167480759 (Scopus ID)
Available from: 2023-09-14 Created: 2023-09-14 Last updated: 2024-07-11Bibliographically approved
3. QM/MM Free Energy Calculations of Long-Range Biological Protonation Dynamics by Adaptive and Focused Sampling
Open this publication in new window or tab >>QM/MM Free Energy Calculations of Long-Range Biological Protonation Dynamics by Adaptive and Focused Sampling
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2024 (English)In: Journal of Chemical Theory and Computation, ISSN 1549-9618, E-ISSN 1549-9626, Vol. 20, no 13, p. 5751-5762Article in journal (Refereed) Published
Abstract [en]

Water-mediated proton transfer reactions are central for catalytic processes in a wide range of biochemical systems, ranging from biological energy conversion to chemical transformations in the metabolism. Yet, the accurate computational treatment of such complex biochemical reactions is highly challenging and requires the application of multiscale methods, in particular hybrid quantum/classical (QM/MM) approaches combined with free energy simulations. Here, we combine the unique exploration power of new advanced sampling methods with density functional theory (DFT)-based QM/MM free energy methods for multiscale simulations of long-range protonation dynamics in biological systems. In this regard, we show that combining multiple walkers/well-tempered metadynamics with an extended system adaptive biasing force method (MWE) provides a powerful approach for exploration of water-mediated proton transfer reactions in complex biochemical systems. We compare and combine the MWE method also with QM/MM umbrella sampling and explore the sampling of the free energy landscape with both geometric (linear combination of proton transfer distances) and physical (center of excess charge) reaction coordinates and show how these affect the convergence of the potential of mean force (PMF) and the activation free energy. We find that the QM/MM-MWE method can efficiently explore both direct and water-mediated proton transfer pathways together with forward and reverse hole transfer mechanisms in the highly complex proton channel of respiratory Complex I, while the QM/MM-US approach shows a systematic convergence of selected long-range proton transfer pathways. In this regard, we show that the PMF along multiple proton transfer pathways is recovered by combining the strengths of both approaches in a QM/MM-MWE/focused US (FUS) scheme and reveals new mechanistic insight into the proton transfer principles of Complex I. Our findings provide a promising basis for the quantitative multiscale simulations of long-range proton transfer reactions in biological systems. 

National Category
Theoretical Chemistry
Research subject
Biochemistry with Emphasis on Theoretical Chemistry
Identifiers
urn:nbn:se:su:diva-231866 (URN)10.1021/acs.jctc.4c00199 (DOI)001225139500001 ()38718352 (PubMedID)2-s2.0-85193210581 (Scopus ID)
Funder
Swedish Research CouncilGerman Research Foundation (DFG), SFB1078German Research Foundation (DFG), TRR235Knut and Alice Wallenberg Foundation, 2019.0251Knut and Alice Wallenberg Foundation, WASPDDLS22:025
Available from: 2024-07-02 Created: 2024-07-02 Last updated: 2024-08-08Bibliographically approved
4. Protein-Induced Membrane Strain Drives Supercomplex Formation
Open this publication in new window or tab >>Protein-Induced Membrane Strain Drives Supercomplex Formation
(English)Manuscript (preprint) (Other academic)
Abstract [en]

Mitochondrial membranes harbor the electron transport chain (ETC) that powers oxidative phosphorylation (OXPHOS) and drives the synthesis of ATP. Yet, under physiological conditions, the OXPHOS proteins operate as higher-order supercomplex (SC) assemblies, although their functional role remains poorly understood and much debated. Here we show that the formation of the mammalian I/III2 supercomplex reduces the molecular strain of inner mitochondrial membranes by altering the local membrane thickness, and leading to an accumulation of both cardiolipin and quinone around specific regions of the SC. We also find that the SC assembly affects the global motion of the individual ETC proteins with possible functional consequences. On a general level, our findings suggest that molecular crowding and entropic effects provide a thermodynamic driving force for the SC formation, with a possible flux enhancement in crowded biological membranes under constrained respiratory conditions.

National Category
Biophysics
Research subject
Biophysics
Identifiers
urn:nbn:se:su:diva-231868 (URN)
Available from: 2024-07-02 Created: 2024-07-02 Last updated: 2024-07-11

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