Mitochondrial fission protein Drp1 inhibition promotes cardiac mesodermal differentiation of human pluripotent stem cells

Hoque, Ashfaqul; Sivakumaran, Priyadharshini; Bond, Simon T.; Ling, Naomi X.Y.; Kong, Anne Mandy; Scott, John W.; Bandara, Nadeeka; Hernández, Damián; Liu, Guei‐Sheung; Wong, Raymond Ching-Bong; Ryan, Michael; Hausenloy, Derek J.; Kemp, Bruce E.; Oakhill, Jonathan S.; Drew, Brian G.; Pébay, Alice; Lim, Shiang Y.

doi:10.1038/s41420-018-0042-9

Cited by 63 publications

(62 citation statements)

References 37 publications

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“…[139][140][141] Changes in the dynamic mitochondrial network can also influence the identity, self-renewal capacity and commitment of stem cells, which reinforces the functional connection between morphology and metabolism, and which likely has implications for cancer (stem) cells as well. [142][143][144][145] Similar changes in the mitochondrial morphology have been observed also in T lymphocytes upon activation. Memory T cells on the other hand are quiescent, depend on oxidative phosphorylation, and hence showed a more fused morphology.…”

Section: Determinants Of the Mitochondrial Network Morphologysupporting

confidence: 74%

“…Interestingly, cancer cells and stem cells share the same energy metabolism and hence share a similar mitochondrial morphology . Changes in the dynamic mitochondrial network can also influence the identity, self‐renewal capacity and commitment of stem cells, which reinforces the functional connection between morphology and metabolism, and which likely has implications for cancer (stem) cells as well . Similar changes in the mitochondrial morphology have been observed also in T lymphocytes upon activation.…”

Section: Mitochondrial Membrane Organizationmentioning

confidence: 63%

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Targeted OMA1 therapies for cancer

Alavi¹

2019

Intl Journal of Cancer

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The mitochondrial inner membrane proteins OMA1 and OPA1 belong to the BAX/BAK1‐dependent apoptotic signaling pathway, which can be regulated by tumor protein p53 and the prohibitins PHB and PHB2 in the context of neoplastic disease. For the most part these proteins have been studied separate from each other. Here, I argue that the OMA1 mechanism of action represents the missing link between p53 and cytochrome c release. The mitochondrial fusion protein OPA1 is cleaved by OMA1 in a stress‐dependent manner generating S‐OPA1. Excessive S‐OPA1 can facilitate outer membrane permeabilization upon BAX/BAK1 activation through its membrane shaping properties. p53 helps outer membrane permeabilization in a 2‐step process. First, cytosolic p53 activates BAX/BAK1 at the mitochondrial surface. Then, in a second step, p53 binds to prohibitin thereby releasing the restraint on OMA1. This activates OMA1, which cleaves OPA1 and promotes cytochrome c release. Clearly, OMA1 and OPA1 are not root causes for cancer. Yet many cancer cells rely on this pathway for survival, which can explain why loss of p53 function promotes tumor growth and confers resistance to chemotherapies.

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Section: Determinants Of the Mitochondrial Network Morphologysupporting

confidence: 74%

Section: Mitochondrial Membrane Organizationmentioning

confidence: 63%

Targeted OMA1 therapies for cancer

Alavi¹

2019

Intl Journal of Cancer

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“…Further, we confirmed that pharmacological inhibition of Drp1 with Mdivi-1, a small molecule inhibitor of Drp1 (Bordt et al, 2017;Hoque et al, 2018) also markedly inhibited mitochondrial fission induced by chronic Ang II stimulation ( Fig 7C). Correspondingly, the mtROS production was also reduced obviously in si-Drp1-transfected ( Fig 7B) or…”

Section: Inhibition Of the Mitochondrial Fission Decreases Mitochondrsupporting

confidence: 74%

eIF5a reduction via decreased Klf5 leads to cell senescence by mitochondrial fission in VSMCs

Zheng

et al. 2019

Preprint

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Though dysregulation of mitochondrial dynamics has been linked to cellular senescence, which contributes to advanced age-related disorders, it is unclear how Klf5, an essential transcriptional factor of cardiovascular remodeling, mediates the link between mitochondrial dynamics and vascular smooth muscle cell (VSMC) senescence. Here we show that Klf5 downregulation in VSMCs is correlated with rupture of abdominal aortic aneurysm (AAA), an age-related vascular disease. Mice lacking Klf5 in VSMCs exacerbate vascular senescence and progression of Ang II-induced AAA by facilitating ROS formation. Klf5 knockdown enhances, while Klf5 overexpression suppresses mitochondrial fission. Mechanistically, Klf5 activates eIF5a transcription through binding to the promoter of eIF5a, which in turn preserves mitochondrial integrity by interacting with Mfn1. Accordingly, decreased expression of eIF5a elicited by Klf5 downregulation leads to mitochondrial fission and excessive ROS production. Inhibition of mitochondrial fission decreases ROS production and VSMC senescence. Our studies provide a potential therapeutic target for age-related vascular disorders.

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“…, IFN225,26 and Drp146 .Intriguingly, likewise for myosin-Va knockdown, Drp1 knockdown has also been shown to result in diminished tumorigenesis and features, such as increased OXPHOS and low clonogenic ability4,5,47 .Our data show that myosin-Va interacts with Spire1C and overexpression of Spire1C increases myosin-Va localization to mitochondria. Recently, non-mitochondrial Spire splice isoforms have been shown to interact with myosin-V motors32 .…”

supporting

confidence: 58%

A novel role for Myosin-Va in mitochondrial fission

Araujo

Silva-Júnior

Zhang

et al. 2019

Preprint

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In cancer cells metabolic changes and mitochondrial morphology are coupled. It is known that the cytoskeleton and molecular motors are directly involved in regulating mitochondrial morphology. Here we show that myosin-Va, an actin-based molecular motor, is required for the malignant properties of melanoma cells and localizes to mitochondria in these cells. Knockdown of myosin-Va increases cellular respiration rates and ROS production and decreases glucose uptake and lactate secretion. In addition, knockdown of myosin-Va results in reduced mitochondrial fission and correspondingly elongated mitochondria. We show that myosin-Va interacts with the mitochondrial outer membrane protein Spire1C, an actin-regulatory protein implicated in mitochondrial fission, and that Spire1C recruits myosin-Va to mitochondria. Finally, we show that during mitochondrial fission myosin-Va localization to mitochondria increases, and that myosin-Va localizes to mitochondrial fission sites immediately adjacent to Drp1 punctae. We conclude that myosin-Va facilitates mitochondrial fission. These data implicate myosin-Va as a target for the Warburg effect in melanoma cells.

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Mitochondrial fission protein Drp1 inhibition promotes cardiac mesodermal differentiation of human pluripotent stem cells

Cited by 63 publications

References 37 publications

Targeted OMA1 therapies for cancer

Targeted OMA1 therapies for cancer

eIF5a reduction via decreased Klf5 leads to cell senescence by mitochondrial fission in VSMCs

A novel role for Myosin-Va in mitochondrial fission

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