Project description:The potential positive feedback between global aquatic deoxygenation and methane (CH4) emission emphasizes the importance of understanding CH4 cycling under O2-limited conditions. Increasing observations for aerobic CH4-oxidizing bacteria (MOB) under anoxia have updated the prevailing paradigm that MOB are O2-dependent; thus, clarification on the metabolic mechanisms of MOB under anoxia is critical and timely. Here, we mapped the global distribution of MOB under anoxic aquatic zones and summarized four underlying metabolic strategies for MOB under anoxia: (a) forming a consortium with oxygenic microorganisms; (b) self-generation/storage of O2 by MOB; (c) forming a consortium with non-oxygenic heterotrophic bacteria that use other electron acceptors; and (d) utilizing alternative electron acceptors other than O2. Finally, we proposed directions for future research. This study calls for improved understanding of MOB under anoxia, and underscores the importance of this overlooked CH4 sink amidst global aquatic deoxygenation.

Project description:Aerobic respiration in bacteria, Archaea, and mitochondria is performed by oxygen reductase members of the heme-copper oxidoreductase superfamily. These enzymes are redox-driven proton pumps which conserve part of the free energy released from oxygen reduction to generate a proton motive force. The oxygen reductases can be divided into three main families based on evolutionary and structural analyses (A-, B- and C-families), with the B- and C-families evolving after the A-family. The A-family utilizes two proton input channels to transfer protons for pumping and chemistry, whereas the B- and C-families require only one. Generally, the B- and C-families also have higher apparent oxygen affinities than the A-family. Here we use whole cell proton pumping measurements to demonstrate differential proton pumping efficiencies between representatives of the A-, B-, and C-oxygen reductase families. The A-family has a coupling stoichiometry of 1 H(+)/e(-), whereas the B- and C-families have coupling stoichiometries of 0.5 H(+)/e(-). The differential proton pumping stoichiometries, along with differences in the structures of the proton-conducting channels, place critical constraints on models of the mechanism of proton pumping. Most significantly, it is proposed that the adaptation of aerobic respiration to low oxygen environments resulted in a concomitant reduction in energy conservation efficiency, with important physiological and ecological consequences.

Project description:Hyporheic zones (HZs)─zones of groundwater-surface water mixing─are hotspots for dissolved organic matter (DOM) and nutrient cycling that can disproportionately impact aquatic ecosystem functions. However, the mechanisms affecting DOM metabolism through space and time in HZs remain poorly understood. To resolve this gap, we investigate a recently proposed theory describing trade-offs between carbon (C) and nitrogen (N) limitations as a key regulator of HZ metabolism. We propose that throughout the extent of the HZ, a single process like aerobic respiration (AR) can be limited by both DOM thermodynamics and N content due to highly variable C/N ratios over short distances (centimeter scale). To investigate this theory, we used a large flume, continuous optode measurements of dissolved oxygen (DO), and spatially and temporally resolved molecular analysis of DOM. Carbon and N limitations were inferred from changes in the elemental stoichiometric ratio. We show sequential, depth-stratified relationships of DO with DOM thermodynamics and organic N that change across centimeter scales. In the shallow HZ with low C/N, DO was associated with the thermodynamics of DOM, while deeper in the HZ with higher C/N, DO was associated with inferred biochemical reactions involving organic N. Collectively, our results suggest that there are multiple competing processes that limit AR in the HZ. Resolving this spatiotemporal variation could improve predictions from mechanistic models, either via more highly resolved grid cells or by representing AR colimitation by DOM thermodynamics and organic N.

Project description:We performed evolution of Escherichia coli K12 MG1655 to study how the system adapts to loss of ubiC gene involved in ubiquinone biosynthesis. RNA-Seq was performed to examine the underlying transcriptional rewiring.

Project description:Increased production of reactive oxygen species (ROS) in mitochondria underlies major systemic diseases, and this clinical problem stimulates a great scientific interest in the mechanism of ROS generation. However, the mechanism of hypoxia-induced change in ROS production is not fully understood. To mathematically analyze this mechanism in details, taking into consideration all the possible redox states formed in the process of electron transport, even for respiratory complex III, a system of hundreds of differential equations must be constructed. Aimed to facilitate such tasks, we developed a new methodology of modeling, which resides in the automated construction of large sets of differential equations. The detailed modeling of electron transport in mitochondria allowed for the identification of two steady state modes of operation (bistability) of respiratory complex III at the same microenvironmental conditions. Various perturbations could induce the transition of respiratory chain from one steady state to another. While normally complex III is in a low ROS producing mode, temporal anoxia could switch it to a high ROS producing state, which persists after the return to normal oxygen supply. This prediction, which we qualitatively validated experimentally, explains the mechanism of anoxia-induced cell damage. Recognition of bistability of complex III operation may enable novel therapeutic strategies for oxidative stress and our method of modeling could be widely used in systems biology studies.

Project description:Microorganisms during aerobic fermentation Raw sequence reads

Project description:Microorganisms during aerobic fermentation Raw sequence reads

Project description:Oxidative phosphorylation (OXPHOS) is essential for the synthesis of the vast majority of ATP in eukaryotic cells. It is carried out by multi-protein assemblies that form the electron transport chain (ETC), which are coupled to the mitochondrial ATP synthase, which uses the proton gradient generated by the ETC to drive ATP synthesis. The assembly of the OXPHOS protein machinery requires the coordinated integration of proteins encoded in the nuclear and the mitochondrial genomes, imposing an additional layer of complexity. While the biogenesis of the individual OXPHOS complexes is well understood, it remains unknown how the assembly of the ETC and ATP synthase is coordinated to achieve the correct stoichiometry of the OXPHOS machinery. Here, we identify the mitochondrial regulatory hub for respiratory assembly (MiRA), which serves as a platform on which complex IV and complex V biogenesis are synchronised to ensure balanced assembly of the ETC and complex V. At the molecular level, this is achieved by a stop-and-go safeguarding mechanism: The novel mitochondrial protein Mra1 binds to and slows down complex IV assembly. Two Go signals are then required for assembly to proceed: Binding of the complex IV assembly factor Rcf2 and interaction with the mitoribosome, which translates the complex V subunit Atp9. Both Go signals induce the clipping and subsequent degradation of Mra1, relieving the molecular brake and allowing parallel maturation of complexes IV and V. The absence of the stop-and-go safety mechanism results in the formation of immature complexes, decreased ATP levels and reduced cell viability. The antagonistic activities at MiRA provide a regulated orchestration of complex IV and V assembly which is essential to avoid the predominance of either complex and an unbalanced ratio of OXPHOS complexes, thus ensuring the correct stoichiometry of protein machineries encoded by two different genomes.

Project description:Oxidative phosphorylation (OXPHOS) is essential for the synthesis of the vast majority of ATP in eukaryotic cells. It is carried out by multi-protein assemblies that form the electron transport chain (ETC), which are coupled to the mitochondrial ATP synthase, which uses the proton gradient generated by the ETC to drive ATP synthesis. The assembly of the OXPHOS protein machinery requires the coordinated integration of proteins encoded in the nuclear and the mitochondrial genomes, imposing an additional layer of complexity. While the biogenesis of the individual OXPHOS complexes is well understood, it remains unknown how the assembly of the ETC and ATP synthase is coordinated to achieve the correct stoichiometry of the OXPHOS machinery. Here, we identify the mitochondrial regulatory hub for respiratory assembly (MiRA), which serves as a platform on which complex IV and complex V biogenesis are synchronised to ensure balanced assembly of the ETC and complex V. At the molecular level, this is achieved by a stop-and-go safeguarding mechanism: The novel mitochondrial protein Mra1 binds to and slows down complex IV assembly. Two Go signals are then required for assembly to proceed: Binding of the complex IV assembly factor Rcf2 and interaction with the mitoribosome, which translates the complex V subunit Atp9. Both Go signals induce the clipping and subsequent degradation of Mra1, relieving the molecular brake and allowing parallel maturation of complexes IV and V. The absence of the stop-and-go safety mechanism results in the formation of immature complexes, decreased ATP levels and reduced cell viability. The antagonistic activities at MiRA provide a regulated orchestration of complex IV and V assembly which is essential to avoid the predominance of either complex and an unbalanced ratio of OXPHOS complexes, thus ensuring the correct stoichiometry of protein machineries encoded by two different genomes.

Project description:Oxidative phosphorylation (OXPHOS) is essential for the synthesis of the vast majority of ATP in eukaryotic cells. It is carried out by multi-protein assemblies that form the electron transport chain (ETC), which are coupled to the mitochondrial ATP synthase, which uses the proton gradient generated by the ETC to drive ATP synthesis. The assembly of the OXPHOS protein machinery requires the coordinated integration of proteins encoded in the nuclear and the mitochondrial genomes, imposing an additional layer of complexity. While the biogenesis of the individual OXPHOS complexes is well understood, it remains unknown how the assembly of the ETC and ATP synthase is coordinated to achieve the correct stoichiometry of the OXPHOS machinery. Here, we identify the mitochondrial regulatory hub for respiratory assembly (MiRA), which serves as a platform on which complex IV and complex V biogenesis are synchronised to ensure balanced assembly of the ETC and complex V. At the molecular level, this is achieved by a stop-and-go safeguarding mechanism: The novel mitochondrial protein Mra1 binds to and slows down complex IV assembly. Two Go signals are then required for assembly to proceed: Binding of the complex IV assembly factor Rcf2 and interaction with the mitoribosome, which translates the complex V subunit Atp9. Both Go signals induce the clipping and subsequent degradation of Mra1, relieving the molecular break and allowing parallel maturation of complexes IV and V. The absence of the stop-and-go safety mechanism results in the formation of immature complexes, decreased ATP levels and reduced cell viability. The antagonistic activities at MiRA provide a regulated orchestration of complex IV and V assembly which is essential to avoid the predominance of either complex and an unbalanced ratio of OXPHOS complexes, thus ensuring the correct stoichiometry of protein machineries encoded by two different genomes.