The Role of Non-Structural Protein NS2A in Flavivirus Assembly and Secretion

Jason Leung

Unknown Date

Flaviviruses are a group of medically relevant pathogens, known to cause serious disease in animals and humans. The previously defined roles of the flavivirus non-structural protein 2A (NS2A) in RNA replication, and modulation of the host antiviral response, has recently been extended to include virus assembly and secretion. In West Nile virus subtype Kunjin (KUN), an Isoleucine (I)-to-Asparagine (N) substitution at position 59 of the NS2A protein blocked the production of secreted virus particles in cells electroporated with viral RNA carrying this mutation. In this study, prolonged incubation of mutant KUN NS2A-I59N replicon RNA, in an inducible BHK-derived packaging cell line (expressing KUN structural proteins C, prM, and E), generated escape mutants that rescued the secretion of infectious virus-like particles. Sequencing identified three groups of revertants that included (i) reversions to wild-type, hydrophobic Ile, (ii) pseudorevertants to more hydrophobic residues (Ser, Thr, and Tyr) at codon 59, and (iii) pseudorevertants retaining Asn at NS2A codon 59, but containing a compensatory mutation (Thr-to-Pro) at NS2A codon 149. Engineering hydrophobic residues at NS2A position 59, or the compensatory T149P mutation into NS2A-I59N replicon RNA, restored the assembly of secreted virus-like particles in packaging cells. T149P mutation also rescued virus production when introduced into the full-length KUN RNA containing an NS2A-I59N mutation. Immunofluorescence and electron microscopy analyses of NS2A-I59N replicon-expressing cells showed a distinct lack of virus-induced membranes normally present in cells expressing wild-type replicon RNA. The compensatory mutation NS2A-T149P restored the induction of membrane structures to a level similar to those observed during wild-type replication. These results further confirm the role of NS2A in virus assembly, demonstrate the importance of hydrophobic residues at codon 59 in this process, implicate the involvement of NS2A in the biogenesis of virus-induced membranes, and suggest a vital role for these induced membranes in virus assembly. To further our understanding of how mutations within NS2A are able to affect the induction of virus-induced membranes, leading to a block in virus assembly, the membrane topology of KUN NS2A was investigated. Using a plasmid encoding NS1 and NS2A proteins with C-terminal c-myc and FLAG epitopes, NS2A proteins containing N-linked acceptor sites and C-terminal truncations were generated. Assays were performed to identify the subcellular localization of specific sequences within NS2A by Western blot and immunofluorescence analyses. While the membrane topology could not be determined experimentally, the findings of this study support the assertion that cleavage at the NS1/NS2A junction requires the majority, if not all of the NS2A protein for proper processing to occur, and suggests that the interaction between hydrophilic loops and -helical transmembrane segments plays an important role in the formation and stability of the flavivirus NS2A protein topology. Based on the knowledge of polyprotein processing events, and utilizing a range of software packages, a topology model of NS2A was predicted. The likelihood of additional sequences within NS2A affecting the ability to induce virus-specific membranes, and facilitate virion assembly, has led to the development of an invasive bacterial screening system, as a delivery vehicle to screen libraries of mutated KUN replicon clones. Using these invasive bacteria to deliver mutated KUN replicons into BHK-derived packaging cells, mutations causing a deficiency in either RNA replication or encapsidation can be identified by performing -gal assays on cells maintained in the presence, or absence of Doxycycline (suppressing the expression of structural proteins), respectively. Furthermore, this system was adapted for use in a 96-well plate format, allowing for high-throughput screening. Thus, KUN replicon clones capable of RNA replication, but unable to assemble and secrete virus-like particles can be identified and further analyzed, in the hope of mapping amino acid residues and motifs involved in encapsidation of flavivirus RNA. Finally, a range of hypotheses are discussed, explaining the possible mechanisms by which NS2A is involved in flavivirus assembly. A number of future directions and applications are also presented.

Kunjin

Flavivirus

Assembly

NS2A

Nonstructural

Membrane biogenesis

Invasive bacteria

Topology

Quantifying Oxidative Stress and its Role in Mitochondrial Biogenesis

Natalie Strobel

Unknown Date

Oxidative and nitrosative stress are deleterious physiological processes caused by an imbalance between reactants such as reactive oxygen and nitrogen species and antioxidants. Due to the links between oxidative and nitrosative stress and disease, there is much interest in accurately quantifying these in biological and physiological samples. There are numerous methods to quantify the in vivo oxidative and nitrosative damage to lipids, DNA and proteins however they are generally time-consuming, expensive and difficult. Furthermore, due to the complex nature of oxidative and nitrosative stress it would be appropriate to measure a number of different biomarkers, however this is rarely done. The first section of this thesis contains research aimed at developing a bioassay to simultaneously detect markers of oxidative and nitrosative stress. This includes; 1) a review of the studies investigating the ability of these biomarkers to predict the onset of disease, 2) a description of the attempts to develop the bioassay, 3) a study designed to test the sensitivity of the bioassay to detect changes in oxidative stress. Unfortunately, the attempts to develop the bioassay were not as successful as hoped and, in the interests of completing the PhD in the time allowed, the PhD changed focus to look at the effects of oxidant:antioxidant balance on mitochondrial biogenesis. The second section of the thesis contains a review of the literature on this topic and two original investigations. It is well documented that oxidative and nitrosative stress contributes to the progression of many diseases including; cardiovascular disease, type 2 diabetes, Alzheimer’s disease, kidney disease and cancer. To determine which biomarkers would have the greatest efficacy in the bioassay, a comprehensive review was undertaken. The aim of the review was to investigate studies which have measured oxidative and nitrosative biomarkers to determine whether they are independent predictors of cardiovascular events (Chapter two). From the review, fifty-one studies were identified with twenty-six of these measuring oxidised (Ox)-LDL, fifteen assessing myeloperoxidase (MPO), seven using lipid peroxidation measures and three quantifying protein oxidation in plasma/serum. The recommendation of the review was that all areas require further investigation, however, it was determined that Ox-LDL and MPO would be beneficial for inclusion in the bio-assay. Other biomarkers considered for the bio-assay were nitrotyrosine, superoxide dismutase and glutathione peroxidase. Chapter three outlines method development used to measure the oxidative and nitrosative markers simultaneously. Recent technology allows multiple analytes to be detected simultaneously from the one sample. The Mulit-plex system is used to detect analytes that have been sandwiched between primary capture and secondary biotinylated detection antibodies. The secondary antibody attaches to streptavidin-phycoerythrin and is used by the Mulit-plex analyser to quantify the analyte. During development of the bio-assay, clumping of microspheres, high background, no detection of standard curve or samples, matrix effects, mislabeling of antibodies by manufacturers and lack of commercial available antibodies were obstacles that limited the success of this method. MPO was the only biomarker that was successful. Chapter four contains a study that investigated the sensitivity of the MPO mulitplex bio-assay. Nine highly trained cyclists underwent an extensive exercise protocol designed to induce dehydration by 4 % body mass, rehydration of 150 % fluid loss and a performance time-trial. Plasma samples were taken at five time points; baseline, post dehydration, post rehydration, pre time-trial and post time-trial and analysed using the mulitplex bio-assay. The results showed that there was a significant increase in MPO post dehydration and post time-trial compared with all other time points (P<0.05), thereby demonstrating that the mulitplex bio-assay is sensitive to detect changes in exercise and appropriate rehydration reduces oxidative stress. The MPO mulitplex bio-assay requires further testing on patients with diseases to further validate its future applications. As mentioned above, due to time constraints it was decided to stop the attempts to create a multi-analyte bioassay and focus on another important area of cellular oxidative stress. Currently, there is much interest in the involvement of oxidant:antioxidant balance in mitochondrial biogenesis. The increase of mitochondrial content within the skeletal muscle, termed mitochondrial biogenesis, provides an increased capacity to generate ATP during exercise and is recognized as one of major cellular adaptations to exercise. Reactive oxygen species are produced during exercise and have been shown to induce mitochondrial biogenesis. One of the key instigators of mitochondrial biogenesis is peroxisome proliferator activated receptor gamma coactivator-1α (PGC-1α). PGC-1α is central to the transcription of mitochondrial and nuclear encoded genes, which regulate downstream pathways such as oxidative phosphorylation and fatty acid oxidation. Antioxidant supplementation is common among athletes and healthy individuals; however, antioxidant supplements suppress reactive oxygen species and could therefore could hinder mitochondrial biogenesis and the positive adaptations associated with exercise. To establish whether antioxidant supplementation reduced mitochondrial biogenesis in skeletal muscle, male Wistar rats were supplemented with α-tocopherol and α-lipoic acid for fourteen weeks (Chapter six). Animals were separated into four groups: 1) sedentary control diet, 2) sedentary antioxidant diet, 3) exercise control diet and 4) exercise antioxidant diet. The exercise animals were trained 5 days/week for 14 weeks. Consistent with increased mitochondrial biogenesis and antioxidant defences following training, there were significant increases in PGC-1α mRNA and protein, COX IV and Cyt C protein abundance, citrate synthase activity, Nfe2l2 and SOD2 protein (P<0.05). Antioxidant supplementation reduced PGC-1α mRNA, PGC-1α and COX IV protein, and citrate synthase enzyme activity (P<0.05) in both sedentary and exercise-trained rats. In summary, antioxidants α-tocopherol and -lipoic acid supplementation suppresses beneficial adaptations in skeletal muscle such as markers of mitochondrial biogenesis and mitochondrial proteins, regardless of training status. The reduction in mitochondrial biogenesis may affect exercise training adaptations and reduce the ability of healthy individuals to attain optimal exercise adaptations. The last investigation (Chapter seven) studied the effect of reduced glutathione, through diethyl maleate (DEM) administration, on upstream regulators of mitochondrial biogenesis, markers of mitochondrial biogenesis and downstream signalling. Glutathione is a key antioxidant that reduces the amount of hydrogen peroxide. Male Wistar rats were divided into six groups 1) sedentary control, 2) sedentary DEM, 3) post-exercise control, 4) post-exercise DEM, 5) exercise-recovery and 6) exercise-recovery DEM. After an exercise bout to fatigue, animals were euthanized directly after exercise (post-exercise) or four hours post exercise (exercise-recovery). Exercising animals given DEM had significantly (P<0.05) decreased glutathione in skeletal muscle and had a significantly (P<0.05) greater increase in PGC-1α gene expression. There were also main interaction effects between exercise and DEM administration on SOD2 activity. Exercise altered the gene expression of GPx and the phosphorylation of p38 MAPK. Glutathione depletion decreased GPX activity and oxidised glutathione levels. These novel findings represent important in vivo evidence of the involvement of glutathione and oxidant:antioxidant balance in mitochondrial biogenisis. Overall this thesis has provided 1) the first comprehensive review on the prognostic ability of oxidative stress biomarkers to predict the onset of cardiovascular disease, 2) detailed information to assist in the further development of a multi-analyte bioassay to quantify oxidative and nitrosative stress, 3) data indicating that the MPO Mulit-plex bioassay is sensitive to detect physiological perturbations to oxidative stress, 4) evidence that antioxidant supplementation suppresses mitochondrial biogenesis and 5) proof that glutathione is important in the regulation of exercise-induced mitochondrial biogenesis.

Μελέτες επί της δομής και λειτουργίας πρωτεϊνικών υπομονάδων του ριβονουκλεοπρωτεϊνικού συμπλόκου της ριβονουκλεάσης Ρ από το Dictyostelium discoideum

Σταματοπούλου, Βασιλική

11 January 2011

Η ριβονουκλεάση Ρ (RNase P) είναι ένα πανταχού παρόν ένζυμο, το οποίο θραύει ενδονουκλεολυτικά τα πρόδρομα μετάγραφα των tRNA, παράγοντας τα ώριμα 5΄ άκρα τους. Πρόσφατα, βρέθηκε πως η RNase P συμμετέχει στην μεταγραφή γονιδίων που κωδικοποιούν tRNA, rRNA και άλλα μικρά μη κωδικοποιούντα RNA. Η RNase P έχει ανιχνευθεί σε αντιπροσώπους και των τριών περιοχών της ζωής (βακτήρια, αρχαία, ευκαρυώτες), καθώς επίσης σε μιτοχόνδρια και χλωροπλάστες, με μοναδική εξαίρεση το αρχαίο Nanoarchaeum equitans. Σε σχεδόν όλους τους οργανισμούς, η RNase P είναι ένα ριβονουκλεοπρωτεϊνικό σύμπλοκο αποτελούμενο από μία απαραίτητη RNA υπομονάδα και ποικίλο αριθμό πρωτεϊνών. Υπάρχουν μόνο δύο, πρόσφατα, αναφερόμενες εξαιρέσεις, αυτές των ανθρώπινων μιτοχονδρίων και των πλαστιδίων του φυτού A. thaliana, των οποίων η RNase P είναι αποκλειστικά πρωτεϊνικής φύσεως. Η RNA υπομονάδα είναι υπεύθυνη για την καταλυτική λειτουργία του ολοενζύμου της RNase P από τα βακτήρια, τα αρχαία και τους ευκαρυώτες. Οι πρωτεϊνικές υπομονάδες είναι απαραίτητες για την κατάλυση in vivo και παίζουν πολλούς ρόλους στη δομή και λειτουργία του ολοενζύμου. Η πυρηνική RNase P από το Dictyostelium discoideum είναι το πιο πλούσιο, σε πρωτεϊνική σύσταση, ολοένζυμο ανάμεσα στα ευκαρυωτικά ένζυμα RNase P που έχουν μελετηθεί μέχρι σήμερα. Είναι ένα ριβονουκλεοπρωτεϊνικό σύμπλοκο, το οποίο αποτελείται από μια RNA υπομονάδα και οχτώ πρωτεΐνες (DRpp40, DRpp30, DRpp29, DRpp25, DRpp21, DRpp20, DPop1, DPop5). Αυτές οι πρωτεΐνες παρουσιάζουν ομοιότητες με τις ομόλογές τους από ανώτερα ευκαρυωτικά ένζυμα, όπως του ανθρώπου, ενώ παράλληλα διατηρούν ιδιοσυγκρασιακά χαρακτηριστικά. Στην παρούσα μελέτη, περιγράφουμε την κλωνοποίηση και τις ιδιότητες αλληλεπίδρασης της πρωτεΐνης DRpp29 με την RNA υπομονάδα της RNase P του D. discoideum. Πειράματα ηλεκτροφορητικής κινητικότητας έδειξαν, πως η DRpp29 δεσμεύεται ειδικά με την RNA υπομονάδα, ένα χαρακτηριστικό που επιβεβαιώθηκε περαιτέρω με τον σχεδιασμό του μοντέλου της δομής της DRpp29. Επιπλέον, κατασκευάστηκαν μεταλλάγματα απολοιφής της DRpp29, για να μελετηθούν οι περιοχές της DRpp29 που συνεισφέρουν ή/και είναι υπεύθυνες για την άμεση αλληλεπίδρασή της με την RNA υπομονάδα. Εντοπίστηκε μια περιοχή, μεταξύ των ευκαρυωτικών ομολόγων, πλούσια σε λυσίνες και αργινίνες, η οποία φαίνεται να διευκολύνει την αλληλεπίδραση των δύο αυτών υπομονάδων. Προσδιορίσαμε, επίσης, με τη διεξαγωγή ανάλυσης αποτυπώματος και τη χρήση δεδομένων βιοπληροφορικής, τη δευτεροταγή δομή της RNA υπομονάδας της RNase P του D. discoideum. Με ανάλυση αποτυπώματος αποκαλύφθηκε, πως η DRpp29 αλληλεπιδρά με την περιοχή εξειδίκευσης (“S-domain”) της RNA υπομονάδας, δείχνοντας, ότι η DRpp29 επηρεάζει την ικανότητα δέσμευσης του υποστρώματος από το ένζυμο. Στη συνέχεια, ελέγχθη η ικανότητα της DRpp29 και των μεταλλαγμάτων της να σχηματίζουν, μαζί με την RNA υπομονάδα του E. coli, ενεργά ενζυμικά σύμπλοκα με δραστικότητα RNase P. Τέλος, ελέγχθη ο σχηματισμός ενός ελάχιστα καταλυτικού πυρήνα της RNase P του D. discoideum, με την πραγματοποίηση πειραμάτων ομόλογης ανασύστασης με την DRpp29, τον πρωτεϊνικό της συνεργάτη DRpp21 και την RNA υπομονάδα / Ribonuclease P (RNase P) is a ubiquitous enzyme, which endonucleolytically cleaves the precursor tRNA transcripts to produce their mature 5΄ ends. Recently, RNase P has been found to participate in the transcription of tRNA, rRNA and other small non-coding RNA genes. RNase P occurs in representatives of all domains of life (bacteria, archaea, eukarya), as well as in mitochondria and chloroplasts, apart from the archeon Nanoarchaeum equitans. In almost every organism, RNase P is a ribonucleoprotein complex, with one essential RNA and a multiple number of protein subunits. There are only two exceptional cases, that of the human mitochondria and the plastids from A. thaliana, whose RNase P lacks an RNA subunit. The RNA subunit is responsible for the main catalytic function of the RNase P holoenzyme in bacteria, archaea and eukarya. Protein subunits are essential for catalysis in vivo and they play multiple roles in structure and function of the holoenzyme. Dictyostelium discoideum nuclear RNase P is the most proteinaceous holoenzyme among the eukaryal RNase P studied so far. It’s a ribonucleoprotein complex, which consists of one RNA and eight protein subunits (DRpp40, DRpp30, DRpp29, DRpp25, DRpp21, DRpp20, DPop1, DPop5). These proteins display similarities with its counterparts from higher eukaryotes, such as the human enzyme, but at the same time they retain distinctive characteristics. In the present study, we report the molecular cloning and interaction details of DRpp29 and RNase P RNA. Electromobility shift assays exhibited that DRpp29 binds specifically to the RNase P RNA subunit, a feature that was further confirmed by the molecular modeling of the DRpp29 structure. Moreover, deletion mutants of DRpp29 were constructed in order to investigate the domains of DRpp29 that contribute to and/or are responsible for the direct interaction with the D. discoideum RNase P RNA. A eukaryotic specific, lysine and arginine rich region was revealed, which seems to facilitate the interaction between these two subunits. We determined the D. discoideum RNase P RNA secondary structure based on footprinting analysis and bioinformatic data. Furthermore, footprinting analysis revealed that DRpp29 interact with the specificity domain (“S-domain”) of the RNA subunit, suggesting that DRpp29 influence the enzyme’s substrate binding ability. Furthermore, we tested the ability of wild type and mutant DRpp29 to form active RNase P enzymatic particles with the E. coli’s RNase P RNA. Finally, we tested the formation of a minimal catalytic core of the D. discoideum RNase P, by performing homologous reconstitution experiments with DRpp29, its protein partner DRpp21 and the RNA subunit

Ριβοένζυμα

572.88

RNase P

tRNA biogenesis

Dictyostelium discoideum

Μελέτες της λειτουργικής συμμετοχής της La πρωτεΐνης του Dictyostelium discoideum στην ωρίμανση πρόδρομων μορίων tRNA

Αποστολίδη, Μαρία

30 May 2012

Η La πρωτεΐνη περιγράφηκε για πρώτη φορά στον άνθρωπο ως αυτοαντιγόνο το οποίο αναγνωρίζεται από αντισώματα που είναι παρόντα στον ορό ασθενών που πάσχουν από συστηματικό ερυθηματώδη λύκο (systemic lupus erythematosus) και σύνδρομο Sjögren. Είναι γνωστό σήμερα ότι συμμετέχει ενεργά στη βιογένεση μικρών μορίων RNA, συμπεριλαμβανομένου της ιδιότητάς της να συνδέεται και να προστατεύει την 3’ ακόλουθη αλληλουχία των πρόδρομων tRNA μεταγράφων. Επιπλέον, έχει προταθεί ότι in vivo διευκολύνει την απομάκρυνση της 5’ οδηγού αλληλουχίας από την RNase P. Στην παρούσα μελέτη, πραγματοποιήθηκε μοριακή κλωνοποίηση της La πρωτεΐνης του D. discoideum (354aa, 40,3-kDa) και υπερέκφρασή της. Η ανασυνδυασμένη La-His6 απομονώθηκε σε δύο στάδια καθαρισμού και εξετάστηκε ως προς την ικανότητα δέσμευσής της σε μόρια tRNA με ανάλυση EMSA (Electrophoresis Mobility Shift Assay). Τα αποτελέσματα με τη δοκιμή του ομόλογου pre-tRNASer που φέρει 3’ ακόλουθη αλληλουχία ως προσδέτη σε σχέση με ένα pre- tRNASer στο οποίο απουσιάζει η αντίστοιχη αλληλουχία, έδειξε ότι η La πρωτεΐνη έχει προτίμηση για αυτούσια πρόδρομα tRNA. In silico ανάλυση της πρωτεΐνης, έδειξε ότι περιλαμβάνει μοτίβα χαρακτηριστικά για RNA πρόσδεση με υψηλή συντήρηση στο Ν-τελικό της άκρο. Η προσθήκη αυξανόμενων συγκεντρώσεων ανασυνδυασμένης πρωτεΐνης La αναστέλλει σε ένα ποσοστό 10% την ωρίμανση του tRNA από την ομόλογη RNase P. Επιπρόσθετα, πραγματοποιήθηκαν in vitro δοκιμές για τη μελέτη της ικανότητας της La να βοηθά στη σωστή αναδίπλωση και άλλων πρόδρομων μεταγράφων της RNA πολυμεράσης ΙΙΙ. Για το λόγο αυτό ελέγχθηκε η ικανότητα ωρίμανσης παρουσία της La και της RNA υπομονάδας της RNase P. Κάτω από ποικίλες συνθήκες δοκιμής η παρουσία της La δεν ευνόησε την ενεργότητα του ριβοενζύμου. Τέλος, φωσφορυλίωση της La πρωτεΐνης σε συγκεκριμένα αμινοξέα δεν έδειξε ενίσχυση της συγγένειας για το υπόστρωμα. Η La του D. discoideum, μπορεί να συνδέεται με αρκετά μεγάλη συγγένεια με το ομόλογό της υπόστρωμα (Kd = 4±1nM, συγκρίσιμη με αντίστοιχες τιμές ομόλογων πρωτεϊνών) χωρίς την απαίτηση του μοτίβου 3’UUU-OH, το οποίο φαίνεται να είναι απαραίτητο για La πρωτεΐνες από άλλους οργανισμούς (H. sapiens, S. pombe, S. cerevisiae, T. brucei). Το γεγονός αυτό εγείρει πολλά ερωτήματα για την εξελικτική προέλευση αυτής της πρωτεΐνης και για την εξακρίβωση του ρόλου της ως αυτοαντιγόνου στα νοσήματα που αναφέρθηκαν. Βιοχημικές και δομικές μελέτες βρίσκονται σε εξέλιξη για να απαντήσουν σε αυτά τα ερωτήματα. / The La protein was first described in humans as an autoantigen recognized by antibodies present in serum of patients suffering from systemic lupus erythematosus and Sjögren syndrome. It is known that it participates actively in the biogenesis of small RNA molecules, including the binding and protection of the 3' trailer sequence of the precursor tRNA. Furthermore, it has been suggested that it facilitates the RNase P to remove the 5' leader sequence in vivo. In this study, molecular cloning and overexpression of the La protein D. discoideum (354aa, 40,3-kDa) were realized. Recombinant La-His6 was purified in two stages and was assayed regarding its capacity to bind tRNA using EMSA (Electrophoresis Mobility Shift Assay). The results testing the homologous pre- tRNASer bearing a 3' trailer sequence as a ligand compared to a pre- tRNASer which lacks the corresponding sequence, showed that the La protein has a preference for intact precursor tRNA. In silico analysis of the protein domain showed that it includes highly conserved motifs characteristic for RNA binding at the N-terminal site. The addition of increasing concentrations of recombinant La protein inhibits the maturation of tRNA by homologous RNase P at a 10% rate. Additionally, in vitro assays were carried out to study the ability of La to assist the proper folding of additional precursor transcripts of RNA polymerase III. Therefore the ability of maturation in presence of La and the RNA subunit of RNase P was assayed. Under various test conditions, the presence of La did not favor any riboenzyme activity. Finally, phosphorylation of La protein in specific amino acids showed no enhancing affinity to the substrate. The La protein from D. discoideum, can bind with quite a high affinity to its homologous substrate (Kd = 4 ± 1nM, comparable to corresponding values of homologous proteins) without the presence of the 3'UUU-OH motif, which appears to be necessary for La proteins from other organisms (H. sapiens, S. pombe, S. cerevisiae, T. brucei). This raises many questions about the evolutionary origin of this protein and the identification of its role as an autoantigen in many autoimmune diseases. Biochemical and structural studies are underway to answer these questions.

Πρωτεΐνη La

Βιογένεση μορίων tRNA

572.884 5

La protein

tRNA biogenesis

Outer Membrane Biogenesis and Stress Response in Escherichia coli

January 2010

abstract: Protein folding is essential in all cells, and misfolded proteins cause many diseases. In the Gram-negative bacterium Escherichia coli, protein folding must be carefully controlled during envelope biogenesis to maintain an effective permeability barrier between the cell and its environment. This study explores the relationship between envelope biogenesis and cell stress, and the return to homeostasis during envelope stress. A major player in envelope biogenesis and stress response is the periplasmic protease DegP. Work presented here explores the growth phenotypes of cells lacking degP, including temperature sensitivity and lowered cell viability. Intriguingly, these cells also accumulate novel cytosolic proteins in their envelope not present in wild-type. Association of novel proteins was found to be growth time- and temperature-dependent, and was reversible, suggesting a dynamic nature of the envelope stress response. Two-dimensional gel electrophoresis of envelopes followed by mass spectrometry identified numerous cytoplasmic proteins, including the elongation factor/chaperone TufA, illuminating a novel cytoplasmic response to envelope stress. A suppressor of temperature sensitivity was characterized which corrects the defect caused by the lack of degP. Through random Tn10 insertion analysis, aribitrarily-primed polymerase chain reaction and three-factor cross, the suppressor was identified as a novel duplication-truncation of rpoE, here called rpoE'. rpoE' serves to subtly increase RpoE levels in the cell, resulting in a slight elevation of the SigmaE stress response. It does so without significantly affecting steady-state levels of outer membrane proteins, but rather by increasing proteolysis in the envelope independently of DegP. A multicopy suppressor of temperature sensitivity in strains lacking degP and expressing mutant OmpC proteins, yfgC, was characterized. Bioinformatics suggests that YfgC is a metalloprotease, and mutation of conserved domains resulted in mislocalization of the protein. yfgC-null mutants displayed additive antibiotic sensitivity and growth defects when combined with null mutation in another periplasmic chaperone, surA, suggesting that the two act in separate pathways during envelope biogenesis. Overexpression of YfgC6his altered steady-state levels of mutant OmpC in the envelope, showing a direct relationship between it and a major constituent of the envelope. Curiously, purified YfgC6his showed an increased propensity for crosslinking in mutant, but not in a wild-type, OmpC background. / Dissertation/Thesis / Ph.D. Microbiology 2010

Microbiology

Biogenesis

Envelope

Protein Folding

Stress Response

Suppressor

Temperature Sensitivity

Functional characterisation of RNA helicases in the remodelling of pre-ribosomal subunits

Brüning, Lukas

08 December 2017

No description available.

570

Ribosome Biogenesis

RNA helicases

RNA biology

Biologie (PPN619462639)

Estudos funcionais de CrNIP7 de Chlamydomonas reinhardtii: uma proteína envolvida na biogênese de ribossomos / Functional studies of CrNIP7 from Chlamydomonas reinhardtii: a protein involved in ribosome biogenesis.

Raissa Ferreira Gutierrez

01 July 2016

A biogênese do ribossomo é um processo complexo, altamente ordenado e regulado, no qual o transcrito primário é processado por endo e exonucleases para gerar os RNAs ribossomais maduros. Este processo foi melhor caracterizado em Saccharomyces cerevisiae, porém alguns fatores atuantes em humanos tiveram uma função divergente descrita. Um desses fatores é a proteína NIP7, altamente conservada em eucariotos, que atua na formação da subunidade ribossomal 60S, em levedura, e 40S, em humanos. Assim, esse trabalho propôs a caracterização funcional da proteína CrNIP7, homóloga a NIP7, presente em Chlamydomonas reinhardtii. C. reinhardtii é uma alga verde unicelular ancestral a plantas, utilizada como modelo eucarioto para estudos de fotossíntese e de flagelos. Nesse trabalho, um estudo de complementação funcional foi realizado utilizando duas linhagens de Saccharomyces cerevisiae diferentes e em ambas CrNIP7 complementou a função de Nip7p de leveduras, indicando uma participação na síntese da subunidade 60S do ribossomo. Uma busca por parceiros de interação de CrNIP7 foi também realizada, utilizando CrNIP7 como isca para rastrear uma biblioteca de cDNA de C. reinhardtii em sistema de duplo híbrido em leveduras, o que resultou em dois novos potenciais parceiros de interação. Esses parceiros foram identificados como proteínas preditas conceitualmente no genoma de C. reinhardtii, denominadas Predicted e G-patch. Adicionalmente, a interação entre CrNIP7 e CrSBDS, proteína homóloga a Sdo1 (de levedura) e HsSBDS (de humanos), foi confirmada através de um experimento de duplo híbrido dirigido. A interação entre as proteínas CrNIP7 e CrSBDS foi validada por pull down e um teste preliminar sugeriu que CrNIP7 e Predicted também interagem in vitro. Análises de bioinformática indicam que Predicted, G-patch e CrSBDS tenham regiões intrinsicamente desordenadas, as quais podem se estruturar na interação com seus parceiros. Em conjunto, os resultados desse trabalho contribuem para entendimento do papel de CrNIP7 na biogênese de ribossomos em Chlamydomonas reinhardtii em comparação com outros modelos eucarióticos. / Ribosome biogenesis is a complex, highly regulated and ordered process in which the primary transcript is processed by endo- and exonucleases to generate the mature ribosomal RNAs. This process was best characterized in Saccharomyces cerevisiae, but some factors have been described in humans with different function. One of these divergent factors is NIP7, a highly conserved protein in eukaryotes, which acts in the formation of ribosomal 60S subunit, in yeast, and 40S, in humans. Based on this, this work proposed the functional characterization of CrNIP7 protein, homologous to NIP7, from Chlamydomonas reinhardtii. C. reinhardtii is a green alga, ancestral to plants, that is used as an eukaryote model for photosynthesis and flagella studies. In this study, a functional complementation assay was performed using two different strains of Saccharomyces cerevisiae and, in both approaches, CrNIP7 protein complemented the function of Nip7p from yeast, indicating its participation in the synthesis of the 60S ribosomal subunit. A two-hybrid assay was carried out using CrNIP7 as bait to screen a C. reinhardtii cDNA library in order to find out CrNIP7 interaction partners, wich resulted in two novel potentially partners. The interacting proteins were identified as conceptually predicted proteins in the genome of C. reinhardtii and were called Predicted and G-patch. Additionally, the interaction between CrNIP7 and CrSBDS, a protein homologous to Sdo1 (yeast) and HsSBDS (humans), was confirmed by a direct two-hybrid assay. The interaction between CrNIP7 and CrSBDS proteins was validated by pull down and a preliminary test suggested that CrNIP7 and Predicted also interact in vitro. Bioinformatics analyzes indicate that Predicted, G-patch and CrSBDS have intrinsically disordered regions, which can be ordered in the moment of interaction. Taken together, the results of this work contribute to understand the role played by CrNIP7 in ribosome biogenesis in Chlamydomonas reinhardtii compared to other eukaryotic models.

Chlamydomonas reinhardtii

Biogênese de ribossomo

CrNIP7

Chlamydomonas reinhardtii

CrNIP7

Ribosome biogenesis

Rubisco biogenesis and assembly in Chlamydomonas reinhardtii / Biogenèse et assemblage de Rubisco chez Chlamydomonas reinhardtii

Wietrzynski, Wojciech

17 October 2017

La nécessité de coordonner l’expression des gènes provenant de génomes différents chez les plantes a conduit à l’émergence de mécanismes imposant un contrôle nucléaire sur l’expression génétique de l’organelle. Des signaux antérogrades, exercés par des protéines reconnaissant des séquences spécifiques, existent en parallèle avec un contrôle des synthèses chloroplastiques dépendant de l’assemblage (CES). Ensemble, ils coordonnent la formation stoichiométrique des complexes photosynthétiques.La Ribulose bisphosphate carboxylase/oxygénase (Rubisco) est une enzyme localisée dans le chloroplaste qui contient deux sous-unités. La grande sous-unité (LSU) et la petite sous-unité (SSU) sont codées par les génomes chloroplastique et nucléaire respectivement. Elles s’assemblent dans le stroma du chloroplaste pour former une holoenzyme hexadécamérique (LSU8SSU8). Pendant mon travail au laboratoire, j’ai tenté de décrire les étapes régulatrices majeures de la synthèse de la Rubisco chez Chlamydomonas reinhardtii en me focalisant sur la régulation post-transcriptionelle de la LSU.J’ai montré que la protéine PPR – MRL1 est un facteur limitant pour l’accumulation de l’ARN messager de rbcL. Bien qu’il ait été décrit précédemment comme un facteur stabilisateur du transcrit susnommé, MRL1 s’est révélé avoir un rôle dans la traduction.J’ai par ailleurs démontré que chez Chlamydomonas, l’expression de la Rubisco est contrôlée par la présence de la SSU. En son absence, la traduction de rbcL est inhibée par son propre produit – la grande sous-unité non assemblée. J’ai pu montrer qu’un intermédiaire d’assemblage, constitué de LSU en complexe avec sa chaperonne RAF1, est nécessaire pour cette régulation, ce qui prouve que ce processus dépend de l’état d’oligomérisation de la LSU. Parallèlement, j’ai caractérisé le devenir de la LSU non assemblée quand la régulation CES est perturbée, et grâce à cela ait contribué à améliorer la connaissance de son processus de repliement et d’assemblage. / The necessity to coordinate the expression of genes originating from different genomes within the plant cell resulted in the appearance of mechanisms imposing nuclear control over organelle gene expression. Anterograde signaling through sequence-specific trans-acting proteins (OTAFs) coexists in the chloroplast with an assembly dependent control of chloroplast synthesis (CES process) that coordinates the stoichiometric formation of photosynthetic complexes.Ribulose bisphosphate carboxylase/oxygenase (Rubisco) is a chloroplast-located carbon fixing enzyme constituted of two subunits. Large subunit (LSU) and small subunit (SSU) are encoded in the chloroplast and nuclear genomes respectively. In the stroma they assemble to form a hexadecameric holoenzyme (LSU8SSU8). In this study I tried to highlight major regulatory points of its synthesis in Chlamydomonas reinhardtii focusing on the posttranscriptional regulation of LSU.I showed that the MRL1 PPR protein is a limiting factor for rbcL mRNA accumulation. Whereas it has been previously designated as a stabilization factor for the abovementioned transcript, MRL1 appeared also to have a function in rbcL translation.Most notably, I have demonstrated that in Chlamydomonas reinhardtii Rubisco expression is controlled by the small subunit (SSU) presence. In its absence rbcL undergoes an inhibition of translation through its own product – the unassembled Rubisco large subunit. This process depends on LSU-oligomerization state as I was able to show that the presence of a high order LSU assembly intermediate bound to the RAF1 assembly chaperone is essential for the regulation to occur. In parallel I shed light on the fate of unassembled LSU in a deregulated CES context, thereby improving our understanding of the process of its folding and assembly.

Rubisco

Chlamydomonas

CES

RAF1

Assemblage

Biogenèse

Biogenesis

Assembly

Rubisco

572.8

Nucleolar Ribosome Assembly

Lackmann, Fredrik

January 2017

Ribosomes are macromolecular machines that are responsible for production of every protein in a living cell. Yet we do not know the details about how these machines are formed. The ribosome consists of four RNA strands and roughly 80 proteins that associate with each other in the nucleolus and form pre-ribosomal complexes. Eukaryotes, in contrast to prokaryotes, need more than 200 non-ribosomal factors to assemble ribosomes. These associate with pre-ribosomal complexes at different stages as they travel from the nucleolus to the cytoplasm and are required for pre-rRNA processing. We do however lack knowledge about the molecular function of most of these factors and what enables pre-rRNA processing. Especially, information is missing about how non-ribosomal factors influence folding of the pre-rRNA and to what extent the pre-ribosomal complexes are restructured during their maturation.  This thesis aims to obtain a better understanding of the earliest events of ribosome assembly, namely those that take place in the nucleolus. This has been achieved by studying the essential protein Mrd1 by mutational analysis in the yeast Saccharomyces cerevisiae as well as by obtaining structural information of nucleolar pre-ribosomal complexes. Mrd1 has a modular structure consisting of multiple RNA binding domains (RBDs) that we find is conserved throughout eukarya. We show that an evolutionary conserved linker region of Mrd1 is crucial for function of the protein and likely forms an essential module together with adjacent RBDs. By obtaining structural information of pre-ribosomal complexes at different stages, we elucidate what structuring events occur in the nucleolus.  We uncover a direct role of Mrd1 in structuring the pre-rRNA in early pre-ribosomal complexes, which provides an explanation for why pre-rRNA cannot be processed in Mrd1 mutants. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 4: Manuscript.</p>

Ribosome biogenesis

RNA

Nucleolus

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Structural, biophysical and functional characterization of Nop7-Erb1-Ytm1 complex and its implications in eukaryotic ribosome biogenesis

WEGRECKI, MARCIN

14 October 2015

[EN] Ribosome biogenesis is one of the most important and energy-consuming processes in the cell. However, the vast majority of the events and factors that are involved in the synthesis of ribosomal subunits are not well understood. Ribosome maturation comprises multiple steps of rRNA processing that require sequential association and dissociation of numerous assembly factors. These proteins establish a complex network of interactions that are essential for the pathway to continue. Extensive studies in Saccharomyces cerevisiae allowed to identify some of the genetic and functional correlations between the pre-ribosomal factors that could be organized into interdependent clusters or sub-complexes. A heterotrimer formed by Nop7, Erb1 and Ytm1 (PeBoW complex in mammals) is crucial for the proper formation of the 60S subunit. Depletion of any of the three proteins is inviable and certain truncations result in aberrant processing of 27SA2 rRNA thus impairing cell proliferation. Nop7 and Erb1 have been shown to bind RNA and are recruited to the pre60S before Ytm1. It is also known that the trimer has to be removed from the nascent particle in order to promote its normal maturation. Despite its relevance in the cell, the exact role of PeBoW is not clear and the interactions within the complex have been poorly characterized. In this study we carry out an extensive biochemical and structural analysis of Nop7-Erb1-Ytm1 trimer from S. cerevisiae and from a thermophilic fungus Chaetomium thermophilum. We have been able to reconstitute a stable complex in vitro that was then used in crystallographic trials. We have solved the structure of the C-terminal domain of Erb1 from yeast that folds into a seven-bladed ß-propeller. We prove that this part of the protein binds RNA in vitro, a property that might be important for its function. Moreover, in spite of previous reports suggesting that the ß-propeller domain of Erb1 would not be essential for ribosome biogenesis, we could solve the crystal structure of Ytm1 bound to the carboxy-terminal portion of Erb1 from C. thermophilum. That finding led us to redefine the macromolecular interactions that hold the complex together. First, we have verified that the N-terminal region of Nop7 interacts with Erb1. Furthermore, we have shown that a good affinity binding takes place in vitro between WD40 domain of Ytm1 and the ß-propeller of Erb1. Upon careful analysis of the interface involved in dimer formation we have designed a mutant of Erb1 that exhibits weaker association with Ytm1. We confirm our structural and biophysical data using S. cerevisiae. We prove that a point mutation that decreases the affinity between propellers of Erb1 and Ytm1 negatively affects growth in yeast because it interferes with 60S production. We show that a very conserved interface of protein-protein interaction could be targeted in order to hinder cell proliferation. / [ES] El ensamblaje de ribosomas es uno de los procesos más importantes y costosos energéticamente en una célula eucariota. A pesar de ello, se sabe relativamente poco acerca de la gran mayoría de los eventos y factores implicados en la síntesis de las subunidades ribosomales. La maduración de ribosomas comprende numerosos pasos de procesamiento del rRNA que requieren la asociación y disociación de más de doscientos factores de ensamblaje. Esas proteínas establecen una compleja red de interacciones que son esenciales para que el proceso pueda llevarse a cabo. Los estudios realizados en Saccharomyces cerevisiae han permitido la identificación de algunas correlaciones genéticas y funcionales entre los factores prerribosomales. Es el caso del heterotrímero formado por Nop7, Erb1 e Ytm1 (complejo PeBoW en mamíferos), que es imprescindible para la correcta formación de la subunidad 60S. La ausencia de cualquiera de las tres proteínas es inviable y también se conocen ciertas variantes truncadas que alteran el procesamiento del rRNA 27SA2 y de este modo afectan la proliferación celular. Se ha demostrado que Nop7 y Erb1 se asocian al rRNA y que su reclutamiento al pre60S ocurre antes de la unión a Ytm1. Además se sabe que el trímero tiene que separarse de la partícula prerribosomal emergente con el fin de favorecer su maduración. A pesar de su gran relevancia en la célula, no está claro el papel exacto del complejo PeBoW y tampoco se dispone de conocimientos suficientes acerca de las interacciones intermoleculares que lo mantienen. Durante el desarrollo de este proyecto se ha llevado a cabo un exhaustivo análisis bioquímico y estructural del trímero Nop7-Erb1-Ytm1 procedente de S. cerevisiae y del hongo termofílico Chaetomium thermophilum. En este trabajo hemos sido capaces de reconstituir el complejo estable in vitro que posteriormente se ha utilizado en los ensayos de cristalización, con los que hemos podido resolver la estructura del dominio carboxi-terminal de Erb1 de levadura, cuyo plegamiento corresponde a una hélice enrollada (ß-propeller) de siete hojas. Gracias a la información estructural, hemos demostrado que esa parte de la proteína es capaz de unir RNA in vitro, lo que puede ser una propiedad importante para su función. Además, a pesar de los estudios anteriores que sugerían que la hélice enrollada de Erb1 no era esencial en la biogénesis del ribosoma, hemos resuelto la estructura cristalina de la proteína Ytm1 unida al dominio C-terminal de Erb1 de C. thermophilum. Ese descubrimiento nos ha permitido redefinir las interacciones macromoleculares que mantienen el complejo. Inicialmente hemos confirmado que el extremo amino-terminal de Nop7 interacciona con Erb1. A continuación, hemos demostrado que el dominio WD40 de Ytm1 se une al ß-propeller de Erb1 con una buena afinidad. Después de un detallado análisis de la superficie involucrada en la formación del dímero, hemos sido capaces de diseñar una variante mutada de Erb1 que se asocia más débilmente con Ytm1. Los hallazgos estructurales y biofísicos se han confirmado in vivo usando S. cerevisiae donde hemos demostrado que una mutación puntual que disminuye la afinidad de unión entre los dominios C-terminales de Erb1 e Ytm1 manifiesta un efecto negativo sobre el crecimiento de levadura porque interfiere con la síntesis de 60S. Nuestros resultados establecen un buen ejemplo de una superficie conservada involucrada en interacciones proteína-proteína, que podría considerarse una buena diana para inhibir la proliferación celular eucariota. / [CAT] L'ensamblatge de ribosomes és un dels processos més importants i energèticament costosos en una cèl·lula eucariota. Tot i això, es coneix relativament poc de la majoria dels factors implicats en la síntesi de les subunitats ribosomals. La maduració de ribosomes compren moltes etapes de processament del rRNA que requereix l'associació i dissociació de més de dos-cents factors d'ensamblatge. Aquestes proteïnes estableixen una complexa xarxa de interaccions que són essencials perquè el procés es pugi dur a terme. Els estudis realitzats en Saccharomyces cerevisiae han permès la identificació de algunes correlacions genètiques i funcionals entre els factors pre-ribosomals. Aquest és el cas del heterotrímer comprés per Nop7, Erb1 i Ytm1 (complex PeBoW en mamífers), que és imprescindible per a la correcta formació de la subunitat 60S. L'absència de qualsevol de les tres proteïnes és inviable i també és coneixen certes variants truncades que alteren el processament del rRNA 27SA3 i que d'aquesta manera afecten a la proliferació cel·lular. S'ha demostrat que Nop7 i Erb1 s'associen al rRNA i que el seu reclutament al pre60S té lloc abans de l'unió a Ytm1. A més a més, es sap que el trímer ha de separar-se de la partícula pre-ribosomal emergent per tal que es produeixi la seua maduració. Malgrat la seua rellevància en la cèl·lula, no s'ha aclarit el paper exacte del complex PeBoW i tampoc n'hi ha coneixements suficients de les interaccions intermoleculars que el mantenen. Durant el desenvolupament d'aquest projecte s'ha dut a terme un exhaustiu anàlisi bioquímic i estructural del trímer Nop7-Erb1-Ytm1 de S. cerevisiae i del fong termofílic Chaetomium thermophilum. En aquest treball hem estat capaços de reconstituir el complex estable in vitro que posteriorment s'ha utilitzat en el assajos de cristal·lització, amb els que hem pogut resoldre l'estructura del domini carboxi-terminal de Erb1 de llevat i que té un plegament corresponent a una hèlix enrotllada (ß-propeller) de set fulles. Gràcies a la informació estructural, hem pogut demostrar que aquesta part de la proteïna té la capacitat d'unir RNA in vitro, el que pot ser una propietat important per a la seua funció. A més a més, malgrat que els estudis anteriors suggerien que la hèlix enrotllada de Erb1 no era essencial en la biogènesis del ribosoma, hem pogut resoldre la estructura cristal·lina de la proteïna Ytm1 unida al domini C-terminal de Erb1 de C. thermophilum. Aquest descobriment ens ha permès redefinir les interaccions macromoleculars que mantenen el complex. Inicialment, hem confirmat que l'extrem amino-terminal de Nop7 interacciona amb Erb1. A continuació, hem demostrat que el domini WD40 de Ytm1 s'uneix al ß-propeller de Erb1 amb bona afinitat. Després d'un anàlisi detallat de la superfície involucrada en la formació del dímer, hem estat capaços de dissenyar una variant mutada de Erb1 que s'associa més dèbilment amb Ytm1. Les dades estructurals i biofísiques s'han confirmat in vivo utilitzant S. cerevisiae on hem demostrat que una mutació puntual que disminueix l'afinitat d'unió entre els dominis C-terminals de Erb1 i Ytm1 manifesta un efecte negatiu en el creixement del llevat perquè interfereix amb la síntesi del 60S. Els nostres resultats estableixen un bon exemple de una superfície conservada involucrada en interaccions proteïna-proteïna, que es podria considerar una bona diana per a inhibir la proliferació cel·lular eucariota. / Wegrecki, M. (2015). Structural, biophysical and functional characterization of Nop7-Erb1-Ytm1 complex and its implications in eukaryotic ribosome biogenesis [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/55941 / TESIS

Ribosome biogenesis

WD40 domain

Protein crystallography

RNA binding

PeBoW complex