Your search keyword '"Tennant, DA"' showing total 6 results

1. Residual Complex I activity and amphidirectional Complex II operation support glutamate catabolism through mtSLP in anoxia.

Author

Ravasz D, Bui D, Nazarian S, Pallag G, Karnok N, Roberts J, Marzullo BP, Tennant DA, Greenwood B, Kitayev A, Hill C, Komlódi T, Doerrier C, Cunatova K, Fernandez-Vizarra E, Gnaiger E, Kiebish MA, Raska A, Kolev K, Czumbel B, Narain NR, Seyfried TN, and Chinopoulos C

Subjects

Humans, Electron Transport Complex I metabolism, Quinones metabolism, Oxidative Phosphorylation, Succinates metabolism, Hypoxia metabolism, Oxidation-Reduction, NAD metabolism, Mitochondria metabolism

Abstract

Anoxia halts oxidative phosphorylation (OXPHOS) causing an accumulation of reduced compounds in the mitochondrial matrix which impedes dehydrogenases. By simultaneously measuring oxygen concentration, NADH autofluorescence, mitochondrial membrane potential and ubiquinone reduction extent in isolated mitochondria in real-time, we demonstrate that Complex I utilized endogenous quinones to oxidize NADH under acute anoxia. 13 C metabolic tracing or untargeted analysis of metabolites extracted during anoxia in the presence or absence of site-specific inhibitors of the electron transfer system showed that NAD +  regenerated by Complex I is reduced by the 2-oxoglutarate dehydrogenase Complex yielding succinyl-CoA supporting mitochondrial substrate-level phosphorylation (mtSLP), releasing succinate. Complex II operated amphidirectionally during the anoxic event, providing quinones to Complex I and reducing fumarate to succinate. Our results highlight the importance of quinone provision to Complex I oxidizing NADH maintaining glutamate catabolism and mtSLP in the absence of OXPHOS., (© 2024. The Author(s).)

Published

2024

2. Metabolic adaptations to hypoxia in the neonatal mouse forebrain can occur independently of the transporters SLC7A5 and SLC3A2.

Author

Fitzgerald E, Roberts J, Tennant DA, Boardman JP, and Drake AJ

Subjects

Adaptation, Biological, Amino Acids, Branched-Chain metabolism, Animals, Animals, Newborn, Biological Transport, Carboxylic Acids pharmacology, Cell Hypoxia, Female, Fusion Regulatory Protein 1, Heavy Chain genetics, Gene Expression Regulation, Hypoxia genetics, Large Neutral Amino Acid-Transporter 1 genetics, Male, Mice, Inbred C57BL, Norbornanes pharmacology, Organ Culture Techniques, Prosencephalon drug effects, Mice, Fusion Regulatory Protein 1, Heavy Chain metabolism, Hypoxia metabolism, Large Neutral Amino Acid-Transporter 1 metabolism, Prosencephalon physiology

Abstract

Neonatal encephalopathy due to hypoxia-ischemia is associated with adverse neurodevelopmental effects. The involvement of branched chain amino acids (BCAAs) in this is largely unexplored. Transport of BCAAs at the plasma membrane is facilitated by SLC7A5/SLC3A2, which increase with hypoxia. We hypothesized that hypoxia would alter BCAA transport and metabolism in the neonatal brain. We investigated this using an organotypic forebrain slice culture model with, the SLC7A5/SLC3A2 inhibitor, 2-Amino-2-norbornanecarboxylic acid (BCH) under normoxic or hypoxic conditions. We subsequently analysed the metabolome and candidate gene expression. Hypoxia was associated with increased expression of SLC7A5 and SLC3A2 and an increased tissue abundance of BCAAs. Incubation of slices with 13 C-leucine confirmed that this was due to increased cellular uptake. BCH had little effect on metabolite abundance under normoxic or hypoxic conditions. This suggests hypoxia drives increased cellular uptake of BCAAs in the neonatal mouse forebrain, and membrane mediated transport through SLC7A5 and SLC3A2 is not essential for this process. This indicates mechanisms exist to generate the compounds required to maintain essential metabolism in the absence of external nutrient supply. Moreover, excess BCAAs have been associated with developmental delay, providing an unexplored mechanism of hypoxia mediated pathogenesis in the developing forebrain.

Published

2021

3. Ex vivo metabolite profiling of paediatric central nervous system tumours reveals prognostic markers.

Author

Bennett CD, Gill SK, Kohe SE, Wilson MP, Davies NP, Arvanitis TN, Tennant DA, and Peet AC

Subjects

Adolescent, Biomarkers, Tumor analysis, Brain Neoplasms chemistry, Brain Neoplasms metabolism, Brain Neoplasms mortality, Child, Child, Preschool, Female, Humans, Magnetic Resonance Spectroscopy, Male, Metabolomics, Prognosis, Proportional Hazards Models, Survival Analysis, Brain Neoplasms diagnosis

Abstract

Brain tumours are the most common cause of cancer death in children. Molecular studies have greatly improved our understanding of these tumours but tumour metabolism is underexplored. Metabolites measured in vivo have been reported as prognostic biomarkers of these tumours but analysis of surgically resected tumour tissue allows a more extensive set of metabolites to be measured aiding biomarker discovery and providing validation of in vivo findings. In this study, metabolites were quantified across a range of paediatric brain tumours using 1 H-High-Resolution Magic Angle Spinning nuclear magnetic resonance spectroscopy (HR-MAS) and their prognostic potential investigated. HR-MAS was performed on pre-treatment frozen tumour tissue from a single centre. Univariate and multivariate Cox regression was used to examine the ability of metabolites to predict survival. The models were cross validated using C-indices and further validated by splitting the cohort into two. Higher concentrations of glutamine were predictive of a longer overall survival, whilst higher concentrations of lipids were predictive of a shorter overall survival. These metabolites were predictive independent of diagnosis, as demonstrated in multivariate Cox regression models. Whilst accurate quantification of metabolites such as glutamine in vivo is challenging, metabolites show promise as prognostic markers due to development of optimised detection methods and increasing use of 3 T clinical scanners.

Published

2019

4. Verteporfin selectively kills hypoxic glioma cells through iron-binding and increased production of reactive oxygen species.

Author

Eales KL, Wilkinson EA, Cruickshank G, Tucker JHR, and Tennant DA

Subjects

Cell Death drug effects, Cell Line, Tumor, DNA Damage, Humans, Oxidative Stress drug effects, Glioma pathology, Iron metabolism, Reactive Oxygen Species metabolism, Tumor Hypoxia drug effects, Verteporfin pharmacology

Abstract

Gliomas are highly malignant brain tumours characterised by extensive areas of poor perfusion which subsequently leads to hypoxia and reduced survival. Therapies that address the hypoxic microenvironment are likely to significantly improve patient outcomes. Verteporfin, a benzoporphyrin-like drug, has been suggested to target the Yes-associated protein (YAP). Increased YAP expression and transcriptional activity has been proposed in other tumour types to promote malignant cell survival and thus YAP-inhibitor, verteporfin, may be predicted to impact glioma cell growth and viability. Due to the extensive hypoxic nature of gliomas, we investigated the effect of hypoxia on YAP expression and found that YAP transcription is increased under these conditions. Treatment of both primary and immortalised glioblastoma cell lines with verteporfin resulted in a significant decrease in viability but strikingly only under hypoxic conditions (1% O 2 ). We discovered that cell death occurs through a YAP-independent mechanism, predominately involving binding of free iron and likely through redox cycling, contributes to production of reactive oxygen species. This results in disruption of normal cellular processes and death in cells already under oxidative stress - such as those in hypoxia. We suggest that through repurposing verteporfin, it represents a novel means of treating highly therapy-resistant, hypoxic cells in glioma.

Published

2018

5. Tissue metabolite profiles for the characterisation of paediatric cerebellar tumours.

Author

Bennett CD, Kohe SE, Gill SK, Davies NP, Wilson M, Storer LCD, Ritzmann T, Paine SML, Scott IS, Nicklaus-Wollenteit I, Tennant DA, Grundy RG, and Peet AC

Subjects

Age Factors, Cerebellar Neoplasms diagnosis, Child, Computational Biology methods, Humans, Metabolic Networks and Pathways, Reproducibility of Results, Spectrum Analysis, Cerebellar Neoplasms metabolism, Metabolome, Metabolomics methods

Abstract

Paediatric brain tumors are becoming well characterized due to large genomic and epigenomic studies. Metabolomics is a powerful analytical approach aiding in the characterization of tumors. This study shows that common cerebellar tumors have metabolite profiles sufficiently different to build accurate, robust diagnostic classifiers, and that the metabolite profiles can be used to assess differences in metabolism between the tumors. Tissue metabolite profiles were obtained from cerebellar ependymoma (n = 18), medulloblastoma (n = 36), pilocytic astrocytoma (n = 24) and atypical teratoid/rhabdoid tumors (n = 5) samples using HR-MAS. Quantified metabolites accurately discriminated the tumors; classification accuracies were 94% for ependymoma and medulloblastoma and 92% for pilocytic astrocytoma. Using current intraoperative examination the diagnostic accuracy was 72% for ependymoma, 90% for medulloblastoma and 89% for pilocytic astrocytoma. Elevated myo-inositol was characteristic of ependymoma whilst high taurine, phosphocholine and glycine distinguished medulloblastoma. Glutamine, hypotaurine and N-acetylaspartate (NAA) were increased in pilocytic astrocytoma. High lipids, phosphocholine and glutathione were important for separating ATRTs from medulloblastomas. This study demonstrates the ability of metabolic profiling by HR-MAS on small biopsy tissue samples to characterize these tumors. Analysis of tissue metabolite profiles has advantages in terms of minimal tissue pre-processing, short data acquisition time giving the potential to be used as part of a rapid diagnostic work-up.

Published

2018

6. Scaling of Memories and Crossover in Glassy Magnets.

Author

Samarakoon AM, Takahashi M, Zhang D, Yang J, Katayama N, Sinclair R, Zhou HD, Diallo SO, Ehlers G, Tennant DA, Wakimoto S, Yamada K, Chern GW, Sato TJ, and Lee SH

Abstract

Glassiness is ubiquitous and diverse in characteristics in nature. Understanding their differences and classification remains a major scientific challenge. Here, we show that scaling of magnetic memories with time can be used to classify magnetic glassy materials into two distinct classes. The systems studied are high temperature superconductor-related materials, spin-orbit Mott insulators, frustrated magnets, and dilute magnetic alloys. Our bulk magnetization measurements reveal that most densely populated magnets exhibit similar memory behavior characterized by a relaxation exponent of [Formula: see text]. This exponent is different from [Formula: see text] of dilute magnetic alloys that was ascribed to their hierarchical and fractal energy landscape, and is also different from [Formula: see text] of the conventional Debye relaxation expected for a spin solid, a state with long range order. Furthermore, our systematic study on dilute magnetic alloys with varying magnetic concentration exhibits crossovers among the two glassy states and spin solid.

Published

2017