Project description:Pancreatic ductal adenocarcinoma (PDAC) is one of the most intractable malignancies and systematic chemotherapies are the most commonly-used standard treatment for PDAC patients diagonosed at advanced stages. However, drug resistance may arise as early as several weeks after chemotherapy initiation, thus limiting the therapeutic efficacy of chemotherapy reagents. Accumulating evidence has demonstrated that acquired tolerance to apoptotic cell death induced by cytotoxic drugs is one of the critical reasons for the failure of chemotherapy. Ferroptosis was originally identified as a unique form of programmed cell death, which is characterized by shrunk mitochondria accompanied with condensed membranes and decreased crista, in drug screens searching for small molecules that can selectively kill RAS-expressing cancer cells. Unlike apoptosis, ferroptosis is driven by iron-catalyzed excessive lipid peroxidation, ultimately leading to the rupture of plasma membrane and cell death. Recent studies indicated that ferroptosis induction can be a promising therapeutic strategy in cancer treatment since it not only can kill tumor cells directly but also can synergize with chemotherapy ,radiotherapy,targeted therapy and immunotherapy. However, transformed malignant cells can acquired resistance to ferroptosis through adaptative changes in their epigenome, genome, transcriptome, translatome or proteome. Multiple mechanisms, such as decreased coenzyme Q10 production mediated by the upregulation of apoptosis-inducing factor mitochondria-associated 2 (AIFM2/FSP1) and elevated expression of cytoprotective genes as a result of the activation of antioxidant transcription factor NFE2L2/NRF2 (nuclear factor erythroid 2-like 2), have been demonstrated to confer ferroptosis resistance. However, transformed malignant cells can acquired resistance to ferroptosis through adaptative changes in their epigenome, genome, transcriptome, translatome or proteome. Multiple mechanisms, such as decreased coenzyme Q10 production mediated by the upregulation of apoptosis-inducing factor mitochondria-associated 2 (AIFM2/FSP1) and elevated expression of cytoprotective genes as a result of the activation of antioxidant transcription factor NFE2L2/NRF2 (nuclear factor erythroid 2-like 2), have been demonstrated to confer ferroptosis resistance. Therefore, unravelling the underlying mechanisms responsible for reduced sensitivity to ferroptosis inducers, such as erastin or RSL3, may pave the way for designing effective therapeutic regimens for PDAC patients.

Project description:Coenzyme Q (or ubiquinone) is a redox-active lipid, which serves as universal electron carrier in the mitochondrial respiratory chain and antioxidant in the plasma membrane limiting lipid peroxidation and ferroptosis. Mechanisms allowing cellular coenzyme Q distribution after synthesis within mitochondria are not understood. Here, we identify the cytosolic lipid transfer protein STARD7 as a critical and limiting factor of intracellular coenzyme Q transport. Dual localization of STARD7 to the intermembrane space of mitochondria and the cytosol upon cleavage by the rhomboid protease PARL ensures the synthesis of coenzyme Q in mitochondria and its transport to the plasma membrane. While cytosolic STARD7 overexpression protects against ferroptosis, it limits CoQ abundance in mitochondria and respiratory cell growth, illustrating the need to coordinate CoQ synthesis and cellular distribution by PARL-mediated STARD7 processing. Our findings highlight the antioxidant function of mitochondrial CoQ against ferroptosis and identify PARL and STARD7 as promising targets to interfere with ferroptosis. The repository contains raw files and methods for project 0112 (brain – whole proteomics) and 0176 (spatial proteomics). The labeling of the raw files and the experiment – raw file matches are available in the individual search zip files. The individual sections are accompanied with the project identifier.

Project description:Coenzyme Q10 deficiency syndrome includes a clinically heterogeneous group of mitochondrial diseases characterized by low content of CoQ10 in tissues. The only currently available treatment is supplementation with CoQ10, which improves the clinical phenotype in some patients but does not reverse established damage. Incubation with CoQ10 restored respiration and apoptotic pathways but did not affect lipid metabolism, cell growth, and undifferentiated phenotype presented by CoQ10 deficient cells. We conclude that the mitochondrial dysfunction caused byCoQ10 deficiency induces a stable survival adaptation of somatic cells from patients, thus explaining their incomplete recovery after treatment. We compared the gene expresion of human dermal fibroblast from healthy people (group 1) with fibroblast from diferent patient diagnosed with the human syndrome of coenzyme Q10 deficiency, which were treated (group 3) or not (group 2) with coenzyme Q10 to recovery ATP levels.

Project description:We conducted a proteomic interactome analysis of well-known regulators of ferroptosis, ACSL4, LPCAT3, ALOX12, ALOX15, PEBP1, NCOA4, GCH1, FSP1, DHODH, SLC7A11, GCLC, GCLM, GSS, and GPX4. Take LPCAT3 as an example, we uncovered an opposing role of its binding protein CEPT1 in suppressing ferroptosis.

Project description:Coenzyme Q10 (CoQ10) is an obligatory element in the respiratory chain and functions as a potent antioxidant of lipid membranes. More recently, anti-inflammatory effects as well as an impact of CoQ10 on gene expression have been observed. To reveal putative effects of Q10 on LPS-induced gene expression, whole genome expression analysis was performed in the monocytic cell line THP-1. 1129 probe sets have been identified to be significantly up-regulated (p < 0.05) in LPS-treated cells when compared to controls. Text mining analysis of the top 50 LPS up-regulated genes revealed a functional connection in the NFκB pathway and confirmed our applied in vitro stimulation model. Moreover, 33 LPS-sensitive genes have been identified to be significantly down-regulated by Q10-treatment between a factor of 1.32 and 1.85. GeneOntology (GO) analysis revealed for the Q10-sensitve genes a primary involvement in protein metabolism, cell proliferation and transcriptional processes. Three genes were either related to NFκB transcription factor activity, cytokinesis or modulation of oxidative stress. In conclusion, our data provide evidence that Q10 down-regulates LPS-inducible genes in the monocytic cell line THP-1. Thus, the previously described effects of Q10 on the reduction of pro-inflammatory mediators might be due to its impact on gene expression. Whole genome expression profiles were analysed from monocytes pre-incubated with ubiquinone (Q10) before subsequent stimulation with LPS. Stimulated (+LPS) and unstimulated (-LPS) monocytes were used as positive and negative controls, respectively. For every experimental group (3 groups in total), three Affymetrix Human Genome U133 Plus 2.0 arrays were used, thus resulting in the analysis of 9 microarrays.

Project description:Coenzyme Q10 (CoQ10) is an obligatory element in the respiratory chain and functions as a potent antioxidant of lipid membranes. More recently, anti-inflammatory effects as well as an impact of CoQ10 on gene expression have been observed. To reveal putative effects of Q10 on LPS-induced gene expression, whole genome expression analysis was performed in the monocytic cell line THP-1. 1129 probe sets have been identified to be significantly up-regulated (p < 0.05) in LPS-treated cells when compared to controls. Text mining analysis of the top 50 LPS up-regulated genes revealed a functional connection in the NFκB pathway and confirmed our applied in vitro stimulation model. Moreover, 33 LPS-sensitive genes have been identified to be significantly down-regulated by Q10-treatment between a factor of 1.32 and 1.85. GeneOntology (GO) analysis revealed for the Q10-sensitve genes a primary involvement in protein metabolism, cell proliferation and transcriptional processes. Three genes were either related to NFκB transcription factor activity, cytokinesis or modulation of oxidative stress. In conclusion, our data provide evidence that Q10 down-regulates LPS-inducible genes in the monocytic cell line THP-1. Thus, the previously described effects of Q10 on the reduction of pro-inflammatory mediators might be due to its impact on gene expression.

Project description:Coenzyme Q10 deficiency syndrome includes a clinically heterogeneous group of mitochondrial diseases characterized by low content of CoQ10 in tissues. The only currently available treatment is supplementation with CoQ10, which improves the clinical phenotype in some patients but does not reverse established damage. We analyzed the transcriptome profiles of fibroblasts from different patients irrespective of the genetic origin of the disease. These cells showed a survival genetic profile apt at maintaining growth and undifferentiated phenotype, promoting anti-apoptotic pathways, and favoring bioenergetics supported by glycolysis and low lipid metabolism. WE conclude that the mitochondrial dysfunction caused byCoQ10 deficiency induces a stable survival adaptation of somatic cells from patients. All samples in triplicate. We compare the gene expresion of human derman fibroblast to fibroblast from 4 different patient diagnosed with the human syndrome of coenzyme Q10 deficiency.

Project description:Coenzyme Q10 in Huntington’s Disease (2CARE)

Project description:Coenzyme Q10 in Huntington’s Disease (2CARE)

Project description:We explored the possibility that the cAMP/PKA pathway affects the expression of the genes involved in Coenzyme Q10 synthesis and other related metabolic pathways. To that end, we performed microarray analyses on Δpka1, Δcgs1, and Δppt1 strains. An article under submission