Eero Lihavainen scite author profile

The machinery of mitochondrial DNA (mtDNA) maintenance is only partially characterized and is of wide interest due to its involvement in disease. To identify novel components of this machinery, plus other cellular pathways required for mtDNA viability, we implemented a genome-wide RNAi screen in Drosophila S2 cells, assaying for loss of fluorescence of mtDNA nucleoids stained with the DNA-intercalating agent PicoGreen. In addition to previously characterized components of the mtDNA replication and transcription machineries, positives included many proteins of the cytosolic proteasome and ribosome (but not the mitoribosome), three proteins involved in vesicle transport, some other factors involved in mitochondrial biogenesis or nuclear gene expression, > 30 mainly uncharacterized proteins and most subunits of ATP synthase (but no other OXPHOS complex). ATP synthase knockdown precipitated a burst of mitochondrial ROS production, followed by copy number depletion involving increased mitochondrial turnover, not dependent on the canonical autophagy machinery. Our findings will inform future studies of the apparatus and regulation of mtDNA maintenance, and the role of mitochondrial bioenergetics and signaling in modulating mtDNA copy number.

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Reversible Disruption of Neuronal Mitochondria by Ischemic and Traumatic Injury Revealed by Quantitative Two-Photon Imaging in the Neocortex of Anesthetized Mice

Kislin

Sword

Fomitcheva

et al. 2016

J. Neurosci.

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Mitochondria play a variety of functional roles in cortical neurons, from metabolic support and neuroprotection to the release of cytokines that trigger apoptosis. In dendrites, mitochondrial structure is closely linked to their function, and fragmentation (fission) of the normally elongated mitochondria indicates loss of their function under pathological conditions, such as stroke and brain trauma. Using in vivo two-photon microscopy in mouse brain, we quantified mitochondrial fragmentation in a full spectrum of cortical injuries, ranging from severe to mild. Severe global ischemic injury was induced by bilateral common carotid artery occlusion, whereas severe focal stroke injury was induced by Rose Bengal photosensitization. The moderate and mild traumatic injury was inflicted by focal laser lesion and by mild photo-damage, respectively. Dendritic and mitochondrial structural changes were tracked longitudinally using transgenic mice expressing fluorescent proteins localized either in cytosol or in mitochondrial matrix. In response to severe injury, mitochondrial fragmentation developed in parallel with dendritic damage signified by dendritic beading. Reconstruction from serial section electron microscopy confirmed mitochondrial fragmentation. Unlike dendritic beading, fragmentation spread beyond the injury core in focal stroke and focal laser lesion models. In moderate and mild injury, mitochondrial fragmentation was reversible with full recovery of structural integrity after 1-2 weeks. The transient fragmentation observed in the mild photo-damage model was associated with changes in dendritic spine density without any signs of dendritic damage. Our findings indicate that alterations in neuronal mitochondria structure are very sensitive to the tissue damage and can be reversible in ischemic and traumatic injuries.

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Asymmetric Disposal of Individual Protein Aggregates in Escherichia coli, One Aggregate at a Time

et al. 2012

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bEscherichia coli cells employ an asymmetric strategy at division, segregating unwanted substances to older poles, which has been associated with aging in these organisms. The kinetics of this process is still poorly understood. Using the MS2 coat protein fused to green fluorescent protein (GFP) and a reporter construct with multiple MS2 binding sites, we tracked individual RNA-MS2-GFP complexes in E. coli cells from the time when they were produced. Analyses of the kinetics and brightness of the spots showed that these spots appear in the midcell region, are composed of a single RNA-MS2-GFP complex, and reach a pole before another target RNA is formed, typically remaining there thereafter. The choice of pole is probabilistic and heavily biased toward one pole, similar to what was observed by previous studies regarding protein aggregates. Additionally, this mechanism was found to act independently on each disposed molecule. Finally, while the RNA-MS2-GFP complexes were disposed of, the MS2-GFP tagging molecules alone were not. We conclude that this asymmetric mechanism to segregate damage at the expense of aging individuals acts probabilistically on individual molecules and is capable of the accurate classification of molecules for disposal. Escherichia coli is a well-established and simple model in aging studies. Stewart and colleagues demonstrated that two apparently identical sister cells resulting from cell division are functionally asymmetric (14). This asymmetry is representative of the aging of the cells, since unwanted protein aggregates tend to concentrate at the older pole of the mother cell. This can be observed as an accumulation of cell constituents with limited diffusion and a long half-life at the old pole of the mother cell, resulting in larger old poles and, consequently, a cumulatively slower growth of the daughter cells receiving these substances. Additional evidence of this phenomenon of asymmetric segregation of protein aggregates at older poles and its association with cellular aging in E. coli was presented previously (9), where it was shown that this pattern of segregation of unwanted substances appears to occur by a common mechanism irrespective of the unwanted substance segregated. The kinetics of this process is yet poorly understood.To better understand the mechanism of the preferential accumulation of unwanted protein aggregates at older poles in E. coli, it is essential to detect and track these aggregates individually. Although the detection of individual molecules in bacteria has been elusive and difficult, a recent technique has been developed that, provided the proper automated image segmentation algorithms, allows the tracking of single RNA molecules in E. coli by tagging them with multiple fluorescent proteins. This technique may be used for the purpose of tracking unwanted aggregates in E. coli. The technique uses the RNA bacteriophage MS2 coat protein fused to green fluorescent protein (GFP) and a reporter construct with multiple MS2 binding sites (5). The RNA-MS2-GFP comple...

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Eero Lihavainen

Mytoe: automatic analysis of mitochondrial dynamics

Screen for mitochondrial DNA copy number maintenance genes reveals essential role for ATP synthase

Reversible Disruption of Neuronal Mitochondria by Ischemic and Traumatic Injury Revealed by Quantitative Two-Photon Imaging in the Neocortex of Anesthetized Mice

Asymmetric Disposal of Individual Protein Aggregates in Escherichia coli, One Aggregate at a Time

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