Keren Demishtein-Zohary scite author profile

Background:The vital interaction between components of the TIM23 import complex and presequences is poorly characterized. Results: A direct interaction between presequences and components of TIM23 was demonstrated and characterized. Conclusions: Trans binding sites exhibit stronger interaction than cis sites. Significance: Stronger binding to the trans side of the TIM23 complex provides an additional driving force for mitochondrial protein import.

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Chloroplast β chaperonins from A. thaliana function with endogenous cpn10 homologs in vitro

Vitlin

Weiss

Demishtein-Zohary

et al. 2011

Plant Mol Biol

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The involvement of type I chaperonins in bacterial and organellar protein folding has been well-documented. In E. coli and mitochondria, these ubiquitous and highly conserved proteins form chaperonin oligomers of identical 60 kDa subunits (cpn60), while in chloroplasts, two distinct cpn60 α and β subunit types co-exist together. The primary sequence of α and β subunits is ~50% identical, similar to their respective homologies to the bacterial GroEL. Moreover, the A. thaliana genome contains two α and four β genes. The functional significance of this variability in plant chaperonin proteins has not yet been elucidated. In order to gain insight into the functional variety of the chloroplast chaperonin family members, we reconstituted β homo-oligomers from A. thaliana following their expression in bacteria and subjected them to a structure-function analysis. Our results show for the first time, that A. thaliana β homo-oligomers can function in vitro with authentic chloroplast co-chaperonins (ch-cpn10 and ch-cpn20). We also show that oligomers made up of different β subunit types have unique properties and different preferences for co-chaperonin partners. We propose that chloroplasts may contain active β homo-oligomers in addition to hetero-oligomers, possibly reflecting a variety of cellular roles.

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The TIM23 mitochondrial protein import complex: function and dysfunction

Demishtein-Zohary

Azem

2016

Cell Tissue Res

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Mitochondria acquire the majority of their proteins from the cytosol in a process that is mediated by intricate multimeric machineries designed to allow proteins to cross and/or to insert themselves into the two mitochondrial membranes. Ongoing studies carried out in yeast over the past few decades have led to the discovery of numerous protein components that constitute several mitochondrial translocases. One of these complexes, the mitochondrial TIM23, is the major translocase for matrix proteins and is the focus of this review. The components of the TIM23 complex are categorized into four functional types. The first type plays the role of receptor for preproteins in the intermembrane space. The second type forms the actual channel that allows proteins to cross the inner mitochondrial membrane. The third species functions as part of the motor that mediates the final steps of import across the inner membrane. Additional components play regulatory roles orchestrating the action of this myriad of subunits. Recent studies provide new insights into the function of the mammalian TIM23 complex and the role that it plays under pathological conditions.

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GxxxG motifs hold the TIM23 complex together

et al. 2015

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Approximately 99% of the mitochondrial proteome is nucleus-encoded, synthesized in the cytosol, and subsequently imported into and sorted to the correct compartment in the organelle. The translocase of the inner mitochondrial membrane 23 (TIM23) complex is the major protein translocase of the inner membrane, and is responsible for translocation of proteins across the inner membrane and their insertion into the inner membrane. Tim23 is the central component of the complex that forms the import channel. A high-resolution structure of the import channel is still missing, and structural elements important for its function are unknown. In the present study, we analyzed the importance of the highly abundant GxxxG motifs in the transmembrane segments of Tim23 for the structural integrity of the TIM23 complex. Of 10 glycines present in the GxxxG motifs in the first, second and third transmembrane segments of Tim23, mutations of three of them in transmembrane segments 1 and 2 resulted in a lethal phenotype, and mutations of three others in a temperature-sensitive phenotype. The remaining four caused no obvious growth phenotype. Importantly, none of the mutations impaired the import and membrane integration of Tim23 precursor into mitochondria. However, the severity of growth impairment correlated with the destabilization of the TIM23 complex. We conclude that the GxxxG motifs found in the first and second transmembrane segments of Tim23 are necessary for the structural integrity of the TIM23 complex.

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Role of Tim17 in coupling the import motor to the translocation channel of the mitochondrial presequence translocase

Demishtein-Zohary

Günsel

Marom

et al. 2017

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The majority of mitochondrial proteins use N-terminal presequences for targeting to mitochondria and are translocated by the presequence translocase. During translocation, proteins, threaded through the channel in the inner membrane, are handed over to the import motor at the matrix face. Tim17 is an essential, membrane-embedded subunit of the translocase; however, its function is only poorly understood. Here, we functionally dissected its four predicted transmembrane (TM) segments. Mutations in TM1 and TM2 impaired the interaction of Tim17 with Tim23, component of the translocation channel, whereas mutations in TM3 compromised binding of the import motor. We identified residues in the matrix-facing region of Tim17 involved in binding of the import motor. Our results reveal functionally distinct roles of different regions of Tim17 and suggest how they may be involved in handing over the proteins, during their translocation into mitochondria, from the channel to the import motor of the presequence translocase.DOI: http://dx.doi.org/10.7554/eLife.22696.001

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