The mitochondrial division inhibitor Mdivi-1 rescues mammalian neurons from anesthetic-induced cytotoxicity

Xu, Fenglian; Armstrong, Ryden; Urrego, Daniela; Qazzaz, Munir; Pehar, Mario; Armstrong, John N.; Shutt, Timothy E.; Syed, Naweed I.

doi:10.1186/s13041-016-0210-x

Cited by 34 publications

(50 citation statements)

References 35 publications

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“…The effects of mdivi-1 are also controversial, especially in terms of its specificity in inhibiting Drp1. Although studies have shown that mdivi-1 inhibits mitochondrial fission, 32,[76][77][78][79][80][81] researchers have also reported that mdivi-1 inhibits complex I of the electron transport chain at concentrations greater than 25 μM. 52 A more recent study showed mdivi-1 is a Drp1 inhibitor that increased complex I, II, and IV enzymatic activities at a concentration of 25 μM.…”

Section: Discussionmentioning

confidence: 99%

Mitochondrial division inhibitor 1 (mdivi‐1) increases oxidative capacity and contractile stress generated by engineered skeletal muscle

et al. 2020

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In skeletal muscle fibers, mitochondria are densely packed adjacent to myofibrils because adenosine triphosphate (ATP) is needed to fuel sarcomere shortening. However, despite this close physical and biochemical relationship, the effects of mitochondrial dynamics on skeletal muscle contractility are poorly understood. In this study, we analyzed the effects of Mitochondrial Division Inhibitor 1 (mdivi‐1), an inhibitor of mitochondrial fission, on the structure and function of both mitochondria and myofibrils in skeletal muscle tissues engineered on micromolded gelatin hydrogels. Treatment with mdivi‐1 did not alter myotube morphology, but did increase the mitochondrial turbidity and oxidative capacity, consistent with reduced mitochondrial fission. Mdivi‐1 also significantly increased basal, twitch, and tetanus stresses, as measured using the Muscular Thin Film (MTF) assay. Finally, mdivi‐1 increased sarcomere length, potentially due to mdivi‐1‐induced changes in mitochondrial volume and compression of myofibrils. Together, these results suggest that mdivi‐1 increases contractile stress generation, which may be caused by an increase in maximal respiration and/or sarcomere length due to increased volume of individual mitochondria. These data reinforce that mitochondria have both biochemical and biomechanical roles in skeletal muscle and that mitochondrial dynamics can be manipulated to alter muscle contractility.

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Section: Discussionmentioning

confidence: 99%

Mitochondrial division inhibitor 1 (mdivi‐1) increases oxidative capacity and contractile stress generated by engineered skeletal muscle

et al. 2020

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“…For example, young rodents exposed to volatile anesthetics including sevoflurane and isoflurane were found to have deficits in long-term memory (Ramage et al, 2013 ). Rat cortical neurons exposed to either sevoflurane or desflurane demonstrated increased cell death, decreased neurite outgrowth and compromised mitochondrial integrity and synaptic function (Xu et al, 2016 ). Studies involving neonatal rodent exposure to intravenous anesthetics such as ketamine and propofol have also described detrimental effects on neuronal survival, dendritic spine density, and memory (Cattano et al, 2008 ; Pesić et al, 2009 ; Briner et al, 2011 ; Huang et al, 2012 ; Yu et al, 2013 ).…”

Section: Clinical Research Related To Anesthetic-induced Neurotoxicitmentioning

confidence: 99%

“…In addition, we systematically evaluate the subcellular impact of modern general anesthetics on neuronal excitability, viability, and connectivity between developing neurons. While many of the findings reviewed here emanate from research conducted on various molluscs, particularly the fresh water snail Lymnaea , these data have nevertheless stood the test of time as it pertains to vertebrates (Xu et al, 2016 ).…”

Section: Introductionmentioning

confidence: 96%

Mechanisms of Anesthetic Action and Neurotoxicity: Lessons from Molluscs

et al. 2018

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Anesthesia is a prerequisite for most surgical procedures in both animals and humans. Significant strides have been made in search of effective and safer compounds that elicit rapid induction and recovery from anesthesia. However, recent studies have highlighted possible negative effects of several anesthetic agents on the developing brain. The precise nature of this cytotoxicity remains to be determined mainly due to the complexity and the intricacies of the mammalian brain. Various invertebrates have contributed significantly toward our understanding of how both local and general anesthetics affect intrinsic membrane and synaptic properties. Moreover, the ability to reconstruct in vitro synapses between individually identifiable pre- and postsynaptic neurons is a unique characteristic of molluscan neurons allowing us to ask fundamental questions vis-à-vis the long-term effects of anesthetics on neuronal viability and synaptic connectivity. Here, we highlight some of the salient aspects of various molluscan organisms and their contributions toward our understanding of the fundamental mechanisms underlying the actions of anesthetic agents as well as their potential detrimental effects on neuronal growth and synaptic connectivity. We also present some novel preliminary data regarding a newer anesthetic agent, dexmedetomidine, and its effects on synaptic transmission between Lymnaea neurons. The findings presented here underscore the importance of invertebrates for research in the field of anesthesiology while highlighting their relevance to both vertebrates and humans.

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“…While it is logical that the observed decrease in inhibitory synaptic neurotransmission may be due to the observed effects on the mitochondria, other explanations are not excluded by these data. Interestingly, in a recent paper, Xu showed that sevoflurane-induced apoptosis in primary cultured neurons could be prevented using a mitochondrial division inhibitor 98 . At this point, there is strong evidence to suggest that early anesthetic exposure strongly affects mitochondrial structure and function in neurons, and there is emerging evidence that mitochondrial disturbance may be associated with decreased synaptic transmission, a known inducer of apoptosis in developing neurons.…”

Section: Effects On Mitochondriamentioning

confidence: 99%

Molecular Mechanisms of Anesthetic Neurotoxicity: A Review of the Current Literature

Jackson

Gray

Jiang

et al. 2016

Journal of Neurosurgical Anesthesiology

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Data from epidemiologic studies and animal models have raised a concern that exposure to anesthetic agents during early postnatal life may cause lasting impairments in cognitive function. It is hypothesized that this is due to disruptions in brain development, but the mechanism underlying this toxic effect remains unknown. Ongoing research, particularly in rodents, has begun to address this question. In this review we examine currently postulated molecular mechanisms of anesthetic toxicity in the developing brain, including effects on cell death pathways, growth factor signaling systems, NMDA and GABA receptors, mitochondria, and epigenetic factors. The level of evidence for each putative mechanism is critically evaluated, and we attempt to draw connections between them where it is possible to do so. While there are many promising avenues of research, at this time no consensus can be reached as to a definitive mechanism of injury.

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The mitochondrial division inhibitor Mdivi-1 rescues mammalian neurons from anesthetic-induced cytotoxicity

Cited by 34 publications

References 35 publications

Mitochondrial division inhibitor 1 (mdivi‐1) increases oxidative capacity and contractile stress generated by engineered skeletal muscle

Mitochondrial division inhibitor 1 (mdivi‐1) increases oxidative capacity and contractile stress generated by engineered skeletal muscle

Mechanisms of Anesthetic Action and Neurotoxicity: Lessons from Molluscs

Molecular Mechanisms of Anesthetic Neurotoxicity: A Review of the Current Literature

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