Dissertations / Theses on the topic 'Terminator Codon'

Nonsense-mediated mRNA decay (NMD) specifically targets mRNAs with premature translation termination codons for rapid degradation. NMD is a highly conserved translation-dependent mRNA decay pathway, and its core Upf factors are thought to be recruited to prematurely terminating mRNP complexes, possibly through the release factors that orchestrate translation termination. Upf1 is the central regulator of NMD and recent studies have challenged the notion that this protein is specifically targeted to aberrant, nonsense-containing mRNAs. Rather, it has been proposed that Upf1 binds to most mRNAs in a translation-independent manner. In this thesis, I investigated the nature of Upf1 association with its substrates in the yeast Saccharomyces cerevisiae. Using biochemical and genetic approaches, the basis for Upf1 interaction with ribosomes was evaluated to determine the specificity of Upf1 association with ribosomes, and the extent to which such binding is dependent on prior association of Upf1’s interacting partners. I discovered that Upf1 is specifically associated with Rps26 of the 40S ribosomal subunit, and that this association requires the N-terminal Upf1 CH domain. In addition, using selective ribosome profiling, I investigated when during translation Upf1 associates with ribosomes and showed that Upf1 binding was not limited to polyribosomes that were engaged in translating NMD substrate mRNAs. Rather, Upf1 associated with translating ribosomes on most mRNAs, binding preferentially as ribosomes approached the 3’ ends of open reading frames. Collectively, these studies provide new mechanistic insights into NMD and the dynamics of Upf1 during translation.

Nonsense-mediated mRNA decay (NMD) specifically targets mRNAs with premature translation termination codons for rapid degradation. NMD is a highly conserved translation-dependent mRNA decay pathway, and its core Upf factors are thought to be recruited to prematurely terminating mRNP complexes, possibly through the release factors that orchestrate translation termination. Upf1 is the central regulator of NMD and recent studies have challenged the notion that this protein is specifically targeted to aberrant, nonsense-containing mRNAs. Rather, it has been proposed that Upf1 binds to most mRNAs in a translation-independent manner. In this thesis, I investigated the nature of Upf1 association with its substrates in the yeast Saccharomyces cerevisiae. Using biochemical and genetic approaches, the basis for Upf1 interaction with ribosomes was evaluated to determine the specificity of Upf1 association with ribosomes, and the extent to which such binding is dependent on prior association of Upf1’s interacting partners. I discovered that Upf1 is specifically associated with Rps26 of the 40S ribosomal subunit, and that this association requires the N-terminal Upf1 CH domain. In addition, using selective ribosome profiling, I investigated when during translation Upf1 associates with ribosomes and showed that Upf1 binding was not limited to polyribosomes that were engaged in translating NMD substrate mRNAs. Rather, Upf1 associated with translating ribosomes on most mRNAs, binding preferentially as ribosomes approached the 3’ ends of open reading frames. Collectively, these studies provide new mechanistic insights into NMD and the dynamics of Upf1 during translation.

Understanding translation efficiency is crucial to pharmaceutical companies that have invested substantial time and effort in engineering bacteria to produce recombinant proteins. While translation initiation and elongation have been studied intensively, much remains obscure in the subprocess of translation termination. We aim to understand how stop codons and the first 3’ flanking (+4) base affect translation termination efficiency. In chapter two, we hypothesized that stop codon usage of UAG and UGA is dependent on the abundance of their respective decoders, RF1 and RF2. We predicted and observed that bacterial species with high relative proportions of RF1 uses UAG more, and vice versa for UGA. In addition, the usage of UGA, not UAG, is always avoided in highly expressed genes. Thus, we argued against the claim made by a recent study that UAG is a minor stop codon in bacteria. The claim is incorrect because UAG does not meet the two criteria of a minor codon: i) it is most avoided in highly expressed genes, and ii) it corresponds to the least abundant decoder. Interestingly, we found that the proportion of RF2 decreases rapidly towards zero in species with high AT contents; this explains why UGA is reassigned to a sense codon in bacterial lineages with high AT content. In chapter three, we examined the role of the first downstream (+4) base Uracil in bacterial translation termination. The +4U is associated with a decrease in stop codon read-through in bacteria and yeast. We hypothesized that i) +4U enhances the termination efficiency of stop signals, and ii) +4U may serve to prevent stop codon misreading by near cognate tRNAs (nc_tRNAs). We predicted that i) +4U is preferred in highly expressed genes (HEGs) than lowly expressed genes (LEGs), and ii) +4U usage increases with the frequency of stop codon nc_tRNAs. We found +4U consistently over-represented in HEGs in contrast to LEGs; however, +4U usage in HEGs decreases in GC-rich species where most stop codons are UGA and UAG. In addition, +4U usage increases significantly with UAA usage in the known highly expressed ribosomal protein genes. These results suggest that +4U is a strong stop signal enhancer for UAA, not UAG or UGA. Furthermore, in HEGs, +4U usage also increases significantly with the abundance of UAA nc_tRNAs, suggesting that +4U increases UAA termination efficiency presumably by reducing misreading of UAA by nc_tRNAs.

Entre 10% et 30% des maladies humaines sont liées à l'apparition d'une mutation non-sens (PTC). La synthèse protéique est alors arrêté prématurément. Cet arrêt peut être inhibé par des molécules inductrices de translecture qui permettent l’incorporation d’un ARNt suppresseur naturel au niveau du PTC (translecture). Le ribosome peut alors franchir le PTC et restaurer l’expression de la protéine.Au cours de ma thèse, je me suis intéressé à la suppression des codons stop en caractérisant de nouvelles molécules inductrices de translecture et en analysant les mécanismes de la fidélité de la traduction.J’ai tout d’abord mis au point un système de criblage innovant avec lequel j’ai testé plus de 17 000 molécules et identifié la molécule TLN468. J’ai pu mettre en évidence que cette molécule est capable d’induire la réexpression d’une protéine p53 active.J'ai aussi caractérisé de nouveaux composés dérivés d’aminoglycosides. J’ai pu montré que le NB124 est capable d’induire l’apoptose de cellules tumorales via la réexpression de la protéine p53 tout ayant une toxicité bien plus faible que la gentamicine.En parallèle, j’ai développé une approche en molécule unique permettant d’étudier les erreurs programmées du ribosome (recodage). J’ai ainsi pu analyser la cinétique d’élongation des ribosomes eucaryotes et montré que l’initiation de la traduction sur un site d’entrée interne (IRES) ralentit le ribosome lors des premiers cycles d’élongation
Nonsense mutations, also known as premature termination codons (PTCs) are responsible for 10% to 30% of all human genetic diseases. Nonsense translation suppression can be induced by readthrough inducers. The presence of such PTC leads to premature translation termination. These stop therapeutic strategies have emerged which attempt to use molecules that facilitate tRNA incorporation at the PTC (readthrough). The, translation continue in the same reading frame until the next stop codon. I first developed an innovative screening system I used to test more than 17,000 molecules and have identified one hit, TLN468 molecule. I have shown that this molecule is able to induce re-expression of an active p53 protein.I also characterized new compounds derived from aminoglycosides. I have shown that the NB124 induces apoptosis of tumor cells by re-expressing p53 protein while having a much lower toxicity than gentamicin.I developed a single molecule approach for studying the ribosome programmed errors (recoding). I was able to analyze the kinetics of elongation eukaryotic ribosomes and showed that the initiation of translation at an internal entry site (IRES) slows the ribosome during the first elongation cycle

La terminaison de la traduction se produit lorsqu’un codon stop entre au site A du ribosome où il est reconnu par le facteur de terminaison eRF1 accompagné du facteur eRF3. Cette étape de la traduction est encore mal comprise chez les eucaryotes. Au cours de ma thèse je me suis intéressée à l’étude de la fidélité de la terminaison de la traduction afin de mieux comprendre et caractériser les mécanismes moléculaires mis en jeu lors du décodage du codon stop.L’un de mes projets consistait à mieux caractériser une région du domaine N-terminal d’eRF1, la cavité P1, identifiée comme étant impliquée dans l’efficacité de terminaison. Grâce à une quantification de l’efficacité de translecture de mutants de la cavité P1, j’ai pu mettre en évidence le rôle de résidus clés comme les serines 33 et 70, impliquées dans le décodage spécifique du codon UGA probablement via une interaction directe entre les deux résidus, ou encore l’arginine 65 et la lysine 109, essentielles pour une terminaison efficace sur les trois codons stop. L’analyse par RMN de ces mutants a également permis de montrer que ces résidus étaient importants pour la conformation correcte de la cavité et potentiellement impliqués dans une interaction directe avec l’ARNm. La combinaison des données génétiques et structurales nous a permis de proposer un modèle d’interaction entre l’ARNm et le facteur de terminaison eRF1 dans lequel le codon stop serait reconnu en partie par l’intermédiaire de la cavité P1. Dans la cellule, la terminaison est toujours en compétition avec la translecture, qui correspond à l’incorporation d’un ARNt proche-cognat au niveau du codon stop. Afin d’identifier les acides aminés incorporés par translecture au niveau du codon stop, j’ai mis au point un système basé sur l’expression et la purification de protéines issues de la translecture qui sont ensuite analysées par spectrométrie de masse. J’ai pu mettre en évidence que la glutamine, la tyrosine et la lysine s’incorporent au niveau des codons UAA et UAG, alors que le tryptophane, la cystéine et l’arginine sont retrouvés au niveau du codon UGA. J’ai également pu montrer que le contexte en 5’ n’influençait pas l’incorporation des acides aminés au codon stop mais qu’en revanche, la présence de la paromomycine avait un impact sur la sélection des ARNt suppresseurs naturels. Ce projet permet d’apporter de nouvelles informations sur les règles de décodage grâce à l’analyse des appariements entre codons stop et anticodons des ARNt naturels suppresseurs. Il permet également d’envisager des perspectives thérapeutiques dans le cadre des maladies liées à la présence d’un codon stop prématuré et pour lesquelles le traitement repose sur l’utilisation de la translecture afin de ré-exprimer des protéines entières
Translation termination occurs when a stop codon enters the A site of the ribosome where it is recognized by eRF1 (eukaryotic release factor 1), associated with eRF3. This step of translation is not yet understood in eukaryotes. During my PhD, I was interested in studying translation termination accuracy to better understand and characterize the molecular mechanisms involved in stop codon decoding.One of my project consisted in characterizing a region in eRF1 N-terminal domain, pocket P1, identified to be involved in termination efficiency. Through a quantification of readthrough efficiency of pocket P1 mutants, I have highlighted the role of key residues, like serine 33 and serine 70, implicated in specific recognition of UGA stop codon, probably through a direct interaction between the two amino acids, and also arginine 65 and lysine 109, essential for efficient termination on the three stop codons. The analysis of the mutants by NMR revealed that these residues are also important for proper conformation of the cavity and potentially involved in a direct interaction with mRNA. The combination of our genetic data and structural analysis allowed us to propose a model of interaction between termination factor eRF1 and the mRNA, in which the stop codon would be recognized partially through pocket P1.In cells, termination always competes with readthrough which corresponds to the incorporation of near-cognate tRNAs at the stop codon. To identify the amino acids inserted by readthrough at the stop codon, I have developed a reporter system based on the expression and purification of readthrough proteins that are analyzed by mass spectrometry. I found that glutamine, tyrosine and lysine are inserted at UAA and UAG stop codons, whereas tryptophan, cysteine and arginine are inserted at UGA stop codon. I also showed that the 5’ nucleotide context does not influence the incorporation of amino acids at the stop codons by readthrough, but that, in contrast, the presence of paromomycin impacted the selection of natural suppressors tRNAs incorporated by readthrough. This project gives us new insights into the decoding rules by analyzing the base pairings between stop codon and near-cognates anticodons. It also allows us to consider therapeutic prospects for the treatment of premature stop codon diseases which uses readthrough as a tool to re-express full-length proteins from mRNAs that are interrupted by the presence of a premature stop codon

Mass production of translationally optimized bacteriophages (hereafter referred to as phages) is the need of the hour in the application of phages to therapy. Understanding translational efficiency of phages is the major preliminary step for mass producing efficient phages. The objective of this thesis is to understand factors affecting translational efficiency of phages. In chapter two, we hypothesized that weak translation initiation efficiency is responsible for weak codon concordance of Escherichia coli lambdoid phages with that of their hosts. We measured the strength of translation initiation using two indices namely minimum folding energy (MFE) and proportion of Shine-Dalgarno sequence (PSD). Empirical results substantiate our hypothesis suggesting lack of strong selection for improving codon adaptation in these phages is due to their weak translation initiation. In chapter three, we measured codon usage concordance between GC-rich and GC-poor Aeromonas phages with their GC-rich host Aeromonas salmonicida. We found low codon usage concordance in the GC-poor Aeromonas phages. We were interested in testing for the role of tRNAs in the GC-poor phages. We observed that the GC-poor phages carry tRNAs for codons that are overused by the phages and underused by the host. These findings suggest that the GC-poor Aeromonas phages carry their own tRNAs for compensating for the compositional difference between their genomes and that of their host. Previously several studies have reported observed avoidance of stable secondary structures in start site of mRNA in a wide range of species. We probed the genomes of 422 phage species and measured their secondary structure stability using MFE. We observed strong patterns of secondary structure avoidance (less negative MFE values) in the translation initiation region (TIR) and translation termination region (TTR) of all analyzed phages. These findings imply selection is operating at these translationally important sites to control stable secondary structures in order to maintain efficient translation.

Les mutations non sens introduisent un codon stop prématuré dans une phase ouverte de lecture. Ce type de mutation est retrouvé chez environ 11% des patients atteints de maladies génétiques et dans de nombreux cancers. En effet, entre 5 et 40% des mutations affectant des gènes suppresseurs de tumeurs sont des mutations non sens. La conséquence de la présence d’une mutation non sens dans un gène est la dégradation rapide de l’ARN messager correspondant, par l’activation d’un mécanisme de surveillance des ARN appelé NMD (pour nonsense-mediated mRNA decay) conduisant à une absence d’expression du gène mutant. Dans le cas des cancers, l’absence d’expression d’un gène suppresseur de tumeurs tel que TP53, perturbe un ensemble de processus biologiques dont l’apoptose, facilitant ainsi la progression tumorale.En utilisant un système de criblage moyen débit permettant d’identifier des molécules capables de ré-exprimer des gènes porteurs d’une mutation non sens en inhibant le NMD et/ou en activant la translecture, plusieurs molécules ont été identifiées. La translecture est un mécanisme naturel conduisant à l’incorporation d’un acide aminé à la position du codon stop prématuré au cours de la traduction. Parmi les molécules identifiées, je me suis intéressée à un extrait végétal nommé H7 et au composé CNSM1 (pour corrector of nonsense mutation 1) qui permettent une ré-expression très efficace du gène TP53 lorsqu’il est porteur d’une mutation non sens. J’ai caractérisé ces composés en montrant notamment la ré-expression du gène TP53 porteur d’une mutation non sens dans différentes lignées cellulaires issues de différents cancers. J’ai montré également la très faible toxicité de ces molécules, validant leur potentielle utilisation en clinique. Mon étude a aussi permis de montrer que la protéine p53 synthétisée est fonctionnelle puisqu'elle est capable d’induire l’activation transcriptionnelle d’un de ses gènes cibles, le gène TP21.En permettant la ré-expression du gène suppresseur de tumeur mutant, des molécules comme CNSM1 ou H7 restaurent la capacité des cellules à entrer en apoptose et pourraient aussi réduire certaines résistances à la chimiothérapie.De plus, par une approche d’édition du génome, j’ai confirmé le lien existant entre le blocage du cytosquelette et l’inhibition du NMD. J’ai aussi identifié deux protéines impliquées dans le réarrangement du cytosquelette qui pourraient être ciblées pour inhiber le NMD en thérapie et ré-exprimer une protéine tronquée fonctionnelle. L’utilisation de H7 ou de CNMS1 pourrait ainsi être couplée à une inhibition du NMD pour optimiser la correction des mutations non sens. Ces molécules correctrices de mutations non sens représentent de nouvelles approches thérapeutiques ciblées du cancer et des maladies rares liées aux mutations non sens
Nonsense mutations generate premature termination codons (PTC) within an open reading frame. This type of mutation is found in about 11% of patients with genetic disorders. Concerning cancer, 5 to 40% of mutations affecting tumor-suppressing genes are nonsense mutations. The presence of a PTC in a gene leads to rapid degradation of its mRNA mediated by the RNA surveillance mechanism named NMD (Nonsense-mediated mRNA decay) preventing the synthesis of truncated proteins. In cancer, the absence of expression of tumor suppressing genes such as TP53 interferes with many biological pathways including apoptosis enabling tumor progression.A screening system that allows identifying molecules capable of re-expressing genes harboring nonsense mutations by inhibiting the NMD system and/or by activating readthrough has been developed in the lab. Readthrough is a natural mechanism, which occurs during translation, leading to the incorporation of an amino acid at the PTC position. Among the molecules that have been identified thanks to the screen, a natural extract named H7 and a compound named CNSM1 efficiently rescues the expression of the nonsense-mutated TP53 gene carrying a PTC.CNSM1 and H7 induces the expression of full-length proteins from PTC-containing genes indicating that these compounds are capable of activating readthrough. I validated the screen results on several cancer cell lines harboring an endogenous nonsense mutation in TP53 gene and showed that the function of p53 was restored in the presence of CNSM1 or H7. I also investigated the cellular toxicity related with the use of CMNS1 on cultured cells and the in vivo effect of H7 in a mouse model harboring a nonsense mutation in dystrophin gene. My results demonstrate that these compounds have a mild cellular toxicity. In addition, using a genome editing approach I confirmed the relationship between the cytoskeletal blockage and the NMD inhibition. I identified two proteins that are implicated in the cytoskeletal rearrangement, which might be targeted to induce NMD inhibition and then the expression of truncated but functional protein from the mutated mRNA. H7 or CNMS1 might be coupled to an NMD inhibition strategy to improve the nonsense mutation correction. Knowing CNSM1 and H7 are so far the most efficient molecule capable of rescuing the expression of PTC-containing genes, these compounds represents a realistic hope for a new-targeted therapy for pathologies associated with nonsense mutations

Au cours de mon travail de thèse j’ai étudié la relation entre les facteurs participant à la terminaison de la traduction et ceux participant à la dégradation des ARNm chez S. cerevisiae.D’une part, je me suis intéressée au facteur Tpa1, caractérisé pour son rôle dans la terminaison de la traduction et la stabilité des ARNm chez S. cerevisiae et dont l’homologue chez S. pombe, Ofd1, participe au contrôle de la réponse hypoxique. Je me suis basée sur la structure de ce facteur, établie par nos collaborateurs pour comprendre plus précisément la fonction moléculaire de Tpa1 et rechercher des similitudes avec sa fonction chez S. pombe.Tpa1 est composée de deux domaines de type DSBH dont le premier, contenant le site catalytique, présente des homologies structurales avec la famille des prolyl-hydroxylases.Nous avons reproduit l’effet de la protéine Tpa1 sur la translecture in vivo et montré que son site catalytique prédit, ainsi que la présence des deux domaines étaient nécessaires pour cette activité. Nous avons aussi observé que Tpa1 inhibait par un mécanisme inconnu le facteur de transcription Hap1, qui régule des gènes en fonction de la quantité d’oxygène. Basé sur l’existence d’un inhibiteur d’Ofd1 chez S. pombe, nous avons ensuite montré qu’Ett1 (l’homologue de cet inhibiteur chez S. cerevisiae) avait un rôle similaire à Tpa1 dans la translecture. Une étude structurale collaborative d’Ett1 a mis en évidence une région conservée, se liant à une molécule de sulfate et à un ligand inconnu. Cette région est importante pour la translecture. Cependant, le substrat de Tpa1 reste pour l’instant inconnu comme les rôles précis de Tpa1 et Ett1 dans la terminaison de la traduction et dans la réponse à l’hypoxie.D’autre part, j’ai étudié le processus de NMD, particulièrement en me focalisant sur le mécanisme de discrimination entre un codon stop précoce (PTC) et un codon stop normal, et en analysant également la modification post-traductionnelle d’un facteur central du NMD, Upf1. Nous avons mis en évidence, qu’en plus de la région aval, la région en amont du PTCparticipait à sa reconnaissance. Nous avons testé plusieurs hypothèses sur le rôle de cette région, qui ont confirmé son rôle sans permettre de démontrer un mécanisme définitif. En parallèle, l’étude de la protéine Upf1 s’est concentrée sur ses modifications posttraductionnelles, particulièrement par phosphorylation. En effet, une telle modification est importante chez son homologue humain. Nous avons pu confirmer l’existence d’une forme modifiée et démontrer que celle-ci était localisée entre les acides aminés 153 et 971. Cette modification s’est avérée être très labile ce qui n’a pas permis de confirmer qu’il s’agissait d’une phosphorylation, ni de la cartographier plus précisément
During my PhD thesis, I analyzed the relation between factors that participate intranslation termination and those participating in mRNA decay in yeast S. cerevisiae.First, I focused on Tpa1, that had been proposed to participate in translationtermination and mRNA decay in S. cerevisiae, and whose homologue in S. pombe, Ofd1,participates to the control of hypoxic response. Based on the structure of Tpa1, established byour collaborators, I performed functional analysis to understand more precisely the molecularfunction of Tpa1 and similarities with its role in S. pombe. Tpa1 is composed of two DSBHdomains; the first, which contains the catalytic site, has structural homologies with the familyof prolyl-hydroxylase. We could reproduce the effect of Tpa1 on stop codon readthrough invivo and we showed that the predicted catalytic site and the presence of the two domains ofTpa1 were necessary for its activity. We also showed that Tpa1 inhibited one factor, Hap1,implicated in regulation of gene expression by oxygen. The existence of an inhibitor of Ofd1in S. pombe, allowed the identification of Ett1 (its homologue in S. cerevisiae). We showedthat Ett1 has a role similar to the one of Tpa1 in translational readthrough. A collaborativestructural and functional study of Ett1 revealed a conserved region, which binds a sulfate ion,and an unknown ligand. This region is important for the readthrough. However, thesubstrate(s) of Tpa1 remain(s) for the moment unknown, and the precise roles of Tpa1 andEtt1 in translation termination and in response to hypoxia remain to be deciphered.I also analyzed the NMD process by focusing more particularly on the mechanism thatallows the discrimination between a normal stop and a PTC (premature termination codon)and on the analysis of the post-translational modification of an important factor for the NMD,Upf1. This study revealed that, not only the region downstream of the PTC but also theupstream region participates to its recognition. We have tested several hypotheses on the roleof this upstream region, which confirmed its implication but did not reveal a definitivemechanism. In parallel, we started the study of the post-translational modifications of Upf1,and more particularly by phosphorylation. Indeed, the phosphorylation of Upf1 in human isvery important for the NMD process. We could confirm the presence of a modified form ofyeast Upf1 and we have demonstrated that it was localized between amino acids 153 and 971.This modification appeared to be highly labile. This prevented us to confirm definitively thatit was really a phosphorylation and to cartography precisely its location

The chimpanzee is humankind’s closest living relative and the two species diverged ~6 million years ago. Comparative studies of the human and chimpanzee genomes and transcriptomes are of great interest to understand the molecular mechanisms of speciation and the development of species-specific traits. The aim of this thesis is to characterize differences between the two species with regard to their genome sequences and the resulting transcript profiles. The first two papers focus on indel divergence and in particular, indels causing premature termination codons (PTCs) in 8% of the chimpanzee genes. The density of PTC genes is correlated with both the distance to the telomere and the indel divergence. Many PTC genes have several associated transcripts and since not all are affected by the PTC we propose that PTCs may affect the pattern of expressed isoforms. In the third paper, we investigate the transcriptome divergence in cerebellum, heart and liver, using high-density exon arrays. The results show that gene expression differs more between tissues than between species. Approximately 15% of the genes are differentially expressed between species, and half of the genes show different splicing patterns. We identify 28 cassette exons which are only included in one of the species, often in a tissue-specific manner. In the fourth paper, we use massive parallel sequencing to study the chimpanzee transcriptome in frontal cortex and liver. We estimate gene expression and search for novel transcribed regions (TRs). The majority of TRs are located close to genes and possibly extend the annotations. A subset of TRs are not found in the human genome. The brain transcriptome differs substantially from that of the liver and we identify a subset of genes enriched with TRs in frontal cortex. In conclusion, this thesis provides evidence of extensive genomic and transcriptomic variability between human and chimpanzee. The findings provide a basis for further studies of the underlying differences affecting phenotypic divergence between human and chimpanzee.

The peroxisome is a subcellular organelle that carries out a diverse range of metabolic functions, including the b-oxidation of very long chain fatty acids, the breakdown of peroxide and the a-oxidation of fatty acids. Disruption of peroxisome metabolic functions leads to severe disease in humans. These diseases can be broadly grouped into two categories: those in which a single enzyme is defective, and those known as the peroxisome biogenesis disorders (PBDs), which result from a generalised failure to import peroxisomal matrix proteins (and consequently result in disruption of multiple metabolic pathways). The PBDs result from mutations in PEX genes, which encode protein products called peroxins, required for the normal biogenesis of the peroxisome. PEX1 encodes an AAA ATPase that is essential for peroxisome biogenesis, and mutations in PEX1 are the most common cause of PBDs worldwide. This study focused on the identification of mutations in PEX1 in an Australasian cohort of PBD patients, and the impact of these mutations on PEX1 function. As a result of the studies presented in this thesis, twelve mutations in PEX1 were identified in the Australasian cohort of patients. The identified mutations can be broadly grouped into three categories: missense mutations, mutations directly introducing a premature termination codon (PTC) and mutations that interrupt the reading frame of PEX1. The missense mutations that were identified were R798G, G843D, I989T and R998Q; all of these mutations affect amino acid residues located in the AAA domains of the PEX1 protein. Two mutations that directly introduce PTCs into the PEX1 transcript (R790X and R998X), and four frameshift mutations (A302fs, I370fs, I700fs and S797fs) were identified. There was also one mutation found in an intronic region (IVS22-19A>G) that is presumed to affect splicing of the PEX1 mRNA. Three of these mutations, G843D, I700fs and G973fs, were found at high frequency in this patient cohort. At the commencement of these studies, it was hypothesised that missense mutations would result in attenuation of PEX1 function, but mutations that introduced PTCs, either directly or indirectly, would have a deleterious effect on PEX1 function. Mutations introducing PTCs are thought to cause mRNA to be degraded by the nonsense-mediated decay of mRNA (NMD) pathway, and thus result in a decrease in PEX1 protein levels. The studies on the cellular impact of the identified PEX1 mutations were consistent with these hypotheses. Missense mutations were found to reduce peroxisomal protein import and PEX1 protein levels, but a residual level of function remained. PTC-generating mutations were found to have a major impact on PEX1 function, with PEX1 mRNA and protein levels being drastically reduced, and peroxisomal protein import capability abolished. Patients with two missense mutations showed the least impact on PEX1 function, patients with two PTC-generating mutations had a severe defect in PEX1 function, and patients carrying a combination of a missense mutation and a PTC-generating mutation showed levels of PEX1 function that were intermediate between these extremes. Thus, a correlation between PEX1 genotype and phenotype was defined for the Australasian cohort of patients investigated in these studies. For a number of patients, mutations in the coding sequence of one PEX1 allele could not be identified. Analysis of the 5' UTR of this gene was therefore pursued for potential novel mutations. The initial analyses demonstrated that the 5' end of PEX1 extended further than previously reported. Two co-segregating polymorphisms were also identified, termed –137 T>C and –53C>G. The -137T>C polymorphism resided in an upstream, in-frame ATG (termed ATG1), and the possibility that the additional sequence represented PEX1 coding sequence was examined. While both ATGs were found to be functional by virtue of in vitro and in vivo expression investigations, Western blot analysis of the PEX1 protein in patient and control cell extracts indicated that physiological translation of PEX1 was from the second ATG only. Using a luciferase reporter approach, the additional sequence was found to exhibit promoter activity. When examined alone the -137T>C polymorphism exerted a detrimental effect on PEX1 promoter activity, reducing activity to half that of wild-type levels, and the -53C>G polymorphism increased PEX1 promoter activity by 25%. When co-expressed (mimicking the physiological condition) these polymorphisms compensated for each other to bring PEX1 promoter activity to near wild-type levels. The PEX1 mutations identified in this study have been utilised by collaborators at the National Referral Laboratory for Lysosomal, Peroxisomal and Related Genetic Disorders (based at the Women's and Children's Hospital, Adelaide), in prenatal diagnosis of the PBDs. In addition, the identification of three common mutations in Australasian PBD patients has led to the implementation of screening for these mutations in newly referred patients, often enabling a precise diagnosis of a PBD to be made. Finally, the strong correlation between genotype and phenotype for the patient cohort investigated as part of these studies has generated a basis for the assessment of newly identified mutations in PEX1.

Over the last few decades, computer simulation techniques have been established as an essential tool for understanding biochemical processes. This thesis deals mainly with the application of free energy calculations to ribosomal complexes and a cardiac ion channel. The linear interaction energy (LIE) method is used to explore the energetic properties of the essential process of codon–anticodon recognition on the ribosome. The calculations show the structural and energetic consequences and effects of first, second, and third position mismatches in the ribosomal decoding center. Recognition of stop codons by ribosomal termination complexes is fundamentally different from sense codon recognition. Free energy perturbation simulations are used to study the detailed energetics of stop codon recognition by the bacterial ribosomal release factors RF1 and RF2. The calculations explain the vastly different responses to third codon position A to G substitutions by RF1 and RF2. Also, previously unknown highly specific water interactions are identified. The GGQ loop of ribosomal RFs is essential for its hydrolytic activity and contains a universally methylated glutamine residue. The structural effect of this methylation is investigated. The results strongly suggest that the methylation has no effect on the intrinsic conformation of the GGQ loop, and, thus, that its sole purpose is to enhance interactions in the ribosomal termination complex. A first microscopic, atomic level, analysis of blocker binding to the pharmaceutically interesting potassium ion channel Kv1.5 is presented. A previously unknown uniform binding mode is identified, and experimental binding data is accurately reproduced. Furthermore, problems associated with pharmacophore models based on minimized gas phase ligand conformations are highlighted. Generalized Born and Poisson–Boltzmann continuum models are incorporated into the LIE method to enable implicit treatment of solvent, in an effort to improve speed and convergence. The methods are evaluated and validated using a set of plasmepsin II inhibitors.

The ribosome is a macromolecular machine that produces proteins in all kingdoms of life. The proteins, in turn, control the biochemical processes within the cell. It is thus of extreme importance that the machine that makes the proteins works with high precision. By using three dimensional structures of the ribosome and homology modelling, we have applied molecular dynamics simulations and free-energy calculations to study the codon specificity of protein synthesis in initiation and termination on an atomistic level. In addition, we have examined the binding of small molecules to riboswitches, which can change the expression of an mRNA. The relative affinities on the ribosome between the eukaryotic initiator tRNA to the AUG start codon and six near-cognate codons were determined. The free-energy calculations show that the initiator tRNA has a strong preference for the start codon, but requires assistance from initiation factors 1 and 1A to uphold discrimination against near-cognate codons. When instead a stop codon (UAA, UGA or UAG) is positioned in the ribosomal A-site, a release factor binds and terminates protein synthesis by hydrolyzing the nascent peptide chain. However, vertebrate mitochondria have been thought to have four stop codons, namely AGA and AGG in addition to the standard UAA and UAG codons. Furthermore, two release factors have been identified, mtRF1 and mtRF1a. Free-energy calculations were used to determine if any of these two factors could bind to the two non-standard stop codons, and thereby terminate protein synthesis. Our calculations showed that the mtRF’s have similar stop codon specificity as bacterial RF1 and that it is highly unlikely that the mtRF’s are responsible for terminating at the AGA and AGG stop codons. The eukaryotic release factor 1, eRF1, on the other hand, can read all three stop codons singlehandedly. We show that eRF1 exerts a high discrimination against near-cognate codons, while having little preference for the different cognate stop codons. We also found an energetic mechanism for avoiding misreading of the UGG codon and could identify a conserved cluster of hydrophobic amino acids which prevents excessive solvent molecules to enter the codon binding site. The linear interaction energy method was used to examine binding of small molecules to the purine riboswitch and the FEP method was employed to explicitly calculate the LIE b-parameters. We show that the purine riboswitches have a remarkably high degree of electrostatic preorganization for their cognate ligands which is fundamental for discriminating against different purine analogs.