scholarly journals Phosphatidylethanolamine made in the inner mitochondrial membrane is essential for yeast cytochromebc1complex function

2018 ◽  
Author(s):  
Elizabeth Calzada ◽  
J. Michael McCaffery ◽  
Steven M. Claypool
Keyword(s):  
Mitochondrial Function ◽  
Mitochondrial Membrane ◽  
Complex Iii ◽  
Biosynthetic Pathways ◽  
Outer Mitochondrial Membrane ◽  
Endomembrane System ◽  
Inner Mitochondrial Membrane ◽  
Mitochondrial Inner Membrane ◽  
Functional Analyses ◽  
Made In

ABSTRACTOf the four separate PE biosynthetic pathways in eukaryotes, one occurs in the mitochondrial inner membrane (IM) and is executed by phosphatidylserine decarboxylase (Psd1p). Deletion of Psd1, which is lethal in mice, compromises mitochondrial function. We hypothesize that this reflects inefficient import of non-mitochondrial PE into the IM. To test this, we re-wired PE metabolism in yeast by re-directing Psd1p to the outer mitochondrial membrane or the endomembrane system. Our biochemical and functional analyses identified the IMS as the greatest barrier for PE import and demonstrated that PE synthesis in the IM is critical for cytochromebc1complex (III) function. Importantly, mutations predicted to disrupt a conserved PE-binding site in the complex III subunit, Qcr7p, impaired complex III activity similar toPSD1deletion. Collectively, these data demonstrate that PE made in the IM by Psd1p is critical to support the intrinsic functionality of complex III and establish one likely mechanism.

Relationships between mitochondrial outer membranes and agranular reticulum in nervous tissue: ultrastructural observations and a new interpretation

1980 ◽  
Vol 46 (1) ◽  
pp. 129-147
Author(s):  
J. Spacek ◽  
A.R. Lieberman
Keyword(s):  
Nervous Tissue ◽  
Mitochondrial Membrane ◽  
Nerve Cells ◽  
Outer Mitochondrial Membrane ◽  
Inner Mitochondrial Membrane ◽  
Thin Sections ◽  
3 Dimensional ◽  
Outer Membranes ◽  
New Interpretation ◽  
In Cells

This study is concerned with extensions of the outer membranes of mitochondria in cells of nervous tissue, and with possible relationships between the extensions and the agranular reticulum. A variety of preparative techniques was applied to a large number of different central nervous tissues (CNS) and peripheral nervous tissues (PNS), using conventional thin sections, thicker sections (100 nm or more) and 3-dimensional reconstructions of serial thin sections. Extensions were commonly observed, particularly from the ends of longitudinally oriented mitochondria in axons and dendrites. Often these had the appearance of, and could be traced into apparent continuity with, adjacent elements of the agranular membrane. In addition to these apical tubular extensions, we also observed and reconstructed short lateral tubular or sac-like extensions and vesicular protrusions of the outer mitochondrial membrane. We discuss and discount the possibility that the extensions are artefacts, consider the structural and biochemical similarities between the outer mitochondrial membrane and agranular reticulum and propose that the outer mitochondrial is part of the agranular reticulum (or a specialized portion of the agranular reticulum). We suggest that the translocation of mitochondria in nerve cells, and probably in other cells as well, involves movement of the inner mitochondrial membrane and the enclosed matrix (mitoplast) within channels of agranular reticulum in continuity, or in transient continuity, with the outer mitochondrial membrane.

Synthesis of the inner mitochondrial membrane and the intercalation of respiratory enzymes during the cell cycle of Chlorella

1976 ◽  
Vol 21 (2) ◽  
pp. 329-340
Author(s):  
B.G. Forde ◽  
B.E. Gunning ◽  
P.C. John
Keyword(s):  
Cell Cycle ◽  
Succinate Dehydrogenase ◽  
Mitochondrial Membrane ◽  
Extended Period ◽  
Outer Mitochondrial Membrane ◽  
Inner Mitochondrial Membrane ◽  
Chlorella Fusca ◽  
Respiratory Enzymes ◽  
Membrane Area ◽  
Enzyme Molecules

The ratio of inner to outer mitochondrial membrane area remains close to 1–8 throughout the cell cycle in synchronized cells of Chlorella fusca var, vacuolata 211-8p. Using estimates of this ratio, together with our previous estimates of mitochondrial surface area, to calculate the absolute area of inner mitochondrial membrane, it is demonstrated that growth of the inner mitochondrial membrane during the cell cycle occupies an extended period and parallels the growth of the whole cell. In contrast, the synthesis of succinate dehydrogenase and cytochrome oxidase is restricted to the last third of the cell cycle. It is concluded that mitochondrial growth involves the intercalation of periodically synthesized respiratory enzymes into membranes made earlier in the cycle, with consequent 5-fold changes in the density of active enzyme molecules in the membrane. These observations are discussed in relation to the control of mitochondiral membrane synthesis, membrane assembly and respiration rate during the cell cycle.

scholarly journals Preprotein Translocase of the Outer Mitochondrial Membrane: Molecular Dissection and Assembly of the General Import Pore Complex

1998 ◽  
Vol 18 (11) ◽  
pp. 6515-6524 ◽  
Author(s):  
Peter J. T. Dekker ◽  
Michael T. Ryan ◽  
Jan Brix ◽  
Hanne Müller ◽  
Angelika Hönlinger ◽  
...  
Keyword(s):  
Mitochondrial Membrane ◽  
Complex Iii ◽  
Outer Mitochondrial Membrane ◽  
Molecular Architecture ◽  
Molecular Dissection ◽  
Yeast Mutant ◽  
Essential Proteins ◽  
Assembly Factor ◽  
Stable Association ◽  
Main Component

ABSTRACT The preprotein translocase of the outer mitochondrial membrane (Tom) is a multisubunit machinery containing receptors and a general import pore (GIP). We have analyzed the molecular architecture of the Tom machinery. The receptor Tom22 stably associates with Tom40, the main component of the GIP, in a complex with a molecular weight of ∼400,000 (∼400K), while the other receptors, Tom20 and Tom70, are more loosely associated with this GIP complex and can be found in distinct subcomplexes. A yeast mutant lacking both Tom20 and Tom70 can still form the GIP complex when sufficient amounts of Tom22 are synthesized. Besides the essential proteins Tom22 and Tom40, the GIP complex contains three small subunits, Tom5, Tom6, and Tom7. In mutant mitochondria lacking Tom6, the interaction between Tom22 and Tom40 is destabilized, leading to the dissociation of Tom22 and the generation of a subcomplex of ∼100K containing Tom40, Tom7, and Tom5. Tom6 is required to promote but not to maintain a stable association between Tom22 and Tom40. The following conclusions are suggested. (i) The GIP complex, containing Tom40, Tom22, and three small Tom proteins, forms the central unit of the outer membrane import machinery. (ii) Tom20 and Tom70 are not essential for the generation of the GIP complex. (iii) Tom6 functions as an assembly factor for Tom22, promoting its stable association with Tom40.

scholarly journals Molecular mechanism of mitochondrial phosphatidate transfer by Ups1

2020 ◽  
Vol 3 (1) ◽  
Author(s):  
Jiuwei Lu ◽  
Chun Chan ◽  
Leiye Yu ◽  
Jun Fan ◽  
Fei Sun ◽  
...  
Keyword(s):  
Conformational Changes ◽  
Mitochondrial Membrane ◽  
Outer Mitochondrial Membrane ◽  
Mitochondrial Membranes ◽  
Inner Mitochondrial Membrane ◽  
Membrane Interaction ◽  
Detailed Mechanism ◽  
Physiological Regulator ◽  
Membrane Bound ◽  
Dynamics Simulations

AbstractCardiolipin, an essential mitochondrial physiological regulator, is synthesized from phosphatidic acid (PA) in the inner mitochondrial membrane (IMM). PA is synthesized in the endoplasmic reticulum and transferred to the IMM via the outer mitochondrial membrane (OMM) under mediation by the Ups1/Mdm35 protein family. Despite the availability of numerous crystal structures, the detailed mechanism underlying PA transfer between mitochondrial membranes remains unclear. Here, a model of Ups1/Mdm35-membrane interaction is established using combined crystallographic data, all-atom molecular dynamics simulations, extensive structural comparisons, and biophysical assays. The α2-loop, L2-loop, and α3 helix of Ups1 mediate membrane interactions. Moreover, non-complexed Ups1 on membranes is found to be a key transition state for PA transfer. The membrane-bound non-complexed Ups1/ membrane-bound Ups1 ratio, which can be regulated by environmental pH, is inversely correlated with the PA transfer activity of Ups1/Mdm35. These results demonstrate a new model of the fine conformational changes of Ups1/Mdm35 during PA transfer.

scholarly journals Mitochondrial respiratory chain inhibitors modulate the metal-induced inner mitochondrial membrane permeabilization.

2010 ◽  
Vol 57 (4) ◽  
Author(s):  
Elena A Belyaeva
Keyword(s):  
Heavy Metal ◽  
Mitochondrial Membrane ◽  
Molecular Mechanisms ◽  
Protective Action ◽  
Membrane Permeabilization ◽  
Mitochondrial Swelling ◽  
Complex Iii ◽  
Rat Liver Mitochondria ◽  
Inner Mitochondrial Membrane ◽  
Mitochondrial Membrane Permeabilization

To elucidate the molecular mechanisms of the protective action of stigmatellin (an inhibitor of complex III of mitochondrial electron transport chain, mtETC) against the heavy metal-induced cytotoxicity, we tested its effectiveness against mitochondrial membrane permeabilization produced by heavy metal ions Cd²(+), Hg²(+), Cu²(+) and Zn²(+), as well as by Ca²(+) (in the presence of P(i)) or Se (in form of Na₂SeO₃) using isolated rat liver mitochondria. It was shown that stigmatellin modulated mitochondrial swelling produced by these metals/metalloids in the isotonic sucrose medium in the presence of ascorbate plus tetramethyl-p-phenylenediamine (complex IV substrates added for energization of the mitochondria). It was found that stigmatellin and other mtETC inhibitors enhanced the mitochondrial swelling induced by selenite. However, in the same medium, all the mtETC inhibitors tested as well as cyclosporin A and bongkrekic acid did not significantly affect Cu²(+)-induced swelling. In contrast, the high-amplitude swelling produced by Cd²(+), Hg²(+), Zn²(+), or Ca²(+) plus P(i) was significantly depressed by these inhibitors. Significant differences in the action of these metals/metalloids on the redox status of pyridine nucleotides, transmembrane potential and mitochondrial respiration were also observed. In the light of these results as well as the data from the recent literature, our hypothesis on a possible involvement of the respiratory supercomplex, formed by complex I (P-site) and complex III (S-site) in the mitochondrial permeabilization mediated by the mitochondrial transition pore, is updated.

scholarly journals Complex III Releases Superoxide to Both Sides of the Inner Mitochondrial Membrane

2004 ◽  
Vol 279 (47) ◽  
pp. 49064-49073 ◽  
Author(s):  
Florian L. Muller ◽  
Yuhong Liu ◽  
Holly Van Remmen
Keyword(s):  
Mitochondrial Membrane ◽  
Complex Iii ◽  
Inner Mitochondrial Membrane

scholarly journals Tim29 is a novel subunit of the human TIM22 translocase and is involved in complex assembly and stability

eLife ◽  
2016 ◽  
Vol 5 ◽  
Author(s):  
Yilin Kang ◽  
Michael James Baker ◽  
Michael Liem ◽  
Jade Louber ◽  
Matthew McKenzie ◽  
...  
Keyword(s):  
Mitochondrial Membrane ◽  
Intermembrane Space ◽  
Outer Mitochondrial Membrane ◽  
Carrier Proteins ◽  
Mitochondrial Import ◽  
Inner Membrane ◽  
Mitochondrial Inner Membrane ◽  
C Terminus ◽  
The Stability ◽  
Human Complex

The TIM22 complex mediates the import of hydrophobic carrier proteins into the mitochondrial inner membrane. While the TIM22 machinery has been well characterised in yeast, the human complex remains poorly characterised. Here, we identify Tim29 (C19orf52) as a novel, metazoan-specific subunit of the human TIM22 complex. The protein is integrated into the mitochondrial inner membrane with it’s C-terminus exposed to the intermembrane space. Tim29 is required for the stability of the TIM22 complex and functions in the assembly of hTim22. Furthermore, Tim29 contacts the Translocase of the Outer Mitochondrial Membrane, TOM complex, enabling a mechanism for transport of hydrophobic carrier substrates across the aqueous intermembrane space. Identification of Tim29 highlights the significance of analysing mitochondrial import systems across phylogenetic boundaries, which can reveal novel components and mechanisms in higher organisms.

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