The Yeast Mitochondrial Proteome, a Study of Fermentative and Respiratory Growth

Ohlmeier, Steffen; Kastaniotis, Alexander J.; Hiltunen, J. Kalervo; Bergmann, Ulrich

doi:10.1074/jbc.m310160200

Cited by 156 publications

(161 citation statements)

References 85 publications

(66 reference statements)

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“…In the case of various CYP and glutathione S-transferase proteins, detailed analysis of targeting mechanism shows a need for the activation of chimeric MT-targeting signals by physiological factors (9 -11, 14). These results on bimodal targeting are also supported by recent proteomic data showing a large number of proteins identified as part of mitochondrial proteome are also localized to extramitochondrial compartments, including the cytosol, peroxisomes, and ER membrane (5)(6)(7)(8). It is therefore highly likely that the bimodal targeting, driven by chimeric NH 2 -terminal signals as shown for various CYP and glutathione S-transferase enzymes, represents a precisely evolved physiological process with functional significance.…”

Section: Erod Erndsupporting

confidence: 67%

“…It remains to be determined if this step is also an important regulatory step that determines the extent of MT targeting. It is becoming increasingly apparent that mitochondria from lower eukaryotes as well as from mammalian cells contain a large number of proteins that were previously thought to be exclusively extramitochondrial in their location and function (5)(6)(7)(8). It is estimated that nearly 50% of the Ͼ1500 proteins associated with mammalian mitochondria may lack canonical mitochondrial-targeting signals.…”

Section: Erod Erndmentioning

confidence: 99%

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Role of Protein Kinase C-mediated Protein Phosphorylation in Mitochondrial Translocation of Mouse CYP1A1, Which Contains a Non-canonical Targeting Signal

Dasari

Anandatheerthavarada

Robin

et al. 2006

Journal of Biological Chemistry

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A large number of mitochondrial proteins lack canonical mitochondrial-targeting signals. The bimodal transport of cytochromes P450 (CYPs) to endoplasmic reticulum and mitochondria (MT), reported previously by us, likely represents one mode of non-canonical protein targeting to MT. Herein, we have studied the mechanism of mouse MT-CYP1A1 targeting to gain insight into the regulatory features and evolutionary conservation of bimodal targeting mechanism. Mouse MT-CYP1A1 consists of two NH 2 -terminal-truncated molecular species, ؉91A1 and ؉331A1. Mutations Pro-2 3 Leu and Tyr-5 3 Leu, which increase the signal recognition particle ( Proteins targeted to mitochondria contain either NH 2 -terminal or internal signals, which include amphipathic ␣-helices, ␤-sheet, and random structures with spaced positively charged residues (1-3). A majority of the NH 2 -terminally located mitochondrial-targeting signals are cleaved by the mitochondrial matrix metalloprotease following their import, although in a number of cases the signals remain uncleaved (1-4). Recent proteomic studies indicate that yeast mitochondria contain as many as 800 proteins while the rodent heart and liver mitochondria may contain well over 1500 proteins (5-8). It is estimated that Ͼ50% of mitochondria-associated proteins in both yeast and mammalian cells lack canonical MT 4 -targeting signals, and the precise mode of targeting of these proteins as well as mechanism of their translocation across the MT membranes remain unclear. The bimodal targeting of CYPs to ER and MT, Alzheimer amyloid precursor protein to plasma membrane and MT, and translocation of cytosolic Glutathione S-transferases to MT (9 -14) may represent one mode of targeting of noncanonical signal containing proteins to the MT compartment.Recent studies from our laboratory showed that different xenobiotic-inducible CYPs such as rat CYP1A1, CYP2E1, and CYP2B1 and others that are widely recognized as microsomal proteins (MC-CYPs) are also targeted to varying degrees to mitochondria (9 -11). These studies led to the concept of a new family of chimeric non-canonical-targeting signals, which function both as ER-targeting and MT-targeting signals, under different physiological conditions. We proposed that bimodal targeting of these CYP proteins is facilitated by the cryptic MTtargeting signal domain (residues 29 -40), located between the transmembrane helical domain (residues 1-30) and the Prorich domain (residues 39 -44) in various members of the CYP1, CYP2, and CYP3 families. We have also shown that the cryptic MT-targeting signals of different CYPs are activated by two distinct mechanisms: (a) endoproteolytic cleavage of the NH 2 -

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Section: Erod Erndsupporting

confidence: 67%

Section: Erod Erndmentioning

confidence: 99%

Role of Protein Kinase C-mediated Protein Phosphorylation in Mitochondrial Translocation of Mouse CYP1A1, Which Contains a Non-canonical Targeting Signal

Dasari

Anandatheerthavarada

Robin

et al. 2006

Journal of Biological Chemistry

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“…The known assembly factors involved in copper ion metallation of CcO are not likely to contribute to the mitochondrial copper pool because they are low abundance proteins. A recent mitochondrion proteomic study showed Sco1 to be a low abundant protein comparable in levels of the CcO subunit Cox6 (42).…”

Section: Resultsmentioning

confidence: 99%

Yeast Contain a Non-proteinaceous Pool of Copper in the Mitochondrial Matrix

Cobine

Ojeda

Rigby

et al. 2004

Journal of Biological Chemistry

203

199

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The yeast mitochondrion is shown to contain a pool of copper that is distinct from that associated with the two known mitochondrial cuproenzymes, superoxide dismutase (Sod1) and cytochrome c oxidase (CcO) and the copper-binding CcO assembly proteins Cox11, Cox17, and Sco1. Only a small fraction of mitochondrial copper is associated with these cuproproteins. The bulk of the remainder is localized within the matrix as a soluble, anionic, low molecular weight complex. The identity of the matrix copper ligand is unknown, but the bulk of the matrix copper fraction is not protein-bound. The mitochondrial copper pool is dynamic, responding to changes in the cytosolic copper level. The addition of copper salts to the growth medium leads to an increase in mitochondrial copper, yet the expansion of this matrix pool does not induce any respiration defects. The matrix copper pool is accessible to a heterologous cuproenzyme. Co-localization of human Sod1 and the metallochaperone CCS within the mitochondrial matrix results in suppression of growth defects of sod2⌬ cells. However, in the absence of CCS within the matrix, the activation of human Sod1 can be achieved by the addition of copper salts to the growth medium.Copper is an essential cell nutrient acting as a cofactor in nearly 20 enzymes (1). However, excess accumulation of copper ions results in toxicity. Evidence for the effectiveness of copper ions as a toxin comes from its historic use as a fungicide, molluscide, and algicide. Homeostatic mechanisms exist in cells to regulate the cellular concentration of copper ions, thus maintaining copper balance and minimizing deleterious effects. Cells appear to maintain a quota for essential metal ions; this quota is primarily the quantity necessary to metallate the various copper proteins (2, 3). Copper ions are required for at least three key enzymes in Saccharomyces cerevisiae. The cuproenzymes include the cytosolic superoxide dismutase Sod1, 1 the plasma membrane ferroxidase Fet3, and the mitochondrial inner membrane enzyme cytochrome c oxidase (CcO). The copper quota of the yeast S. cerevisiae is about 5 ϫ 10 5 atoms per cell (3, 4).It is unclear what fraction of the 5 ϫ 10 5 copper atoms per cell is from copper in Sod1, Fet3, and CcO. Expression of these copper-binding proteins varies with growth conditions, suggesting that the copper may be distributed differently depending on growth conditions. Clearly, a significant fraction of the cellular copper is associated with Sod1; however, not all Sod1 molecules are metallated (4, 5). Fet3 requires four copper ions for activity, but levels of this protein are dependent on iron status of the medium (6). CcO levels vary depending on whether the cells are grown by fermentation or respiration. In addition, a varying quantity of cellular copper exists bound to two metallothioneins, Cup1 and Crs5 (7,8). Expression of CUP1 and CRS5 is regulated by copper levels through the copper-responsive transcription factor Ace1 (9, 10). An increase in the free Cu(I) ion pool activates Ace1 throu...

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“…The purity of organelles and other protein complexes is crucial to subcellular proteome research [13][14][15][16][17]. For the isolation of subcellular structures and organelles several methods, such as differential-and density-gradient centrifugation [18][19][20], immunoisolation [8], affinity purification, [21], and freeflow electrophoresis [22], have been applied. It has been shown that such fractionations improved identification of proteins from targeted subcellular structures [8,10,[12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Use of selective extraction and fast chromatographic separation combined with electrophoretic methods for mapping of membrane proteins

et al. 2005

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Use of selective extraction and fast chromatographic separation combined with electrophoretic methods for mapping of membrane proteinsA model system for selective solubilization and fast separation of proteins from the rat liver membrane fraction and purified rat liver plasma membranes for their further proteomic analysis is presented. For selective solubilization, high-pH solutions and a concentrated urea solution, combined with different detergents, are used. After extraction, proteins are separated by anion-exchange chromatography or a combination of anion-and cation-exchange chromatography with convective interaction monolithic supports. This separation method enables fast and effective prefractionation of membrane proteins based on their hydrophobicity and charge prior to one-dimensional (1-D) and 2-D electrophoresis and mass spectrometry. By use of this sample preparation method, the less-abundant proteins can be detected and identified.

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The Yeast Mitochondrial Proteome, a Study of Fermentative and Respiratory Growth

Cited by 156 publications

References 85 publications

Role of Protein Kinase C-mediated Protein Phosphorylation in Mitochondrial Translocation of Mouse CYP1A1, Which Contains a Non-canonical Targeting Signal

Role of Protein Kinase C-mediated Protein Phosphorylation in Mitochondrial Translocation of Mouse CYP1A1, Which Contains a Non-canonical Targeting Signal

Yeast Contain a Non-proteinaceous Pool of Copper in the Mitochondrial Matrix

Use of selective extraction and fast chromatographic separation combined with electrophoretic methods for mapping of membrane proteins

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