Oma1, a Novel Membrane-bound Metallopeptidase in Mitochondria with Activities Overlapping with the m-AAA Protease

Käser, Michael; Kambacheld, Melanie; Kisters‐Woike, Brigitte; Langer, Thomas

doi:10.1074/jbc.m305584200

Cited by 141 publications

(155 citation statements)

References 53 publications

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“…This was consistent with the notion of membrane stress responses; abnormal membrane proteins are expected to be attacked from both sides of the membrane. Kaser et al (31) reported recently that a membrane-bound metalloprotease called Oma1 functions in the degradation of a mitochondrial membrane protein in conjunction with Yta10/12, a mitochondrial homolog of the FtsH protease. Unlike HtpX, Oma1 was reported to cleave a substrate membrane protein on both sides of the membrane.…”

Section: Discussionmentioning

confidence: 99%

Proteolytic Activity of HtpX, a Membrane-bound and Stress-controlled Protease from Escherichia coli

Sakoh

Ito

Akiyama

2005

Journal of Biological Chemistry

100

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Escherichia coli HtpX is a putative membrane-bound zinc metalloprotease that has been suggested to participate in the proteolytic quality control of membrane proteins in conjunction with FtsH, a membrane-bound and ATP-dependent protease. Here, we biochemically characterized HtpX and confirmed its proteolytic activities against membrane and soluble proteins. HtpX underwent selfdegradation upon cell disruption or membrane solubilization. Consequently, we purified HtpX under denaturing conditions and then refolded it in the presence of a zinc chelator. When supplemented with Zn 2؉ , the purified enzyme exhibited self-cleavage activity. In the presence of zinc, it also degraded casein and cleaved a solubilized membrane protein, SecY. We verified its ability to cleave SecY in vivo by overproducing both HtpX and SecY. These results showed that HtpX is a zinc-dependent endoprotease member of the membrane-localized proteolytic system in E. coli.It is vital for cells that membranes and membrane proteins retain their integrity. Malfolded and misassembled membrane proteins, produced under stressful conditions and in non-physiological situations, should receive proteolytic quality control. In Escherichia coli, FtsH, a membrane-bound and ATP-dependent zinc metalloprotease, is known to play a central role in the degradation of unstable membrane proteins (1, 2). Thus, it degrades SecY, a subunit of protein translocase (3), and Fo subunit a of proton ATPase (4) when they have failed to assemble. It also degrades YccA, the function of which is unknown (5), and some unstable cytosolic proteins (1, 2). A characteristic feature of FtsH is that it processively degrades membrane-protein substrates by recognizing their ends when they protrude sufficiently into the cytosol (6, 7). This degradation appears to be accompanied by dislocation of the substrate from the membrane, a process presumably mediated by the ATPase function of .In E. coli, only a few other membrane-integrated proteases are known: DegS and RseP (YaeL), which introduce regulated cleavage into a membrane-bound substrate (11-13), and Lep, which cleaves off a signal peptide of secretory precursor proteins (14). HtpX was first described by Kornitzer et al. (15) as a heat-inducible protein from E. coli with sequence features of a membrane protein and a metalloprotease. They showed that its expression, in a form truncated at the C-terminal, enhanced degradation of cellular proteins in puromycin-treated cells (15). Subsequently, it was also shown that the htpX gene in Xylella fastidiosa was induced by an increase in temperature (16), whereas the Streptococcus gordonii htpX was not heat-inducible (17). Disruption of S. gordonii htpX caused changes in several properties of the cell surface, although the relationship of these changes with any protease activity of HtpX was unclear (17).We rediscovered HtpX during the course of study of cellular responses to "membrane protein stress." Our results showed that ftsH disruption led to the induction of the Cpx stress response, which wa...

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Section: Discussionmentioning

confidence: 99%

Proteolytic Activity of HtpX, a Membrane-bound and Stress-controlled Protease from Escherichia coli

Sakoh

Ito

Akiyama

2005

Journal of Biological Chemistry

100

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“…Although some proteases appear to exert regulatory functions during mitochondrial biogenesis, a role for others in quality control is just emerging. These include the metallopeptidase Oma1, which was originally discovered in yeast to cleave a mutant IM protein in the absence of the m-AAA protease and was thus termed Oma1 because of its overlapping activity with the m-AAA protease (Käser et al 2003). Oma1 is evolutionarily conserved and is also found in higher eukaryotes, although a role in turnover/processing of misfolded proteins substrates has not yet been assigned.…”

Section: Mitochondrial Quality Controlmentioning

confidence: 99%

Quality Control of Mitochondrial Proteostasis

Baker

Tatsuta²,

Langer

2011

Cold Spring Harbor Perspectives in Biology

230

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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“…OMA1 was identified in yeast as an ATP-independent zinc metalloprotease that locates at mitochondrial inner membrane and displays activities overlapping with a m-AAA protease [12]. OMA1 is a mitochondrial quality control protease and was reported as a new key regulator of metabolic homeostasis [13].…”

Section: Introductionmentioning

confidence: 99%

Membrane depolarization activates the mitochondrial protease OMA 1 by stimulating self‐cleavage

2014

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Mitochondrial inner membrane fusion depends on the dynaminrelated GTPase OPA1 and the function of OPA1 is regulated by proteolytic cleavage. The mitochondrial proteases Yme1L and OMA1 cleave OPA1 at S2 and S1 sites, respectively. Here, we show that OMA1 is cleaved to a short form (S-OMA1) by itself upon mitochondrial membrane depolarization; S-OMA1 is degraded quickly but could be stabilized by CCCP treatment or Prohibitin knockdown in cells. In addition, OMA1 processing is positively correlated with OPA1 cleavage at the S1 site and the regulation of mitochondrial morphology. Thus, our results reveal the molecular mechanism for OMA1 activation toward OPA1 processing.

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Oma1, a Novel Membrane-bound Metallopeptidase in Mitochondria with Activities Overlapping with the m-AAA Protease

Cited by 141 publications

References 53 publications

Proteolytic Activity of HtpX, a Membrane-bound and Stress-controlled Protease from Escherichia coli

Proteolytic Activity of HtpX, a Membrane-bound and Stress-controlled Protease from Escherichia coli

Quality Control of Mitochondrial Proteostasis

Membrane depolarization activates the mitochondrial protease OMA 1 by stimulating self‐cleavage

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