Context-dependent threats to the fidelity of translation of the genetic code.

Moghal, Adil Baig

03 November 2016

No description available.

Biochemistry

Molecular Biology

Microbiology

mistranslation

aminoacyl tRNA

oxidative stress

nutrient starvation

translational fidelity

Development of gain-of-function reporters to probe trans-editing of misacylated tRNA <i>in vivo</i>.

Howard, C.Bradley, Howard

January 2016

No description available.

Biochemistry

Chemistry

Molecular Biology

trans-editing

aminoacyl-tRNA synthetases

deacylase

protein fidelity

Functional Studies of Transfer RNA Interactions in the Ribosome

Walker, Sarah Elizabeth

10 September 2008

No description available.

Biochemistry

Microbiology

ribosome

tRNA

GTPase

EF-G

hybrid states

translocation

frameshift suppression

Characterizing the Role of Ribosomal Protein L7Ae in Archaeal RNase P Catalysis and Exploring the Use of Archaeal RNase P as a Functional Genomics Tool

Cho, I-Ming

16 December 2010

No description available.

Biochemistry

RNase P

ribonucleoprotein

tRNA

kink turn (K turn)

L7Ae

external guide sequence

Lysyl-tRNA Synthetase-Capsid Interaction in Human Immunodeficiency Virus-1: Implications for the Priming of Reverse Transcription and Therapeutic Development

Dewan, Varun

17 July 2012

No description available.

Biochemistry

Biophysics

Molecular Biology

Host-viral interactions

Lysyl-tRNA synthetase

HIV-1 capsid

Origin of tRNA Genes in Trypanosoma and Leishmania and Comparison of Eukaryote Phylogenies Obtained from Mitochondrial rRNA and Protein Sequences

Yang, Xiaoguang

January 2005

<p> Two studies are presented in this thesis. First part is about the origin of tRNA genes in Trypanosoma and Leishmania. These organisms have special mitochondrial DNA, termed kinetoplast DNA (kDNA), which is unique in its structure and function. kDNA is a massive network which is composed of thousands of connected DNA circles. Unlike most other mitochondrial genomes, there is no gene encoding tRNAs in their kDNAs. So all the tRNAs used in mitochondria must be encoded on nuclear genes and transported from the cytoplasm into the mitochondria. So our question of interest is where the tRNA genes in their nucleus come from. We carry out phylogenetic analysis of these genes and the corresponding ones in bacteria, mitochondria and eukaryotic nuclei. There is no evidence indicating gene transfer from mitochondria to nucleus on the basis of this analysis. These results are consistent with the simplest hypothesis, i.e. that all tRNA genes of Trypanosoma and Leishmania have the same origin as nuclear genes of other eukaryotes.</p> <p> The second part is about the comparison of eukaryote phylogenies obtained from mitochondrial rRNA and protein sequences. We carried out phylogenetic analysis for the species which have complete mitochondrial genomes by using both concatenated mitochondrial rRNA and protein sequences. We got phylogenies for three groups, fungi/metazoan, plant/algae and stramenopile/alveolate group. The analysis is useful for the further study of position of the genetic code changes and the mechanisms involved.</p> / Thesis / Master of Science (MSc)

Beyond the Sequence: Unraveling the Evolutionary Stories of Proteins through Bioinformatic Analysis

Reinhardt, Franziska

17 May 2024

Proteins, as pivotal players in biological processes, undergo evolutionary changes due to mutations, whether spontaneous or induced by external factors. These mutations lead to significant genomic differences, contributing to the emergence of new species. From the basic principles of evolution, including variation, selection, fitness, inheritance, and reproduction, to the detailed analysis of specific proteins in different taxonomic groups, this dissertation explores the intricate field of protein evolution. In this thesis the study of bacterial and eukaryotic proteins is covered. It includes the study of enzymes in bacteria, such as CCA-adding enzyme and poly(A) polymerase, providing insights into the evolutionary divergence of these vital proteins. An analysis of existing species protein sequences and the prediction of corresponding ancestral sequences reveals a putative ancestral gammaproteobacterial CCA-adding enzyme, which is functional, thermotolerant and has a high specificity for CCA incorporation and substrate interactions. To address the challenges of suboptimal protein sequence data quality, the develop- ment of the ExceS-A split aligner is presented, which provides an automated solution to search for high quality protein sequences across diverse species groups. It is designed for exon-by-exon comparisons of coding sequences. The computation of exon/intron structure, inherent in spliced alignment procedures, is crucial for distinguishing paralo- gous members within gene families. The simplicity and effectiveness of this blat-based approach offer distinct advantages, especially for genes with extensive introns and applications involving fragmented genome assemblies, outperforming established tools in these scenarios. The application of the tool ExceS-A is then demonstrated in the study of neu- ropeptide Y/RFamide-like receptors in nematodes, shedding light on the evolutionary dynamics within this G protein-coupled receptor (GPCR) family. The Neuropeptide Y/RFamide-like receptors play crucial roles in locomotion, feeding, and reproduction. This extensively studied receptor group in Caenorhabditis elegans, comprising 41 recep- tors, served as a starting point for understanding the family’s expansion in nematodes. 159 nematode genomes revealed a total of 1557 neuropeptide Y/RFamide-like receptor sequences. The high conservation of these receptors across nematoda underscores their significance while highlighting family diversification in nematode evolution, with clade-specific duplications and losses across the phylum and unique patterns observed in the genus Caenorhabditis. Further, the dissertation focuses on the detailed analysis of GPCRs, with a particular interest in the ADRB2 and ADRB1 and Y1R and Y2R receptor, unraveling their conservation patterns and investigating their roles in G protein coupling. The investigation extends to the broader context of GPCR signaling pathways, emphasizing the crucial long-distance signaling and proposing hypotheses regarding amino acid conservation within chordates. Molecular dynamics simulations are used to uncover allosteric mechanisms and networks, providing valuable insights into protein dynamics and interactions. The investigation aimed at determining whether the conservation of amino acids within the chordate group is higher along the transmission pathway of GPCRs compared to the normal shortest path. Contrary to the hypothesis, results for ADRB2 and Y2R receptors, both with ligands and G-proteins, showed no significant difference in conservation rates between weighted and unweighted paths. Analysis revealed that unweighted paths favor hydrophobic interactions, while weighted paths predominantly involve peptide bonds, emphasizing their importance in allosteric signal transmission. Possible reasons for the lack of a significant increase in conservation values include the overall high conservation of amino acids in transmembrane helix 2-6 and the need for more precise information about mutual information in conservation score calculations. Future efforts will explore modified k-shortest path algorithms to identify alternative geometrically related contacts. The dissertation concludes by highlighting the crucial role of bioinformatics in performing complex analyses and processing large datasets. The basics laid here provide a foundation for interdisciplinary collaboration and contribute significant insights into the evolution of proteins. As a comprehensive knowledge framework, this work is able to guide future research efforts and underscores the ongoing importance of uncovering the complex interactions that govern protein evolution in the field of biological research.

info:eu-repo/classification/ddc/000

ddc:000

New Platforms to Diversify the Chemical Space of the Expanding Genetic Code:

Ficaretta, Elise Danielle

January 2024

Thesis advisor: Abhishek Chatterjee / Genetic code expansion (GCE) is an enabling technology whereby noncanonical amino acids (ncAAs) can be site-specifically incorporated into proteins of interest, allowing for vast applications and an improved understanding of structure-function relationships in biology. GCE stands out as a versatile platform due to the use of a variety of engineered aminoacyl-tRNA synthetase (aaRS)/transfer RNA (tRNA) pairs, and it has endowed proteins with over 200 distinct ncAAs in both prokaryotic and eukaryotic systems. My dissertation outlines endeavors aimed at broadening the chemical diversity of α-amino side chains and substrates beyond α-amino acids in both prokaryotic and eukaryotic organisms through the utilization of GCE technology. This was achieved by creating universal GCE platforms called altered translational machinery (ATM) strains, which eliminate the limitations of orthogonality for the evolution of aaRS/tRNA pairs. This expansion enables the use of the same aaRS/tRNA pair for ncAA incorporation functionalities into multiple domains of life. Moreover, the diversity of ncAAs that can be genetically encoded in eukaryotic cells was enhanced by evolving the E. coli leucyl-tRNA synthetase (EcLeuRS)/tRNA pair using a yeast-based selection system. This advancement facilitated the incorporation of novel ncAAs into proteins within mammalian cells. Additionally, I worked toward developing a platform for introducing monomers into the genetic code beyond α-amino acids. This involved developing an aaRS evolution platform that doesn't rely on translation as a selectable readout. Finally, I worked towards the creation of polyester-polyamide oligomers with sequence control as a step towards the goal of generating sequence-defined biopolymers with new-to-nature backbone chemistries. / Thesis (PhD) — Boston College, 2024. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

Aminoacyl-tRNA synthetase

Chemistry

Directed evolution

Genetic code expansion

Molecular biology

Synthetic biology

Supercomplexes multifonctionnels chez les mitochondries, et chez E. coli

Daoud, Rachid

09 1900

Les processus mitochondriaux tels que la réplication et la traduction sont effectués par des complexes multiprotéiques. Par contre, le métabolisme et la voie de maturation des ARN mitochondriaux (p. ex précurseurs des ARNt et des ARNr) sont habituellement traités comme une suite de réactions catalysées par des protéines séparées. L’exécution fidèle et optimale de ces processus mitochondriaux, exige un couplage étroit nécessaire pour la canalisation des intermédiaires métaboliques. Or, les évidences en faveur de l'interconnexion postulée de ces processus cellulaires sont peu nombreuses et proviennent en grande partie des interactions protéine-protéine. Contrairement à la perception classique, nos résultats révèlent l’organisation des fonctions cellulaires telles que la transcription, la traduction, le métabolisme et la régulation en supercomplexes multifonctionnels stables, dans les mitochondries des champignons (ex Saccharomyces cerevisiae, Aspergillus nidulans et Neurospora crassa), des animaux (ex Bos taurus), des plantes (B. oleracea et Arabidopsis thaliana) et chez les bactéries (ex E. coli) à partir desquelles les mitochondries descendent. La composition de ces supercomplexes chez les champignons et les animaux est comparable à celle de levure, toutefois, chez les plantes et E. coli ils comportent des différences notables (ex, présence des enzymes spécifiques à la voie de biosynthèse des sucres et les léctines chez B. oleracea). Chez la levure, en accord avec les changements dûs à la répression catabolique du glucose, nos résultats révèlent que les supercomplexes sont dynamiques et que leur composition en protéines dépend des stimulis et de la régulation cellulaire. De plus, nous montrons que l’inactivation de la voie de biosynthèse des lipides de type II (FASII) perturbe l’assemblage et/ou la biogenèse du supercomplexe de la RNase P (responsable de la maturation en 5’ des précurseurs des ARNt), ce qui suggère que de multiples effets pléiotropiques peuvent être de nature structurale entre les protéines. Chez la levure et chez E. coli, nos études de la maturation in vitro des précurseurs des ARNt et de la protéomique révèlent l’association de la RNase P avec les enzymes de la maturation d’ARNt en 3’. En effet, la voie de maturation des pré-ARNt et des ARNr, et la dégradation des ARN mitochondriaux semblent êtres associées avec la machinerie de la traduction au sein d’un même supercomplexe multifonctionnel dans la mitochondrie de la levure. Chez E. coli, nous avons caractérisé un supercomplexe similaire qui inclut en plus de la RNase P: la PNPase, le complexe du RNA degradosome, l’ARN polymérase, quatre facteurs de transcription, neuf aminoacyl-tRNA synthétases, onze protéines ribosomiques, des chaperons et certaines protéines métaboliques. Ces résultats supposent l’association physique de la transcription, la voie de maturation et d’aminoacylation des ARNt, la dégradation des ARN. Le nombre de cas où les activités cellulaires sont fonctionnellement et structurellement associées est certainement à la hausse (ex, l’éditosome et le complexe de la glycolyse). En effet, l’organisation en supercomplexe multifonctionnel représente probablement l’unité fonctionnelle dans les cellules et les analyses de ces super-structures peuvent devenir la prochaine cible de la biologie structurale. / It is known that processes such as transcription, translation and intron splicing require a multitude of proteins (plus a few non-protein components) organized in large ‘molecular machines’. But, according to traditional views, processing of RNA precursors (e.g., tRNA and rRNA) and metabolic pathways are pools of individual enzymes (single proteins or small complexes), with sequential enzymatic reaction steps connected via diffusible metabolites. This perception is incompatible with the ‘molecular crowding’ in most cellular compartments (e.g., 60% in the mitochondrial matrix). It is also not in line with the cumulating indirect evidence from comprehensive studies of protein-protein interactions and affinity purification, showing that numerous protein complexes involving different metabolic and regulatory processes are interconnected. However, direct evidence of extensive cross-talk among diverse cellular processes remains to be clearly demonstrated. Here we show that in mitochondria of yeast and other fungi (Neurospora crassa and Rhizopus oryzae), animal (Bos taurus), plant (Brassica oleracea), and in E. coli (standing for the “bacterial ancestor” of mitochondria), metabolism is physically interlinked (in supercomplexes) with translation, replication, transcription and RNA processing. Further, the supercomplexes also contain a variety of helper proteins, in support of earlier reports that describe such proteins as important structural units assisting complex assembly. Whereas the composition of supercomplexes in fungi (e.g., Neurospora crassa), animals and yeast is relatively similar, plants and E. coli present substantial compositional differences (e.g., plant-specific enzymes involved in the biosynthesis of sugars and secondary metabolites). In yeast, the supercomplex pattern of glucose-repressed cells is completely different from that of cells grown on galactose/glycerol, and the protein composition perfectly correlates with known regulatory changes under glucose repression. The destabilization of the complex organization is also illustrated by the deletion of genes in the mitochondrial fatty acid type II biosynthetic pathway (mutant strain oar1Δ). Mutants have both, a defect in fatty acid synthesis and in 5’ processing of mitochondrial tRNA, and no longer have a supercomplex containing Oar1p and components of RNase P (5’ tRNA processing). The pleiotropic mutant phenotype is best explained by a structural (assembly) defect. Also in yeast mitochondria, we demonstrate that RNase P and tRNA Z activities are part of a large complex, which further includes the RNA degradosome complex, five additional RNA processing proteins, and several other mitochondrial pathways. 5’ and 3’ tRNA processing enzymes are also associated in a large, multifunctional supercomplex in E. coli that includes six out of the seven proteins of the RNA degradosome, nine aminoacyl-tRNA synthases, RNA polymerase plus four transcription factors, eleven ribosomal proteins plus four translation factors, several components of protein folding and maturation, and a small set of metabolic enzymes. Apparently, not only is RNA processing coordinated, but it is also structurally connected to aminoacylation, transcription and other cellular functions. The number of documented cases where functionally related activities are structurally integrated is definitely increasing (e.g., editosome, glycolysis complex, etc). Indeed, structural integration of related functions and pathways may turn out to be a principle and the analyses of such super-structures may become a next structural biology frontier.

processus mitochondriaux

E coli

supercomplexe multifonctionnel

canalisation métabolique

maturation des précurseurs des ARNt

aminoacylion des ARNt matures

dégradation des ARN

process of mitochondria

E coli

multifunctional supercomplexes

metabolic channeling

maturation of tRNA precursors

tRNA aminoacylation

RNA dégradation

Untersuchungen zu Struktur-Funktionsbeziehungen in der tRNA-ähnlichen Struktur des Rüben-Gelbmosaik-Virus / Analysis of structure-function relationships within the tRNA-like structure of the Turnip Yellow Mosaic Virus

Klug, Christian

21 January 2004

No description available.

Mathematics and Computer Science

TYMV

Replikation

tRNA-ähnliche Struktur

Valylierung

570 Biowissenschaften

Biologie

TYMV

replication

tRNA-like structure

valylation

42.13

48.54