Project description:<p>Mitochondrial metabolic remodeling is a hallmark of the Trypanosoma brucei digenetic life cycle since the insect stage utilizes the cost-effective oxidative phosphorylation to generate ATP, while bloodstream cells switch to less energetically efficient aerobic glycolysis. Due to difficulties in acquiring enough parasites from the tsetse fly vector for biochemical analysis, the dynamics of the parasite´s mitochondrial metabolic rewiring in the vector have remained obscure. Here, we took advantage of in vitro-induced differentiation to follow changes at the RNA, protein and metabolite levels. This multi-omics and cell-based profiling showed an immediate redirection of electron flow from the cytochrome mediated pathway to a mitochondrial alternative oxidase, an increase in proline consumption and its oxidation, elevated activity of complex II and certain TCA cycle enzymes, which led to mitochondrial inner membrane hyperpolarization and increased ROS levels in both mitochondrion and cytosol. Interestingly, these ROS molecules acted as signaling molecules driving developmental progression since exogenous expression of catalase, a ROS scavenger, halted the in vitro-induced cell differentiation. Our results provide insights into the mechanisms of the parasite´s mitochondrial rewiring and reinforce the emerging concept that mitochondria act as signaling organelles through release of ROS to drive cellular differentiation.</p><p><br></p><p><strong>Data availability:</strong></p><p><a href='https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?&amp;acc=GSE140796' rel='noopener noreferrer' target='_blank'>RNA-Seq</a></p><p>Proteomic data associated with this study are available in the PRIDE repository: accession number <a href='https://www.ebi.ac.uk/pride/archive/projects/PXD016370' rel='noopener noreferrer' target='_blank'>PXD016370</a>.</p>

Project description:Mitochondrial metabolic remodeling is a hallmark of the Trypanosoma brucei digenetic life cycle since the insect stage utilizes the cost-effective oxidative phosphorylation to generate ATP, while bloodstream cells switch to less energetically efficient aerobic glycolysis. Due to difficulties in acquiring enough parasites from the tsetse fly vector for biochemical analysis, the dynamics of the parasite´s mitochondrial metabolic rewiring in the vector have remained obscure. Here, we took advantage of in vitro-induced differentiation to follow changes at the RNA levels.

Project description:We studied dynamics within mitochondrial complexes in MEFs from CLPP-/- and wildtype mice.

Project description:sample collection protocol:We used FACS to separate the E14.5 neocortical cells into high mitochondrial reactive oxygen species (mtROS) and low mitochondrial ROS cell populations and compared their expression profiles. Transition of progenitors through progressive stages of differentiation probably involves dynamic changes in mtROS levels, depending on the needs of the cell. We found that the progenitors had higher levels of mtROS, but these levels significantly decreased with differentiation.

Project description:FBXW7 modulates stress response by post-translational modification of HSF1 HSF1 orchestrates the heat-shock response upon exposure to heat stress and activates a transcriptional program vital for cancer cells. In this study we assayed for genome-wide localization of HSF1 enrichment in the HCT116 FBXW7 KO colon cells and their wild type counterpart in untreated cells and upon heat shock. These results revealed that accumulation of nuclear HSF1 in FBXW7 KO cells results in rewiring of the HSF1 transcriptional program. Five million cells were used for the ChIP and precipitated using 5 micrograms of antibody (cell signaling, 4356) against human HSF1

Project description:The aerobic yeast Yarrowia lipolytica is an established model organism to study mitochondrial protein complexes. Here we performed a complexome analysis of intact mitochondria to study the function of NDUFAF1 in the assembly of respiratory complex I. In the ndufaf1 deletion strain the PD module of the membrane arm accumulated but mature complex I was virtually absent.

Project description:Stem cells are uniquely dependent on both oxidative phosphorylation and glycolysis to maintain pluripotency and drive differentiation. Here, we identified that stem cells sorted by their inherent differences in mitochondrial activity exhibited significantly altered germline differentiation potential. Stem cells with lower average mitochondrial membrane potential were less proliferative and generated less ROS and ATP despite having a similar mitochondrial DNA copy number as cells with higher membrane potential. We demonstrate that pluripotent stem cells exhibit a large range of mitochondrial activity from an otherwise homogenous population, and that they are dependent on this activity to drive differentiation.

Project description:We use adaptive laboratory evolution to generate strains which tolerate high levels of the redox cycling compound paraquat, which produces reactive oxygen species (ROS). We combine resequencing, iModulon analysis of the transcripome, and metabolic models to elucidate six interacting stress tolerance mechanisms: 1) modification of transport, 2) activation of ROS stress responses, 3) use of ROS-sensitive iron regulation, 4) motility, 5) broad transcriptional reallocation toward growth, and 6) metabolic rewiring to decrease NADH production. This work thus reveals the genome-scale systems biology of ROS tolerance.

Project description:Single cell RNA-seq analysis of Mitochondrial ROS low CD34+ cells and Mitochondrial ROS high CD34+ cells

Project description:Neurodegeneration in mitochondrial disorders is considered irreversible because of limited metabolic plasticity in neurons, yet the cell-autonomous implications of mitochondrial dysfunction for neuronal metabolism in vivo are poorly understood. Here, we profiled the cell-specific proteome of Purkinje neurons undergoing progressive OXPHOS deficiency caused by disrupted mitochondria fusion dynamics. We found that mitochondrial dysfunction triggers a profound rewiring of the proteomic landscape culminating in the sequential activation of precise metabolic programs preceding cell death. Surprisingly, we identified a marked induction of pyruvate carboxylase (PCx) and other key anaplerotic enzymes involved in replenishing intermediates into the TCA cycle. Suppression of PCx aggravated neurodegeneration, showing that anaplerosis is protective in OXPHOS-deficient neurons. Restoration of mitochondrial fusion in end-stage degenerating neurons fully reversed these metabolic hallmarks thereby preventing cell death. Our findings identify a previously unappreciated pathway conferring resilience to mitochondrial dysfunction and show that neurodegeneration can be reversed even at advanced disease stages.