Long-read sequencing reveals atypical mitochondrial genome structure in a New Zealand marine isopod

Most animal mitochondrial genomes are small, circular and structurally conserved. However, recent work indicates that diverse taxa possess unusual mitochondrial genomes. In Isopoda , species in multiple lineages have atypical and rearranged mitochondrial genomes. However, more species of this speciose taxon need to be evaluated to understand the evolutionary origins of atypical mitochondrial genomes in this group. In this study, we report the presence of an atypical mitochondrial structure in the New Zealand endemic marine isopod, Isocladus armatus. Data from long- and short-read DNA sequencing suggest that I. armatus has two mitochondrial chromosomes. The first chromosome consists of two mitochondrial genomes that have been inverted and fused together in a circular form, and the second chromosome consists of a single mitochondrial genome in a linearized form. This atypical mitochondrial structure has been detected in other isopod lineages, and our data from an additional divergent isopod lineage (Sphaeromatidae) lends support to the hypothesis that atypical structure evolved early in the evolution of Isopoda . Additionally, we find that an asymmetrical site previously observed across many species within Isopoda is absent in I. armatus , but confirm the presence of two asymmetrical sites recently reported in two other isopod species.

Role of Mitochondria in Physiology of Chondrocytes and Diseases of Osteoarthritis and Rheumatoid Arthritis

Purpose of Review Mitochondria are recognized to be one of the most important organelles in chondrocytes for their role in triphosphate (ATP) generation through aerobic phosphorylation. Mitochondria also participate in many intracellular processes involving modulating reactive oxygen species (ROS), responding to instantaneous hypoxia stress, regulating cytoplasmic transport of calcium ion, and directing mitophagy to maintain the homeostasis of individual chondrocytes. Designs To summarize the specific role of mitochondria in chondrocytes, we screened related papers in PubMed database and the search strategy is ((mitochondria) AND (chondrocyte)) AND (English [Language]). The articles published in the past 5 years were included and 130 papers were studied. Results In recent years, the integrity of mitochondrial structure has been regarded as a prerequisite for normal chondrocyte survival and defect in mitochondrial function has been found in cartilage-related diseases, such as osteoarthritis (OA) and rheumatoid arthritis (RA). However, the understanding of mitochondria in cartilage is still largely limited. The mechanism on how the changes in mitochondrial structure and function directly lead to the occurrence and development of cartilage-related diseases remains to be elusive. Conclusion This review aims to summarize the role of mitochondria in chondrocytes under the physiological and pathological changes from ATP generation, calcium homeostasis, redox regulation, mitophagy modulation, mitochondria biogenesis to immune response activation. The enhanced understanding of molecular mechanisms in mitochondria might offer some new cues for cartilage remodeling and pathological intervention.

Aflatoxin and Disruption of Energy Metabolism

Aflatoxins constitute a cluster of mycotoxins that are derived from fungal metabolites and are produced from diverse fungi species, especially Aspergillus. They are a collection of closely linked heterocyclic compounds produced predominantly by two filamentous fungi, Aspergillus flavus and Aspergillus parasiticus. They are also known to cause severe health threats to humans and animals, thereby resulting to several complications like immunotoxicity, teratogenicity hepatotoxicity. Aflatoxins interfere with normal metabolic processes. This interference encompasses the regulatory processes that occur throughout the progression of energy metabolism. Thus, the effects of aflatoxins are seen in the inhibition of ATP generation, carbohydrate and lipid metabolism, mitochondrial structure and proteins synthesis. This chapter will focus on the mechanisms of aflatoxin-induced disruption of lipids, carbohydrates, and proteins metabolism, and how they affect the bioenergetic systems.

TRAP1 inhibits MIC60 ubiquitination to mitigate the injury of cardiomyocytes and protect mitochondria in extracellular acidosis

Extracellular acidosis-induced mitochondrial damage of cardiomyocytes leads to cardiac dysfunction, but no detailed mechanism or efficient therapeutic target has been reported. Here we found that the protein levels of MIC60 were decreased in H9C2 cells and heart tissues in extracellular acidosis, which caused mitochondrial damage and cardiac dysfunction. Overexpression of MIC60 maintains H9C2 cells viability, increases ATP production and mitochondrial membrane potential, mitigates the disruptions of mitochondrial structure and cardiac injury. Mechanistically, extracellular acidosis excessively promoted MIC60 ubiquitin-dependent degradation. TRAP1 mitigated acidosis-induced mitochondrial impairments and cardiac injury by directly interacting with MIC60 to decrease its ubiquitin-dependent degradation in extracellular acidosis.

Perillaldehyde improves cognitive function in vivo and in vitro by inhibiting neuronal damage via blocking TRPM2/NMDAR pathway

Background Vascular cognitive dysfunction in patients with vascular dementia (VD) is a kind of severe cognitive dysfunction syndrome caused by cerebrovascular diseases. At present, effective drugs to improve the cognitive function of VD patients still need to be explored. Transient Receptor Potential Melastatin 2 (TRPM2) channel is a nonspecific cation channel that plays a key role in the toxic death of neurons. Perillaldehyde (PAE) has the protective effect of epilepsy and insomnia and other central nervous system diseases. The aim of this study is to explore whether PAE improves cognitive function in VD rats and to investigate the potential mechanisms in vivo and vitro. Methods VD rats were induced by bilateral common carotid arteries occlusion (2-vessel occlusion [2VO]) and treated with PAE for 4 weeks. The neuroprotective effects of PAE was subsequently assessed by the Morris water maze, hematoxylin–eosin (HE) staining, Golgi staining, electron microscopy, Neuron-specific nuclear protein (Neu N) staining, and TdT-mediated dUTP nick end labeling (TUNEL) staining. After primary hippocampal neurons were isolated, cell viability was detected by MTT assay and intracellular Ca2+ concentration was detected by calcium imaging assay. The content of Nitriteoxide (NO), Malondialdehyde (MDA) and Superoxide dismutase (SOD) activity in serum of rats were observed by Enzyme Linked Immunosorbent Assay (ELISA). Immunohistochemistry, Western blot, and Confocal laser scanning were used to detect the expression levels of N-methyl-d-asprtate receptor-2B (NR2B) and TRPM2. Results The results showed that PAE can improve the number and activity of neurons, increase the length and number of dendrites in hippocampus, decrease the Vv value and PE value of neuronal nucleus and mitochondrial structure significantly, increase the s value and L value in nucleus structure, decrease the s value and L value in mitochondrial structure, and improve the learning and memory ability of rats significantly. And PAE can strengthen the ability of antioxidant stress confirmed by increasing the activity of SOD and reducing the production of MDA. The results of western blot, immunohistochemistry and immunofluorescence showed that PAE could reduce the level of TRPM2 and increase the expression of NR2B. Conclusions Taken together, our findings provide evidence that the neuroprotective effects of PAE in VD rats maybe through TRPM2 inhibition and subsequent activation of NMDAR signaling pathway.

Iron Overload, Oxidative Stress, and Ferroptosis in the Failing Heart and Liver

Iron accumulation is a key mediator of several cytotoxic mechanisms leading to the impairment of redox homeostasis and cellular death. Iron overload is often associated with haematological diseases which require regular blood transfusion/phlebotomy, and it represents a common complication in thalassaemic patients. Major damages predominantly occur in the liver and the heart, leading to a specific form of cell death recently named ferroptosis. Different from apoptosis, necrosis, and autophagy, ferroptosis is strictly dependent on iron and reactive oxygen species, with a dysregulation of mitochondrial structure/function. Susceptibility to ferroptosis is dependent on intracellular antioxidant capacity and varies according to the different cell types. Chemotherapy-induced cardiotoxicity has been proven to be mediated predominantly by iron accumulation and ferroptosis, whereas there is evidence about the role of ferritin in protecting cardiomyocytes from ferroptosis and consequent heart failure. Another paradigmatic organ for transfusion-associated complication due to iron overload is the liver, in which the role of ferroptosis is yet to be elucidated. Some studies report a role of ferroptosis in the initiation of hepatic inflammation processes while others provide evidence about an involvement in several pathologies including immune-related hepatitis and acute liver failure. In this manuscript, we aim to review the literature to address putative common features between the response to ferroptosis in the heart and liver. A better comprehension of (dys)similarities is pivotal for the development of future therapeutic strategies that can be designed to specifically target this type of cell death in an attempt to minimize iron-overload effects in specific organs.

Metabolic Changes in Venetoclax Resistance Are Determined By Differentiation State in T-Cell Acute Lymphoblastic Leukemia

T-cell acute lymphoblastic leukaemia (T-ALL) is an aggressive hematologic malignancy arising from the transformation of immune T-cell lymphocytes. Early T-cell progenitor (ETP-ALL) is a subgroup particularly associated with chemoresistance and a high risk for relapse. Recently, it was shown that ETP-ALL is dependent on the expression of the anti-apoptotic protein BCL-2, and is sensitive to inhibition with ABT-199, a BCL-2 specific BH3 mimetic 1,2. However, one issue with a targeted agent, such as ABT-199, is the development of acquired resistance. Interestingly, there have been numerous high impact papers connecting ABT-199 resistance to altered oxidative phosphorylation (OXPHOS) 3,4. While there are relatively few studies into T-ALL metabolism, there is evidence that aerobic glycolysis, the conversion of glucose to lactate, is greater in proliferating T-cells than in T-ALL and that NOTCH signalling can drive mitochondrial OXPHOS 5. A recent study showed that the transcription factor RUNX2 altered T-ALL metabolism, increasing both glycolysis and OXPHOS and enhancing leukemic cell migration 6. However, there has been relatively little research into the metabolic profile of T-ALL at distinct stages of differentiation. The aim of this study was to determine the role of ABT-199 resistance in altering metabolism and determine if that was due to the differentiation state of the T-ALL. ABT-199 R LOUCY cells were generated by chronic exposure to increasing concentrations of ABT-199 administered every two days. The EZH2 KO Jurkat cell lines were previously generated through CRISPR-Cas9 engineering 7. In order to assess the metabolic profile, cells were attached to a 96 well plate using CellTak and the extracellular acidification rate (ECAR) and oxidative phosphorylation (OXPHOS) was measured on a Seahorse Bioscience XF96 Extracellular Flux Analyzer. Anti-apoptotic dependence was measured using BH3 profiling and cell death by Annexin V/propidium iodide staining. The mitochondrial structure was visualized using transmission electron microscopy. Previously, we generated ABT-199 resistant ETP-ALL LOUCY cells (ABT-199 R) following continuous exposure to ABT-199 over a prolonged period of several months 8. The ABT-199 R cells showed dependence on BCL-XL for survival and sensitivity to the BCL-XL inhibitor WEHI 539. The ABT-199 R cells showed evidence of differentiation to a more mature T-cell. The ABT-199 R cells had increased surface CD3 (sCD3) expression and CD1A expression, along with increased expression of TAL1 and LMO2 genes compared to parental LOUCY cells. Interestingly, the ABT-199 R cells showed enhanced basal respiration, ATP production and max respiration compared to the parental cells. Indeed, analysis of the expression of OXPHOS complexes showed increased expression of complexes I-IV in the ABT-199 R cells, compared to the parental controls. Indeed, the parental LOUCY cells appeared to have reduced cristae number and length compared to the ABT-199R cells. Next, we assessed if inhibiting OXPHOS with a series of inhibitors (oligomycin, rotenone, antimycin) could sensitize the ABT-199 R LOUCY cells to ABT-199. However, we did not detect any changes to sensitivity of ABT-199. This led us to hypothesize that perhaps the changes in OXPHOS were due differentiation state of the LOUCY cells. We confirmed that more typical T-ALL cell lines (JURKAT and CEM-CCRF) had higher OXPHOS than the ETP-ALL cell line LOUCY and had higher expression of the OXPHOS complexes I-IV by Western blotting. To assess if de-differentiation of a more typical T-ALL cell line would cause a reduction in OXPHOS we turned to the EZH2 knockout (K/O) Jurkat cells 7. We found that EZH2 KO2 showed a reduction in the differentiation markers CD1A and CD3 on the cell surface and TAL1 gene expression, compared to WT control Jurkats. Next, we assessed the OXPHOS and found that the de-differentiated EZH2 cells had reduced OXPHOS compared to the parental controls, with altered mitochondrial structure. Suggesting, that de-differentiation of typical T-ALL cell line reduces OXPHOS. In this study we show that metabolic phenotype is linked to the maturation stage of T-ALL. We believe that the altered metabolism identified in ABT-199 resistance is linked to the selection of a more mature cell type. Highlighting, that altered metabolism may not be a driver of resistance to ABT-199 but a consequence of the maturation stage of the resistant cell. Disclosures Di Grande: Novartis: Current Employment. Leon: BenevolentAI: Current Employment. Mansour: Astellas: Consultancy, Honoraria; Janssen: Consultancy. Bond: Haematology Association of Ireland Award funded by Novartis: Research Funding. Ni Chonghaile: AbbVie: Research Funding.