Import of Presequence-Containing Precursor Proteins into Mitochondria

Melin, Jonathan

03 July 2014

No description available.

572

mitochondria

presequence

TOM

Biologie (PPN619462639)

Protein interactions along the presequence import pathway

Schulz, Christian

11 November 2013

No description available.

570

mitochondria

protein translocation

presequence

Tim50

Biologie (PPN619462639)

Import of proteins along the presequence pathway

Schendzielorz, Alexander Benjamin

15 November 2017

No description available.

572

Biologie (PPN619462639)

Functional and structural studies of the Presequence protease, PreP

Bäckman, Hans G

January 2014

AtPreP (Arabidopsis thaliana Presequence Protease) is a zink metallooligopeptidase that is dually targeted to both mitochondria and chloroplasts. In these organelles it functions as a peptidasome that degrades the N-terminal targeting peptides that are cleaved off from the mature protein after protein import, as well as other unstructured peptides. In A. thaliana there are two isoforms of PreP, AtPreP1 and AtPreP2.  We have performed characterization studies of single and double prep knockout plants. Immunoblot analysis revealed that both PreP isoforms are expressed in all tissues with highest expression levels in flowers and siliques. Furthermore, AtPreP1 was shown to be the most abundant isoform of the two. When comparing phenotype, the atprep2 mutant was similar to wild type, whereas the atprep1 mutant had a slight pale-green phenotype in the early developmental stages. The atprep1 atprep2 double knockout plants showed a chlorotic phenotype in true leaves, especially prominent during the early developmental stages. When analysing the first true leaves of double knockout plants, we found a significant decrease in chlorophyll a and b content. Mitochondrial respiratory rates measurements showed partially uncoupled mitochondria. Ultrastructure analysis using electron microscopy on double knockout plants showed aberrant chloroplasts with altered grana stacking and clearly fewer starch granules. Older plants showed less altered  phenotype, although there was a significant decrease in the accumulated biomass of about 40% compared to wild type. Peptidolytic activity studies showed no sign of compensatory mechanisms in the absence of AtPreP in mitochondria; in contrast we found a peptidolytic activity in the chloroplast membranes not related to AtPreP. In addition to zinc located in the catalytic site, crystallographic data revealed two Mg-binding sites in the AtPreP structure. To further investigate the role of these Mg-binding sites, we have made AtPreP variants that are unable to bind metal ions. Our data shows that one of these sites located close to the catalytic site is important for the activity of AtPreP. We also measured proteolytic activity of four human PreP-SNP variants and observed that the activity of all the hPreP-SNPs variants was lower; especially the hPreP-SNP (A525D) variant that displayed only 20-30 % of wild type activity. Interestingly, the activity was fully restored for all SNP-variants by addition of Mg2+.

Presequence Protease

PreP

AtPreP

hPreP

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Insights into mitochondrial presequence and carrier import pathways

Gomkale, Ridhima

12 November 2018

No description available.

572

Mitochondria

Import

presequence pathway

carrier pathway

Biologie (PPN619462639)

Unraveling the Intricate Architecture of Human Mitochondrial Presequence Translocase - Insights on its Evolution and Role in Tumourigenesis

Sinha, Devanjan

January 2013

The present thesis focuses on the elucidation of human mitochondrial inner membrane presequence-translocation machinery with implications on cancer cell proliferation. Mitochondria are the endosymbiotic organelles in an eukaryotic cell performing a vast repertoire of functions and require approximately 1500 proteins. However, the mitochondria genome contains only 13 protein-coding genes primarily transcribing the complexes of the electron transport chain. Therefore, it is evident that most of the mitochondrial proteome is encoded by the nucleus and synthesized on cytosolic ribosomes. Chapter 1: Mechanism of mitochondrial inner membrane protein translocation and its oncogenic connection. Mitochondria consist of different routes of directing proteins to their intramitochondrial destinations. The presequence pathway, mediated by the inner membrane TIM23 complex, is responsible for the import of matrix and a number of single transmembrane helixes containing inner membrane proteins. This pathway accounts for approximately 60% of the total proteome imported into the organelle and hence, is the major focus of discussion in the present study. The components of the TIM23 complex can be subdivided into two groups, the protein conducting channel and the import motor. The initial translocation across the TIM23 channel utilizes the electrochemical membrane potential that exists across the inner membrane whereas the final step of the translocation process is driven by energy from ATP hydrolysis. MtHsp70 forms the central component of the import motor, and its function is regulated by the J-proteins. Pam18 stimulates the ATPase activity of mtHsp70. Pam16, on the other hand, forms a subcomplex with Pam18 and exerts an inhibitory effect its ATPase stimulatory activity, in turn regulating the activity of the import motor. The stoichiometric coupling with the substrate binding-release cycle of mtHsp70 drives the import process. Although the organization of presequence translocation machinery and its functional annotations have been described in detail in yeast system, little information is available on its organization in human. It is difficult to contemplate the existence of similar machinery in human mitochondria with complex and diversified functions. Human mitochondria apart from regulating the metabolic pathways are involved in progression of cancer, neurodegenerative disorders, responses to xenobiotic stress and induction of apoptosis. Numerous reports have shown that mutations and overexpression of human orthologs of translocase components are associated with various cancer subtypes. Such disease condition also involves targeting of specific cell signaling molecules that reprogram organellar functions and alter the cellular phenotype. Based on this evidence we defined our study into four broad objectives – 1) identify the components of human presequence translocase as Chapter two and three, 2) characterize the subunit organization of human presequence translocation machinery in Chapter four, 3) determine the functional connection between the translocase components and the cancer phenotype in Chapter four and five and 4) understand how the functions of J-proteins have evolved across the species as Chapter six. Chapter 2: Unraveling the role of Magmas in human mitochondrial protein transport. Pam16 plays a critical role in regulation of import process by governing the activity of the import motor. Proteins orthologous to Pam16 had been reported earlier to be overexpressed in various metabolically active tissues and cancer subtypes. We found that in humans a protein named as Mitochondria Associated Granulocyte Macrophage colony Stimulating factor signaling molecule (Magmas) showed significant sequence similarity with yeast Pam16 at its C-terminal region. Magmas was initially discovered as a protein that was overexpressed in neoplastic prostrate and when the cells were exposed to GM-CSF. Our experiments suggested that Magmas localized in human and yeast mitochondria and it was associated with the inner mitochondrial membrane. Magmas could complement the growth of yeast cells that were deleted for the essential gene PAM16 and could import precursor proteins into the mitochondria. Like Pam16, Magmas was able to form a stable heterodimeric subcomplex with yeast Pam18 and human Pam18 ortholog DnaJC19 (JC19). We found that J-domain forms the minimal region required for heterodimer formation between Magmas and Pam18/JC19. Mutations in Magmas J-like domain resulted in temperature sensitive growth phenotypes in yeast cells and associated import defect in translocating precursor proteins into the organelle due to inability to form a stable subcomplex with Pam18 and JC19, resulting in loss of import function. Loss of subcomplex formation leads to dissociation of Pam18 from the translocation machinery highlighting the importance of Magmas in tethering Pam18/JC19 to the presequence translocase. Magmas, showing characteristic of a J-like protein, was unable to stimulate the ATPase activity of mtHsp70. However, it exerted an inhibitory effect on the ATP stimulatory effect of the J-protein Pam18/JC19, indicating that Magmas has a regulatory effect on the overall activity of import motor. In contrast Magmas mutants those are incapable of forming a stable heterodimer with Pam18 were unable to regulate the activity of Pam18 resulting in import defects. In summary, our results highlight that Magmas is an ortholog of yeast Pam16 performing similar functions at the import channel. Chapter 3: Existence of two J-protein subcomplexes at the translocation channel with distinct physiological functions. JC19 has been regarded as the human ortholog of Pam18 whose loss of function was associated with dilated cardiomyopathy and ataxia syndrome. However, immunoprecipitation analysis using anti-Magmas antibody revealed the presence of a second J-protein identified as DnaJC15 (JC15) that shared a highly similar J-domain with JC19. JC15 was initially identified as a protein whose loss in expression resulted in development of a chemoresistant phenotype in ovarian carcinoma cells exposed to chemotherapeutic treatment. We found that JC15 localizes in mitochondria where it was associated with the inner membrane. Similar to Pam18 and JC19, JC15 heterodimerized with Magmas/Pam16 through its J-domain and associated with the presequence translocase of the inner membrane. A loss of function mutation at the J-domain of JC15 destabilizes its interaction with Magmas resulting in protein translocation defects and temperature-sensitive growth phenotype in yeast cells. The JC15 mutant showed inability to get associated with the translocation channel and had dysregulated stimulation of mtHsp70 activity leading to decreased mitochondria biogenesis and loss of mitochondrial membrane potential. In summary, our results showed that JC15 is the second human ortholog of Pam18 with similar functions. In contrast to yeast, in human mitochondria JC15 and JC19 were found to form two separate and distinct J-protein subcomplexes with Magmas at the mitochondrial import motor. The essentiality of the J-proteins for normal human mitochondria function was addressed through siRNA mediated downregulation of Magmas, JC19 and JC15. We found that Magmas and JC19 are essential for normal mitochondrial function and cell viability whereas JC15 is dispensable and might have a supportive role. Interestingly, both JC19 and JC15 interacted with Magmas with equal affinity and stimulated mtHsp70’s ATPase activity by equivalent levels. This shows that both JC19 and JC15 share similar properties in terms of their functions at the import channel, and the differences might be in a much broader perspective in terms of their association with the translocation channel. Chapter 4: Architecture of human mitochondrial inner membrane presequence -translocation machinery. In yeast, there exists a single J-protein subcomplex formed by Pam16 and Pam18, which is recruited to the sole translocase. However, humans present a completely different scenario where there exists a two distinct subcomplexes formed by Magmas with either of the J-proteins. So the question arises how the individual subcomplexes is recruited to the translocation machinery; whether they are associated to one or differentially recruited to two different translocases. We identified the existence of three distinct translocases in the human system constituted by the two J-proteins along with the Tim17 paralogs. JC15 along with Tim17a forms the translocase A of size similar to that of the yeast system, and it forms the ancestral translocase in the humans. Tim17b isoforms, on the other hand, associates with JC19 to form mammalian specific translocases B1 and B2. The association of the J-proteins at the translocation channel was found to be mediated by Magmas as a subcomplex. Downregulation of Magmas resulted in dissociation of both the J-proteins, and its overexpression resulted in redistribution of J-proteins at the translocases. We found that translocase B imported precursor proteins at a comparatively higher rate as compared to translocase A. Disruption of translocase B had deleterious effects on cell viability, respiratory chain complex's activities, Fe-S cluster biogenesis, mitochondria morphology, regulation of free radical levels and maintenance of mitochondrial genome. In contrast, depletion of translocase A did not significantly alter the survivability of cells, mitochondrial activity and maintenance of organellar morphology. This shows that translocase B is essential and performs the constitutive import function in the mammalian system whereas translocase A is dispensable and might have a supportive role in maintenance of mitochondrial function. However, translocase A play a specific role in human mitochondria in context to cancer cells. We observed that the elevated level of Tim17a found in cancer cells is responsible for maintenance of higher mitochondrial DNA copy number and higher proliferative potential of cancer cells. Additionally, translocase A also plays a specific role in translocation of cell signaling proteins that lack a mitochondrial targeting sequence into the mitochondria, highlighting the possible role of this translocase in neoplastic transformation. Chapter 5: Mechanistic insights into the role of JC15 as a part of translocase A in chemoresistant phenotype. JC15 had been initially identified to be associated with development of chemoresistance in cancer cells. However, the molecular mechanism followed by the protein has not been elucidated yet. Our studies have shown that overexpression of JC15 leads to increased sensitivity of cells to chemotherapeutic drug cisplatin and are coupled with complete loss of membrane potential, mitochondrial swelling and cytochrome c release. However, this chemosensitive phenotype was partially ameliorated upon preexposing the cell to cyclosporine A which is an inhibitor of cyclophilin D, a critical component of mitochondrial membrane transition pore (MPTP) complex. A similar reversal of phenotype was observed upon depleting cyclophilin D even under JC15 overexpressing background. This highlighted a possible functional connection between these two proteins. In order to check this hypothesis other way around, we overexpressed cyclophilin D in the cells which resulted in constitutive opening of the MPTP complex, enhanced mitochondrial swelling and reduced cell viability. In contrast, the gain of function anomalies of cyclophilin D overexpression was significantly reversed upon JC15 depletion. We observed through co-immunoprecipitation analysis that JC15 activates cyclophilin D by releasing it from the inhibitory effects of TRAP1 and couples it to the MPTP complex. Additionally, we have also shown that the J-domain of JC15 is critical for its interaction with cyclophilin D and loss of function mutation at the J-domain of JC15 disrupts its interaction with cyclophilin D. As a result the JC15 mutant is not able to mount a chemosensitive response to cisplatin drug. Chapter 6: Identification of regions determining the divergence of J-proteins functions at the mitochondrial import motor. The above studies show ample evidence to suggest that the two human J-proteins have undergone significant divergence in their function in human mitochondria in spite of having a highly similar J-domain. Therefore, we asked the question that how the human J-proteins have evolved and diversified from the primitive yeast protein Pam18 and what are the regional determinants in the protein sequence that dictate the function of the J-domain. We utilized a purely genetic approach to address the problem. We observed that JC19 was unable to rescue the growth of yeast cells deleted for the essential gene Pam18 and JC15 expression resulted in cold sensitive phenotype. We used JC15 as the model protein for our assays and applied three methodologies. First, generation and isolation of a series of mutations in JC15 that could rescue the cold sensitive phenotype, and the growth of the cells were similar to the wild type. Second, to identify the regulatory residues by isolation of second site suppressors that could be the suppressor the mutant phenotypes isolated earlier. Third, we utilized a purely evolutionary approach by swapping the individual domains between the three J-proteins- Pam18, JC19 and JC15. Our genetic data support the idea that the partial loss of function of human J-protein in the yeast system is due to altered subcomplex dynamics with Pam16. The altered dynamics of the subcomplex is mainly regulated by the residues in the arm, linker and helical regions of the J-domain, especially the helix II regions. Our analysis has also uncovered a critical role of the targeting (T) region of J-proteins which along with inter-membrane space (IMS) domain share significant sequence diversity among J-proteins in yeast and humans. The T-region in conjunction with the IMS domain plays a crucial role in regulating the J-domain’s function across the kingdoms and within the species. Although, our genetic data needs to be supplemented with biochemical evidence, this study provides significant insights into the diversity of J-protein function across the species and mode of their regulation through regions flanking the J-domain.

Mitochondrial Protein Translocation

Mitochondria

Human Mitochondria Biogenesis

Mitochondrial J-Proteins

Organellar Protein Translocation

Mitochondrial Protein Translocation

Cancer - Mitochondria

Apoptosis - Mitochondria

Tumourigenesis

Mitocondria - Tumourigenicity

Biochemistry

Understanding the Dynamic Organization of the Presequence-Translocase in Translocation of Preproteins Across Mitochondrial Inner Membrane

Pareek, Gautam

January 2014

Mitochondrion is an endosymbiotic organelle synthesizing ~1% of its proteome, while remaining ~99% of the proteins are encoded by the nuclear genome and translated on the cytosolic ribosome. Therefore active mitochondrial biogenesis requires efficient protein transport destined for the different sub-compartments. Mitochondrion contains specialized translocation machineries in the outer and in the inner membrane known as TOM40 and TIM23-complex respectively. Import of a majority of mitochondrial proteome is mediated by inner membrane presequence translocase (TIM23 complex). However, the structural organization of Tim23-complex and mechanisms of mitochondrial inner membrane protein translocation is still elusive. Therefore, the present thesis addresses above elusive questions. Chapter 2 highlights the functional significance of different segments of Tim23 in regulating the conformational dynamics of the presequence-translocase- Tim23 is the central channel forming subunit of the presequence-translocase which recruits additional components for the assembly of the core complex. However the functional significance of different segments of Tim23 was not understood due to the lack of suitable conditional mutants. Our study has reported many conditional mutants from different segments of Tim23 which are precisely defective in the organization of the core complex and in the recruitment of the import motor component which enhances our understanding of protein translocation across mitochondrial inner membrane. Chapter 3 highlights the functional cooperativity among mtHsp70 paralogs and orthologs using Saccharomyces cerevisiae as a model organism- mtHsp70s are implicated in a broad spectrum of functions inside the mitochondria. In case of lower eukaryotes gene duplication event has given rise to multiple copies of Hsp70s thereby presenting an opportunity of division of function among these paralogs. The mitochondria of yeast Saccharomyces cerevisiae contains three Hsp70s, including Ssc1, Ssq1 and Ssc3 (Ecm10). The Ssc1 is essential for protein translocation and de novo protein folding functions while Ssq1 is needed for the Fe/S cluster biogenesis inside the mitochondria. Although it has been proposed earlier that, Ssc1 and Ssc3 possesses overlapping functions in protein translocation as a part of import motor in the Tim23-complex. However the physiological relevance and experimental evidences in favor above hypothesis was not established clearly. Our study has reported Ssc3 as an ‘atypical chaperone’ which cannot perform the generalized chaperone functions due to the conformational plasticity associated with both the domains of Ssc3 resulting into weaker client protein affinity, altered interaction with cochaperones and dysfunctional allosteric interface. Additionally, we have also highlighted the role of Nucleotide-binding domain in determining the functional specificity among Hsp70 paralogs and orthologs.

Mitochondria

Nucleotide Binding

Mitochondrial Biogenesis

Mitochondrial Presquence Translocase

Preprotein Translocation

Saccharomyces Cerevisiae

Presequence Translocase Tim23

Mitochondrial Inner Membrane

Mitochondrial Hsp70s

Biochemistry

Charakterizace glycinové smyčky alfa podjednotky mitochondriální procesující peptidasy Saccharomyces cerevisiae / Characterization of gycin-rich loop of mitochondrial processing peptidase alpha subunit from Saccharomyces cerevisiae

Chytrá, Dana

January 2012

Mitochondrial processing peptidase (MPP) is a heterodimeric enzyme which belongs to M16B subfamily of metaloendopeptidases. A universal function of this enzyme is in recognition and cleavage of great number of mitochondrial preprotein presequences, which differ in length and amino acid sequence. MPP consists of catalytical β-MPP and probably recognizing α-MPP. The most conservative region in α-MPP is GRL - glycine-rich loop. Its function is supposed in primary interaction with preprotein presequence. It is possible to study conformational change of GRL after binding the substrate by fluorescence experiments. In this diploma thesis the constructs coding the α-MPP with the single reporter tryptophan residue in the position 289 or 299 were prepared using site-directed mutagenesis. These forms of α-MPP were produced in E. coli BL21(DE3)+pGroESL. Activities of MPP dimer containing α-MPP with the single tryptophan residue in the reporter position were compared with MPP from wild type of S. cerevisiae. Used substrate was yeast malate dehydrogenase precursor with fused presequence (pMDH) from three organisms (yeast, mouse and melon). These presequences differ in their length. Activities of MPP dimer containing α-MPP with the single reporter tryptophan residue in the position 289 were about 70 % while...

Structural and Functional Analysis of the Mitochondrial Presequence Translocase / Strukturelle und funktionelle Analyse der Präsequenz-spezifischen mitochondriellen Translokase

Lytovchenko, Oleksandr

07 August 2012

No description available.

570 Biowissenschaften

Biologie

RA 000

Mitochondrien

TIM23

Präsequenz-Translokase

Elektronenmikroskopie

Tim21

Tim50

Mitochondria

TIM23

presequence translocase

electron microscopy

Tim21

Tim50

35.70