Increased Degradation Rates in the Components of the Mitochondrial Oxidative Phosphorylation Chain in the Cerebellum of Old Mice

Popa‐Wagner, Aurel; Sandu, Raluca Elena; Coman, Cristin; Uzoni, Adriana; Welle, Kevin; Hryhorenko, Jennifer R.; Ghaemmaghami, Sina

doi:10.3389/fnagi.2018.00032

Cited by 19 publications

(14 citation statements)

References 59 publications

(69 reference statements)

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“…The use of stable isotope labeling in conjunction with LC-MS/MS has opened the door for analyses of protein turnover kinetics on a global scale (4,9,17,18,29). In a number of model systems, proteomic studies have shown that aged individuals have significantly slowed protein turnover compared to younger counterparts (30)(31)(32), although this effect may not be universal and appears variable for different proteins, tissues and organisms (33)(34)(35)(36).…”

Section: Introductionmentioning

confidence: 99%

Interspecies differences in proteome turnover kinetics are correlated with lifespans and energetic demands

Swovick

Firsanov

Welle

et al. 2020

Preprint

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Cells continually degrade and replace damaged and old proteins. However, the high energetic demand of protein turnover generates reactive oxygen species (ROS) that compromise the long-term health of the proteome. Thus, the relationship between aging, protein turnover and energetic demand remains unclear. Here, we used a proteomic approach to measure rates of protein turnover within primary fibroblasts isolated from a number of species with diverse lifespans including the longest-lives rodent, the naked mole rat and the longest-lived mammal, the bowhead whale. We show that organismal lifespan is negatively correlated with turnover rates of highly abundant proteins. In comparison to mice, cells from long-lived naked mole rats have slower rates of protein turnover, lower levels of ATP production and reduced ROS levels. Despite having slower rates of protein turnover, naked mole rat cells tolerate protein misfolding stress more effectively than mouse cells. We suggest that in lieu of rapid constitutive turnover, longlived species may have evolved more energetically efficient mechanisms for selective detection and clearance of damaged proteins.

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Section: Introductionmentioning

confidence: 99%

Interspecies differences in proteome turnover kinetics are correlated with lifespans and energetic demands

Swovick

Firsanov

Welle

et al. 2020

Preprint

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“…One such ubiquitination target of Parkin is HIF-1, and Parkin expression was very recently shown to have an inverse correlation with both HIF-1 levels and metastasis in human breast cancer tissue [30]. As mentioned previously, with aging comes increased dysfunction in mitochondrial ETC proteins; imbalanced turnover has also been noted in proteins involved in the mitophagy process, for example in the mouse cerebellum [31] and aging skeletal muscle from several mammals [32]. An area of continued focus regarding the Parkin/PINK1 pathway are its roles in regulating basal mitophagy/proteostasis as opposed to activation only in response to a stress signal.…”

Section: Cellular Proteome Imbalance Results Through Numerous Mechanimentioning

confidence: 99%

When nature’s robots go rogue: exploring protein homeostasis dysfunction and the implications for understanding human aging disease pathologies

Reisz

Barrett

Nemkov

et al. 2018

Expert Review of Proteomics

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Proteins have been historically regarded as 'nature's robots': Molecular machines that are essential to cellular/extracellular physical mechanical properties and catalyze key reactions for cell/system viability. However, these robots are kept in check by other protein-based machinery to preserve proteome integrity and stability. During aging, protein homeostasis is challenged by oxidation, decreased synthesis, and increasingly inefficient mechanisms responsible for repairing or degrading damaged proteins. In addition, disruptions to protein homeostasis are hallmarks of many neurodegenerative diseases and diseases disproportionately affecting the elderly. Areas covered: Here we summarize age- and disease-related changes to the protein machinery responsible for preserving proteostasis and describe how both aging and disease can each exacerbate damage initiated by the other. We focus on alteration of proteostasis as an etiological or phenomenological factor in neurodegenerative diseases such as Alzheimer's, Parkinson's, and Huntington's, along with Down syndrome, ophthalmic pathologies, and cancer. Expert commentary: Understanding the mechanisms of proteostasis and their dysregulation in health and disease will represent an essential breakthrough in the treatment of many (senescence-associated) pathologies. Strides in this field are currently underway and largely attributable to the introduction of high-throughput omics technologies and their combination with novel approaches to explore structural and cross-link biochemistry.

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“…Popa-Wagner et al [ 62 ] have shown that the turnover rates for DMN1l and FIS1, which are proteins implicated in mitochondrial biogenesis, mitophagy, and fission go in opposite directions in the cerebellum of 22-month-old C57BL6j mice when compared to three-month-old mice. Unlike previous studies that have reported decreased turnover rates for the mitochondrial respiratory complexes of aged rodents, the authors found increased turnover rates for mitochondrial proteins of the oxidative phosphorylation chain in the aged mice when compared to young mice.…”

Section: Latest Findingsmentioning

confidence: 99%

Brain Mitochondria, Aging, and Parkinson’s Disease

Rango

Bresolin

2018

Genes

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This paper reconsiders the role of mitochondria in aging and in Parkinson’s Disease (PD). The most important risk factor for PD is aging. Alterations in mitochondrial activity are typical of aging. Mitochondrial aging is characterized by decreased oxidative phosphorylation, proteasome activity decrease, altered autophagy, and mitochondrial dysfunction. Beyond declined oxidative phosphorylation, mitochondrial dysfunction consists of a decline of beta-oxidation as well as of the Krebs cycle. Not inherited mitochondrial DNA (mtDNA) mutations are acquired over time and parallel the decrease in oxidative phosphorylation. Many of these mitochondrial alterations are also found in the PD brain specifically in the substantia nigra (SN). mtDNA deletions and development of respiratory chain deficiency in SN neurons of aged individuals as well as of individuals with PD converge towards a shared pathway, which leads to neuronal dysfunction and death. Finally, several nuclear genes that are mutated in hereditary PD are usually implicated in mitochondrial functioning to a various extent and their mutation may cause mitochondrial impairment. In conclusion, a tight link exists between mitochondria, aging, and PD.

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Increased Degradation Rates in the Components of the Mitochondrial Oxidative Phosphorylation Chain in the Cerebellum of Old Mice

Cited by 19 publications

References 59 publications

Interspecies differences in proteome turnover kinetics are correlated with lifespans and energetic demands

Interspecies differences in proteome turnover kinetics are correlated with lifespans and energetic demands

When nature’s robots go rogue: exploring protein homeostasis dysfunction and the implications for understanding human aging disease pathologies

Brain Mitochondria, Aging, and Parkinson’s Disease

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