Investigation of the Glutaredoxin system with the biogenesis of mitochondrial intermembrane space proteins

Tran, Peter

January 2016

Mitochondrial protein biogenesis depends on the import of nucleus-encoded precursors from the cytosol. Import is highly regulated and specific for different subcompartments, with intermembrane space (IMS) import driven by an oxidative mechanism on conserved cysteine residues. Oxidative folding in the IMS is facilitated by the mitochondria import and assembly (MIA) pathway. Proteins can only be imported into the IMS in Cys-reduced unfolded forms, as oxidation prevents translocation into the IMS. How the import-competent forms are maintained in the cytoplasm is lesser characterised compared to the MIA pathway. Two recent studies suggest that the cytosolic Thioredoxin (Trx) and Glutaredoxin (Grx) reductase systems play a role in facilitating IMS protein import, with previous evidence identifying a role for yeast Trxs in small Tim protein biogenesis. In this study, the redox properties of the yeast Trx and Grx systems were investigated, as well as whether the yeast Grx system play a role in the biogenesis of two typical types of IMS precursor proteins. First, in vitro studies were carried out to determine the standard redox potentials (E°’) of the Trx and Grx enzymes. This was a quantifiable parameter of reducing activity and the results were described in Chapter 3. This study determined the E°’Trx1 value, which was shown to be a more effective reductant compared to other orthologs. Experimental limitations prevented the Grx system E°’ values being determined. Next, whether the Grx plays a role in the biogenesis of the CX3C motif-containing small Tim proteins were investigated using yeast genetic in vivo and biochemical analysis methods. The results were described in Chapter 4. There, Grxs were observed to not affect cell growth, but in using overexpressed Tim9 as an import model, significant differences were observed for the Grx system as GRX deletion significantly decreased overexpressed Tim9 levels. Study on the isolated mitochondria and cytosol with overexpressed Tim9 was unclear however. This study also observed a genetic interaction between GRX andYME1 that recovered cell functioning under respiratory conditions. Finally, whether the Grx system plays a role in the biogenesis of CX9C motif-containing proteins (Mia40, Mia40C and Cox17) was studied in Chapter 5. Whilst Mia40C (C-domain of Mia40) and Cox17 are imported into mitochondria via the MIA pathway, the full-length Mia40 is a substrate of the presequence-targeted TIM23 pathway. The results indicated that import of the full-length Mia40 was unaffected by GRX deletion. However, studies of an overexpressed Mia40C as a substrate of the MIA pathway, showed strong mitochondrial protein level decreases caused by deletion of the Grx proteins. This decrease was also accompanied by an accumulation of unimported Mia40C in the cytosol. Cox17 as an alternative MIA pathway substrate also showed decreased mitochondrial levels in the GRX deletion mutants. These results altogether suggest that the cytosolic Grx system can function in the biogenesis of CX9C motif-containing IMS proteins imported through the MIA pathway, as well as the CX3C small Tim proteins. The topic of how IMS proteins are degraded in the cell was also raised by the study of Yme1.

572

Evoluce importu proteinů do mitochondrií / Evolution of mitochondrial protein import

Dohnálek, Vít

January 2020

1 Abstract Even though mitochondria possess their own genome and ribosomes, majority of mitochondrial proteins is encoded in the nucleus and translated by cytosolic ribosomes. Hence it was necessary to establish transport complexes allowing the import of proteins from the cytosol. These complexes are best described in yeast. However, we are encountering organisms lacking many of the subunits of these complexes with increasing frequency. Therefore, we are presenting the overview of the distribution of the subunits within eukaryotic organisms. We specifically take a closer look at parasitic protist Giardia intestinalis that is well known for its extreme reductions of the import complexes. There have been only few subunits identified so far. Porin Tom40, that is responsible for translocating all the incoming proteins across the outer mitochondrial membrane, has been identified despite the high divergence, while homolog of Sam50 hasn't been successfully identified yet. Sam50 is however believed to be necessary for insertion of Tom40 into the membrane. Vast part of this thesis is dedicated to this phenomenon that is highly uncommon and maybe unique among the eukaryotic organisms.

Elektrophysiologische und biochemische Charakterisierung von rekombinanten und nativen Kanalproteinen aus der inneren Chloroplasten-Hüllmembran und dem Cyanobakterium Synechocystis

Mehrle, Alexander

23 May 2001

Elektrophysiologische und biochemische Charakterisierung von rekombinanten und nativen Kanalproteinen aus der inneren Chloroplasten-Hüllmembran und dem Cyanobakterium Synechocystis In der vorliegenden Arbeit wurden zwei angenommene Kaliumkanäle heterolog exprimiert und untersucht. Außerdem wurde die elektrophysiologische Charakterisierung des am Proteinimport beteiligten Proteins Tic110 durchgeführt. Ergänzt wurden diese Experimente durch eine elektrophysiologische Charakterisierung von Ionenkanälen in der inneren Chloroplasten-Hüllmembran. Sowohl in Synechocystis sp. PCC 6803 als auch in Arabidopsis thaliana konnten zwei Gene identifiziert werden, die wahrscheinlich Kaliumkanäle codieren. Das Genprodukt aus Arabidopsis ist wahrscheinlich im Chloroplasten lokalisiert und besitzt sechs putative transmembrane Durchgänge. Es ähnelt strukturell den Kaliumkanälen AKT1 und KAT1. Der potentielle Synechocystis-Kanal besitzt aufgrund von Sekundärstrukturvorhersagen Ähnlichkeit mit dem Kaliumkanal KcsA aus Streptomyces lividans und eukaryontischen Kanälen der IRK-Familie. Beide Proteine wurden als His-Tag Fusionsproteine in Baculovirus-infizierten Sf21-Insektenzellen überexprimiert und konnten in der Membranfraktion der Zellen nachgewiesen werden. Patch-Clamp-Messungen in der ’Whole-Cell’ und ’Excised-Patch’ Konfiguration an den Insektenzellen zeigten, dass keine funktionellen Kanäle in der Plasmamembran lokalisiert waren. Beide Kanäle konnten mittels nicht-ionischer Detergentien solubilisiert werden, aber nur der Synechocystis-Kanal konnte mittels Ni-Affinitätschromatographie gereinigt werden. Nach Rekonstitution des Proteins in Azolektin-Liposomen zeigte sich bei Messungen im Bilayer-System jedoch keine Kanalaktivität. Ursache hierfür ist wahrscheinlich eine zu geringe Offenwahrscheinlichkeit des Proteins oder eine nicht funktionelle Rekonstitution. Weiterhin wurden bei elektrophysiologischen Messungen mit der Bilayer-Methode Ionenkanäle in der isolierten inneren Hüllmembran von Chloroplasten untersucht. Es konnte die Existenz eines Kaliumkanals bestätigt sowie zwei bisher unbekannte Kanäle (CIMCC1 und CIMCC2) charakterisiert werden. CIMCC1 ist mäßig selektiv für Kationen (PK/PCl = 3.5), besitzt einen Haupt- und einen Unterleitwert von 680 bzw. 330 pS (in 250 mM KCl) und eine spannungsunabhängige Offenwahrscheinlichkeit von 70 %. Der Kanal könnte aufgrund seiner Eigenschaften am Transport von Aminosäuren über die innere Chloroplasten-Hüllmembran beteiligt sein. CIMCC2 ist Kationen-selektiv (PK/PCl = 5.3), besitzt einen Leitwert von 600 pS (in 250 mM KCl) und schließt bei höheren positiven bzw. negativen Membranpotentialen. Der Kanal ist durch wenige 100 nM des Präpeptids Troe33 blockierbar, weshalb er eine Rolle im Import von Proteinen in den Chloroplasten spielen könnte. Ferner konnte im Rahmen dieser Arbeit gezeigt werden, dass das Protein Tic110 nach heterologer Expression in E. coli und Rekonstitution in Liposome eine hydrophile Pore bildet, deren Eigenschaften denen von Proteinimportkanälen in der äußeren Membran von Chloroplasten und Mitochondrien ähnelt. Aufgrund einer Sekundärstrukturvorhersage und des CD-Spektrums ist, im Gegensatz zu vorherigen Annahmen, eine von b-Faltblättern dominierte Sekundärstruktur wahrscheinlich. Der durch Tic110 gebildete Kanal ist Kationen-selektiv, hat einen Leitwert von 446 pS in 250 mM KCl und einen Porendurchmesser zwischen 15 und 34 Angström. Die spannungsabhängige Offenwahrscheinlichkeit ist maximal bei kleinen Membranpotentialen und nimmt zu höheren positiven und negativen Spannungen hin ab. Weiterhin ist der Kanal durch geringe Konzentrationen des Präpeptids Troe33 (ca. 100 nM) spezifisch hemmbar. Tic110 besitzt funktionell eine starke Ähnlichkeit mit CIMCC2 in der inneren Hüllmembran, was nahelegt, dass es sich hierbei um die gleichen Proteine handelt. Ausgehend von diesen Eigenschaften ist es wahrscheinlich, dass Tic110 die Proteinimportpore der inneren Chloroplasten-Hüllmembran darstellt.

Protein-Import

Kaliumkanäle

Chloroplast

innere Hüllmembran

Elektrophysiologie

Kanäle

32 - Biologie

ddc:570

The mitochondrial protein import machinery

Ross, Katharina

27 October 2009

Menschliche Mitochondrien enthalten etwa 1500 bis 2000 Proteine. Die meisten dieser Proteine werden im Zellkern kodiert und im Zytoplasma synthetisiert, und müssen daher über eine spezielle Maschinerie in die Mitochondrien transportiert werden. Obwohl mittlerweile viele Details über die Wirkungsweise dieser Proteinschleusen bekannt sind, wurden einige wichtige Aspekte des Proteinimports noch nicht ausreichend untersucht. Zum einen ist nicht bekannt, ob die einzelnen Importkomplexe einen Einfluss auf die mitochondrienvermittelte Apoptose haben. Weiterhin ist offen, welche genaue Rolle der Mitochondrienimport in der Pathogenese von Neisseria gonorrhoeae spielt. Außerdem ist unklar, ob Faktoren des Importapparates für die Aufrechterhaltung der mitochondrialen Morphologie notwendig sind. Um diese Fragestellungen zu untersuchen, wurden im Rahmen der vorliegenden Arbeit permanente Zelllinien hergestellt, in denen die Expression einzelner am Mitochondrienimport beteiligter Proteine mittels RNA-Interferenz (RNAi) inhibiert werden kann. Mithilfe dieser Zelllinien wurde getestet, ob die proapoptotischen Proteine Bax und Bak die Importmaschinerie benötigen, um in die äußere Mitochondrienmembran zu gelangen. Die Präsenz der beiden proapoptotischen Proteine in Mitochondrien während der Apoptose ist sehr entscheidend, da Bax und Bak in den Mitochondrien oligomerisieren und damit weitere Schritte der Apoptose einleiten. Im Widerspruch zu früheren Publikationen konnte hier gezeigt werden, dass die Translokation von Bax und Bak in die äußere Mitochondrienmembran unabhängig von Proteinimportfaktoren erfolgt. Der zweite Teil dieser Arbeit beschäftigt sich mit dem Einfluss mitochondrialer Importproteine auf die Pathogenese von Neisseria gonorrhoeae. Das Neisserienprotein PorB transloziert während der Infektion in die Mitochondrien der Wirtszelle und induziert Apoptose. Aufgrund der strukturellen Ähnlichkeit von PorB zu bestimmten Proteinen der äußeren Mitochondrienmembran wurde bisher angenommen, dass PorB diesen endogenen Proteinen auf ihrem Importweg in die äußere Mitochondrienmembran folgt. Überraschenderweise wurde im Rahmen dieser Arbeit entdeckt, dass PorB nicht von allen Komplexen der Importmaschinerie in den Mitochondrien erkannt wird. Infolgedessen transloziert es in die innere Mitochondrienmembran und wirkt dadurch toxisch auf die Wirtszelle. In einem weiteren Projekt wurde untersucht, welche Rolle die Proteinimportkomplexe der äußeren mitochondrialen Membran in der Aufrechterhaltung der Mitochondrienmorphologie spielen. Unter Verwendung der beschriebenen Zelllinien wurde entdeckt, dass in Abwesenheit des SAM (sorting and assembly) Importkomplexes die Struktur der inneren Mitochondrienmembran derangiert ist. Es wurden zudem Hinweise darauf gefunden, dass die Ursache für diesen Befund in einer Unterbrechung von Kontaktstellen zwischen den beiden Mitochondrienmembranen liegen könnte, für deren Aufrechterhaltung möglicherweise der SAM-Komplex verantwortlich ist. Die in dieser Arbeit vorgestellten Ergebnisse erlauben neue Einblicke in verschiedene Aspekte des Proteinimports in Mitochondrien. Zudem wurde mit der Entwicklung der stabilen Zelllinien ein neues Model geschaffen, anhand dessen in Zukunft weitere Detail des mitochondrialen Proteinimports erforscht werden können. / Human mitochondria comprise about 1500 to 2000 proteins. While only 13 proteins are encoded by the mitochondrial DNA the vast majority of mitochondrial proteins is encoded in the nucleus, synthesized in the cytosol, and translocated into mitochondria by a special protein import machinery. Although many details are now known about its function several important aspects of protein import in mitochondria were not unraveled yet. To begin with, the influence of the different mitochondrial import complexes on apoptosis is not known. Further, the exact role of the protein import machineries in mitochondria in the pathogenesis of Neisseria gonorrhoeae has not been clarified yet. Moreover, the question whether factors involved in protein import are required for the maintenance of the mitochondrial morphology is still unsolved. In order to address these open issues, permanent cell lines were generated within the frame of the present thesis in which the expression of single proteins implicated in mitochondrial import can be inhibited via RNA interference (RNAi). Using these cell lines, it was investigated whether the proapoptotic proteins Bax and Bak require the import machinery in order to gain access to the outer mitochondrial membrane. The presence of both proapoptotic proteins in mitochondria is essential during apoptosis as Bax and Bak oligomerize in the outer mitochondrial membrane leading to the execution of apoptosis. In contrast to earlier publications, results presented here prove that the translocation of Bax and Bak into the outer mitochondrial membrane occurs independent of its import machineries. The second part of this thesis explores the influence of mitochondrial import proteins on the pathogenesis of Neisseria gonorrhoeae. The neisserial protein PorB translocates into the mitochondria of host cells during infection and induces apoptosis. Because of structural similarities of PorB to a certain class of proteins in the outer mitochondrial membrane, it was assumed that PorB would follow the import pathway of these endogenous proteins into the outer mitochondrial membrane. Surprisingly, it was found within the present study that PorB is not recognized by all complexes implicated in this import pathway. As a consequence, it translocates into the inner mitochondrial membrane to exert its toxic effect on the host cell. In a further project, the role of import complexes of the outer mitochondrial membrane in the maintenance of the mitochondrial morphology was investigated. Using the described cell lines, it was found that in the absence of the SAM (sorting and assembly) import device, the structure of the inner mitochondrial membrane was disrupted. Further, evidence was found that the reason for this phenotype could be an interruption of contact sites between the two mitochondrial membranes, whose preservation possibly requires the SAM complex. The results presented here allow new insights into different aspects of mitochondrial protein import. Further, with the development of the stable cell lines a new model was generated that will allow future investigations on details about mitochondrial protein import.

Mitochondrien

Apoptose

Proteinimport

Neisserien

Cristae

apoptosis

Mitochondria

protein import

neisseria

cristae

570 Biowissenschaften, Biologie

32 Biologie

WE 3100

ddc:570

Investigation of a Plant Mitochondrial Tat System

Eudy, Kathryn E.

18 November 2021

No description available.

Biochemistry

Identifikation, Klonierung und funktionelle Charakterisierung neuer Isoformen der humanen Importin Alpha Proteinfamilie

Köhler, Matthias

04 December 2003

Der "klassische" Importweg von Proteinen wie Transkriptionsfaktoren, Kernrezeptoren oder viralen Proteinen in den Zellkern erfolgt in Abhängigkeit der Importine alpha und beta. Während nur ein Importin beta existiert, waren zu Beginn der Arbeiten zwei humane alpha-Importine bekannt. In der vorliegenden Arbeit wird die Identifikation, Klonierung und funktionelle Charakterisierung von vier neuen humanen alpha-Importinen beschrieben. Anhand ihrer Primärstruktur wurden die sechs alpha-Importine in drei Subfamilien unterteilt. Um die Hypothese zu testen, dass die verschiedenen Importin alpha Isoformen spezifische Funktionen ausüben und sich nicht vollständig gegenseitig ersetzen können, wurde zunächst ihre Expression auf RNA- und Proteinebene analysiert. Hier ließen sich differentielle Expressionsmuster in verschiedenen humanen Zellen und Geweben nachweisen. In vitro Analysen mit rekombinant exprimierten und aufgereinigten Proteinen deuteten daraufhin, dass die neu identifizierten Isoformen tatsächliche Importfunktion besitzen, dass sich jedoch die verschiedenen alpha-Importine in ihren Substratspezifitäten unterscheiden. Verschiedene neue Substrate der alpha-Importine wurden identifiziert und deren Importwege im Detail analysiert. Unterschiede in der Regulation der Expression der alpha-Importine in Abhängigkeit von Zellproliferation, Zelldifferenzierung bzw. in unterschiedlichen Diabetesmodellen der Ratte deuteten ebenfalls auf spezifische Funktionen der verschiedenen Isoformen hin. Die spezifische Inhibition der Importin alpha Expression in kultivierten HeLa-Zellen mittels RNA-Interferenz führte bei den meisten Isoformen zu einer ausgeprägten Inhibition der Zellproliferation, wodurch erstmals der Nachweis essentieller Funktionen verschiedener alpha-Importine in lebenden humanen Zellen erbracht wurde. In weiterführenden Experimenten sollen die Ursachen für die Inhibition der Zellproliferation bei Importin alpha-Mangel geklärt und die Bedeutung der unterschiedlichen alpha-Importine in vivo weiter analysiert werden. / The "classical" import of proteins like transcription factors, nuclear receptors or viral proteins into the nucleus depends on importins alpha and beta. While only one importin beta is known, two human alpha-importins had been described. In this study the identification, cloning and functional characterisation of four novel human alpha-importins is reported. Based on their primary structures the human alpha-importins can be grouped into three distinct subfamilies. To test the hypothesis that the various alpha-Importins differ in their specific functions and cannot substitute for each other first their expression at the RNA- and protein levels were analyzed. Differential expression patterns in various human cells and tissues could be demonstrated. In vitro analyses using recombinantly expressed and purified proteins indicated, that the newly identified isoforms posses import functions in deed. However, there was evidence for differences in their substrate specific import efficacies. New substrates of the alpha-importins were identified and their import pathways analyzed in detail. Differences in the expression regulation of the alpha-importins depending on cellular proliferation and differentiation as well as in different rat models of diabetes further pointed towards specific functions of the various alpha-importins. Specific expression inhibition of several isoforms of the importin alpha protein family in cultured HeLa-cells using RNA-interference technology caused a strong inhibition of cellular proliferation. This is the first proof for essential functions of different alpha-importins in living human cells. Future experiments shall identify the mechanisms involved in the cellular proliferation inhibition due to importin a deficiency and further analyze the role of the different alpha-importins in vivo.

Importin alpha

nukleozytoplasmatischer Proteinimport

Zellproliferation

RNA-Interferenz

importin alpha

nucleocytoplasmic protein import

cellular proliferation

RNA-interference

610 Medizin

33 Medizin

ddc:610

Understanding in vivo Significance of Allosteric Regulation in mtHsp70s : Revealing its Implications in Parkinson's Disease Progression

Samaddar, Madhuja

January 2015

Mitochondria are essential eukaryotic organelles, acting as the sites for numerous crucial metabolic and signalling pathways. The biogenesis of mitochondria requires efficient targeting of several hundreds of proteins from the cytosol, to their varied functional locations within the organelle. The translocation of localized proteins across the inner membrane, and their subsequent folding is achieved by the ATP-dependent function of mitochondrial Hsp70 (mtHsp70). It is a bonafide member of the Hsp70 chaperone family, which are involved in a multitude of functions, together aimed at protein quality control and maintenance of cellular homeostasis. These varied functions of Hsp70 proteins require binding to exposed hydrophobic patches in substrate polypeptides thus preventing non-productive associations. The interaction with substrates occurs through the substrate-binding domain (SBD) and is regulated by the ATPase activity of the nucleotide-binding domain (NBD), through a series of conformational changes. Conversely, substrate binding to the SBD also stimulates ATP hydrolysis, and thereby the core activities of the two domains are regulated by mutual allosteric signalling. This mechanism of bidirectional inter-domain communication is indispensable for Hsp70 function, which is characterized by cycles of substrate binding and release, coupled to cycles of ATP binding and hydrolysis. The process of allosteric regulation in Hsp70 proteins has been comprehensively investigated, especially in the bacterial homolog, DnaK. However, the in vivo functional significance of inter-domain communication in the eukaryotic mtHsp70 system and the mechanism of its regulation remain unexplored. Furthermore, the complex physiological implications of impairment in allosteric communication and their correlation with diverse disease conditions, including Myelodysplastic syndrome (MDS), and Parkinson’s disease (PD), are yet to be elucidated. Based on this brief introduction, the primary research objectives set out in the present thesis were to: 1. uncover the regulation of ligand-modulated allosteric communication between the two domains of mtHsp70; and its in vivo significance in the context of protein import into the organelle. (Chapter 2) 2. understand the role of mtHsp70 in progression of Parkinson’s disease; and to study the modulation of α-synuclein toxicity by the protein quality control function of the mtHsp70 chaperone network. (Chapters 3 and 4) We have employed a battery of genetic and biochemical approaches to investigate the above questions using the Saccharomyces cerevisiae mtHsp70 protein, Ssc1; an essential protein that is involved in a plethora of critical functions in this eukaryotic model system. Objective 1: Structural studies, primarily in bacterial DnaK, have yielded mechanistic insights into its interactions with ligands and cochaperones, as well as conformational transitions in different ligand-bound states. In recent years, the availability of crystal structures of full-length DnaK and detailed information from NMR studies and single-molecule resolution spectroscopic analyses (both DnaK and eukaryotic Hsp70s), have significantly contributed to our understanding of the inter-domain interface, critical residues and contacts, and the energetics of the entire process of ligand-modulated conformational changes. Although eukaryotic mtHsp70s have a high degree of conservation with DnaK, they possess significant differences in their conformational and biochemical properties. They are essential for a vast repertoire of physiological functions, which are distinctly different from their bacterial counterpart. Using a combined in vivo and in vitro approach, we have uncovered specific structural elements within mtHsp70s, which are required for allosteric modulation of the chaperone cycle and maintenance of in vivo functions of the protein. Foremost, we demonstrate that a conserved SBD loop, L4,5 plays a critical role in inter-domain communication, and multiple mutations in this loop result in significant growth and protein translocation defects. The mutants are associated with a specific set of altered biochemical properties, which are indicative of impaired inter-domain communication. Using the loop L4,5 mutant, E467A as a template for genetic screening, we report a series of intragenic suppressor mutations, which are capable of correcting a distinct subset of the altered properties, and thereby leading to restoration of in vivo functions, including growth, preprotein import and mitochondria biogenesis. The suppressors modify the altered conformational landscape associated with E467A, and also provide us with information regarding unique aspects governing the regulation of allosteric communication, especially in physiological contexts. Strikingly, they reveal that restoration of communication in the NBD to SBD direction is sufficient for function, when the protein is primed in a high ATPase activity state. In this unique scenario, the requirement for ATPase stimulation upon substrate binding is rendered unnecessary, thereby making conformational changes in the SBD to NBD direction, dispensable for function. Further, we provide evidence to show that loop L4,5 functions synergistically with the linker region, working in tandem for organization of the inter-domain interface and propagation of communication. Together, our analyses provide the first insights into regulation of allosteric inter-domain communication in vivo and their implications in mitochondrial protein translocation and organelle biogenesis. Objective 2: Point mutations in the loop L4,5 have been associated with Myelodysplastic syndrome. Additionally, a mutation isolated in clinical cases of Parkinson’s disease was found to be impaired in allosteric communication. These observations further highlight the importance of efficient inter-domain communication in mtHsp70 in the complex physiological scenario of eukaryotic cells. Independent clinical screens of PD patients have revealed unique point mutations in the mtHsp70 and a strong association of the gene locus with the disease progression. This is also correlated with decreased mtHsp70 levels in affected neurons and the interactions of this protein with established PD-candidate proteins like α-synuclein and Dj-1. Further, mitochondrial dysfunction is a common phenomenon associated with neurodegenerative disorders. To understand the specific role of mtHsp70 in PD, we have developed a yeast model for studying the disease variants in isolation from other players of the multifactorial disease, and in complete absence of the wild type protein. We generated two analogous PD-mutations in Ssc1, R103W and P486S; which recapitulated the symptoms of mitochondrial dysfunction in affected neurons, including cell death, inner membrane depolarization, increased generation of ROS, and respiratory incompetence. At the molecular level, we observed an increased aggregation propensity of R103W, while P486S exhibited futile enhanced interaction with J-protein cochaperone partners thereby resulting in loss of chaperoning activity and impaired mitochondrial protein quality control. Remarkably, these altered biochemical properties mimicked similar defects in the human mtHsp70 variants, therefore, affirming the involvement of mtHsp70 in PD progression. To further investigate the relevance of impaired mitochondrial protein quality control in PD, we have explored whether mtHsp70 can act as a genetic modifier of α-synuclein toxicity. It is known that α-synuclein can act as an unfolded substrate for the Hsp70 chaperone system and also deposits as intracellular aggregates in PD-affected brains. Intriguingly, it is known to translocate into mitochondria under conditions of neuronal stress in spite of lacking a canonical mitochondrial signal sequence. Utilizing our yeast-PD model, we find that targeting of α-synuclein A30P disease variant into mitochondria leads to a severe mitochondrial dysfunction phenotype in the wild type Ssc1 background, but not the P486S mutant background. This results in multiple cellular manifestations, which are reversed upon overexpression of the Ssc1 chaperone. Significantly, increasing the J-protein cochaperone availability also leads to reversal of the mutant-associated defects. However, the simultaneous overexpression of both together does not additively improve the protective effects; highlighting the importance of the relative availability of chaperone and cochaperone proteins in preventing aggregation. Our analyses further reveal that while both the wild type and P486S Ssc1 proteins are equally capable of delaying aggregation of α-synuclein, only the wild-type chaperone is better able to prevent aggregation in the presence of its J-protein cochaperone, leading to accumulation of soluble oligomeric species. These observations raised the intriguing possibility, that the reduced chaperoning ability of the proline to serine PD-mutant is, in fact, a compensatory adaptation, favoring the aggregation of α-synuclein over its more toxic soluble oligomeric form. We verify this hypothesis with the aggregation kinetics of A30P α-synuclein, whose intrinsically lower aggregation tendency results in a pronounced delay in aggregation with the wild-type chaperone, thereby strongly favoring the toxic oligomeric species and correlating with the observed lethality in yeast cells. In conclusion, our study provides a model of α-synuclein aggregation-related toxicity and its modulation by the extent of protein quality control within the mitochondrial matrix, through the action of the mtHsp70 chaperone network.

Eukaryotic Organelle

Mitochonodria

Parkinson's Disease Progression

Mitochondrial Heat Shock Protein 70

Hsp70 Proteins

Saccharomyces cerevisiae mtHsp70 Protein

Allosteric Regulation

Mitochondrial Protein Import

Mitochondria Biogenesis

Mitochondrial HSP70 Chaperon Network

Heat Shock Proteins

mtHSp70

mtHsp70s

Parkinson's Disease

Biochemistry