Mitochondrial regular arrangement in muscle cells: a “crystal-like” pattern

Vendelin, Marko; Béraud, Nathalie; Guerrero, Karen; Andrienko, Tatiana; Kuznetsov, Andrey V.; Olivares, José; Kay, Laurence; Saks, Valdur

doi:10.1152/ajpcell.00281.2004

Cited by 176 publications

(163 citation statements)

References 42 publications

(74 reference statements)

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“…For instance, the classic measurement of mitochondrial section area on electron micrographs is limited by the very complex three-dimensional organization of mitochondria as a global network (16,31,51), the morphometric parameters of which also vary widely on energy status (17-19, 23, 35). Accordingly, in our study, there was an important variability of mitochondrial morphology between tissues: in heart and skeletal muscle, they presented essentially with a regular quasi-crystalline organization (46), whereas in liver and kidney they looked more irregular and less compacted by tissue architecture. In brain, the mitochondria looked more like a collection of small and numerous ovoid sections.…”

Section: Discussionmentioning

confidence: 43%

Physiological diversity of mitochondrial oxidative phosphorylation

Bénard¹,

Faustin²,

Passerieux³

et al. 2006

American Journal of Physiology-Cell Physiology

264

158

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To investigate the physiological diversity in the regulation and control of mitochondrial oxidative phosphorylation, we determined the composition and functional features of the respiratory chain in muscle, heart, liver, kidney, and brain. First, we observed important variations in mitochondrial content and infrastructure via electron micrographs of the different tissue sections. Analyses of respiratory chain enzyme content by Western blot also showed large differences between tissues, in good correlation with the expression level of mitochondrial transcription factor A and the activity of citrate synthase. On the isolated mitochondria, we observed a conserved molar ratio between the respiratory chain complexes and a variable stoichiometry for coenzyme Q and cytochrome c, with typical values of [1–1.5]:[30–135]:[3]:[9–35]:[6.5–7.5] for complex II:coenzyme Q:complex III:cytochrome c:complex IV in the different tissues. The functional analysis revealed important differences in maximal velocities of respiratory chain complexes, with higher values in heart. However, calculation of the catalytic constants showed that brain contained the more active enzyme complexes. Hence, our study demonstrates that, in tissues, oxidative phosphorylation capacity is highly variable and diverse, as determined by different combinations of 1) the mitochondrial content, 2) the amount of respiratory chain complexes, and 3) their intrinsic activity. In all tissues, there was a large excess of enzyme capacity and intermediate substrate concentration, compared with what is required for state 3 respiration. To conclude, we submitted our data to a principal component analysis that revealed three groups of tissues: muscle and heart, brain, and liver and kidney.

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Section: Discussionmentioning

confidence: 43%

Physiological diversity of mitochondrial oxidative phosphorylation

Bénard¹,

Faustin²,

Passerieux³

et al. 2006

American Journal of Physiology-Cell Physiology

264

158

View full text Add to dashboard Cite

show abstract

“…Fluorescent cardiac mitochondria were observed between the Z-lines of sarcomeres and arranged as longitudinal bundles along the myofibrils ( Figure 1B) [17,18]. In skeletal muscle, mt-cpYFP staining of I band-delimited mitochondria [18,19] gave rise to transverse doublet bands at 2.6 µm intervals ( Figure 1C) that overlapped with staining by tetramethylrhodamine methyl ester (TMRM), a mitochondrial membrane potential (∆Ψm) indicator (Supplementary information, Figure S3). Unlike striated muscles, axons within the sciatic nerve trunk were filled with slender mitochondria (Figure 1D), many of which were engaged in anterograde or retrograde trafficking.…”

Section: Pan-tissue Mt-cpyfp Transgenic Micementioning

confidence: 95%

Imaging superoxide flash and metabolism-coupled mitochondrial permeability transition in living animals

et al. 2011

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The mitochondrion is essential for energy metabolism and production of reactive oxygen species (ROS). In intact cells, respiratory mitochondria exhibit spontaneous "superoxide flashes", the quantal ROS-producing events consequential to transient mitochondrial permeability transition (tMPT). Here we perform the first in vivo imaging of mitochondrial superoxide flashes and tMPT activity in living mice expressing the superoxide biosensor mt-cpYFP, and demonstrate their coupling to whole-body glucose metabolism. Robust tMPT/superoxide flash activity occurred in skeletal muscle and sciatic nerve of anesthetized transgenic mice. In skeletal muscle, imaging tMPT/superoxide flashes revealed labyrinthine three-dimensional networks of mitochondria that operate synchronously. The tMPT/ superoxide flash activity surged in response to systemic glucose challenge or insulin stimulation, in an apparently frequency-modulated manner and involving also a shift in the gating mode of tMPT. Thus, in vivo imaging of tMPTdependent mitochondrial ROS signals and the discovery of the metabolism-tMPT-superoxide flash coupling mark important technological and conceptual advances for the study of mitochondrial function and ROS signaling in health and disease.

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“…For example, in cultured fibroblasts mitochondria form extensive reticular networks, whereas in neuronal cells, mitochondria can be found enriched at areas of high-energy demand, including presynaptic termini, axon initial segments, and growth cones. Furthermore, in muscle cells, mitochondria adopt a very uniform intermyofibrillar conformation (Vendelin et al 2005). The dynamic nature of mitochondria provides an explanation as to how they adopt varying organizations in different cell populations.…”

mentioning

confidence: 99%

Quality Control of Mitochondrial Proteostasis

Baker

Tatsuta²,

Langer

2011

Cold Spring Harbor Perspectives in Biology

223

193

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A decline in mitochondrial activity has been associated with aging and is a hallmark of many neurological diseases. Surveillance mechanisms acting at the molecular, organellar, and cellular level monitor mitochondrial integrity and ensure the maintenance of mitochondrial proteostasis. Here we will review the central role of mitochondrial chaperones and proteases, the cytosolic ubiquitin-proteasome system, and the mitochondrial unfolded response in this interconnected quality control network, highlighting the dual function of some proteases in protein quality control within the organelle and for the regulation of mitochondrial fusion and mitophagy.

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Mitochondrial regular arrangement in muscle cells: a “crystal-like” pattern

Cited by 176 publications

References 42 publications

Physiological diversity of mitochondrial oxidative phosphorylation

Physiological diversity of mitochondrial oxidative phosphorylation

Imaging superoxide flash and metabolism-coupled mitochondrial permeability transition in living animals

Quality Control of Mitochondrial Proteostasis

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