Heterochronic Parabiosis: Old Blood Induces Changes in Mitochondrial Structure and Function of Young Mice

Abstract Heterochronic parabiosis models have been utilized to demonstrate the role of blood-borne circulating factors in systemic effects of aging. In previous studies, heterochronic parabiosis has shown positive effects across multiple tissues in old mice. More recently, a study demonstrated old blood had a more profound negative effect on muscle performance and neurogenesis of young mice. In this study, we used heterochronic parabiosis to test the hypothesis that circulating factors mediate mitochondrial bioenergetic decline, a well-established biological hallmark of aging. We examined mitochondrial morphology, expression of mitochondrial complexes, and mitochondrial respiration from skeletal muscle of mice connected as heterochronic pairs, as well as young and old isochronic controls. Our results indicate that young heterochronic mice had significantly lower total mitochondrial content and on average had significantly smaller mitochondria compared to young isochronic controls. Expression of complex IV followed a similar pattern: young heterochronic mice had a trend for lower expression compared to young isochronic controls. Additionally, respirometric analyses indicate that young heterochronic mice had significantly lower complex I, complex I + II, and maximal mitochondrial respiration and a trend for lower complex II-driven respiration compared to young isochronic controls. Interestingly, we did not observe significant improvements in old heterochronic mice compared to old isochronic controls, demonstrating the profound deleterious effects of circulating factors from old mice on mitochondrial structure and function. We also found no significant differences between the young and old heterochronic mice, demonstrating that circulating factors can be a driver of age-related differences in mitochondrial structure and function.

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Drosophila MICOS knockdown impairs mitochondrial structure and function and promotes mitophagy in muscle tissue

Biology Open ◽

10.1242/bio.054262 ◽

2020 ◽

Vol 9 (12) ◽

pp. bio054262

Author(s):

Li-jie Wang ◽

Tian Hsu ◽

Hsiang-ling Lin ◽

Chi-yu Fu

Keyword(s):

Muscle Tissue ◽

Mammalian Cells ◽

Structure And Function ◽

Tissue Homeostasis ◽

Mitochondrial Morphology ◽

Mitochondrial Structure ◽

And Function ◽

Nucleoid Structure

ABSTRACTThe mitochondrial contact site and cristae organizing system (MICOS) is a multi-protein interaction hub that helps define mitochondrial ultrastructure. While the functional importance of MICOS is mostly characterized in yeast and mammalian cells in culture, the contributions of MICOS to tissue homeostasis in vivo remain further elucidation. In this study, we examined how knocking down expression of Drosophila MICOS genes affects mitochondrial function and muscle tissue homeostasis. We found that CG5903/MIC26-MIC27 colocalizes and functions with Mitofilin/MIC60 and QIL1/MIC13 as a Drosophila MICOS component; knocking down expression of any of these three genes predictably altered mitochondrial morphology, causing loss of cristae junctions, and disruption of cristae packing. Furthermore, the knockdown flies exhibited low mitochondrial membrane potential, fusion/fission imbalances, increased mitophagy, and limited cell death. Reductions in climbing ability indicated deficits in muscle function. Knocking down MICOS genes also caused reduced mtDNA content and fragmented mitochondrial nucleoid structure in Drosophila. Together, our data demonstrate an essential role of Drosophila MICOS in maintaining proper homeostasis of mitochondrial structure and function to promote the function of muscle tissue.

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The endogenous radical scavenger A1M binds to complex I and protects mitochondrial structure and function; an novel cellular protective mechanism

Free Radical Biology and Medicine ◽

10.1016/j.freeradbiomed.2012.08.512 ◽

2012 ◽

Vol 53 ◽

pp. S43

Author(s):

M.G. Olsson⁎ ◽

L.W. Rosenlöf ◽

H. Kotarsky ◽

M. Mörgelin ◽

V. Fellman ◽

...

Keyword(s):

Complex I ◽

Structure And Function ◽

Radical Scavenger ◽

Protective Mechanism ◽

Mitochondrial Structure ◽

And Function

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Intermittent Hypoxia-Hyperoxia and Oxidative Stress in Developing Human Airway Smooth Muscle

Antioxidants ◽

10.3390/antiox10091400 ◽

2021 ◽

Vol 10 (9) ◽

pp. 1400

Author(s):

Colleen M. Bartman ◽

Daniel Wasim Awari ◽

Christina M. Pabelick ◽

Y. S. Prakash

Keyword(s):

Smooth Muscle ◽

Oxidative Damage ◽

Airway Smooth Muscle ◽

Mitochondrial Respiration ◽

Intermittent Hypoxia ◽

Structure And Function ◽

Airway Smooth Muscle Cells ◽

Mitochondrial Morphology ◽

Antioxidant Defense Systems ◽

And Function

Premature infants are frequently and intermittently administered supplemental oxygen during hypoxic episodes, resulting in cycles of intermittent hypoxia and hyperoxia. The relatively hypoxic in utero environment is important for lung development while hyperoxia during the neonatal period is recognized as detrimental towards the development of diseases such as bronchopulmonary dysplasia and bronchial asthma. Understanding early mechanisms that link hypoxic, hyperoxic, and intermittent hypoxic-hyperoxic exposures to altered airway structure and function are key to developing advanced therapeutic approaches in the clinic. Changes in oxygen availability can be detrimental to cellular function and contribute to oxidative damage. Here, we sought to determine the effect of oxygen on mitochondria in human fetal airway smooth muscle cells exposed to either 5% O2, 21% O2, 40% O2, or cycles of 5% and 40% O2 (intermittent hypoxia-hyperoxia). Reactive oxygen species production, altered mitochondrial morphology, and changes in mitochondrial respiration were assessed in the context of the antioxidant N-acetylcysteine. Our findings show developing airway smooth muscle is differentially responsive to hypoxic, hyperoxic, or intermittent hypoxic-hyperoxic exposure in terms of mitochondrial structure and function. Cycling O2 decreased mitochondrial branching and branch length similar to hypoxia and hyperoxia in the presence of antioxidants. Additionally, hypoxia decreased overall mitochondrial respiration while the addition of antioxidants increased respiration in normoxic and O2-cycling conditions. These studies show the necessity of balancing oxidative damage and antioxidant defense systems in the developing airway.

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Role of Mitochondria-Cytoskeleton Interactions in the Regulation of Mitochondrial Structure and Function in Cancer Stem Cells

Cells ◽

10.3390/cells9071691 ◽

2020 ◽

Vol 9 (7) ◽

pp. 1691

Author(s):

Jungmin Kim ◽

Jae-Ho Cheong

Keyword(s):

Stem Cells ◽

Cancer Stem Cells ◽

Energy Requirement ◽

High Energy ◽

Structure And Function ◽

Mitochondrial Morphology ◽

Voltage Dependent Anion Channel ◽

Mesenchymal Transition ◽

Mitochondrial Structure ◽

And Function

Despite the promise of cancer medicine, major challenges currently confronting the treatment of cancer patients include chemoresistance and recurrence. The existence of subpopulations of cancer cells, known as cancer stem cells (CSCs), contributes to the failure of cancer therapies and is associated with poor clinical outcomes. Of note, one of the recently characterized features of CSCs is augmented mitochondrial function. The cytoskeleton network is essential in regulating mitochondrial morphology and rearrangement, which are inextricably linked to its functions, such as oxidative phosphorylation (OXPHOS). The interaction between the cytoskeleton and mitochondria can enable CSCs to adapt to challenging conditions, such as a lack of energy sources, and to maintain their stemness. Cytoskeleton-mediated mitochondrial trafficking and relocating to the high energy requirement region are crucial steps in epithelial-to-mesenchymal transition (EMT). In addition, the cytoskeleton itself interplays with and blocks the voltage-dependent anion channel (VDAC) to directly regulate bioenergetics. In this review, we describe the regulation of cellular bioenergetics in CSCs, focusing on the cytoskeleton-mediated dynamic control of mitochondrial structure and function.

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The Radical-Binding Lipocalin A1M Binds to a Complex I Subunit and Protects Mitochondrial Structure and Function

Antioxidants and Redox Signaling ◽

10.1089/ars.2012.4658 ◽

2013 ◽

Vol 18 (16) ◽

pp. 2017-2028 ◽

Cited By ~ 24

Author(s):

Magnus G. Olsson ◽

Lena W. Rosenlöf ◽

Heike Kotarsky ◽

Tor Olofsson ◽

Tomas Leanderson ◽

...

Keyword(s):

Complex I ◽

Structure And Function ◽

Mitochondrial Structure ◽

And Function

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Abstract 262: Knockout of Type VI Collagen Preserves Mitochondrial Structure and Function Following Myocardial Infarction

Circulation Research ◽

10.1161/res.117.suppl_1.262 ◽

2015 ◽

Vol 117 (suppl_1) ◽

Author(s):

J G Meszaros ◽

Daniel J Luther ◽

Patrick T Kang ◽

Yeong-Renn Chen ◽

R Lance Miller ◽

...

Keyword(s):

Myocardial Infarction ◽

Respiratory Control ◽

Ischemic Injury ◽

Structure And Function ◽

Matrix Proteins ◽

Mitochondrial Morphology ◽

Mitochondrial Structure ◽

Transmission Electron ◽

And Function

Cardiac remodeling is a dynamic process that is accelerated after myocardial infarction (MI), and the traditional focus of key extracellular matrix proteins that mediate remodeling has been on the fibrillar types I and III collagen. We have previously reported that knockout mice of the lesser-known, non-fibrillar collagen VI (Col6-/-) are protected from MI injury as evidenced by significantly reduced infarct size, fibrosis and apoptosis leading to preserved long-term cardiac function. Determining the mechanisms underlying this cardioprotection is the goal of this study. Interestingly, the Col6-/- mice are a model for Bethlam Myopathy, a rare skeletal muscular dystrophy that is characterized by mitochondrial dysfunction leading to premature apoptosis of skeletal myocytes. We hypothesized that alterations in mitochondrial structure and function in the myocardium of Col6-/- mice may play key mechanistic roles responses to ischemic injury. Mitochondrial morphology was visualized by transmission electron microscopy to compare pre- and post-MI changes. Mitochondria from uninjured Col6-/- LV tissue had similar morphology as WT, and at 3 days post-MI the mitochondrial morphology was similarly compromised in both WT and Col6-/- mice. However, at 14 days post-MI the Col6-/- mitochondria were less swollen (43 ± 5.1% decrease in overall volume) and displayed improved orientation/organization over WT (continuous strands). We measured basal O2 consumption and 24 hours post-MI in mitochondria isolated from the infarcted zones of both genotypes. The respiratory control index (RCI) of the Col6-/- mitochondria was lower in the basal, uninjured hearts (7.2 ± 0.9 in WT vs. 4.9 ± 0.6 in Col6-/-). However, the RCI of mitochondria in the infarcted region of Col6-/- hearts at 24 hours post-MI declined less than WT (post-MI values of 2.7 ± 0.5 in WT vs. 2.8 ± 0.7 in Col6-/-) . These data indicate that Col6-/- mice have preserved mitochondrial morphology and a smaller decline in respiration following MI, which may represent a novel homeostatic mechanism underlying protection from ischemic injury in the Col6-/- heart.

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