Project description:Gene expression analysis of 2-month-old Ctrl and Tfam-SCKO mice. At this age mitochondrial function is disrupted in the Schwann cells of Tfam-SCKO mice ,but their nerves display only very limited pathology. Mitochondrial dysfunction is a common cause of peripheral neuropathy. Much effort has been devoted to examining the role played by neuronal/axonal mitochondria, but how mitochondrial deficits in peripheral nerve glia (Schwann cells, SCs) contribute to peripheral nerve diseases remains unclear. Here, we investigate a mouse model of peripheral neuropathy secondary to SC mitochondrial dysfunction (Tfam-SCKOs). We show that disruption of SC mitochondria activates a maladaptive integrated stress response through actions of heme-regulated inhibitor kinase (HRI), and causes a shift in lipid metabolism away from fatty acid synthesis toward oxidation. These alterations in SC lipid metabolism result in depletion of important myelin lipid components as well as in accumulation of acylcarnitines, an intermediate of fatty acid b-oxidation. Importantly, we show that acylcarnitines are released from SCs and induce axonal degeneration. A maladaptive integrated stress response as well as altered SC lipid metabolism are thus underlying pathological mechanisms in mitochondria-related peripheral neuropathies. Total RNA samples were prepared by isolating and pooling RNA from three different 2-month-old MPZ-Tfam KO and Ctrl mice. 2 replicates per genotype were used in this experiment and they were prepared entirely independently.

Project description:ChIP-seq data characterizing the occupancy of TFAM over the mitochondrial and nuclear genomes in HeLa cells. Characterization of mitochondrial and nuclear genome-wide TFAM binding in HeLa cells

Project description:The goal of this analysis was to utilize microarray profiling to identify basal alterations in gene expression in response to TFAM depletion and mtDNA stress. Mitochondrial DNA (mtDNA) is normally present at thousands of copies per cell and is packaged into several hundred higher-order structures termed nucleoids. The abundant mtDNA-binding protein, TFAM (transcription factor A,mitochondrial), regulates nucleoid architecture, abundance and segregation. Complete mtDNA depletion profoundly impairs oxidative phosphorylation, triggering calcium-dependent stress signalling and adaptive metabolic responses. However, the cellular responses to mtDNA instability, a physiologically relevant stress observed in many human diseases and ageing, remain poorly defined. Here we show that moderate mtDNA stress elicited by TFAM deficiency engages cytosolic antiviral signalling to enhance the expression of a subset of interferon-stimulated genes. Mechanistically, we find that aberrant mtDNA packaging promotes escape of mtDNA into the cytosol, where it engages the DNA sensor cGAS (also known as MB21D1) and promotes STING (also known as TMEM173)–IRF3-dependent signalling to elevate interferon-stimulated gene expression, potentiate type I interferon responses and confer broad viral resistance. Furthermore, we demonstrate that herpesviruses induce mtDNA stress, which enhances antiviral signalling and type I interferon responses during infection. Our results further demonstrate that mitochondria are central participants in innate immunity, identify mtDNA stress as a cell-intrinsic trigger of antiviral signaling and suggest that cellular monitoring of mtDNA homeostasis cooperates with canonical virus sensing mechanisms to fully engage antiviral innate immunity. Murine embryonic fibroblasts were isolated from wild-type or Tfam+/- E13.5 littermate embryos. RNA from passage-matched wild-type and Tfam+/- MEF lines was extracted in duplicate and hybridized onto Affymetrix microarrays. Four arrays were performed in total with two technical replicates per genotype.

Project description:Langerhans cells (LCs) are skin-resident professional antigen-presenting dendritic cells (DCs) to maintain skin homeostasis. The number and function of LCs are significantly reduced during the skin aging processes, which is closely related to the aging-associated skin disorders. However, the reasons underlying the changes of LC features with age are uncertain. Mitochondria are well known to be the main powerhouse to regulate cell fitness and function, and a decline in mitochondrial quality and activity was associated with normal aging and correlated with the development of a wide range of age-related diseases. So far, it is unknown if mitochondrial abnormality is involved in skin disorders by regulating LC homeostasis. The mitochondrial transcription factor A (Tfam) acts as a nuclear-encoded transcription factor and plays a critical role in mitochondrial stabilization. To explore the role of mitochondrial quality in LC homeostasis, we generated the mice with conditional deletion of Tfam in LC lineage. We found that Tfam-deficient LCs exhibits mitochondrial abnormality including morphology and membrane permeability of mitochondria, decreased cell number as well as maturation, whereas increased phagocytosis and inflammatory response of LCs. Interestingly, age-LCs from human skin have lower Tfam expression compared to young-LCs, and have the similar features with Tfam-deficient LCs analyzed by scRNA sequence (HRA000395). Thus, our data highlight that Tfam-mediated mitochondrial stability is essential for epidermal LC maintenance and function, which might be explain the states of increased susceptible to skin infections and rising incidence of cutaneous tumor in the elder. This is the first time to investigate the effect of mitochondria abnormality on LC homeostasis, which might be helpful for therapeutic interventions in aging-associated skin pathologies.

Project description:The developing erythroid cells require highly coordinated gene expression and metabolism. By comparing the proteomic and transcriptomic changes in human hematopoietic stem/progenitor cells (HSPCs) and lineage-committed erythroid progenitors (ProEs), and uncover pathways related to mitochondrial biogenesis enhanced through post-transcriptional regulation. Two principal mitochondrial factors TFAM and PHB2 are tightly regulated at the protein level and indispensable for mitochondria and erythropoiesis. Depletion of TFAM in erythroid cells alters intracellular metabolism, leading to elevated histone acetylation, deregulated gene expression, defective mitochondria function and erythropoiesis.

Project description:In this report, we showed that TFAM deficiency caused impaired AM mitochondrial fitness, altered metabolism and defective lipid catabolic responses, leading to diminished AM quantity and altered AM phenotypes. We demonstrated that TFAM deficiency did not impair AM differentiation from their precursors, but caused reduced AM maintenance. RNA-seq experiment revealed that TFAM deficiency caused impaired AM self-renewal capability. We showed that TFAM deficiency in AMs caused impaired clearance of respiratory debris, surfactant and enhanced susceptibility to severe influenza virus infection. Finally, we found that influenza infection resulted in disruption of TFAM-mediated mitochondrial fitness and metabolism in AMs.

Project description:The germinal centre (GC) reaction requires a unique bioenergetic supply. Although mitochondria are remodelled upon antigen stimulation, mitochondrial function in B cells is still poorly understood. To gain a better understanding of the role of mitochondria in B cell function, we generated a mice that lack, specifically in B cells, TFAM, a transcription factor necessary for mitochondrial biogenesis. TFAM knock-out (KO) mice displayed a blockage of the GC reaction and established an immune response featured by the differentiation of activated B cells towards memory B cells and aged-related B cells, hallmarks of an aged immune response. Unexpectedly, GC blockage in TFAM KO mice did not cause defects in the bioenergetic supply but this phenotype was associated with a defect in remodelling of the lysosomal compartment in B cells. Therefore, these results may describe a new mitochondrial function for antigen presentation during the GC reaction, the abrogation of which may be the basis of an aged immune response.

Project description:Objectives: The transcription factor TFAM is controlling the transcription of core proteins required for mitochondrial homeostasis. The aim of the current study was to investigate changes in TFAM expression in systemic sclerosis (SSc), to analyze mitochondrial function and to evaluate the consequences for fibroblast activation. Methods: The expression of TFAM was analyzed by immunofluorescence and Western blot. The effects of TFAM knockout were investigated in cultured fibroblasts and in bleomycin-induced skin and lung fibrosis and in TβRIact-induced skin fibrosis. Results: The expression of TFAM was downregulated in fibroblasts in SSc skin and in cultured SSc fibroblasts. The downregulation of TFAM was associated with decreased mitochondrial number and accumulation of damaged mitochondria with release of mtDNA, accumulation of deletions in mtDNA, metabolic alterations with impaired OXPHOS and release of the mitokine GDF15. Chronic, but not acute exposure of normal fibroblasts to TGFβ mimicked the finding in SSc fibroblasts with downregulation of TFAM and accumulation of mitochondrial damage. Downregulation of TFAM promotes fibroblast activation with upregulation of fibrosis-relevant GO-terms in RNASeq. Mice with fibroblast-specific knockout of TFAM are prone to fibrotic tissue remodeling with fibrotic responses even to NaCl instillation and enhanced sensitivity to bleomycin injection and TβRIact-overexpression. TFAM knockout fosters SMAD3 signaling to promote fibroblast activation. Conclusions: Alterations in the key mitochondrial transcription factor TFAM in response to prolonged activation of TGFβ and associated mitochondrial damage induce transcriptional programs that promote fibroblast-to-myofibroblast transition and drive tissue fibrosis.

Project description:The developing erythroid cells require highly coordinated gene expression and metabolism. By comparing the proteomic and transcriptomic changes in human hematopoietic stem/progenitor cells (HSPCs) and lineage-committed erythroid progenitors (ProEs), and uncover pathways related to mitochondrial biogenesis enhanced through post-transcriptional regulation. Two principal mitochondrial factors TFAM and PHB2 are tightly regulated at the protein level and indispensable for mitochondria and erythropoiesis. To determine the role of TFAM in mitochondrial function during erythroid development, we generated Tfam conditional knockout (KO) mice by an erythroid-specific EpoR-Cre allele. We isolated the CD71+Ter119+ embryonic day (E)13.5 fetal liver erythroid cells by FACS sorting, and performed RNA-seq transcriptional profiling analysis.

Project description:The developing erythroid cells require highly coordinated gene expression and metabolism. By comparing the proteomic and transcriptomic changes in human hematopoietic stem/progenitor cells (HSPCs) and lineage-committed erythroid progenitors (ProEs), and uncover pathways related to mitochondrial biogenesis enhanced through post-transcriptional regulation. Two principal mitochondrial factors TFAM and PHB2 are tightly regulated at the protein level and indispensable for mitochondria and erythropoiesis. To determine the role of TFAM and PHB2 in mitochondrial function during erythroid development, we employed shRNA-mediated depeltion of TFAM and PHB2 expression in differentiating erythroid cells, and performed RNA-seq transcriptional profiling analysis.