La méthylation flavine-dépendante d’acides nucléiques : aspects évolutifs, métaboliques, biochimiques et spectroscopiques / Flavin-dependent methylation of nucleic acids : evolutionary, metabolic, biochemical and spectroscopic aspects

Sournia, Pierre

14 December 2016

La méthylation de l’uridine sur son carbone 5 est apparue au cours de l’évolution sous plusieurs formes. Tout d’abord, les thymidylate synthases permettent la synthèse de novo du dTMP, un précurseur essentiel de l’ADN des trois règnes du vivant. Deux familles de thymidylate synthases sont connues à ce jour : ThyA et la flavo-enzyme ThyX, codées par des gènes hétérologues et ayant des structures et mécanismes réactionnels radicalement différents. En outre, cette méthylation de l’uridine est apparue (probablement plus tard) sous forme de modifications post-transcriptionnelles des ARNt et ARNr. Cette thèse vise à questionner les contraintes évolutives ayant menés indépendament à ces quatres types de méthylation de l’uridine.Une première partie décrit l’identification d’une voie métabolique permetant la complémentation du phénotype d’auxotrophie pour la thymidine par des analogues nucléotidiques chez Escherichia coli. Une approche de biologie synthétique en vue d’établir une voie alternative de biosynthèse du thymidylate a aussi été mise en œuvre. Une technique de sélection de gènes de complémentation du phénotype d’auxotrophie pour la thymidine, issus de mutagénèse aléatoire, a pu être développée. Dans une seconde partie, des études biochimiques et sppectroscopiques ont été réalisées sur la méthyle-transférase flavine-dépendante TrmFO, responsable de la méthylation post-transciptionnelle de l’uridine 54 des ARNt de certains microorganismes.L’implication de certains résidus dans la fixation du substrat a pu être déterminée d’une part, et certains intermédiaires réactionnels potentiels ont été caractérisés spectralement d’autre part. Ces dernières observations s’appuient, en outre, sur des études en cours de spectroscopie résolue en temps et des simulations de dynamique moléculaire afin de mieux comprendre les flavoprotéines en général et les méthyle transférases flavine-dépendantes en particulier. / Enzymes catalyzing the methylation of uridine at its carbon 5 position have appeared independently in different forms across evolution. Thymidylate synthases ThyA and the flavoprotein ThyX catalyze the de novo synthesis of dTMP, an essential DNA precursor in the three domains of life. They are encoded by heterologous genes and have drastically different structures and reaction mechanisms. On the other hand, this uridine methylation is also performed by tRNA and rRNA post-transcriptional modification enzymes.This thesis assesses the question of the evolutionary constraints that have led independently to four kinds of uridine methylation. The first part describes the identification of a metabolic pathway allowing the complementation of thymidine auxotrophy by non-natural nucleotide analogs in Escherichia coli. A synthetic biology approach, aiming to establish an alternative pathway for thymidylate biosynthesis, was also implemented and a selection strategy for thymidine auxotrophy-complementing genes, could be developed.In a second part, biochemical and spectral studies where realised on the flavin-dependent methyltransferase TrmFO, responsible for the post-transcriptional methylation of uridine at the invariant position 54 of tRNA in several microorganisms. The involvement of specific amino acid residues in substrate fixation and in stabilization of potential reaction intermediates was demonstrated. Their spectral characterization supports previously proposed reaction schemes for flavin-dependent thymidylate forming enzymes. These observations are currently being pursued by parallel approaches combining time-resolved spectroscopy and molecular dynamics simulations, aiming to further our understanding of how flavin mediates the transfer of carbon molecules from folate to uracil rings.

Flavoenzymes

Évolution dirigée

Spectroscopie optique

ARNt methyltransférase TrmFO

(ribo)thymidine

Anabolisme des nucléotides

Flavoenzymes

Directed evolution

Optic spectroscopy

TRNA methyltransferase TrmFO

(ribo)thymidine

Nucleotides anabolism

家族性自律神経失調症におけるIKBKAP遺伝子の異常スプライシングを是正させる低分子化合物RECTASは、同疾患で低下異常を示すtRNA修飾を回復させる

吉田, 真弓

25 May 2015

京都大学 / 0048 / 新制・課程博士 / 博士(生命科学) / 甲第19208号 / 生博第341号 / 新制||生||45(附属図書館) / 32200 / 京都大学大学院生命科学研究科高次生命科学専攻 / (主査)教授 垣塚 彰, 教授 渡邊 直樹, 教授 影山 龍一郎 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

RNA病

pre-mRNA スプライシング

低分子化合物

tRNA修飾

神経変性疾患

460

A fluorescence-based approach to elucidate the subunit arrangement of the essential tRNA deaminase from <i>Trypanosoma brucei</i>

Winner, Katherine M.

January 2019

No description available.

Biochemistry

Molecular Biology

Microbiology

Parasitology

Trypanosoma brucei

African Sleeping Sickness

Trypanosomiasis, African

Transfer RNA

tRNA editing

ADAT2

ADAT3

GFP

fluorescence

tRNomics: Genomic Organization and Processing Patterns of tRNAs

Bermudez Santana, Clara Isabel

13 September 2010

Surprisingly little is known about the organization and distribution of tRNAs and tRNA-related sequences on a genome-wide scale. While tRNA complements are usually reported in passing as part of genome annotation efforts, and peculiar features such as the tandem arrangements of tRNAs in Entamoeba histolytica have been described in some detail, comparative studies are rare. We therefore set out to systematically survey the genomic arrangement of tRNAs in a wide range of eukaryotes to identify common patterns and taxon-specific peculiarities. We found that tRNA complements evolve rapidly and that tRNA locations are subject to rapid turnover. At the phylum level, distributions of tRNA numbers are very broad, with standard deviations on the order of the mean. Even within fairly closely related species, we observe dramatic changes in local organization. Consistent with this variability, syntenic conservation of tRNAs is also poor in general, with turn-over rates comparable to those of unconstrained sequence elements. We conclude that the genomic organization of tRNAs shows complex, lineage-specific patterns characterized by extensive variability, and that this variability is in striking contrast to the extreme levels of sequence-conservation of the tRNA genes themselves. Our comprehensive analysis of eukaroyotic tRNA distributions provides a basis for further studies into the interplay between tRNA gene arrangements and genome organization in general. Secondly, we focused on the investigation of small non-coding RNAs (ncRNAs) from whole transcriptome data. Since ncRNAs constitute a significant part of the transcriptome, we explore this data to detect and classify patterns derived from transcriptome-associated loci. We selected three distinct ncRNA classes: microRNAs, snoRNAs and tRNAs, all of which undergo maturation processes that lead to the production of shorter RNAs. After mapping the sequences to the reference genome, specific patterns of short reads were observed. These read patterns appeared to reflect RNA processing and, if so, should specify the RNA transcripts from which they are derived. In order to investigate whether the short read patterns carry information on the particular ncRNA class from which they orginate, we performed a random forest classification on the three distinct ncRNA classes listed above. Then, after exploring the potential classification of general groups of ncRNAs, we focused on the identification of small RNA fragments derived from tRNAs. After mapping transcriptome sequence data to reference genomes, we searched for specific short read patterns reflecting tRNA processing. In this context, we devised a common tRNA coordinate system based on conservation and secondary structure information that allows vector representation of processing products and thus comparison of different tRNAs by anticodon and amino acid. We report patterns of tRNA processing that seem to be conserved across species. Though the mechanisms and functional implications underlying these patterns remain to be clarified, our analysis suggests that each type of tRNA exhibits a specific pattern and thus appears to undergo a characteristic maturation process.

info:eu-repo/classification/ddc/000

ddc:000

Structure of Retroviral 5′-Untranslated Regions and Interactions with Host and Viral Proteins

Comandur, Roopa

January 2016

No description available.

Biochemistry

Cellular Biology

Virology

HIV-1

PFV

reverse transcription

tRNA

UTR

hLysRS

TLE

fluorescence anisotropy

SAXS

NMR, SHAPE

anticodon binding domain

Aminoacyl-tRNA Synthetase Production for Unnatural Amino Acid Incorporation and Preservation of Linear Expression Templates in Cell-Free Protein Synthesis Reactions

Broadbent, Andrew

01 March 2016

Proteins—polymers of amino acids—are a major class of biomolecules whose myriad functions facilitate many crucial biological processes. Accordingly, human control over these biological processes depends upon the ability to study, produce, and modify proteins. One innovative tool for accomplishing these aims is cell-free protein synthesis (CFPS). This technique, rather than using living cells to make protein, simply extracts the cells' natural protein-making machinery and then uses it to produce protein in vitro. Because living cells are no longer involved, scientists can freely adapt the protein production environment in ways not otherwise possible. However, improved versatility and yield of CFPS protein production is still the subject of considerable research. This work focuses on two ideas for furthering that research.The first idea is the adaptation of CFPS to make proteins containing unnatural amino acids. Unnatural amino acids are not found in natural biological proteins; they are synthesized artificially to possess useful properties which are then conferred upon any protein made with them. However, current methods for incorporating unnatural amino acids do not allow incorporation of more than one type of unnatural amino acid into a single protein. This work helps lay the groundwork for the incorporation of different unnatural amino acid types into proteins. It does this by using modified aminoacyl-tRNA synthetases (aaRSs), which are key components in CFPS, to be compatible with unnatural amino acids. The second idea is the preservation of DNA templates from enzyme degradation in CFPS. Among the advantages of CFPS is the option of using linear expression templates (LETs) in place of plasmids as the DNA template for protein production. Because LETs can be produced more quickly than plasmids can, using LETs greatly reduces the time required to obtain a DNA template for protein production. This renders CFPS a better candidate for high-throughput testing of proteins. However, LETs are more susceptible to enzyme-mediated degradation than plasmids are, which means that LET-based CFPS protein yields are lower than plasmid-based CFPS yields. This work explores the possibility of increasing the protein yield of LET-based CFPS by addition of sacrificial DNA, DNA which is not used as a protein-making template but which is degraded by the enzymes in place of the LETs.

Andrew Broadbent

cell-free protein synthesis (CFPS)

unnatural amino acid incorporation

aminoacyl-tRNA synthetase

linear expression template (LET)

aminoacylation assay

sacrificial DNA

Chemical Engineering

Studies on RNA Modification and Editing in <i>Trypanosoma brucei</i>

Fleming, Ian Murray Cameron

08 June 2016

No description available.

Microbiology

Biochemistry

Cellular Biology

Parasitology

RNA modification

RNA editing

rRNA

tRNA

ribosome

cytokinesis

Trypanosoma brucei

kinetoplastid

ribosome assembly

ribosome biogenesis

genetic screen

Exploring Protein-Nucleic Acid Interactions Using Graph And Network Approaches

Sathyapriya, R

03 1900

The flow of genetic information from genes to proteins is mediated through proteins which interact with the nucleic acids at several stages to successfully transmit the information from the nucleus to the cell cytoplasm. Unlike in the case of protein-protein interactions, the principles behind protein-nucleic acid interactions are still not very (Pabo and Nekludova, 2000) and efforts are still underway to arrive at the basic principles behind the specific recognition of nucleic acids by proteins (Prabakaran et al., 2006). This is mainly due to the innate complexity involved in recognition of nucleotides by proteins, where, even within a given family of DNA binding proteins, different modes of binding and recognition strategies are employed to suit their function (Luscomb et al., 2000). Such difficulties have also not made possible, a thorough classification of DNA/RNA binding proteins based on the mode of interaction as well as the specificity of recognition of the nucleotides. The availability of a large number of structures of protein-nucleic acids complexes (albeit lesser than the number of protein structures present in the PDB) in the past few decades has provided the knowledge-base for understanding the details behind their molecular mechanisms (Berman et al., 1992). Previously, studies have been carried out to characterize these interactions by analyzing specific non-covalent interactions such as hydrogen bonds, van der Walls, and hydrophobic interactions between a given amino acid and the nucleic acid (DNA, RNA) in a pair-wise manner, or through the analysis of interface areas of the protein-nucleic acid complexes (Nadassy et al., 1998; Jones et al., 1999). Though the studies have deciphered the common pairing preferences of a particular amino acid with a given nucleotide of DNA or RNA, there is little room for understanding these specificities in the context of spatial interactions at a global level from the protein-nucleic acid complexes. The representation of the amino acids and the nucleotides as components of graphs, and trying to explore the nature of the interactions at a level higher than exploring the individual pair-wise interactions, could provide greater details about the nature of these interactions and their specificity. This thesis reports the study of protein-nucleic interactions using graph and network based approaches. The evaluation of the parameters for characterizing protein-nucleic acid graphs have been carried out for the first time and these parameters have been successfully employed to capture biologically important non-covalent interactions as clusters of interacting amino acids and nucleotides from different protein-DNA and protein-RNA complexes. Graph and network based approaches are well established in the field of protein structure analysis for analyzing protein structure, stability and function (Kannan and Vishveshwara, 1999; Brinda and Vishveshwara, 2005). However, the use of graph and network principles for analyzing structures of protein-nucleic acid complexes is so far not accomplished and is being reported the first time in this thesis. The matter embodied in the thesis is presented as ten chapters. Chapter 1 lays the foundation for the study, surveying relevant literature from the field. Chapter 2 describes in detail the methods used in constructing graphs and networks from protein-nucleic acid complexes. Initially, only protein structure graphs and networks are constructed from proteins known to interact with specific DNA or RNA, and inferences with regard to nucleic acid binding and recognition were indirectly obtained . Subsequently, parameters were evaluated for representing both the interacting amino acids and the nucleotides as components of graphs and a direct evaluation of protein-DNA and Protein-RNA interactions as graphs has been carried out. Chapter 3 and 4 discuss the graph and network approaches applied to proteins from a dataset of DNA binding proteins complexed with DNA. In chapter 3, the protein structure graphs were constructed on the basis of the non-covalent interactions existing between the side chains of amino acids. Clusters of interacting side chains from the graphs were obtained using the graph spectral method. The clusters from the protein-DNA interface were analyzed in detail for the interaction geometry and biological importance (Sathyapriya and Vishveshwara, 2004). Chapter 4 also uses the same dataset of DNA binding proteins, but a network-based approach is presented. From the analysis of the protein structure networks from these DNA binding proteins, interesting observations relating the presence of highly connected nodes(or hubs) of the network to functionally important amino acids in the structure, emerged. Also, the comparison between the hubs identified from the protein-protein and the protein-DNA interfaces in terms of their amino acid composition and their connectivity are also presented (Sathyapriya and Vishveshwara, 2006) Chapter 5 and 6 deal with the graph and network applications to a specific system of protein-RNA complex (aminoacyl-tRNA synthetases) to gain insights into their interface biology based on amino acid connectivity. Chapter 5 deals with a dataset of aminoacyl-tRNA synthetase (aaRS) complexes obtained with various ligands like ATP, tRNA and L-amino acids. A graph based identification of side chain clusters from these ligand-bound aaRS structures has highlighted important features of ligand-binding at the catalytic sites of the two structurally different classes of aaRS (Class I and Class II). Side chain clusters from other regions of aaRS such as the anticodon binding region and the ligand-activation sites are discussed. A network approach is used in a specific system of aaRS(E.coli Glutaminyl-tRNA synthetase (GlnRS) complexed with its ligands, to specifically understand the effects of different ligand binding., in chapter 6. The structure networks of E.coli GlnRS in the ligand-free and different ligand-bound states are constructed. The ligand-free and the ligand-bound complexes are compared by analyzing their network properties and the presence of hubs to understand the effect of ligand-binding. These properties have elegantly captured the effects of ligand-binding to the GlnRS structure and have also provided an alternate method for comparing three dimensional structures of proteins in different ligand-bound states (Sathyapriya and Vishveshwara, 2007). In contrast to protein structure graphs (PSG), both the interacting amino acids and nucleotides (DNA/RNA) form the components of the protein-nucleic acid graphs (PNG) from protein-nucleic acid complexes. These graphs are constructed based on the non-covalent interactions existing between the side chains of the amino acids and nucleotides. After representing the interacting nucleotides and amino acids as graphs, clusters of the interacting components are identified. These clusters are the strongly interacting amino acids and nucleotides from the protein-nucleic acid complexes. These clusters can be generated at different strengths of interaction between the amino acid side chain and the nucleotide (measured in terms of its atomic connectivity) and can be used for detecting clusters of non-specific as well as specific interactions of amino acids and nucleotides. Though the methodology of graph construction and cluster identification are given in chapter 2, the details of the parameters evaluated for constructing PNG are given in chapter 7. Unlike in the previous chapters, the succeeding chapters deal exclusively with results that are obtained from the analyses of PNG. Two examples of obtaining clusters from a PNG are given, one each for a protein-DNA and a protein-RNA complex. In the first example, a nucleosome core particle is subjected to the graph based analysis and different clusters of amino acids with different regions of the DNA chain such as phosphate, deoxyribose sugar and the base are identified. Another example of aminoacyl-tRNA synthetase complexed with its cognate tRNA is used to illustrate the method with a protein-RNA complex. Further, the method of constructing and analyzing protein-nucleic acid graphs has been applied to the macromolecular machinery of the pre-translocation complex of the T. thermophilus 70S ribosome. Chapter 8 deals exclusively with the results identified from the analysis of this magnificent macromolecular ensemble. The availability of the method that can handle interactions between both amino acids and the nucleotides of the protein-nucleic acid complexes has given us the basis fro evaluating these interactions in a level higher than that of analyzing pair-wise interactions. A study on the evaluation of short hydrogen bonds(SHB) in proteins, which does not fall under the realm of the main objective of the thesis, is discussed in the Chapter 9. The short hydrogen bonds, defined by the geometrical distance and angle parameters, are identified from a non-redundant dataset of proteins. The insights into their occurrence, amino acid composition and secondary structural preferences are discussed. The SHB are present in distinct regions of protein three-dimensional structures, such that they mediate specific geometrical constraints that are necessary for stability of the structure (Sathyapriya and Vishveshwara, 2005). The significant conclusions of various studies carried out are summarized in the last chapter (Chapter 10). In conclusion, this thesis reports the analyses performed with protein-nucleic acid complexes using graph and network based methods. The parameters necessary for representing both amino acids and the nucleotides as components of a graph, are evaluated for the first time and can be used subsequently for other analyses. More importantly, the use of graph-based methods has resulted in considering the interaction between the amino acids and the nucleotides at a global level with respect to their topology of the protein-nucleic acid complexes. Such studies performed on a wide variety of protein-nucleic acid complexes could provide more insights into the details of protein-nucleic acid recognition mechanisms. The results of these studies can be used for rational design of experimental mutations that ascertain the structure-function relationships in proteins and protein-nucleic acid complexes.

Protein-Nucleic Acid Interactions

Protein-RNA Interactions

Protein Structure Graphs

Protein Nucleotide Graphs (PNG)

Protein-DNA Complexes

Protein-RNA Complexes

Aminoacyl-tRNA Synthetase

Glutaminyl-tRNA Synthetase (GlnRS)

Proteins - Short Hydrogen Bonds

Protein Structure Networks

Protein-RNA Interaction

Structure Graphs

Protein-RNA Graphs

70S Ribosome

Biochemical Genetics

Structural Studies on Mycobacterium Tuberculosis Peptidyl-tRNA Hydrolase and Ribosome Recycling Factor, Two Proteins Involved in Translation

Selvaraj, M

January 2013

Protein synthesis is a process by which organisms manufacture their proteins that perform various cellular activities either alone or in combination with other similar or different molecules. In eubacteria, protein synthesis proceeds at a rate of around 15 amino acids per second. The ribosomes, charged tRNAs and mRNAs can be considered as the core components of protein synthesis system which, in addition, involves a panel of non-ribosomal proteins that regulate the speed, specificity and accuracy of the process. Peptidyl-tRNA hydrolase (Pth) and ribosome recycling factor (RRF) are two such non-ribosomal proteins involved in protein synthesis. These two proteins are essential for eubacterial survival and the work reported in this thesis involves structural characterization of these two proteins from the bacterial pathogen, Mycobacterium tuberculosis. The protein structures were solved using established techniques of protein crystallography. Hanging drop vapour diffusion method and crystallization under oil using microbatch plates were the methods employed for protein crystallization. X-ray intensity data were collected on a MAR Research imaging plate mounted on a Rigaku RU200 X-ray generator in all the cases. The data were processed using DENZO and MOSFLM. The structures were solved by molecular replacement method using the program PHASER. Structure refinements were carried out using programs CNS and REFMAC. Model building was carried out using COOT. PROCHECK, ALIGN, CHIMERA, and PYMOL were used for structure validation and analysis of the refined structures. Peptidyl-tRNA hydrolase cleaves the ester bond between tRNA and the attached peptide in peptidyl-tRNA that has dropped off from ribosome before reaching the stop codon, in order to avoid the toxicity resulting from peptidyl-tRNA accumulation and to free the tRNA to make it available for further rounds in protein synthesis. To begin with, the structure of the enzyme from M. tuberculosis (MtPth) was determined in three crystal forms. This structure and the structure of the same enzyme from Escherichia coli (EcPth) in its crystal differ substantially on account of the binding of the C-terminus of the E.coli enzyme to the peptide binding site of a neighboring molecule in the crystal. A detailed examination of this difference led to an elucidation of the plasticity of the binding site of the enzyme. The peptide-binding site of the enzyme is a cleft between the body of the molecule and a polypeptide stretch involving a loop and a helix. This stretch is in open conformation when the enzyme is in the free state as in the crystals of MtPth. Furthermore, there is no physical continuity between the tRNA and the peptide-binding sites. The molecule in the EcPth crystal mimics the peptide-bound conformation of the enzyme. The peptide stretch involving a loop and a helix, referred to earlier, now closes on the bound peptide. Concurrently, a gate connecting the tRNA and the peptide-binding site opens primarily through the concerted movement of the two residues. Thus, the crystal structure of MtPth when compared with that of EcPth, leads to a model of structural changes associated with enzyme action on the basis of the plasticity of the molecule. A discrepancy between the X-ray results and NMR results, which subsequently became available, led to X-ray studies on new crystal forms of the enzyme. The results of these studies and those of the enzyme from different sources that became available, confirmed the connection deduced previously between the closure of the lid at the peptide-binding site and the opening of the gate that separates the peptide-binding site and tRNA binding site. The plasticity of the molecule indicated by X-ray structures is in general agreement with that deduced from the available solution NMR results. The correlation between the lid and the gate movement is not, however, observed in the NMR structure of MtPth. The discrepancy between the X-ray and NMR structures of MtPth in relation to the functionally important plasticity of the molecule, referred to earlier, also led to molecular dynamics simulations. The X-ray and the NMR studies along with the simulations indicated an inverse correlation between crowding and molecular volume. A detailed comparison of proteins for which X-ray and the NMR structures are available appears to confirm this correlation. In consonance with the reported results of the investigation in cellular components and aqueous solutions, the comparison indicates that the crowding results in compaction of the molecule as well as change in its shape, which could specifically involve regions of the molecule important for function. Crowding could thus influence the action of proteins through modulation of the functionally important plasticity of the molecule. After termination of protein synthesis at the stop codon, the ribosome remains as a post-termination complex (PoTC), consisting of the 30S and the 50S subunits, mRNA and a deacylated tRNA. This complex has to be disassembled so that the ribosome is available for the next round of translation initiation. Ribosome recycling factor (RRF) binds to ribosome and in concert with elongation factor G (EF.G), performs the recycling of ribosome that results in disassembly of PoTC. The structure of this L-shaped protein with two domains connected by a hinge, from Mycobacterium tuberculosis (MtRRF) was solved previously in our laboratory. The relative movement of domains lies at the heart of RRF function. Three salt bridges were hypothesized to reduce the flexibility of MtRRF when compared to the protein from E.coli (EcRRF), which has only one such salt bridge. Out of these three bridges, two are between domain 1 and domain 2, whereas the third is between the hinge region and the C-terminus of the molecule. These salt bridges were disrupted with appropriate mutations and the structure and activity of the mutants and their ability to complement EcRRF were explored. An inactive C-terminal deletion mutant of MtRRF was also studied. Major, but different, structural changes were observed in the C-terminal deletion mutant and the mutant involving the hinge region. Unlike the wild type protein and the other mutants, the hinge mutant complements EcRRF. This appears to result from the increased mobility of the domains in the mutant, as evidenced by the results of librational analysis. In addition to the work on PTH and RRF, the author was involved during the period of studentship in carrying out X-ray studies of crystalline complexes involving amino acids and carboxylic acids, which is described in the Appendix of the thesis. The complexes studied are that of tartaric acid with arginine and lysine.

Mycobacterium tuberculosis

Peptidyl-transfer RNA Hydrolase

Eubacteria - Translation

Ribosome Recycling Factor (RRF)

Peptidyl-transfer RNA

Mycobacterial Protein Synthesis

Non-Ribosomal Proteins

Mycobacterial Proteins

Peptidyl-tRNA Hydrolase

Molecular Biology

Caenorhabditis elegans as a research tool to study mitochondrial diseases associated with defects in tRNA modification

Navarro González, María del Carmen

21 March 2016

[EN] Post-transcriptional modification of the wobble uridine (U34) of a tRNA set is an evolutionary conserved process, produced by homologous proteins from the MnmA/MTU1, MnmE/GTPBP3 and MnmG/MTO1 families. Mutations in the human genes MTU1 and GTPBP3 or MTO1 produce acute infantile liver failure, and hypertrophic cardiomyopathy and lactic acidosis, respectively, which usually cause lethality in the first months of life. It is assumed that the primary cause of these diseases is the lack of the modifications introduced by the MTU1 protein in position 2 (tiol) and GTPBP3 and MTO1 proteins (taurinomethylation) in position 5 at U34 in a subgroup of mt-tRNAs. Nevertheless, the molecular mechanisms underlying these diseases (and other diseases associated with such modifications) are not clear. The reason why the typical defects of oxidative phosphorylation (due to impaired mitochondrial translation) produce such wide range of phenotypes is still unknown. Our hypothesis sustains that the mitochondria-nucleus retrograde signaling pathways triggered by the hypomodification at position 2 and 5 of U34 are different, and that each nuclear response is modulated by the genetic and epigenetic programs of cells and organisms. In this work, we have used the nematode Caenorhabditis elegans as a model organism to study the effects of inactivating the homologue proteins to MTU1, GTPBP3 and MTO1, which we have named as MTTU-1, MTCU-1 and MTCU-2, respectively. We have proved that these nuclear encoded proteins are located in mitochondria and are involved in U34 modification of mt-tRNAs. The mtcu-1 and mtcu-2 mutants show a reduction in fertility, while the mttu-1 mutant shows a reduction in fertility and a lengthening of the reproductive cycle (both phenotypes are thermosensitive). The phenotypes exhibited by the mttu-1, mtcu-1 and mtcu-2 mutants support our hypothesis, in which the mttu-1 single mutation, on the one hand, and the mtcu-1 and mtcu-2 single mutations, on the other hand, trigger different retrograde signaling pathways which produce specific nucear expression. Thus, a nuclear dependent phenotypic trait (as transcription or mt-tRNAs stability) and the expression of nuclear genes as ucp-4, hsp-6, hsp-60 and other genes involved in mitochondrial metabolism show a differential pattern in both group of mutants. hsp-6 and hsp-60 genes (UPRmt markers) are downregulated in mttu-1 single mutant, which could be related to fertility and reproductive cycle thermosensitivity. The three single mutants exhibit reduced expression of glycolysis and ß-oxidation genes (usually more drastic in the mttu-1 mutant), an induction of a glutaminolysis marker, and an induction of the ucp-4 gene, which encodes a transporter of the succinate to the mitochondria. Due to all three single mutants display a mild OXPHOS dysfunction, we propose that the observed changes in the expression of genes involved in the mitochondrial metabolism reveal a TCA cycle reprogramming aimed to compensate the reduction of acetil-CoA (coming from glycolysis and fatty acid oxidation) though the activation of anaplerotic pathways characterized by the succinate import to mitochondria by UCP-4 and the incorporation of 2-oxoglurate from glutaminolysis. We also analyze the effects of the simultanous suppression of modifications at positions 2 and 5 of U34 in C. elegans. The double mutant mtcu-2;mttu-1 displayed a severe OXPHOS dysfunction and a 5-fold higher AMP/ATP ratio, which was associated with embryonic lethality, developmental arrest in primary larval stages, penetrant sterility in adults and extended lifespan. This lifespan extension is modulated by signaling pathways which depend on AMPK (specifically on AAK-1 catalitic subunit) and steroid hormones, through DAF-9 and DAF-12 proteins. This work shows the important gene reprogramming related to mitochondrial metabolism in response to U34 hypomodification of mt-tRNAs, and shows new connexions between signaling pathways that extend lifespan. / [ES] La modificación post-transcripcional de la uridina de tambaleo (U34) de ciertos tRNAs es un proceso conservado evolutivamente, realizado por proteínas homólogas de las familias MnmA/MTU1, MnmE/GTPBP3 y MnmG/MTO1, y biológicamente relevante. De hecho, mutaciones en los genes humanos MTU1 y GTPBP3 o MTO1 causan fallo hepático infantil agudo y cardiomiopatía hipertrófica infantil, respectivamente, que producen letalidad durante los primeros meses de vida. Se asume que la causa primaria de estas enfermedades es la ausencia de las modificaciones introducidas por la proteína MTU1 en la posición 2 (tiol) y las proteínas GTPBP3 y MTO1 (taurinometil) en la posición 5 de la U34 en un grupo de mt-tRNAs. Se desconocen los mecanismos subyacentes y las razones por las que el déficit de OXPHOS resultante en todos los casos (atribuido a alteraciones de la traducción mitocondrial de proteínas) produce fenotipos tan diversos. Nuestra hipótesis es que la señalización retrógrada mitocondria-núcleo promovida por la hipomodificación de los mt-tRNAs en 2 ó 5 de la U34 es diferente y la respuesta nuclear viene modulada por el programa genético y epigenético de células y organismos. Hemos utilizado el nematodo C. elegans como modelo para estudiar los efectos producidos por la inactivación de las proteínas homólogas de MTU1, GTPBP3 y MTO1 a las que hemos denominado MTTU-1, MTCU-1 y MTCU-2. Hemos comprobado que estas proteínas, codificadas por el núcleo, son de localización mitocondrial y están implicadas en la modificación de la U34 de los mt-tRNAs. Los mutantes mtcu-1 y mtcu-2 presentan una reducción en su fertilidad y, en el caso del mutante simple mttu-1, fenotipos asociados a termosensibilidad. Los fenotipos exhibidos por los mutantes mttu-1, mtcu-1 y mtcu-2 sustentan la hipótesis de que la mutación mttu-1, y las mutaciones mtcu-1 y mtcu-2 promueven señales retrógradas diferentes que producen patrones de expresión nuclear específicos. Así, un rasgo fenotípico dependiente de genes nucleares (como lo es la transcripción y/o estabilidad de los mt-tRNAs) y la expresión de genes nucleares como ucp-4, hsp-6, hsp-60 y otros implicados en el metabolismo mitocondrial muestran un patrón diferente en los dos grupos de mutantes. Los genes hsp-6 y hsp-60 (marcadores de la UPRmt) están regulados a la baja en el mutante mttu-1. Los tres mutantes simples exhiben una reducción en la expresión de genes de la glicólisis y de la ß-oxidación de los ácidos grasos, una inducción en un marcador de glutaminolisis y una inducción en el gen ucp-4 (mayor en mttu-1) implicado en el transporte de succinato a la mitocondria. Dado que los tres mutantes simples presentan una disfunción OXPHOS relativamente suave, proponemos que los cambios de expresión en genes que modulan el metabolismo mitocondrial revelan una reprogramación del ciclo del TCA que compensa la disminución en el aporte de acetil-CoA procedente de glicólisis y oxidación de ácidos grasos con la activación de rutas anapleróticas del ciclo del TCA (importe de succinato a la mitocondria por UCP-4 y aporte de ¿-cetoglutarato procedente de la glutaminolisis). También analizamos los efectos de la anulación simultánea de las modificaciones en las posiciones 2 y 5 de la U34. El doble mutante mttu-1;mtcu-2 presenta una disfunción OXPHOS severa, con una ratio AMP/ATP 5 veces superior al control, que resulta en letalidad embrionaria, detención del desarrollo en estadios larvarios tempranos y esterilidad completa en los adultos que presentan, por otra parte, una longevidad unas dos veces superior a la cepa control. Este incremento de la longevidad está modulado por rutas de señalización que dependen de la subunidad catalítica AAK-1 (AMPK), y de hormonas esteroideas (proteínas DAF-9 y DAF-12). El trabajo muestra la importante reprogramación de genes relacionados con el metabolismo mitocondrial en respuesta a la hipomodificación de la U34 de los mt-tRNAs y / [CAT] La modificació post-transcripcional de la uridina de balanceig (U34) de certs tRNAs és un procés conservat evolutivament realitzat per proteïnes homòlogues a les de les famílies MnmA/MTU1, MnmE/GTPBP3 i MnmG/MTO1 i biològicament relevant. De fet, mutacions en els gens humans MTU1 i GTPBP3 o MTO1 causen fallada hepàtica infantil aguda i cardiomiopatia hipertròfica infantil amb acidosis làctica, respectivament, que produïxen letalitat durant els primers mesos de vida. S'assumix que la causa primària d'aquestes malalties és l'absència de les modificacions introduïdes per la proteïna MTU1 a la posició 2 (tiol) i per les proteïnes GTPBP3 i MTO1 (taurinometil) a la posició 5 de la U34 en un grup de mt-tRNAs. Es desconeixen els mecanismes subjacents en estes malalties i les raons per les quals el dèficit de la OXPHOS resultant en tots els casos (atribuït a alteracions de la traducció mitocondrial de proteïnes) produïx fenotips tan diversos. La nostra hipòtesi és que la senyalització retrògrada mitocondria-nucli promoguda per la hipomodificació dels mt-tRNAs en 2 o 5 de la U34 és diferent i la resposta nuclear en cada cas es dependent del programa genètic i epigenètic de cèl¿lules i organismes. Hem utilitzat el nematode C. elegans com a organisme model per a estudiar els efectes produïts per la inactivació de les proteïnes homòlogues de MTU1, GTPBP3 i MTO1 a les que hem denominat MTTU-1, MTCU-1 i MTCU-2. Hem comprovat que aquestes proteïnes, codificades pel nucli, són de localització mitocondrial i estan implicades en la modificació de la U34 dels mt-tRNAs. Els mutants mtcu-1 i mtcu-2 presenten una reducció en la seua fertilitat i, en el cas del mutant mttu-1, fenotipus associats a termosensibilitat. Els fenotipus exhibits pels mutants mttu-1, mtcu-1 i mtcu-2 sustenten la hipòtesi que la mutació mttu-1, i les mutacions mtcu-1 i mtcu-2 promouen senyals retrògrads diferents que produïxen patrons d'expressió nuclears específics. Així, un tret fenotípic dependent de gens nuclears (com ho és la transcripció i/o l'estabilitat dels mt-tRNAs) i l'expressió de gens nuclears com ucp-4, hsp-6, hsp-60 i altres implicats en el metabolisme mitocondrial mostren un patró diferent en els dos grups de mutants. Els gens hsp-6 i hsp-60 (marcadors de la UPRmt) estan regulats a la baixa en el mutant mttu-1. Els tres mutants simples exhibixen una reducció en l'expressió de gens de la glicòlisi i de la ß-oxidació dels àcids grassos, una inducció en un marcador de glutaminolisi i una inducció en el gen ucp-4 (major en el mutant mttu-1) implicat en el transport de succinat a la mitocondria. Atés que els tres mutants simples presenten una disfunció OXPHOS relativament suau, proposem que els canvis d'expressió en gens que modulen el metabolisme mitocondrial revelen una reprogramació del cicle del TCA que compensa la disminució en l'aportació d'acetil-CoA procedent de la glicòlisi i de l'oxidació d'àcids grassos amb l'activació de rutes anaplerótiques del cicle del TCA (importació de succinat a la mitocondria per UCP-4 i aportació de ¿-cetoglutarat de la glutaminolisi). També s'analitzen els efectes de l'anul¿lació simultània de les modificacions en 2 i 5 de la U34. El doble mutant mttu-1;mtcu-2 presenta una disfunció OXPHOS severa, amb una ràtio AMP/ATP 5 vegades superior al control, que resulta en letalitat embrionària, detenció del desenvolupament en estadis larvaris primerencs, esterilitat completa en els adults i una longevitat unes 2 vegades superior al control. Aquest increment de la longevitat està modulat per rutes de senyalització que depenen de la subunitat catalítica AAK-1 (AMPK), i d'hormones esteroidees (a través de les proteïnes DAF-9 i DAF-12). En resum, aquest treball mostra per primera vegada a nivell d'un animal model la important reprogramació de gens relacionats amb el metabolisme mitocondrial en resposta a la hipomodificació de la U34 dels mt-tRNAs i / Navarro González, MDC. (2016). Caenorhabditis elegans as a research tool to study mitochondrial diseases associated with defects in tRNA modification [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/61978 / TESIS

Modificación del tRNA

Hipomodificación del tRNA mitocondrial

Caenorhabditis elegans

MTTU-1

MTCU-1

MTCU-2

MnmA/MTU1

MnmE/GTPBP3

MnmG/MTO1

Disfunción mitocondrial

OXPHOS

TCA

Metabolismo

UCP-4

Fertilidad

Desarrollo

Longevidad

AMPK

AAK-1

DAF-9

DAF-12