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

Structural and functional studies of mitochondrial small Tim proteins

Guo, Liang

January 2013

Most mitochondrial proteins are encoded by nuclear DNA, and synthesised in the cytosol, then imported into the different mitochondrial subcompartments. To reach their destination, mitochondrial inner membrane proteins require import across the outer mitochondrial membrane, and through the intermembrane space. This passage through the IMS is assisted by the small Tim proteins. This family is characterised by conserved cysteine residues arranged in a twin CX3C motif. They can form Tim9-Tim10 and Tim8-Tim13 complexes, while Tim12 appears to form part of a Tim9-Tim10-Tim12 complex that is associated with the inner membrane translocase TIM22 complex. Current models suggest that the biogenesis of small Tim proteins and their assembly into complexes is dependent on the redox states of the proteins. However, the role of the conserved cysteine residues, and the disulphide bonds formed by them, in small Tim biogenesis and complex formation is not clear. As there is no research about the structural characterisation of Tim12 and double cysteine mutants of Tim9, purification of these proteins was attempted using different methods. To investigate how cysteine mutants affect complex formation, the purified double cysteine mutants of Tim9 were studied using in vitro methods. It showed that the double cysteine mutants were partially folded, and they can form complexes with Tim10 with low affinities, suggesting disulphide bonds are important for the structures and complex formation of small Tim proteins. The effect of cysteine mutants on mitochondrial function was addressed using in vivo methods. It showed that cysteines of small Tim proteins were not equally essential for cell viability, and growth defect of the lethal cysteine mutant was caused by low level of protein. Thus, the conclusion of this study is that disulphide bond formation is highly important for correct Tim9- Tim10 complex formation, and yeast can survive with low levels of complex, but it results in instability of the individual proteins.

572.8

Insights Into Oxidative Folding Of Retinol Binding Protein In The Endoplasmic Reticulum : A Study In Isolated Microsomes

Rajan, Sundar S

02 1900

The central role played by the Endoplasmic Reticulum (ER) in the correct folding and assembly of secretary and membrane proteins cannot be overstated. As the first compartment in the secretary pathway, it is responsible for the synthesis, modification and targeting of proteins to their proper destinations within the secretary pathway and the extracellular space. Protein folding in this specialized compartment is dynamic and involves a host of molecular chaperones and folding catalysts. Once inside the ER lumen, proteins fold into their native conformation and undergo a multitude of post-translational modifications, including N-linked glycosylation and disulfide oxidation. The proper conformational maturation of nascent proteins that traverse the secretary pathway is both aided and monitored by a complex process termed ER quality control. A variety of quality control mechanisms that rely on the chaperone systems operate in the ER. These act in close concert with the molecular machinery involved in degradation of non-native proteins to maintain homeostasis. The common goal of these mechanisms is to prevent expression and secretion of misfolded proteins. As a general rule, only those proteins that have successfully completed their folding and passed a stringent selection process are allowed to exit the ER on their way to their final destinations. The importance of the normal functioning of the ER is underlined by the fact that disruption in protein folding, resulting in ER stress, has now been identified as the biochemical basis of many ER storage diseases including Diabetes mellitus, Endocrinopathies and Hemophilia A. Processing events occurring inside the ER lumen are known to influence the efficiency of protein secretion. Vastly different rates of exocytose observed among secretary proteins have been found to correlate with the rate of exit from the ER. One such example is the interesting secretion property exhibited by Retinol Binding Protein (RBP) The principal carrier of retinol (Vitamin A) in plasma. RBP is a single domain protein consisting of three intramolecular disulfide bonds and helps transport retinol from the liver stores to the various target tissues in the body. Availability of its ligand, retinol, while not affecting its synthesis, is known to be the major factor in regulating RBP secretion from the liver. In the absence of retinol, apo-RBP has been shown to be retained in the ER by a hitherto unclear mechanism. Like most other secretary proteins, RBP is co-translationally targeted to the ER lumen, where it undergoes disulfide oxidation as the only modification. It has been shown to form a complex with another secretary protein, Transthyretin (TTR) in the ER and this complex formation is thought to prevent premature glomerular filtration of the otherwise small RBP with its bound retinol. Despite attaining a mature conformation, apo-RBP is not secreted and awaits conversion to its ligand-bound, holo form in order to exit the ER. It is widely believed that ligand binding may relieve this retention of RBP from the ER quality control machinery. However the precise mechanisms that mediate and regulate RBP folding, ligand binding, TTR assembly and secretion are not clearly understood. Though the folding and secretion properties of RBP have been described in HepG2 cells, its interactions with the ER resident chaperones have not been addressed. Apart from being an important cell biological question, the study of RBP assumes a lot of significance with its recent emergence as a key player in the pathogenesis of type 2 diabetes mellitus. It has been proposed that lowering of serum RBP levels could be a new strategy for treating type 2 diabetes mellitus. The present study was undertaken with the intention of analyzing the oxidative folding of RBP in the ER more closely. A systematic approach aimed at understanding the early events associated with folding and maturation of RBP, with particular emphasis on the role of ER-resident chaperones and the quality control machinery, is likely to provide interesting insights into the mechanisms involved in its ligand dependent secretion. Reconstitution of RBP biogenesis in a cell free system. The folding of RBP in cells is extremely quick with rapid oxidation kinetics. This makes it difficult to systematically analyze the early folding events in cultured cells. It was necessary to make use of a simplified system that would faithfully recapitulate the folding process in the ER. Therefore, a cell free translation system consisting of rabbit reticulocyte lysate and canine pancreatic microcosms as a source of ER-derived membranes was developed. This system affords the advantage of easy manipulation while still preserving the overall environment that prevails in the ER of intact cells. Extensive biochemical and functional characterization of the isolated microcosms was carried out and in vitro translation and microsomal translocation of RBP was established. Though initially confined to studies on membrane insertion and core glycosylate, the cell free system supplemented with microcosms has subsequently been used to analyze folding and assembly of a number of secretary and membrane proteins. A similar strategy has been adopted in the present study of RBP folding and maturation. Oxidative folding of RBP in isolated microcosms: Delineation of its disulfide oxidation pathway Using glutathione (GSSG) as the oxidant, co- and posttranslational disulfide oxidation of RBP was carried out in isolated microcosms. The ability to manipulate the redox status of this cell free system has helped to considerably slow down the oxidative folding of RBP so that a more careful analysis of the folding process could be performed. RBP was found to undergo oxidative folding with a t1/2 of 30 minutes and folding proceeded through at least one disulfide-bonded intermediate. Non-reducing SDS PAGE was used to resolve the folding intermediates. The pattern of oxidation was in good agreement with that reported earlier in HepG2 cells. No significant effect of retinol was observed on either the folding kinetics or the pattern of disulfide oxidation of RBP in isolated microsomes.A DTT sensitivity assay, used to probe the conformational maturity of folding RBP, revealed that RBP was capable of maturing into a DTT-resistant conformation in isolated microsomes. With the aid of disulfide mutants, the probable disulfide oxidation pathway of RBP in the ER has been determined. Single and double disulfide mutants of RBP were generated by site-directed mutagenesis and their posttranslational oxidation patterns were analyzed and compared with that of the wild type protein. Based on the results obtained, it was clear that the folding intermediate was made up of one of the two big disulfide loops and that the presence of both these loops was essential for RBP to fold into a fully oxidized, compact form. It has not been possible to determine the contribution of the third, smallest disulfide loop to the oxidative folding of RBP. Molecular events associated with the early oxidative folding of RBP To gain insights into the possible role of ER chaperones in the oxidative folding of RBP, the oligomeric state of folding RBP was analyzed by velocity sedimentation and chemical crosslinking assays. Velocity sedimentation analysis revealed that the reduced form of RBP was present in a large complex of size >100 S20,W. Upon disulfide oxidation, it readily dissociated from the complex and assumed a monomeric state. This was evident even during co-translational oxidation which suggested that RBP transiently associated with the large complex during its oxidative folding. Dynamic nature of this complex indicated that this could be a folding complex containing the chaperone machinery of the ER. These results were also supported by crosslinking analysis performed in unbroken microsomes using the homo-bifunctional crosslinker, DSP. The early folding forms of RBP could be crosslinked to a large complex while upon disulfide oxidation, RBP matured to its monomeric form and was no longer crosslinkable. Sedimentation and crosslinking analyses of the RBP disulfide mutants revealed that while the double disulfide mutant remained irreversibly associated with the large complex, the single mutants were released upon acquiring one of the two big disulfide loops. This suggested that despite the lack of one of the two major disulfides, these mutants were considered ‘folded’ by the quality control machinery in the ER while the double mutant probably resembled a molten globule state and was therefore considered ‘unfolded’ and irreversibly retained. Results from crosslinking analysis in microsomes not engaged in active translation suggested that chaperones of the ER were organized in a complex constitutively thereby lending support to the concept of ER-matrix, a large network of luminal proteins consisting of ER chaperones and accessory factors. Given this scenario, it is not unlikely that newly synthesized protein substrates transiently associate with this large pre-existing complex of chaperones and dissociate during late stages of their maturation. Conclusion In all, this study provides significant insights into some of the early events associated with the oxidative folding of RBP in the ER. The delineation of the disulfide oxidation pathway of RBP has been possible. The results obtained from this study suggest that RBP probably dissociates from the quality control quite early during its folding process and this step in its maturation might not be influenced by retinol. The stimulus for its ligant dependent secretion is likely to operate at a later stage of its sojourn in the ER, possibly consequent to positive cues from accessory binding factors such as TTR. Lastly, Perservation of the ER microenvironment in isolated microsomes, as evidenced from this study, augurs well for the use of this system to analyze mechanisms underlying folding, maturation, secretion and/or retention of secretory proteins.

Endoplasmic Reticulum (ER)

Retinol Binding Protein (RBP)

Oxidative Folding

Endoplasmic Reticulum Chaperones

Secretory Proteins

Microsomes

Biochemistry

Etudes structurales de la défensine AhPDF1 de la plante Arabidopsis halleri impliquée dans la tolérance au zinc / Structural studies of the plant defensin AhPDF1 from Arabidopsis halleri involved in zinc tolerance

Meindre, Fanny

17 December 2013

Mon travail de thèse porte sur la protéine AhPDF1 de la plante Arabidopsis halleri. AhPDF1 est une défensine de 51 résidus, riche en cystéines qui participe à la défense de la plante en jouant un rôle antifongique. La défensine AhPDF1 possède 8 cystéines impliquées dans ses 4 ponts disulfure, elle présente un repliement en CSαβ. Des travaux récents sur AhPDF1 ont permis d’identifier une nouvelle fonction : la tolérance aux métaux lourds, en particulier la tolérance au zinc. L’objectif général du projet dans lequel s’intègre ma thèse est donc de comprendre, au niveau atomique et en lien avec l’état d’oxydation des cystéines, le mécanisme par lequel les défensines de plantes confèrent la tolérance au zinc. Dans une majeure partie de ma thèse j’ai travaillé à la production de la défensine AhPDF1 d’abord dans Escherichia coli puis dans Pichia pastoris. J’ai ensuite mis au point la synthèse chimique de la protéine AhPDF1 et optimisé l’étape la plus délicate, celle du repliement oxydatif. Après avoir produit la défensine AhPDF1 en quantité et qualité suffisante, j’ai réalisé son étude structurale par RMN. De plus cette structure m’a servi de base pour modéliser, par homologie, toutes les autres défensines actuellement identifiées d’Arabidopsis halleri et Arabidopsis thaliana. Enfin, j’ai appris à maîtriser les conditions qui permettent de conserver la protéine dans un état partiellement réduit et j’ai réalisé les premiers essais de chélation de la défensine avec le zinc. / My thesis focuses on the AhPDF1 plant defensin from Arabidopsis halleri. AhPDF1 is a 51-residue, cysteine-rich protein involved in the plant defense, and playing an antifungal role. AhPDF1 defensin has eight cysteins involved in its four disulfide bridges, and presents a folding in CSαβ. Recent work on AhPDF1 allowed to identify a new function : the tolerance to heavy metals, especially zinc tolerance. The overall objective of the project that fits my thesis is to understand, at the atomic level and in relation to the oxidation state of cysteins, the mechanism by which the plant defensins confer zinc tolerance. In a major part of my thesis I worked on the production of AhPDF1 defensin first in Escherichia coli and in Pichia pastoris. Then, I developed the chemical synthesis of AhPDF1 and optimized the most delicate step of the oxidative folding. After producing AhPDF1 defensin in sufficient quantity and quality, I realized its structural study by NMR. Furthermore, this structure was used as starting structure, for modeling by homology all other defensins currently identified from Arabidopsis halleri and Arabidopsis thaliana. Finally, I learnt how to master the conditions that maintain the protein in a partially reduced state in order to achieve the first assay of zinc chelation with defensin.

Défensine de plantes

Arabidopsis halleri

Antifongique

Ponts disulfure

Zinc

Structure

RMN

Repliement oxydatif

Plant defensin

Arabidopsis halleri

Antifungal

Disulfide

Zinc

Structure

NMR

Oxidative folding