Exploring the rns gene landscape in ophiostomatoid fungi and related taxa: Molecular characterization of mobile genetic elements and biochemical characterization of intron-encoded homing endonucleases.

Abdel-Fattah, Mohamed Hafez

January 2012

The mitochondrial small-subunit ribosomal RNA (mt. SSU rRNA = rns) gene appears to be a reservoir for a number of group I and II introns along with the intron- encoded proteins (IEPs) such as homing endonucleases (HEases) and reverse transcriptases. The key objective for this thesis was to examine the rns gene among different groups of ophiostomatoid fungi for the presence of introns and IEPs. Overall the distribution of the introns does not appear to follow evolutionary lineages suggesting the possibility of rare horizontal gains and frequent loses. Some of the novel findings of this work were the discovery of a twintron complex inserted at position S1247 within the rns gene, here a group IIA1 intron invaded the ORF embedded within a group IC2 intron. Another new element was discovered within strains of Ophiostoma minus where a group II introns has inserted at the rns position S379; the mS379 intron represents the first mitochondrial group II intron that has an RT-ORF encoded outside Domain IV and it is the first intron reported to at position S379. The rns gene of O. minus WIN(M)371 was found to be interrupted with a group IC2 intron at position mS569 and a group IIB1 intron at position mS952 and they both encode double motif LAGLIDADG HEases referred as I-OmiI and I-OmiII respectively. These IEPs were examined in more detail to evaluate if these proteins represent functional HEases. To express I-OmiI and I-OmiII in Escherichia. coli, a codon-optimized versions of I-OmiI and I-OmiII sequences were synthesized based on differences between the fungal mitochondrial and bacterial genetic code. The optimized I-OmiI and I-OmiII sequences were cloned in the pET200/D TOPO expression vector system and transformed into E. coli BL21 (DE3). These two proteins were biochemically characterized and the results showed that: both I-OmiI and I-OmiII are functional HEases. Detailed data for I-OmiII showed that this endonuclease cleaves the target site two nucleotides upstream of the intron insertion site generating 4 nucleotide 3’overhangs.

Mitochondrial genome

Mobile introns

Homing endonucleases

mt. SSU rRNA gene

Twintron

reverse transcriptase

Exploring the rns gene landscape in ophiostomatoid fungi and related taxa: Molecular characterization of mobile genetic elements and biochemical characterization of intron-encoded homing endonucleases.

Abdel-Fattah, Mohamed Hafez

January 2012

The mitochondrial small-subunit ribosomal RNA (mt. SSU rRNA = rns) gene appears to be a reservoir for a number of group I and II introns along with the intron- encoded proteins (IEPs) such as homing endonucleases (HEases) and reverse transcriptases. The key objective for this thesis was to examine the rns gene among different groups of ophiostomatoid fungi for the presence of introns and IEPs. Overall the distribution of the introns does not appear to follow evolutionary lineages suggesting the possibility of rare horizontal gains and frequent loses. Some of the novel findings of this work were the discovery of a twintron complex inserted at position S1247 within the rns gene, here a group IIA1 intron invaded the ORF embedded within a group IC2 intron. Another new element was discovered within strains of Ophiostoma minus where a group II introns has inserted at the rns position S379; the mS379 intron represents the first mitochondrial group II intron that has an RT-ORF encoded outside Domain IV and it is the first intron reported to at position S379. The rns gene of O. minus WIN(M)371 was found to be interrupted with a group IC2 intron at position mS569 and a group IIB1 intron at position mS952 and they both encode double motif LAGLIDADG HEases referred as I-OmiI and I-OmiII respectively. These IEPs were examined in more detail to evaluate if these proteins represent functional HEases. To express I-OmiI and I-OmiII in Escherichia. coli, a codon-optimized versions of I-OmiI and I-OmiII sequences were synthesized based on differences between the fungal mitochondrial and bacterial genetic code. The optimized I-OmiI and I-OmiII sequences were cloned in the pET200/D TOPO expression vector system and transformed into E. coli BL21 (DE3). These two proteins were biochemically characterized and the results showed that: both I-OmiI and I-OmiII are functional HEases. Detailed data for I-OmiII showed that this endonuclease cleaves the target site two nucleotides upstream of the intron insertion site generating 4 nucleotide 3’overhangs.

Mitochondrial genome

Mobile introns

Homing endonucleases

mt. SSU rRNA gene

Twintron

reverse transcriptase

Small intron definition of MVM pre-mRNAs /

Haut, Donald David,

January 1998

Thesis (Ph. D.)--University of Missouri--Columbia, 1998. / "July 1998." Typescript. Vita. Includes bibliographical references (leaves 111-119). Also available on the Internet.

Molecular genetic analysis of nucleotide excision repair genes in Dictyostelium discoideum /

Lee, Sungkeun,

January 1997

Thesis (Ph. D.)--University of Missouri-Columbia, 1997. / Typescript. Vita. Includes bibliographical references (leaves 124-125). Also available on the Internet.

Molecular genetic analysis of nucleotide excision repair genes in Dictyostelium discoideum

Lee, Sungkeun,

January 1997

Thesis (Ph. D.)--University of Missouri-Columbia, 1997. / Typescript. Vita. Includes bibliographical references (leaves 124-125). Also available on the Internet.

Generation of recombinant influenza A virus without M2 ion channel protein by introducing a point mutation at the 5' end of viral intron

Cheung, Kai-wing.

January 2004

Thesis (M. Phil.)--University of Hong Kong, 2005. / Title proper from title frame. Also available in printed format.

Functional diversity within a ribosomal-like protein family in Arabidopsis thaliana / Diversité fonctionnelle au sein d'une famille de protéines de type ribosomique chez Arabidopsis thaliana

Wang, ChuanDe

27 November 2018

L'expression des ARN mitochondriaux et chloroplastiques des plantes implique un grand nombre de modifications post-transcriptionnelles, parmi lesquelles l'épissage des introns est un processus essentiel. Sur la base de leur structure et des mécanismes d'épissage associés, les introns peuvent être classés en deux familles et ceux présents dans les organites des plantes appartiennent au groupe II. Les introns mitochondriaux et chloroplastiques de groupe II sont fortement dégénérés et ont perdu la capacité de s'auto-épisser in vivo. Leur élimination nécessite l’action de nombreux facteurs protéiques codés dans le noyau et importés dans les organites. Les protéines de liaison à l'ARN jouent un rôle prédominant dans ce processus complexe. Les protéines ribosomales sont des protéines abondantes se liant à l'ARN et peuvent être recrutées pour remplir diverses fonctions annexes. Au cours de ma thèse, j’ai étudié la fonction des protéines de type uL18 chez Arabidopsis, qui comprend 8 membres. Ces protéines partagent un domaine uL18 plutôt dégénéré, mais dont la structure est conservée, et dont la fonction initiale est de permettre l’association avec l’ARNr 5S. Nos résultats ont montré que cinq protéines de type uL18 sont adressées aux mitochondries et trois aux chloroplastes. Deux d’entre elles correspondent à de véritables protéines ribosomales uL18 associées aux ribosomes des organites, tandis que deux autres (uL18-L1 et uL18-L8) se sont transformées en facteurs d'épissage et sont nécessaires à l'élimination d’introns mitochondriaux ou chloroplastiques spécifiques. L'analyse d'un troisième membre de la famille, uL18-L5, a révélé qu'il participait à l'épissage de nombreux introns mitochondriaux. Mes résultats ont permis de révéler que les facteurs dérivés des protéines ribosomales uL18 jouent un rôle essentiel dans l’épissage des introns du groupe II mitochondriaux ou chloroplastiques chez les végétaux et que ces fonctions ciblent sot un seul intron ou bien plusieurs d’entre eux. / RNA expression in plant organelles implies a large number of post-transcriptional modifications in which intron splicing is an essential process. Based on RNA structures and splicing mechanisms, introns can be classified into two families and organellar introns of seed plants are categorized as group II. Organellar group II introns are highly degenerate and have lost the ability to self-splice in vivo. Their removal from transcripts is thus facilitated by numerous nuclear-encoded proteins that are post-translationaly imported into organelles. Among them, RNA binding proteins play predominant roles in this complex process. Ribosomal proteins are abundant RNA-binding proteins and could be recruited to carry out multifarious auxiliary functions. During my thesis, I investigated the function of the uL18 ribosomal-like protein family in Arabidopsis that comprises 8 members. The members of this protein family share a rather degenerate but structurally conserved uL18 domain whose original function is to permit association with the 5S rRNA. Our results showed that five uL18-Like proteins are targeted to mitochondria and three to chloroplasts. Two of these proteins correspond to real ribosomal uL18 proteins that incorporate into organellar ribosomes, while two other members (uL18-L1 and uL18-L8) have turned into splicing factors and are required for the removal of specific mitochondrial or plastid group II introns. The analysis of a third member, uL18-L5, revealed that it participated in the splicing of numerous mitochondrial introns. Our results revealed that uL18-like factors play essential roles in group II intron splicing in both mitochondria and plastids of plants and that these functions could target a single or multiple introns.

Arabidopsis thaliana

Mitochondries

Traduction

Protéines ribosomales

Épissage des introns

Arabidopsis thaliana

Mitochondria

Translation

Ribosomal proteins

Intron splicing

Intron and Small RNA Localization in Mammalian Neurons

Saini, Harleen

31 July 2019

RNA molecules are diverse in form and function. They include messenger RNAs (mRNAs) that are templates for proteins, splice products such as introns that can generate functional noncoding RNAs, and a slew of smaller RNAs such as transfer RNAs (tRNAs) that help decode mRNAs into proteins. RNAs can show distinct patterns of subcellular localization that play an important role in protein localization. However, RNA distribution in cells is incompletely understood, with prior studies focusing primarily on RNAs that are long (>200 nucleotides), fully processed, and polyadenylated. We examined the distribution of RNAs in neurons. Neuronal compartments can be separated by long distances and play distinct roles, raising the possibility that RNA localization is especially overt and functionally meaningful in these cells. In our exploration, we physically dissected projections from cell bodies of neurons from the rat brain and sequenced total RNA. We describe two main findings. First, we identified excised introns that are enriched in neuronal projections and confirmed their localization by single- molecule fluorescence in situ hybridization. These are a previously unknown set of circular RNAs in neuronal projections: tailless lariats that possess a non- canonical C branchpoint. Second, we observed a highly abundant population of small (20-150 nucleotide) RNAs in neuronal projections, most of which are tRNAs. For both circular introns and tRNAs, we did not observe known RNA localization signals. Thus, many types of RNA, if sufficiently stable, appear free to diffuse to distant locations, their localization perhaps aided by the movement of large organelles in the confines of neuronal projections. Our survey of RNA molecules across subcellular compartments provides a foundation for investigating the function of these molecules and the mechanisms that localize them.

Neurons

RNA localization

Introns

Splicing

tRNA

Bioinformatics

Genomics

Molecular and Cellular Neuroscience

Molecular Biology

Differential evolution of non-coding DNA across eukaryotes and its close relationship with complex multicellularity on Earth

Lozada Chávez, Irma

06 April 2023

Here, I elaborate on the hypothesis that complex multicellularity (CM, sensu Knoll) is a major evolutionary transition (sensu Szathmary), which has convergently evolved a few times in Eukarya only: within red and brown algae, plants, animals, and fungi. Paradoxically, CM seems to correlate with the expansion of non-coding DNA (ncDNA) in the genome rather than with genome size or the total number of genes. Thus, I investigated the correlation between genome and organismal complexities across 461 eukaryotes under a phylogenetically controlled framework. To that end, I introduce the first formal definitions and criteria to distinguish ‘unicellularity’, ‘simple’ (SM) and ‘complex’ multicellularity. Rather than using the limited available estimations of unique cell types, the 461 species were classified according to our criteria by reviewing their life cycle and body plan development from literature. Then, I investigated the evolutionary association between genome size and 35 genome-wide features (introns and exons from protein-coding genes, repeats and intergenic regions) describing the coding and ncDNA complexities of the 461 genomes. To that end, I developed ‘GenomeContent’, a program that systematically retrieves massive multidimensional datasets from gene annotations and calculates over 100 genome-wide statistics. R-scripts coupled to parallel computing were created to calculate >260,000 phylogenetic controlled pairwise correlations. As previously reported, both repetitive and non-repetitive DNA are found to be scaling strongly and positively with genome size across most eukaryotic lineages. Contrasting previous studies, I demonstrate that changes in the length and repeat composition of introns are only weakly or moderately associated with changes in genome size at the global phylogenetic scale, while changes in intron abundance (within and across genes) are either not or only very weakly associated with changes in genome size. Our evolutionary correlations are robust to: different phylogenetic regression methods, uncertainties in the tree of eukaryotes, variations in genome size estimates, and randomly reduced datasets. Then, I investigated the correlation between the 35 genome-wide features and the cellular complexity of the 461 eukaryotes with phylogenetic Principal Component Analyses. Our results endorse a genetic distinction between SM and CM in Archaeplastida and Metazoa, but not so clearly in Fungi. Remarkably, complex multicellular organisms and their closest ancestral relatives are characterized by high intron-richness, regardless of genome size. Finally, I argue why and how a vast expansion of non-coding RNA (ncRNA) regulators rather than of novel protein regulators can promote the emergence of CM in Eukarya. As a proof of concept, I co-developed a novel ‘ceRNA-motif pipeline’ for the prediction of “competing endogenous” ncRNAs (ceRNAs) that regulate microRNAs in plants. We identified three candidate ceRNAs motifs: MIM166, MIM171 and MIM159/319, which were found to be conserved across land plants and be potentially involved in diverse developmental processes and stress responses. Collectively, the findings of this dissertation support our hypothesis that CM on Earth is a major evolutionary transition promoted by the expansion of two major ncDNA classes, introns and regulatory ncRNAs, which might have boosted the irreversible commitment of cell types in certain lineages by canalizing the timing and kinetics of the eukaryotic transcriptome.:Cover page Abstract Acknowledgements Index 1. The structure of this thesis 1.1. Structure of this PhD dissertation 1.2. Publications of this PhD dissertation 1.3. Computational infrastructure and resources 1.4. Disclosure of financial support and information use 1.5. Acknowledgements 1.6. Author contributions and use of impersonal and personal pronouns 2. Biological background 2.1. The complexity of the eukaryotic genome 2.2. The problem of counting and defining “genes” in eukaryotes 2.3. The “function” concept for genes and “dark matter” 2.4. Increases of organismal complexity on Earth through multicellularity 2.5. Multicellularity is a “fitness transition” in individuality 2.6. The complexity of cell differentiation in multicellularity 3. Technical background 3.1. The Phylogenetic Comparative Method (PCM) 3.2. RNA secondary structure prediction 3.3. Some standards for genome and gene annotation 4. What is in a eukaryotic genome? GenomeContent provides a good answer 4.1. Background 4.2. Motivation: an interoperable tool for data retrieval of gene annotations 4.3. Methods 4.4. Results 4.5. Discussion 5. The evolutionary correlation between genome size and ncDNA 5.1. Background 5.2. Motivation: estimating the relationship between genome size and ncDNA 5.3. Methods 5.4. Results 5.5. Discussion 6. The relationship between non-coding DNA and Complex Multicellularity 6.1. Background 6.2. Motivation: How to define and measure complex multicellularity across eukaryotes? 6.3. Methods 6.4. Results 6.5. Discussion 7. The ceRNA motif pipeline: regulation of microRNAs by target mimics 7.1. Background 7.2. A revisited protocol for the computational analysis of Target Mimics 7.3. Motivation: a novel pipeline for ceRNA motif discovery 7.4. Methods 7.5. Results 7.6. Discussion 8. Conclusions and outlook 8.1. Contributions and lessons for the bioinformatics of large-scale comparative analyses 8.2. Intron features are evolutionarily decoupled among themselves and from genome size throughout Eukarya 8.3. “Complex multicellularity” is a major evolutionary transition 8.4. Role of RNA throughout the evolution of life and complex multicellularity on Earth 9. Supplementary Data Bibliography Curriculum Scientiae Selbständigkeitserklärung (declaration of authorship)

info:eu-repo/classification/ddc/000

ddc:000

L'utilité du gène LEAFY pour la systématique des Caesalpinioideae (Leguminosae)

Archambault, Annie

January 2001

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.

Génome nucléaire

Évolution moléculaire

Gène en copie unique

Familles multigéniques

Analyse phylogénétique

Incongruence

Introns

Caractère