Metalloproteases of the Inner Mitochondrial Membrane

Levytskyy, Roman M.; Bohovych, Iryna; Khalimonchuk, Oleh

doi:10.1021/acs.biochem.7b00663

Cited by 50 publications

(41 citation statements)

References 91 publications

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“…The significance of these proteases for mitochondrial quality control in neurons is clear from the neurologic phenotypes associated with mutations in their genes. These phenotypes include non-syndromic mental retardation, spastic paraplegia, and spastic and spinocerebellar ataxias (Levytskyy et al, 2017). When oxidative damage has occurred, this mode of protein turnover may be considered the mitochondrion’s first line of defense, capable of removing a potentially problematic protein as soon as it forms.…”

Section: How Are Mitochondria Cleared?mentioning

confidence: 99%

Mitostasis in Neurons: Maintaining Mitochondria in an Extended Cellular Architecture

Misgeld

Schwarz

2017

Neuron

406

409

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SUMMARY Neurons have more extended and complex shapes than other cells and consequently face a greater challenge in distributing and maintaining mitochondria throughout their arbors. Neurons can last a lifetime, but proteins turn over rapidly. Mitochondria, therefore, need constant rejuvenation no matter how far they are from the soma. Axonal transport of mitochondria and mitochondrial fission and fusion contribute to this rejuvenation, with local protein synthesis likely also to be involved. Maintenance of a healthy mitochondrial population also requires the clearance of damaged proteins and organelles. This involves degradation of individual proteins, sequestration in mitochondria-derived vesicles, organelle degradation by mitophagy and macroautophagy, and in some cases transfer to glial cells. Both long-range transport and local processing are thus at work in achieving neuronal mitostasis – the maintenance of an appropriately distributed pool of healthy mitochondria for the duration of a neuron’s life. Accordingly, defects in the processes that support mitostasis are significant contributors to neurodegenerative disorders.

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Section: How Are Mitochondria Cleared?mentioning

confidence: 99%

Mitostasis in Neurons: Maintaining Mitochondria in an Extended Cellular Architecture

Misgeld

Schwarz

2017

Neuron

406

409

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“…Several other proteolytic events in cells, such as removal of a signal peptide by signal peptidase (Blobel & Dobberstein, ) and proteolytic cleavages by mitochondrial AAA proteases (Levytskyy et al , ), formally share similarities to ectodomain shedding, but will not be discussed in this review, as they occur either during protein biosynthesis but not on the mature protein (signal peptidase), or do not occur in the secretory or endocytic pathway (mitochondria).…”

Section: Definition Of Ectodomain Sheddingmentioning

confidence: 99%

“…Cleavage sites within the juxtamembrane region are typically at a short distance of often 10 -35 amino acids from the TM segment, but more distant cleavage sites are possible and, in fact, the exact cleavage sites have only been determined for few shedding substrates (e.g., summarized for ADAMs and BACE1 in Caescu et al, 2009;Yan, 2017). Several other proteolytic events in cells, such as removal of a signal peptide by signal peptidase (Blobel & Dobberstein, 1975) and proteolytic cleavages by mitochondrial AAA proteases (Levytskyy et al, 2017), formally share similarities to ectodomain shedding, but will not be discussed in this review, as they occur either during protein biosynthesis but not on the mature protein (signal peptidase), or do not occur in the secretory or endocytic pathway (mitochondria).…”

Section: Definition Of Ectodomain Sheddingmentioning

confidence: 99%

Proteolytic ectodomain shedding of membrane proteins in mammals—hardware, concepts, and recent developments

2018

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Proteolytic removal of membrane protein ectodomains (ectodomain shedding) is a post-translational modification that controls levels and function of hundreds of membrane proteins. The contributing proteases, referred to as sheddases, act as important molecular switches in processes ranging from signaling to cell adhesion. When deregulated, ectodomain shedding is linked to pathologies such as inflammation and Alzheimer's disease. While proteases of the "a disintegrin and metalloprotease" (ADAM) and "beta-site APP cleaving enzyme" (BACE) families are widely considered as sheddases, in recent years a much broader range of proteases, including intramembrane and soluble proteases, were shown to catalyze similar cleavage reactions. This review demonstrates that shedding is a fundamental process in cell biology and discusses the current understanding of sheddases and their substrates, molecular mechanisms and cellular localizations, as well as physiological functions of protein ectodomain shedding. Moreover, we provide an operational definition of shedding and highlight recent conceptual advances in the field. While new developments in proteomics facilitate substrate discovery, we expect that shedding is not a rare exception, but rather the rule for many membrane proteins, and that many more interesting shedding functions await discovery.

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“…YME1L preserves mitochondrial proteostasis and function acting both as a quality control and as a regulatory enzyme in the IM (Quiros et al, 2015;Levytskyy et al, 2017). Besides cleaving OPA1, it degrades damaged or non-assembled IM proteins such as respiratory chain subunits or TIMM17A, a subunit of a protein translocase in the IM (Stiburek et al, 2012;Rainbolt et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Loss of the mitochondrial i ‐ AAA protease YME 1L leads to ocular dysfunction and spinal axonopathy

et al. 2018

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Disturbances in the morphology and function of mitochondria cause neurological diseases, which can affect the central and peripheral nervous system. The i‐AAA protease YME1L ensures mitochondrial proteostasis and regulates mitochondrial dynamics by processing of the dynamin‐like GTPase OPA1. Mutations in YME1L cause a multi‐systemic mitochondriopathy associated with neurological dysfunction and mitochondrial fragmentation but pathogenic mechanisms remained enigmatic. Here, we report on striking cell‐type‐specific defects in mice lacking YME1L in the nervous system. YME1L‐deficient mice manifest ocular dysfunction with microphthalmia and cataracts and develop deficiencies in locomotor activity due to specific degeneration of spinal cord axons, which relay proprioceptive signals from the hind limbs to the cerebellum. Mitochondrial fragmentation occurs throughout the nervous system and does not correlate with the degenerative phenotype. Deletion of Oma1 restores tubular mitochondria but deteriorates axonal degeneration in the absence of YME1L, demonstrating that impaired mitochondrial proteostasis rather than mitochondrial fragmentation causes the observed neurological defects.

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Metalloproteases of the Inner Mitochondrial Membrane

Cited by 50 publications

References 91 publications

Mitostasis in Neurons: Maintaining Mitochondria in an Extended Cellular Architecture

Mitostasis in Neurons: Maintaining Mitochondria in an Extended Cellular Architecture

Proteolytic ectodomain shedding of membrane proteins in mammals—hardware, concepts, and recent developments

Loss of the mitochondrial i ‐ AAA protease YME 1L leads to ocular dysfunction and spinal axonopathy

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