Transmission Electron Microscopy reveals propionic acid-induced alterations to mitochondrial morphology in SH-SY5Y cells. Buchanan, E., Mahony, C., Bam, S., Jaffer, M., Macleod, S., Watt, M. V. D., Jacobs, C., & O'Ryan, C. Preprints, Preprints, nov, 2022. ![Transmission Electron Microscopy reveals propionic acid-induced alterations to mitochondrial morphology in SH-SY5Y cells [link]](https://bibbase.org/img/filetypes/link.svg "link")
Paper doi abstract bibtex Mitochondrial dysregulation is implicated in numerous neurological disorders. Mitochondrial dynamics; including biogenesis; fusion and fission; are essential components of mitostasis which is modulated by complex regulatory mechanisms. Although expression studies are often used to investigate mitochondrial dynamics; these studies may be limited by the interdependent and temporal nature of mitostasis. Transmission electron microscopy (TEM) and cryogenic preparation methods provide a direct approach to examine mitochondrial ultrastructure in neurons. We investigated the utility of TEM to visualize mitochondrial morphological changes in SH-SY5Y cells treated with propionic acid (PPA). We examined whether morphological alterations were associated with differences in membrane potential or expression of biogenesis; fusion and fission genes. PPA induced a significant decrease in mitochondrial area (p\textless0.01 5mM); Feret's diameter and perimeter (p\textless0.05 5mM); and in area2 (p\textless0.05 3mM; p\textless0.01 5mM) – consistent with a shift towards fission. Morphological changes were not associated with significant differences in mitochondrial membrane potential. However; we observed decreased gene expression of NRF1 (p\textless0.01); TFAM (p\textless0.05); and STOML2 (p\textless0.0001). These data support a disruption of the balance in dynamics to preserve function under stress. This demonstrates the utility of TEM to provide insight into mitochondrial dynamics and function which can inform targeted mechanistic investigations into neuropathology.
@article{Buchanan2022,
abstract = {Mitochondrial dysregulation is implicated in numerous neurological disorders. Mitochondrial dynamics; including biogenesis; fusion and fission; are essential components of mitostasis which is modulated by complex regulatory mechanisms. Although expression studies are often used to investigate mitochondrial dynamics; these studies may be limited by the interdependent and temporal nature of mitostasis. Transmission electron microscopy (TEM) and cryogenic preparation methods provide a direct approach to examine mitochondrial ultrastructure in neurons. We investigated the utility of TEM to visualize mitochondrial morphological changes in SH-SY5Y cells treated with propionic acid (PPA). We examined whether morphological alterations were associated with differences in membrane potential or expression of biogenesis; fusion and fission genes. PPA induced a significant decrease in mitochondrial area (p{\textless}0.01 5mM); Feret's diameter and perimeter (p{\textless}0.05 5mM); and in area2 (p{\textless}0.05 3mM; p{\textless}0.01 5mM) – consistent with a shift towards fission. Morphological changes were not associated with significant differences in mitochondrial membrane potential. However; we observed decreased gene expression of NRF1 (p{\textless}0.01); TFAM (p{\textless}0.05); and STOML2 (p{\textless}0.0001). These data support a disruption of the balance in dynamics to preserve function under stress. This demonstrates the utility of TEM to provide insight into mitochondrial dynamics and function which can inform targeted mechanistic investigations into neuropathology.},
author = {Buchanan, Erin and Mahony, Caitlyn and Bam, Sophia and Jaffer, Mohamed and Macleod, Sarah and Watt, Mignon Van Der and Jacobs, Caron and O'Ryan, Colleen},
doi = {10.20944/PREPRINTS202211.0553.V1},
file = {:C$\backslash$:/Users/01462563/AppData/Local/Mendeley Ltd./Mendeley Desktop/Downloaded/Buchanan et al. - 2022 - Transmission Electron Microscopy reveals propionic acid-induced alterations to mitochondrial morphology in SH-S.pdf:pdf},
journal = {Preprints},
keywords = {OA,SH-SY5Y,biogenesis,dynamics,fission,fund{\_}not{\_}ack,fusion,mitochondrial,morphology,neuronal models,neuropathology,original,transmission electron mi-croscopy},
mendeley-tags = {OA,fund{\_}not{\_}ack,original},
month = {nov},
pages = {2022110553},
publisher = {Preprints},
title = {{Transmission Electron Microscopy reveals propionic acid-induced alterations to mitochondrial morphology in SH-SY5Y cells}},
url = {https://www.preprints.org/manuscript/202211.0553/v1},
year = {2022}
}
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We investigated the utility of TEM to visualize mitochondrial morphological changes in SH-SY5Y cells treated with propionic acid (PPA). We examined whether morphological alterations were associated with differences in membrane potential or expression of biogenesis; fusion and fission genes. PPA induced a significant decrease in mitochondrial area (p\\textless0.01 5mM); Feret's diameter and perimeter (p\\textless0.05 5mM); and in area2 (p\\textless0.05 3mM; p\\textless0.01 5mM) – consistent with a shift towards fission. Morphological changes were not associated with significant differences in mitochondrial membrane potential. However; we observed decreased gene expression of NRF1 (p\\textless0.01); TFAM (p\\textless0.05); and STOML2 (p\\textless0.0001). These data support a disruption of the balance in dynamics to preserve function under stress. 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