Structures et Fonctions des séquences subtélomériques productrices de piRNA / Structures and functions of subtelomeric piRNA producing sequences

Asif-Laidin, Amna

04 April 2016

Les TAS (Telomeric Associated Sequences) sont des régions sub-télomériques répétées non codantes formant un locus hétérochromatique chez Drosophila melanogaster. Il existe deux grandes familles de TAS, les TAS-R et les TAS-L possédant une structure et des propriétés différentes. Durant cette thèse, j'ai montré que les TAS dériveraient d'une séquence commune appelée TLL rapprochant ainsi les TAS-R et les TAS-L. Par ailleurs, une étude des populations de drosophiles récoltées récemment dans la nature a permis de montrer qu'il existe une pression de sélection pour la présence du TAS-X dans ces souches alors que celui peut être perdu quand les drosophiles sont maintenues dans les laboratoires pendant plusieurs générations. Le TAS-X pourrait avoir un rôle différent dans la nature. Par ailleurs, j'ai montré que les locus TAS permettent l'établissement de la répression des séquences qui s'y insèrent par la transmission de ses propriétés épigénétiques. Ce type de mécanisme pourrait être généralisé aux autres locus producteurs de piRNA du génome qui assurerait ainsi la répression d'un nouvel élément qui arriverait dans une " trappe génomique ". / TAS (Telomeric Associated Sequences) are heterochromatic subtelomeric region made of non coding repeated sequences in Drosophila melanogaster. There are two TAS families : TAS-R and TAS-L, with different structures and properties. In this study, we are showing that the TAS could have derived from a common sequence called TLL suggesting that TAS-R and TAS-L are more related than previously thought. Moreover, analysis of drosophila populations recently collected from the wild have shown that there is selection pressure for the presence of TAS-X in those lines, while this locus can be lost when flies are maintened in laboratory conditions for several generations. Thus TAS-X could have a special role in the wild. I have also shown that TAS loci transfer their epigenetic properties to the sequences that land in their loci, thereby establishing their repression. This kind of mechanism could be generalized to the other genomic piRNA producing loci that would ensure the repression of a novel element landing in a « genomic trap ».

TAS

Eléments Transposables

Subtélomères

Petits ARN non codants

PiRNA

Drosophile

Telomere Associated Sequence

Drosophila melanogaster

Subtelomer

576.5

A piRNA regulation landscape in C. elegans and a computational model to predict gene functions

Chen, Hao

28 October 2020

Investigating mechanisms that regulate genes and the genes' functions are essential to understand a biological system. This dissertation is consists of two specific research projects under these aims, which are for understanding piRNA's regulation mechanism and predicting genes' function computationally. The first project shows a piRNA regulation landscape in C. elegans. piRNAs (Piwi-interacting small RNAs) form a complex with Piwi Argonautes to maintain fertility and silence transposons in animal germlines. In C. elegans, previous studies have suggested that piRNAs tolerate mismatched pairing and in principle could target all transcripts. In this project, by computationally analyzing the chimeric reads directly captured by cross-linking piRNA and their targets in vivo, piRNAs are found to target all germline mRNAs with microRNA-like pairing rules. The number of targeting chimeric reads correlates better with binding energy than with piRNA abundance, suggesting that piRNA concentration does not limit targeting. Further more, in mRNAs silenced by piRNAs, secondary small RNAs are found to be accumulating at the center and ends of piRNA binding sites. Whereas in germline-expressed mRNAs, reduced piRNA binding density and suppression of piRNA-associated secondary small RNAs targeting correlate with the CSR-1 Argonaute presence. These findings reveal physiologically important and nuanced regulation of piRNA targets and provide evidence for a comprehensive post-transcriptional regulatory step in germline gene expression. The second project elaborates a computational model to predict gene function. Predicting genes involved in a biological function facilitates many kinds of research, such as prioritizing candidates in a screening project. Following the “Guilt By Association” principle, multiple datasets are considered as biological networks and integrated together under a multi-label learning framework for predicting gene functions. Specifically, the functional labels are propagated and smoothed using a label propagation method on the networks and then integrated using an “Error correction of code” multi-label learning framework, where a “codeword” defines all the labels annotated to a specific gene. The model is then trained by finding the optimal projections between the code matrix and the biological datasets using canonical correlation analysis. Its performance is benchmarked by comparing to a state-of-art algorithm and a large scale screen results for piRNA pathway genes in D.melanogaster. Finally, piRNA targeting's roles in epigenetics and physiology and its cross-talk with CSR-1 pathway are discussed, together with a survey of additional biological datasets and a discussion of benchmarking methods for the gene function prediction.

Bioinformatics

Biological networks

Error correction of code

Gene function prediction

Multi-label learning

piRNA

Regulation

La régulation des éléments transposables par la voie des piARN : Les différences entre lignées germinales mâles et femelles et leurs conséquences sur la dynamique de transposition / Transposable element under piRNA genes regulation in Drosophila : male and female germline differences and their consequences for transposition dynamic

Saint leandre, Bastien

24 February 2016

Les Eléments Transposables (ET) sont des parasites du génome caractérisés par leur capacité à se répliquer plus rapidement que les autres éléments génétiques du génome. La régulation par la voie des piARN joue un rôle essentiel pour limiter l’expansion des ET dans les lignées germinales des animaux.La première question posée est comment le génome répond face à une nouvelle invasion par un ET. Dans ce but, nous avons introduit le transposon de Classe II mariner (sous-famille mos1) chez D. melanogaster, qui ne contient naturellement pas l’élément. Nous avons montré, qu’après son amplification autonome dans le génome, l’élément avait atteint un équilibre en termes de nombre de copies, depuis qu’une régulation de novo par les piARN avait été acquise.Deuxièmement, nous avons étudié la mobilisation de l’élément mariner au cours du processus de colonisation des régions géographiques tempérées. A partir d’un large panel de populations naturelles nous avons trouvé que l’activité moyenne de mariner était remarquablement augmentée dans les populations non-Africaines en comparaison aux populations Africaines. Ces variations peuvent s’expliquer par un fort polymorphisme d’expression (transcriptionnel et traductionnel) des gènes de la voie des piARN.Le troisième chapitre soutient que la forte activité des ET dans la lignée germinale mâle est un phénomène global chez les drosophiles. Par ailleurs, le contenu en ET chez les espèces sœurs (D. melanogaster et D. simulans) a fortement divergé et, cela a affecté la réponse associée à la production des piARN. Chez D. melanogaster, de nombreux « burst » de transposition ont eut lieu récemment. Ces familles d’ET sont activement réprimées par les piARN dans l’ovaire et donc, se retrouvent massivement surexprimés dans les testicules. Chez D. simulans, nous pensons que la réponse par les piARN résulte principalement d’une régulation passée qui semble être la relique d’anciennes invasions d’ET.La voie des piARN est supposé être « garante de l’intégrité du génome » de par son rôle actif dans la défense contre les ET. Cependant, si la sélection naturelle purge les génomes de ces parasites délétères, il semble que les mécanismes de régulation de l’hôte contribuent au maintien de l’homéostasie du génome en limitant leur expansion, et quelque part en favoriser le maintien sur long terme. Ainsi, une autre interprétation pourrait être que la voie des piARN est « garante de la diversification du génome » de par son rôle à faciliter l’accumulation des ET. / Transposable Elements (TEs) are genomic parasites characterized by their ability to replicate faster than any other genetic element in the genomes. The piRNA mediated silencing is of central importance to limit TE expansion in the germline of animal species. The present dissertation explores the relationship between TEs and piRNAs alongside their evolutionary dynamics.The first question raised here was to understand how the genome responds to a new TE invasion. For that purpose, we injected a mariner Class II transposon into D. melanogaster genome that does not naturally contain the element. We found that, after its self-replication into the genome, the element have reached a copy number equilibrium since a de novo piRNA mediated regulation have been acquired.Second, we studied the mariner rewiring activity during the colonization of geographical temperate regions. From a large sampling of D. simulans natural populations, we found the mean activity of mariner to be strikingly higher in non-African populations compared to the African ones. These findings support the idea that selection acting on piRNA effector proteins has been of central importance to explain TE lineages diversification during colonization process.The third chapter provides evidences to propose that, the strong TE activity in testes, is a general phenomenon in Drosophila. We also observed that TE landscape divergence between the two sister species, have affected the genomic response mediated by the piRNAs. As a response of their recent bursts of transposition, TEs overexpressed in testes are preferentially silenced by piRNAs in D. melanogaster ovaries. By contrast, we assumed the D. simulans piRNA response to be the relic of a past regulation that still persists mostly against inactive TEs.The piRNA silencing in the germline, is assumed to be the “vanguard of genome” defense and integrity due to its active role against TEs. However, while natural selection purifies the genome from its deleterious parasites, it seems that the host regulation contributes to genome homeostasis by limiting their expansion, and somehow, favors their longterm maintenance. Thus, another interpretation would have been that piRNA silencing is the “vanguard of genome” diversification due to its active role in facilitating TE accumulation

PiARN

Elements Transposable

Lignée germinale

Epigénétique

Régulation

Mariner

PiRNA

Transposable Element

Germline

Epigenetic

Regulation

Mariner

Molekulární aspekty muskuloskeletálních onemocnění a význam malých regulačních RNA / Molecular aspects of musculoskeletal diseases and the role of small regulatory RNAs

Pleštilová, Lenka

January 2015

Rheumatic diseases are common, usually chronic, painful and to some extent invalidating medical conditions. Understanding of the disease pathogenesis is still very fragmentary. Hyperreactivity of the immune system and defect of autotolerance are probably contributed by local factors, which helps to explain, why some joints/muscles are more affected than others. All this results from a complex net of interactions between immune cells, synovial fibroblasts, chondrocytes, osteocytes, myocytes and other cells. In the submitted PhD thesis I have focused on three groups of molecules: regulatory RNAs, S100 proteins and autoantibodies. In the theoretical part, I sum up the current knowledge on their biogenesis, function and the role in rheumatology. In the investigative part, I present six original publications and one review on the role of those molecules in development of rheumatoid arthritis (RA) and idiopathic inflammatory myositis (IIM). One of the main studies was focused on expression of PIWI-interacting RNAs (piRNAs) in RA synovial fibroblasts (SF). piRNAs are small regulatory RNAs which in complex with PIWIL proteins regulate gene expression and silence transpozoms. piRNA expression was considered to be limited to germline and cancer cells. We have found 267 PIWI-interacting RNAs to be expressed...

Molekulární aspekty muskuloskeletálních onemocnění a význam malých regulačních RNA / Molecular aspects of musculoskeletal diseases and the role of small regulatory RNAs

Pleštilová, Lenka

January 2015

Rheumatic diseases are common, usually chronic, painful and to some extent invalidating medical conditions. Understanding of the disease pathogenesis is still very fragmentary. Hyperreactivity of the immune system and defect of autotolerance are probably contributed by local factors, which helps to explain, why some joints/muscles are more affected than others. All this results from a complex net of interactions between immune cells, synovial fibroblasts, chondrocytes, osteocytes, myocytes and other cells. In the submitted PhD thesis I have focused on three groups of molecules: regulatory RNAs, S100 proteins and autoantibodies. In the theoretical part, I sum up the current knowledge on their biogenesis, function and the role in rheumatology. In the investigative part, I present six original publications and one review on the role of those molecules in development of rheumatoid arthritis (RA) and idiopathic inflammatory myositis (IIM). One of the main studies was focused on expression of PIWI-interacting RNAs (piRNAs) in RA synovial fibroblasts (SF). piRNAs are small regulatory RNAs which in complex with PIWIL proteins regulate gene expression and silence transpozoms. piRNA expression was considered to be limited to germline and cancer cells. We have found 267 PIWI-interacting RNAs to be expressed...

Adaptive Evolution of piRNA pathway in Drosophila

Parhad, Swapnil S.

31 May 2018

Major fraction of eukaryotic genomes is composed of transposons. Mobilization of these transposons leads to mutations and genomic instability. In animals, these selfish genetic elements are regulated by a class of small RNAs called PIWI interacting RNAs (piRNAs). Thus host piRNA pathway acts as a defense against pathogenic transposons. Many piRNA pathway genes are rapidly evolving indicating that they are involved in a host-pathogen arms race. In my thesis, I investigated the nature of this arms race by checking functional consequences of the sequence diversity in piRNA pathway genes. In order to study the functional consequences of the divergence in piRNA pathway genes, we swapped piRNA pathway genes between two sibling Drosophila species, Drosophila melanogaster and Drosophila simulans. We focused on RDC complex, composed of Rhino, Deadlock and Cutoff, which specifies piRNA clusters and regulates transcription from clusters. None of the D. simulans RDC complex proteins function in D. melanogaster. Rhino and Deadlock interact and colocalize in D. simulans and D. melanogaster, but D. simulans Rhino does not bind D. melanogaster Deadlock, due to substitutions in the rapidly evolving Shadow domain. Cutoff from D. simulans stably binds and traps D. melanogaster Deadlock. Adaptive evolution has thus generated cross-species incompatibilities in the piRNA pathway which may contribute in reproductive isolation.

piRNA pathway

host-pathogen arms race

adaptive evolution

RNA biology

hybrid incompatibility

Evolution

Genetics

Molecular Biology

Maelstrom Represses Canonical RNA Polymerase II Transcription in Drosophila Dual-Strand piRNA Clusters

Chang, Timothy H.

20 April 2018

Transposons constitute much of the animal genome. While many transposons are ancient and inactivated, numerous others are intact and must be actively repressed. Uncontrolled transposons can cause genomic instability through DNA damage or mutations and must be carefully silenced in the germline or risk sterility or mutations that are passed on to offspring. In Drosophila melanogaster, 23–30 nt long piRNAs direct transposon silencing by serving as guides for Aubergine, Argonaute3, and Piwi, the three fly PIWI proteins. piRNAs derive from piRNA clusters—large heterochromatic DNA loci comprising transposons and transposon fragments. piRNAs are loaded into PIWI proteins via the ping-pong cycle which serves to amplify guide piRNAs. Loaded Piwi then enters the nucleus to transcriptionally repress transposons by establishing heterochromatin. Therefore, to silence transposons, transposon sequences must also be expressed. To bypass this paradox, the HP1 homolog Rhino (Rhi) allows non-canonical, promoter-independent, transcription of transposons embedded in heterochromatin. Transposon RNAs produced in this manner are “incoherent” and have little risk of being translated into transposon-encoded proteins required for transposition. This thesis focuses on understanding how piRNA clusters permit non-canonical transcription yet restrict canonical transcription. We found that although Rhi promotes non-canonical transcription in piRNA clusters, it also creates a transcriptionally permissive environment that is amenable to canonical transcription. In addition, we discovered that the conserved protein, Maelstrom, is required to repress promoter-driven transcription of individual, potentially active, transposons within piRNA clusters and allows Rhi to transcribe such transposon sequences into incoherent piRNA precursors.

PIWI-interacting RNA

piRNA

Maelstrom

transposon

small silencing RNA

chromatin

Rhino

Piwi

Cell Biology

Molecular Biology

TREX Function in piRNA Biogenesis and Transposon Silencing

Zhang, Gen

30 December 2019

The Piwi interacting RNA pathway (piRNA) transcriptionally and post-transcriptionally silences transposons in the germline to maintain host genome integrity and faithful transmission of the genetic materials. In Drosophilaovaries, maternally loaded piRNAs kick-start piRNA biogenesis and convert precursor transcripts into piRNAs to replenish the piRNA pool during oogenesis. piRNA clusters are the genomic source of piRNA precursors, which are determined by the HP1 homolog Rhino and accessary factors. Rhino specifically binds to piRNA cluster chromatin. I was intrigued by how Rhino localizes to piRNA clusters to specify piRNA precursors. TREX is a conserved mRNA biogenesis complex composed of UAP56 and the THO complex. Identification of UAP56 as a cluster transcript-processing factor established the link between piRNA biogenesis and the general mRNA processing machinery. In my thesis, I investigated the functions of UAP56 and THO in piRNA cluster transcript processing. I characterized an RNP specific to cluster transcripts, defined by binding with both factors, which is distinct from RNP of bulk mRNA transcripts, and found that assembly of these RNPs depends on Rhino. These findings imply that piRNA precursors are specified co-transcriptionally. Additionally, I found that TREX mutants lead to a loss of Rhino binding specificity. I propose that Rhino and TREX co-transcriptionally scan for cluster and transposon sequences to establish loci that produce piRNA precursors. Surprisingly, I also discovered a piRNA-independent function for TREX in transposon silencing. I showed that TREX mutants lead to transcriptionally activation of a number of transposon families without affecting their piRNA biogenesis and piRNA mediated repressive histone modifications. I propose that TREX could mediate a conserved transposon silencing mechanism.

piRNA pathway

transposon

transcriptional silencing

TREX

THO

UAP56

RNA biology

Molecular Biology

Transcriptome-Wide piRNA Profiling in Human Brains for Aging Genetic Factors

Mao, Qiao, Fan, Longhua, Wang, Xiaoping, Lin, Xiandong, Cao, Yuping, Zheng, Chengchou, Zhang, Yong, Zhang, Huihao, Garcia-Milian, Rolando, Kang, Longli, Shi, Jing, Yu, Ting, Wang, Kesheng, Zuo, Lingjun, Li, Chiang-Shan R., Guo, Xiaoyun, Luo, Xingguang

01 January 2019

OBJECTIVE: Piwi-interacting RNAs (piRNAs) represent a molecular feature shared by all nonaging biological systems, including the germline and somatic cancer stem cells, which display an indefinite renewal capacity and lifespan-stable genomic integrity and are potentially immortal. Here, we tested the hypothesis that piRNA is a critical genetic determinant of aging in humans. METHODS: Expression of transcriptome-wide piRNAs (n=24k) was profiled in the human prefrontal cortex of 12 subjects (84.9±9.5, range 68-100, years of age) using microarray technology. We examined the correlation between these piRNAs' expression levels and age, adjusting for covariates including disease status. RESULTS: A total of 9,453 piRNAs were detected in brain. Including seven intergenic and three intronic piRNAs, ten piRNAs were significantly associated with age after correction for multiple testing (|r|=0.9; 1.9×10≤p≤9.9×10). CONCLUSION: We conclude that piRNAs might play a potential role in determining the years of survival of humans. The underlying mechanisms might involve the suppression of transposable elements (TEs) and expression regulation of aging-associated genes.

Alzheimer’s disease

aging

brain

gene expression

piRNA

transposable elements (TEs)

years of survival

Biostatistics and Epidemiology

Hochwasserschutz für Pirna

16 December 2022

Die Bürgerinformation enthält Informationen zum geplanten Hochwasserschutz in Pirna. Redaktionsschluss: 31.07.2015

Sachsen, Hochwasserschutz, Elbe

info:eu-repo/classification/ddc/627

ddc:627

Pirna; Hochwasserschutz