SUMMARY The sirtuin gene family (SIRT) is hypothesized to regulate the aging process and play a role in cellular repair. This work demonstrates that SIRT3−/− mouse embryonic fibroblasts (MEFs) exhibit abnormal mitochondrial physiology as well as increases in stress-induced superoxide levels and genomic instability. Expression of a single oncogene (Myc or Ras) in SIRT3−/− MEFs results in in vitro transformation and altered intracellular metabolism. Superoxide dismutase prevents transformation by a single oncogene in SIRT3−/− MEFs and reverses the tumor permissive phenotype as well as stress-induced genomic instability. In addition, SIRT3−/− mice develop ER/PR-positive mammary tumors. Finally, human breast and other human cancer specimens exhibit reduced SIRT3 levels. These results identify SIRT3 as a genomically expressed, mitochondrial localized tumor suppressor.
The FALCOR rate calculator is currently accessible at http://www.mitochondria.org/protocols/FALCOR.html. This program is written as a Java Applet, requiring a web browser enabled with Sun MicroSystems' Java Virtual Machine.
Because of the ongoing pandemic around the world, the mechanisms underlying the SARS-CoV-2-induced COVID-19 are subject to intense investigation. Based on available data for the SARS-CoV-1 virus, we suggest how CoV-2 localization of RNA transcripts in mitochondria hijacks the host cell’s mitochondrial function to viral advantage. Besides viral RNA transcripts, RNA also localizes to mitochondria. SARS-CoV-2 may manipulate mitochondrial function indirectly, first by ACE2 regulation of mitochondrial function, and once it enters the host cell, open-reading frames (ORFs) such as ORF-9b can directly manipulate mitochondrial function to evade host cell immunity and facilitate virus replication and COVID-19 disease. Manipulations of host mitochondria by viral ORFs can release mitochondrial DNA (mtDNA) in the cytoplasm and activate mtDNA-induced inflammasome and suppress innate and adaptive immunity. We argue that a decline in ACE2 function in aged individuals, coupled with the age-associated decline in mitochondrial functions resulting in chronic metabolic disorders like diabetes or cancer, may make the host more vulnerable to infection and health complications to mortality. These observations suggest that distinct localization of viral RNA and proteins in mitochondria must play essential roles in SARS-CoV-2 pathogenesis. Understanding the mechanisms underlying virus communication with host mitochondria may provide critical insights into COVID-19 pathologies. An investigation into the SARS-CoV-2 hijacking of mitochondria should lead to novel approaches to prevent and treat COVID-19.
Highlights Mitochondria are the hub of cellular oxidative homeostasis. Mitochondria are the major source of reactive oxygen species (ROS). Extracellular mitochondria are found in blood, in circulating platelets and vesicles. COVID-19 pathogenesis is aggravated by the hyper- inflammatory state. Inflammation activates events leading to microbiota & mitochondrial oxidative damage. Mitochondrial damage contributes to coagulopathy, ferroptosis & microbial dysbiosis. Blood & platelet mitochondria dysfunction may accelerate systemic coagulopathy events. Targeting mitochondria dysfunction may provide useful therapeutic strategies against COVID-19 pathogenesis.
The human MutY homolog (hMYH) is a DNA glycosylase involved in the removal of adenines or 2-hydroxyadenines misincorporated with template guanines or 7,8-dihydro-8-oxodeoxyguanines. hMYH is associated in vivo with apurinic/apyrimidinic endonuclease (APE1), proliferating cell nuclear antigen (PCNA), and replication protein A (RPA) in HeLa nuclear extracts as shown by immunoprecipitation and Western blotting. However, binding of hMYH to DNA polymerases  and ␦ was not detected. By using constructs containing different portions of hMYH fused to glutathione S-transferase, we have demonstrated that the APE1-binding site is at a region around amino acid residue 300, that the PCNA binding activity is located at the C terminus, and that RPA binds to the N terminus of hMYH. A peptide consisting of residues 505-527 of hMYH that contains a conserved PCNA-binding motif binds PCNA, and subsequent amino acid substitution identified Phe-518 and Phe-519 as essential residues required for PCNA binding. RPA binds to a peptide that consists of residues 6 -32 of hMYH and contains a conserved RPA-binding motif. The PCNA-and RPA-binding sites of hMYH are further confirmed by peptide and antibody titration. These results suggest that hMYH repair is a long patch base excision repair pathway.
Reactive oxygen species (ROS) are known to be involved in many physiological and pathological processes. Initially ROS-producing NADPH oxidase (NOX) proteins were thought to be present in phagocytes. However, recent studies have demonstrated that NOX proteins are expressed in many other cell types and tissues. NOX family members' expression and function seems to vary from tissue to tissue. We determined the expression of the NOX family of proteins (NOX1-5) in normal breast tissue and breast tumors. Our study revealed that normal breast tissues express NOX1, 4 and 5 genes. Similar pattern of expression was revealed in a breast epithelial cell line. We found that NOX4 was overexpressed in the majority of breast cancer cell lines and primary breast tumors. NOX4 was also overexpressed in ovarian tumors. Overexpression of NOX4 in normal breast epithelial cells resulted in cellular senescence, resistance to apoptosis, and tumorigenic transformation. Overexpression of NOX4 in already transformed breast tumor cells also showed increased tumorigenicity. Strong evidence suggests that regulation of these processes occurs through NOX4 generation of ROS in the mitochondria. We demonstrate that the NOX4 protein contains a 73 amino acid long mitochondrial localization signal at the N-terminus that is capable of transporting a passenger protein GFP into the mitochondria. Treatment of NOX4 overexpressing cells with catalase resulted in decreased tumorigenic characteristics. Together, this study provides evidence for an oncogenic function for NOX4 protein localized to mitochondria and suggests that NOX4 is a novel source of ROS produced in the mitochondria. This study also identifies a possible treatment of NOX4-induced breast cancer by antioxidant treatment.
Reactive oxygen species (ROS) function as cellular switches for signaling cascade involved in cell growth, cell death, mitogenesis, angiogenesis and carcinogenesis. ROS are produced as a byproduct of oxidative phosphorylation (OXPHOS) in the mitochondria. It is estimated that 2-4% of the oxygen consumed during OXPHOS is converted to ROS. Besides mitochondria, NADPH-oxidase 1 (Nox1) also generates a significant amount of ROS in the cell. In this paper, we tested the hypothesis that mitochondria control Nox 1 redox signaling and the loss of control of this signaling contribute to tumorigenesis. We analyzed Nox1 expression in a mitochondrial gene knockout (ρ 0 ) cell line and in the isogenic cybrid cell line in which mitochondrial genes were restored by transfer of wild type mitochondria into ρ 0 cells. Our study revealed, for the first time, that the inactivation of mitochondrial genes leads to down-regulation of Nox1 and that the transfer of wild type mitochondrial genes restored the Nox1 expression to a level comparable to that in the parental cell line. Consistent with Nox1 down-regulation, we found that ρ 0 cells contained low levels of superoxide anion and that superoxide levels reversed to parental levels in cybrid cells when Nox1 expression was restored by transfer of wild type mitochondria. Increasing mitochondrial superoxide levels also increased the expression of Nox1 in parental cells. Confocal microscopy studies revealed that Nox1 localizes in the mitochondria. Nox1 was highly expressed in breast (86%) and ovarian (71%) tumors and that its expression positively correlated with expression of cytochrome C oxidase encoded by mtDNA. Our study, described in this paper demonstrates the existence of cross talk between the mitochondria and NADPH oxidase. Furthermore, our studies suggest that mitochondria control Nox1 redox signaling and the loss of control of this signaling contributes to breast and ovarian tumorigenesis.
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