Global ETD Search

151	Genome-Wide Regulation of Both Canonical and Non-canonical RNA-directed DNA Methylation Mechanisms in <i>Arabidopsis thaliana</i> Panda, Kaushik Kant January 2017 (has links) No description available. Bioinformatics Biology Genetics Molecular Biology Transposable Elements RNA-directed DNA methylation Small interfering RNA siRNA
152	Tolérance au soi : rôle des éléments transposables dans les tissus somatiques et le thymus Larouche, Jean-David 08 1900 (has links) Les éléments transposables (TE) sont des séquences répétitives représentant environ 45% des génomes humain et murin. Il est généralement assumé que leur expression est réprimée dans les cellules somatiques pour protéger l’intégrité du génome, et cette régulation épigénétique est fréquemment perdue dans les cancers, menant à la surexpression des TEs dans les tumeurs. Puisque l’expression aberrante des TEs est associée à l’infiltration de la tumeur par les cellules immunitaires, les TEs sont considérés comme des cibles prometteuses d’immunothérapies du cancer. Une meilleure description de l’expression des TEs dans les tissus somatiques ainsi que dans le thymus, l’organe responsable du développement de la tolérance au soi des lymphocytes T, est toutefois nécessaire pour évaluer la capacité des TEs d’induire des réponses immunitaires et déterminer si l’expression des TEs est belle et bien spécifique aux tumeurs. L’objectif de cette thèse est donc de brosser un portrait exhaustif de l’expression des TEs dans les tissus somatiques humains ainsi que dans le thymus. Pour ce faire, des données transcriptomiques et immunopeptidomiques ont été analysées pour mieux comprendre les interactions entre les TEs et les lymphocytes T à l’état basal. Nos résultats ont montré que l’expression des TEs est répandue dans les tissus somatiques humains, bien que leur niveau d’expression varie d’un tissu à l’autre et que plusieurs TEs sont exprimés de façon tissu-spécifique. De plus, les TEs peuvent être traduits et présentés par le CMH-I à la surface de cellules non-cancéreuses. Nous avons aussi déterminé que les TEs ont trois fonctions potentielles dans le thymus : ils pourraient fournir des sites de liaison à un grand nombre de facteurs de transcription dans toutes les populations cellulaires du thymus, ils stimuleraient la sécrétion d’IFN ɑ/β par les pDCs thymiques, et ils contribuent aux sélections positive et négative des thymocytes. Nos travaux illustrent la complexité des interactions entre les TEs et le système immunitaire adaptatif. Finalement, étant donnée l’expression répandue des TEs dans les tissus somatiques, nos travaux soulignent l’importance d’établir la tolérance des lymphocytes T à l’égard des TEs pour éviter des réactions auto-immunes. / Transposable elements are repetitive sequences representing around 45% of the human and murine genomes. It is generally assumed that their expression is repressed in somatic cells to preserve genomic integrity, but this epigenetic regulation is frequently lost in cancer cells, leading to the aberrant expression of TEs in tumors. As aberrant TE expression is associated with tumor infiltration by immune cells, TEs are considered as promising cancer immunotherapy targets. However, a better description of TE expression in somatic tissues and in the thymus, the organ responsible of T cell self-tolerance induction, is required to evaluate the potential of TEs to induce immune responses as well as the tumor specificity of TE expression. Thus, this thesis’ objective is to draw an exhaustive profile of TE expression in human somatic tissues and in the thymus. To do so, we analyzed transcriptomic and immunopeptidomic data to better understand interactions between TEs and T cells at steady state. Our work shows that TE expression is widespread in human somatic tissues, even though their expression level varies between tissues and many TEs are expressed in a tissue-specific manner. Additionally, TEs are translated and presented by the MHC-I on the surface of non-malignant cells. We also determined that TEs have three potential functions in the thymus: they could provide transcription factor binding sites in all cell populations of the thymus, they might induce the constitutive IFN ɑ/β secretion of thymic pDCs, and they contribute to both positive and negative selections of thymocytes. Altogether, our work illustrates the complexity of the interactions between TEs and the vertebrate adaptive immune system. Given the widespread expression of TEs in somatic tissues, this thesis highlights the importance of establishing T cell tolerance towards TE sequences to avoid autoimmune reactions in peripheral tissues. Éléments transposables Peptides associés au CMH-I Thymus Immunologie Transcriptomique Transposable elements MHC I-associated peptides Immunology Transcriptomics
153	Repeat turnover meets stable chromosomes: repetitive DNA sequences mark speciation and gene pool boundaries in sugar beet and wild beets Schmidt, Nicola, Sielemann, Katharina, Breitenbach, Sarah, Fuchs, Jörg, Pucker, Boas, Weisshaar, Bernd, Holtgräwe, Daniela, Heitkam, Tony 17 January 2025 (has links) Sugar beet and its wild relatives share a base chromosome number of nine and similar chromosome morphologies. Yet, interspecific breeding is impeded by chromosome and sequence divergence that is still not fully understood. Since repetitive DNAs are among the fastest evolving parts of the genome, we investigated, if repeatome innovations and losses are linked to chromosomal differentiation and speciation. We traced genome and chromosome-wide evolution across 13 beet species comprising all sections of the genera Beta and Patellifolia. For this, we combined short and long read sequencing, flow cytometry, and cytogenetics to build a comprehensive framework that spans the complete scale from DNA to chromosome to genome. Genome sizes and repeat profiles reflect the separation into three gene pools with contrasting evolutionary patterns. Among all repeats, satellite DNAs harbor most genomic variability, leading to fundamentally different centromere architectures, ranging from chromosomal uniformity in Beta and Patellifolia to the formation of patchwork chromosomes in Corollinae/Nanae. We show that repetitive DNAs are causal for the genome expansions and contractions across the beet genera, providing insights into the genomic underpinnings of beet speciation. Satellite DNAs in particular vary considerably between beet genomes, leading to the evolution of distinct chromosomal setups in the three gene pools, likely contributing to the barriers in beet breeding. Thus, with their isokaryotypic chromosome sets, beet genomes present an ideal system for studying the link between repeats, genomic variability, and chromosomal differentiation and provide a theoretical fundament for understanding barriers in any crop breeding effort. info:eu-repo/classification/ddc/580 ddc:580
154	Dynamique des hélitrons dans le genome d'Arabidopsis thaliana : développement de nouvelles stratégies d'analyse des éléments transposables Tempel, Sébastien 18 June 2007 (has links) (PDF) Les hélitrons constituent un groupe d'éléments transposables découverts récemment dans les génome eucaryotes. A travers une étude bioinformatique, nous avons étudié leur mode d'invasion, la modularité de leur séquence et leurs impacts sur les gènes à leur proximité dans le génome d'Arabidopsis thaliana. Les hélitrons sont les éléments transposables les plus répandus dans ce génome ; néanmoins ils ne sont que partiellement reconnus par des logiciels d'alignement. Nous avons modélisé ces éléments sous la forme d'une grammaire formelle. Cette grammaire est constituée des deux extrémités terminales séparées par une séquence nucléotidique quelconque de taille fixée. Nous avons créé une matrice d'occurrences des modèles associant toutes les combinaisons possibles d'extrémités. La matrice a fait apparaître des associations préférentielles entre certaines extrémités et a permis la découverte de nouvelles familles d'hélitrons chimériques. La détection des ORFs contenant les protéines de transposition a permis de confirmer la relation hélitron autonome non-autonome et de comprendre le mécanisme de création des chimères d'hélitrons. Nous avons proposé une nouvelle nomenclature des hélitrons basée sur leurs extrémités et non sur leur séquence globale. L'étude de la séquence d'une famille d'hélitrons a montré une réorganisation constante des domaines nucléiques entre les différentes copies de cette famille. Pour comprendre cette organisation, nous avons mis au point le logiciel DomainOrganizer qui permet d'observer la composition en domaines des éléments transposables. DomainOrganizer détecte les frontières entre domaines à partir d'un alignement multiple et crée la liste des domaines. A partir de cette liste, il recherche, par un algorithme d'optimisation combinatoire, le nombre minimal de domaines qui recouvrent au maximum l'ensemble des séquences. Enfin, DomainOrganizer visualise et classe les séquences en fonction de leurs domaines. L'analyse par domaines de la famille AtREP21 a permis de comprendre la nature de cette variabilité et de retracer l'histoire évolutive de cette famille à partir de l'identification des domaines. L'étude de la localisation des hélitrons AtREP3 dans ce génome de plante a montré une insertion préférentielle de ceux-ci dans les promoteurs de gènes. Les profils d'expression de ces gènes, nous a permis d'identifier plusieurs clusters. Par ailleurs, les motifs de régulation ont montré une grande variabilité de motifs dans les promoteurs mais pas dans les hélitrons. Ces résultats ont montré que les hélitrons non-autonomes transportent dans leurs séquences internes des motifs de liaisons aux facteurs de transcription. Des analyses complémentaires devront être réalisées pour comprendre l'action régulatrice des hélitrons sur les gènes situés à leur proximité. [INFO:INFO_OH] Computer Science/Other Bioinformatique Analyse de séquences Elément transposable Arabidopsis thaliana Domaines nucléiques Hélitron Chimère Modélisation syntaxique Optimisation combinatoire Co-régulation Arbres des suffixes
155	Transposable elements in the salmonid genome Minkley, David Richard 30 April 2018 (has links) Salmonids are a diverse group of fishes whose common ancestor experienced an evolutionarily important whole genome duplication (WGD) event approximately 90 MYA. This event has shaped the evolutionary trajectory of salmonids, and may have contributed to a proliferation of the repeated DNA sequences known as transposable elements (TEs). In this work I characterized repeated DNA in five salmonid genomes. I found that over half of the DNA within each of these genomes was derived from repeats, a value which is amongst the highest of all vertebrates. I investigated repeats of the most abundant TE superfamily, Tc1-Mariner, and found that large proliferative bursts of this element occurred shortly after the WGD and continued during salmonid speciation, where they have produced dramatic differences in TE content among extant salmonid lineages. This work provides important resources for future studies of salmonids, and advances the understanding of two important evolutionary forces: TEs and WGDs. / Graduate / 2019-04-19 Transposable elements Salmon Genome annotation Repeats Genome evolution Bioinformatics Speciation Evolution Tc1-Mariner Whole genome duplication Polyploidy Fish Rainbow trout Arctic char Atlantic salmon Coho salmon Chinook salmon Salmo salar Salvelinus alpinus Oncorhynchus mykiss Oncorhynchus kisutch Oncorhynchus tshawytscha
156	Cytogenetika vybraných skupin paprskoploutvých ryb (Actinopterygii): Evolučně -ekologické aspekty spjaté s dynamikou repetitivních sekvencí a s výskytem polyploidie / Cytogenetics of selected groups of ray-finned fishes (Actinopterygii): Evolutionary-ecological questions associated with the dynamics of repetitive sequences and the occurrence of polyploidy Sember, Alexandr January 2016 (has links) Ray-finned fishes (Actinopterygii) exhibit the greatest biodiversity among vertebrates. The vast majority of extant actinopterygian fish species belong to clade Teleostei - a lineage whose significant evolutionary success might have resulted from a teleost specific whole- genome duplication (TSGD) that occurred at the onset of this group, subsequent to its divergence from the rest of actinopterygian lineages. Despite the growing body of sequenced fish genomes and analyses of their transcriptomes, the largest contribution to understanding fish genomes comes from analyses of DNA content and from cytogenetics. Genomes of ray-finned fishes and especially those of Teleostei exhibit vast diversity and rapid dynamics of repetitive DNA sequences whose variability is reflected in a wide range of fish genome sizes and in the dynamics behind karyotype differentiation. Therefore, ray-finned fishes offer a unique opportunity to study genome variability as a driving force underlying morphological and ecological diversification, evolution and adaptation. Particularly, the mapping of repetitive DNA sequences by means of fluorescence in situ hybridization (FISH) has proven to be a very useful and informative approach during the last two decades and contributed greatly to our understanding of the fish genome...
157	Small RNA Sorting in Drosophila Produces Chemically Distinct Functional RNA-Protein Complexes: A Dissertation Horwich, Michael D. 10 June 2008 (has links) Small interfering RNAs (siRNAs), microRNAs (miRNAs), and piRNAs (piRNA) are conserved classes of small single-stranded ~21-30 nucleotide (nt) RNA guides that repress eukaryotic gene expression using distinct RNA Induced Silencing Complexes (RISCs). At its core, RISC is composed of a single-stranded small RNA guide bound to a member of the Argonaute protein family, which together bind and repress complementary target RNA. miRNAs target protein coding mRNAs—a function essential for normal development and broadly involved in pathways of human disease; small interfering RNAs (siRNA) defend against viruses, but can also be engineered to direct experimental or therapeutic gene silencing; piwi associated RNAs (piRNAs) protect germline genomes from expansion of parasitic nucleic acids such as transposons. Using the fruit fly, Drosophila melanogaster, as a model organism we seek to understand how small silencing RNAs are made and how they function. In Drosophila, miRNAs and siRNAs are proposed to have parallel, but separate biogenesis and effector machinery. miRNA duplexes are excised from imperfectly paired hairpin precursors by Dicer1 and loaded into Ago1; siRNA duplexes are hewn from perfectly paired long dsRNA by Dicer2 and loaded into Ago2. Contrary to this model we found one miRNA, miR-277, is made by Dicer1, but partitions between Ago1 and Ago2 RISCs. These two RISCs are functionally distinct—Ago2 could silence a perfectly paired target, but not a centrally bulged target; Ago1 could silence a bulged target, but not a perfect target. This was surprising since both Ago1 and Ago2 have endonucleolytic cleavage activity necessary for perfect target cleavage in vitro. Our detailed kinetic studies suggested why—Ago2 is a robust multiple turnover enzyme, but Ago1 is not. Along with a complementary in vitro study our data supports a duplex sorting mechanism in which Diced duplexes are released, and rebind to Ago1 or Ago2 loading machinery, regardless of which Dicer produced them. This allows structural information embedded in small RNA duplexes to direct small RNA loading into Ago1 and/or Ago2, resulting in distinct regulatory outputs. Small RNA sorting also has chemical consequences for the small RNA guide. Although siRNAs were presumed to have the signature 2′, 3′ hydroxyl ends left by Dicer, we found that small RNAs loaded into Ago2 or Piwi proteins, but not Ago1, are modified at their 3´ ends by the RNA 2´-O-methyltransferase DmHen1. In plants Hen1 modifies the 3´ ends all small RNAs duplexs, protecting and stabilizing them. Implying a similar function in flies, piRNAs are smaller, less abundant, and their function is perturbed in hen1 mutants. But unlike plants, small RNAs are modified as single-strands in RISC rather than as duplexes. This nicely explains why the dsRNA binding domain in plant Hen1 was discarded in animals, and why both dsRNA derived siRNAs and ssRNA derived piRNAs are modified. The recent discovery that both piRNAs and siRNAs target transposons links terminal modification and transposon silencing, suggesting that it is specialized for this purpose. RNA Interference Drosophila melanogaster RNA Helicases RNA-Induced Silencing Complex RNA Small Interfering Methyltransferases MicroRNAs DNA Transposable Elements Drosophila Proteins RNA Transport Amino Acids, Peptides, and Proteins Animal Experimentation and Research Genetic Phenomena
158	A Novel Role of UAP56 in piRNA Mediated Transposon Silencing: A Dissertation Zhang, Fan 02 August 2013 (has links) Transposon silencing is required to maintain genome stability. The non-coding piRNAs effectively suppress of transposon activity during germline development. In the Drosophila female germline, long precursors of piRNAs are transcribed from discrete heterochromatic clusters and then processed into primary piRNAs in the perinuclear nuage. However, the detailed mechanism of piRNA biogenesis, specifically how the nuclear and cytoplasmic processes are connected, is not well understood. The nuclear DEAD box protein UAP56 has been previously implicated in protein-coding gene transcript splicing and export. I have identified a novel function of UAP56 in piRNA biogenesis. In Drosophila egg chambers, UAP56 co-localizes with the cluster-associated HP1 variant Rhino. Nuage is a germline-specific perinuclear structure rich in piRNA biogenesis proteins, including Vasa, a DEAD box with an established role in piRNA production. Vasa-containing nuage granules localize directly across the nuclear envelope from cluster foci containing UAP56 and Rhino, and cluster transcripts immunoprecipitate with both Vasa and UAP56. Significantly, a charge-substitution mutation that alters a conserved surface residue in UAP56 disrupts co-localization with Rhino, germline piRNA production, transposon silencing, and perinuclear localization of Vasa. I therefore propose that UAP56 and Vasa function in a piRNA-processing compartment that spans the nuclear envelope. DEAD-box RNA Helicases DNA Transposable Elements Drosophila Proteins Drosophila melanogaster Germ Cells Nuclear Envelope Small Interfering RNA Dissertations, UMMS RNA, Small Interfering Biochemistry Genetics Genomics Molecular Biology Molecular Genetics
159	Unveiling Molecular Mechanisms of piRNA Pathway from Small Signals in Big Data: A Dissertation Wang, Wei 01 October 2015 (has links) PIWI-interacting RNAs (piRNA) are a group of 23–35 nucleotide (nt) short RNAs that protect animal gonads from transposon activities. In Drosophila germ line, piRNAs can be categorized into two different categories— primary and secondary piRNAs— based on their origins. Primary piRNAs, generated from transcripts of specific genomic regions called piRNA clusters, which are enriched in transposon fragments that are unlikely to retain transposition activity. The transcription and maturation of primary piRNAs from those cluster transcripts are poorly understood. After being produced, a group of primary piRNAs associates Piwi proteins and directs them to repress transposons at the transcriptional level in the nucleus. Other than their direct role in repressing transposons, primary piRNAs can also initiate the production of secondary piRNA. piRNAs with such function are loaded in a second PIWI protein named Aubergine (Aub). Similar to Piwi, Aub is guided by piRNAs to identify its targets through base-pairing. Differently, Aub functions in the cytoplasm by cleaving transposon mRNAs. The 5' cleavage products are not degraded but loaded into the third PIWI protein Argonaute3 (Ago3). It is believed that an unidentified nuclease trims the 3' ends of those cleavage products to 23–29 nt, becoming mature piRNAs remained in Ago3. Such piRNAs whose 5' ends are generated by another PIWI protein are named secondary piRNAs. Intriguingly, secondary piRNAs loaded into Ago3 also cleave transposon mRNA or piRNA cluster transcripts and produce more secondary piRNAs loaded into Aub. This reciprocal feed-forward loop, named the “Ping-Pong cycle”, amplified piRNA abundance. By dissecting and analyzing data from large-scale deep sequencing of piRNAs and transposon transcripts, my dissertation research elucidates the biogenesis of germline piRNAs in Drosophila. How primary piRNAs are processed into mature piRNAs remains enigmatic. I discover that primary piRNA signal on the genome display a fixed periodicity of ~26 nt. Such phasing depends on Zucchini, Armitage and some other primary piRNA pathway components. Further analysis suggests that secondary piRNAs bound to Ago3 can initiate phased primary piRNA production from cleaved transposon RNAs. The first ~26 nt becomes a secondary piRNA that bind Aub while the subsequent piRNAs bind Piwi, allowing piRNAs to spread beyond the site of RNA cleavage. This discovery adds sequence diversity to the piRNA pool, allowing adaptation to changes in transposon sequence. We further find that most Piwi-associated piRNAs are generated from the cleavage products of Ago3, instead of being processed from piRNA cluster transcripts as the previous model suggests. The cardinal function of Ago3 is to produce antisense piRNAs that direct transcriptional silencing by Piwi, rather to make piRNAs that guide post-transcriptional silencing by Aub. Although Ago3 slicing is required to efficiently trigger phased piRNA production, an alternative, slicing-independent pathway suffices to generate Piwi-bound piRNAs that repress transcription of a subset of transposon families. The alternative pathway may help flies silence newly acquired transposons for which they lack extensively complementary piRNAs. The Ping-Pong model depicts that first ten nucleotides of Aub-bound piRNAs are complementary to the first ten nt of Ago3-bound piRNAs. Supporting this view, piRNAs bound to Aub typically begin with Uridine (1U), while piRNAs bound to Ago3 often have adenine at position 10 (10A). Furthermore, the majority of Ping-Pong piRNAs form this 1U:10A pair. The Ping-Pong model proposes that the 10A is a consequence of 1U. By statistically quantifying those target piRNAs not paired to g1U, we discover that 10A is not directly caused by 1U. Instead, fly Aub as well as its homologs, Siwi in silkmoth and MILI in mice, have an intrinsic preference for adenine at the t1 position of their target RNAs. On the other hand, this t1A (and g10A after loading) piRNA directly give rise to 1U piRNA in the next Ping-Pong cycle, maximizing the affinity between piRNAs and PIWI proteins. Small Interfering RNA Argonaute Proteins RNA Interference Drosophila Proteins High-Throughput Nucleotide Sequencing DNA Transposable Elements Dissertations, UMMS RNA, Small Interfering High-Throughput Nucleotide Sequencing Biochemistry Bioinformatics Computational Biology Molecular Biology Molecular Genetics
160	Dysregulated trophoblast-specific gene expression mediated by retroviral regulatory sequences contributes to preeclampsia (PE) Anwar, Rabia 11 March 2021 (has links) Präeklampsie (PE) ist eine Komplikation, die während der Schwangerschaft auftritt, fast 2-8% aller Schwangerschaften betrifft und human spezifisch ist. PE ist eine der Hauptursachen für den Tod von Mutter und Kind. Eine abnormale Plazentaentwicklung aufgrund einer verminderten Trophoblasteninvasion und einem gestörten Umbau der Spiralarterien trägt zur Pathogenese der PE bei. Klinisch wird die PE durch Bluthochdruck und Proteinurie, auftretendnach der 20. Schwangerschaftswoche, diagnostiziert und kann durch eine Funktionsstörung von Organen begleitet werden. Bei besonders schweren Verläufen ist die frühzeitige Endbindung die letzte Möglichkeit das Überleben der Mutter zu gewährleisten. Das Ziel dieser Studie ist es, weitere Gene zu identifizieren, die durch ERVs in der menschlichen Plazenta spezifisch reguliert werden und in PE dysreguliert sind. Um dieses Ziel zu erreichen, wurde das Transkriptom von primären menschlichen Trophoblastenzellen von 5 gesunden und 5 früh einsetzenden PE-Plazenten mittels RNA-Sequenzierung analysiert. Es wurden 335 Gene identifiziert, welche eine höhere Expression in den Trophoblastenzellen im Vergleich zu anderen Geweben aufwiesen. Zusätzlich zeigten einige der Gene (n=88) eine Co-Regulation der Expression durch retrovirale LTRs (10-kb 5‘ des transcription start side (TSS) des Gens). Hauptinteresse lag hierbei auf den Genen, welche ebenfalls eine Dysregulation in der PE aufwiesen (n = 16). Diese Studie identifizierte EPS8L1, das durch primaten-spezifisches ERV-LTR (MLT1G1) in Trophoblastenzellen reguliert wird, als einen wichtigen Faktor in der Entwicklung der menschlichen Plazenta. EPS8L1 ist in der PE Plazenta dysreguliert und involviert in mehrere Signalwege und die Funktionalität von Trophoblasten wie Invasion, Angiogenese und Redoxhomöostase. Hierdurch führt diese Arbeit zu einem besseren Verständnis der PE und deren human-spezifischer Natur. / Preeclampsia (PE) is a complication that occurs during pregnancy and affects almost 2-8% of all pregnancies and is often regarded as a human-specific disorder.1,2 PE is one of the major causes of maternal and fetal death.1 Failure of the trophoblast cells to invade into the maternal decidua results in the improper remodeling of spiral arteries leading to PE pathogenesis. Clinically, it is diagnosed as a maternal syndrome, diagnosed by the new-onset of hypertension and proteinuria or other end-organ dysfunction after the 20th week of pregnancy. So far, the only effective treatment of the disorder is the removal of the placenta tissue and delivery of the infant. The aim of this study is to identify additional genes that are regulated by the human ERV-LTRs in the human placenta specifically, and are dysregulated in PE. To achieve this aim, the transcriptome of primary human trophoblast cells of 5 healthy and 5 early-onset PE placentas were analyzed by RNA sequencing (RNA-seq). RNA-seq analysis identified genes (n=335) with stronger expression in the trophoblast cells as compared to other human body tissues. Additionally, some of the genes (n=88) showed co-regulation of expression by the human ERV-LTRs in their vicinity (10-kb upstream of transcription start side (TSS) of the gene). Since my interest was to identify the new targets of PE pathogenesis, so I focused on genes (n=16) with dysregulated expression in women presented with PE. This study identified a new gene EPS8L1, regulated by primate-specific ERV-LTR in trophoblast cells that has a predominant role in the human placenta development and demonstrated that its dysregulation affected multiple pathways involved in trophoblast function like invasion, angiogenesis and maintenance of cell redox homeostasis. Furthermore, this study leads to the better understanding of the disease by explaining certain aspects of human-specific nature of PE. Präeklampsie (PE) Humanen Endogenen Retrovirus (ERVs), Retrovirale LTRs Trophoblasten-spezifische Gene (TSG) Preeclampsia (PE), Transposable elements (TEs), Endogenous Retroviruses (ERVs) Long Terminal Repeats (LTRs), Trophoblast-Specific Genes (TSGs) 570 Biologie YM 6604 YM 6613 YM 6619 YM 6612 ddc:570

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