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211	Development and characterization of two new tools for plant genetic engineering: A CRISPR/Cas12a-based mutagenesis system and a PhiC31-based gene switch Bernabé Orts, Juan Miguel 16 December 2019 (has links) Tesis por compendio / [ES] La mejora genética vegetal tiene como objetivo la obtención de plantas con rasgos mejorados o características novedosas que podrían ayudar a superar los objetivos de sostenibilidad. Para este fin, la biotecnología vegetal necesita incorporar nuevas herramientas de ingeniería genética que combinen una mayor precisión con una mayor capacidad de mejora. Las herramientas de edición genética recientemente descubiertas basadas en la tecnología CRISPR/Cas9 han abierto el camino para modificar los genomas de las plantas con una precisión sin precedentes. Por otro lado, los nuevos enfoques de biología sintética basados en la modularidad y la estandarización de los elementos genéticos han permitido la construcción de dispositivos genéticos cada vez más complejos y refinados aplicados a la mejora genética vegetal. Con el objetivo final de expandir la caja de herramientas biotecnológicas para la mejora vegetal, esta tesis describe el desarrollo y la adaptación de dos nuevas herramientas: una nueva endonucleasa específica de sitio (SSN) y un interruptor genético modular para la regulación de la expresión transgénica. En una primera parte, esta tesis describe la adaptación de CRISPR/Cas12a para la expresión en plantas y compara la eficiencia de las variantes de Acidaminococcus (As) y Lachnospiraceae (Lb) Cas12a con Streptococcus pyogens Cas9 (SpCas9) descritos anteriormente en ocho loci de Nicotiana benthamiana usando expresión transitoria. LbCas12a mostró la actividad de mutagénesis promedio más alta en los loci analizados. Esta actividad también se confirmó en experimentos de transformación estable realizados en tres plantas modelo diferentes, a saber, N. benthamiana, Solanum lycopersicum y Arabidopsis thaliana. Para este último, los efectos mutagénicos colaterales fueron analizados en líneas segregantes sin la endonucleasa Cas12a, mediante secuenciación del genoma descartándose efectos indiscriminados. En conjunto, los resultados muestran que LbCas12a es una alternativa viable a SpCas9 para la edición genética en plantas. En una segunda parte, este trabajo describe un interruptor genético reversible destinado a controlar la expresión génica en plantas con mayor precisión que los sistemas inducibles tradicionales. Este interruptor, basado en el sistema de recombinación del fago PhiC31, fue construido como un dispositivo modular hecho de partes de ADN estándar y diseñado para controlar el estado transcripcional (encendido o apagado) de dos genes de interés mediante la inversión alternativa de un elemento regulador central de ADN. El estado del interruptor puede ser operado externa y reversiblemente por la acción de los actuadores de recombinación y su cinética, memoria y reversibilidad fueron ampliamente caracterizados en experimentos de transformación transitoria y estable en N. benthamiana. En conjunto, esta tesis muestra el diseño y la caracterización funcional de herramientas para la ingeniería del genómica y biología sintética de plantas que ahora ha sido completada con el sistema de edición genética CRISPR/Cas12a y un interruptor genético reversible y biestable basado en el sistema de recombinación del fago PhiC31. / [CA] La millora genètica vegetal té com a objectiu l'obtenció de plantes amb trets millorats o característiques noves que podrien ajudar a superar els objectius de sostenibilitat. Amb aquesta finalitat, la biotecnologia vegetal necessita incorporar noves eines d'enginyeria genètica que combinen una major precisió amb una major capacitat de millora. Les eines d'edició genètica recentment descobertes basades en la tecnologia CRISPR/Cas9 han obert el camí per modificar els genomes de les plantes amb una precisió sense precedents. D'altra banda, els nous enfocaments de biologia sintètica basats en la modularitat i l'estandardització dels elements genètics han permès la construcció de dispositius genètics cada vegada més complexos i sofisticats aplicats a la millora genètica vegetal. Amb l'objectiu final d'expandir la caixa d'eines biotecnològiques per a la millora vegetal, aquesta tesi descriu el desenvolupament i l'adaptació de dues noves eines: una nova endonucleasa específica de lloc (SSN) i un interruptor genètic modular per a la regulació de l'expressió transgènica . En una primera part, aquesta tesi descriu l'adaptació de CRISPR/Cas12a per a l'expressió en plantes i compara l'eficiència de les variants de Acidaminococcus (As) i Lachnospiraceae (Lb) Cas12a amb la ben establida Streptococcus pyogens Cas9 (SpCas9), en vuit loci de Nicotiana benthamiana usant expressió transitòria. LbCas12a va mostrar l'activitat de mutagènesi mitjana més alta en els loci analitzats. Aquesta activitat també es va confirmar en experiments de transformació estable realitzats en tres plantes model diferents, a saber, N. benthamiana, Solanum lycopersicum i Arabidopsis thaliana. Per a aquest últim, els efectes mutagènics col·laterals van ser analitzats en línies segregants sense l'endonucleasa Cas12a, mitjançant seqüenciació completa del genoma i descartant efectes indiscriminats. En conjunt, els resultats mostren que LbCas12a és una alternativa viable a SpCas9 per a l'edició genètica en plantes. En una segona part, aquest treball descriu un interruptor genètic reversible destinat a controlar l'expressió gènica en plantes amb major precisió que els sistemes induïbles tradicionals. Aquest interruptor, basat en el sistema de recombinació del bacteriòfag PhiC31, va ser construït com un dispositiu modular fet de parts d'ADN estàndard i dissenyat per controlar l'estat transcripcional (encès o apagat) de dos gens d'interès mitjançant la inversió alternativa d'un element regulador central d'ADN. L'estat de l'interruptor pot ser operat externa i reversiblement per acció dels actuadors de recombinació i la seva cinètica, memòria i reversibilitat van ser àmpliament caracteritzats en experiments de transformació transitòria i estable en N. benthamiana. En conjunt, aquesta tesi mostra el disseny i la caracterització funcional d'eines per a l'enginyeria del genòmica i biologia sintètica de plantes que ara ha sigut completat amb el sistema d'edició genètica CRISPR/Cas12a i un interruptor genètic biestable i reversible basat en el sistema de recombinació del bacteriòfag PhiC31. / [EN] Plant breeding aims to provide plants with improved traits or novel features that could help to overcome sustainability goals. To this end, plant biotechnology needs to incorporate new genetic engineering tools that combine increased precision with higher breeding power. The recently discovered genome editing tools based on CRISPR/Cas9 technology have opened the way to modify plant¿s genomes with unprecedented precision. On the other hand, new synthetic biology approaches based on modularity and standardization of genetic elements have enabled the construction of increasingly complex and refined genetic devices applied to plant breeding. With the ultimate goal of expanding the toolbox of plant breeding techniques, this thesis describes the development and adaptation to plant systems of two new breeding tools: a site-specific nuclease (SSNs), and a modular gene switch for the regulation of transgene expression. In a first part, this thesis describes the adoption of the SSN CRISPR/Cas12a for plant expression and compares the efficiency of Acidaminococcus (As) and Lachnospiraceae (Lb) Cas12a variants with the previously described Streptococcus pyogens Cas9 (SpCas9) in eight Nicotiana benthamiana loci using transient expression experiments. LbCas12a showed highest average mutagenesis activity in the loci assayed. This activity was also confirmed in stable genome editing experiments performed in three different model plants, namely N. benthamiana, Solanum lycopersicum and Arabidopsis thaliana. For the latter, off-target effects in Cas12a-free segregating lines were discarded at genomic level by deep sequencing. Collectively, the results show that LbCas12a is a viable alternative to SpCas9 for plant genome engineering. In a second part, this work describes the engineering of a new reversible genetic switch aimed at controlling gene expression in plants with higher precision than traditional inducible systems. This switch, based on the bacteriophage PhiC31 recombination system, was built as a modular device made of standard DNA parts and designed to control the transcriptional state (on or off) of two genes of interest by alternative inversion of a central DNA regulatory element. The state of the switch can be externally and reversibly operated by the action of the recombination actuators and its kinetics, memory, and reversibility were extensively characterized in N. benthamiana using both transient expression and stable transgenics. Altogether, this thesis shows the design and functional characterization of refined tools for genome engineering and synthetic biology in plants that now has been expanded with the CRISPR/Cas12a gene editing system and the phage PhiC31-based toggle switch. / Bernabé Orts, JM. (2019). Development and characterization of two new tools for plant genetic engineering: A CRISPR/Cas12a-based mutagenesis system and a PhiC31-based gene switch [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/133055 / Compendio Plant synthetic biology PhiC31 RDF Toggle switch Recombinase Integrase Site-specific recombination GoldenBraid CRISPR/Cas9 CRISPR/Cas12a Off-target Plant gene editing Genome engineering BIOQUIMICA Y BIOLOGIA MOLECULAR
212	WARS1 and SARS1: Two tRNA synthetases implicated in autosomal recessive microcephaly Bögershausen, Nina, Krawczyk, Hannah E., Jamra, Rami A., Lin, Sheng‐Jia, Yigit, Gökhan, Hüning, Irina, Polo, Anna M., Vona, Barbara, Huang, Kevin, Schmidt, Julia, Altmüller, Janine, Luppe, Johannes, Platzer, Konrad, Dörgeloh, Beate B., Busche, Andreas, Biskup, Saskia, Mendes, Marisa I., Smith, Desiree E. C., Salomons, Gajja S., Zibat, Arne, Bültmann, Eva, Nürnberg, Peter, Spielmann, Malte, Lemke, Johannes R., Li, Yun, Zenker, Martin, Varshney, Gaurav K., Hillen, Hauke S., Kratz, Christian P., Wollnik, Bernd 27 January 2025 (has links) Aminoacylation of transfer RNA (tRNA) is a key step in protein biosynthesis, carried out by highly specific aminoacyl‐tRNA synthetases (ARSs). ARSs have been implicated in autosomal dominant and autosomal recessive human disorders. Autosomal dominant variants in tryptophanyl‐tRNA synthetase 1 (WARS1) are known to cause distal hereditary motor neuropathy and Charcot‐Marie‐Tooth disease, but a recessively inherited phenotype is yet to be clearly defined. Seryl‐tRNA synthetase 1 (SARS1) has rarely been implicated in an autosomal recessive developmental disorder. Here, we report five individuals with biallelic missense variants in WARS1 or SARS1, who presented with an overlapping phenotype of microcephaly, developmental delay, intellectual disability, and brain anomalies. Structural mapping showed that the SARS1 variant is located directly within the enzyme's active site, most likely diminishing activity, while the WARS1 variant is located in the N‐terminal domain. We further characterize the identified WARS1 variant by showing that it negatively impacts protein abundance and is unable to rescue the phenotype of a CRISPR/Cas9 wars1 knockout zebrafish model. In summary, we describe two overlapping autosomal recessive syndromes caused by variants in WARS1 and SARS1, present functional insights into the pathogenesis of the WARS1‐ related syndrome and define an emerging disease spectrum: ARS‐related developmental disorders with or without microcephaly. info:eu-repo/classification/ddc/570 ddc:570 info:eu-repo/classification/ddc/610 ddc:610
213	Functions of tribbles (TRIB) pseudokinase proteins in the bovine ovary Pashaei, Maryam 07 1900 (has links) La croissance folliculaire anormale, l'anoestrus et l'anovulation sont parmi les principales causes de la baisse de fertilité chez les bovins laitiers à haut rendement. Lors de la croissance folliculaire et de l'ovulation, les cellules stéroïdogènes, y compris les cellules de granulosa (GC), jouent un rôle crucial dans la maturation et la libération de l'ovocyte. Il est donc essentiel de décrire en détail les processus physiologiques et pathologiques régulant la fonction ovarienne. Des études précédentes de notre laboratoire ont identifié et caractérisé pour la première fois un membre de la famille des pseudo-kinases Tribbles (à savoir TRIB2) dans les cellules ovariennes de granulosa. La famille Tribbles comprend des protéines de type sérine-thréonine kinase largement exprimées (TRIB1, TRIB2 et TRIB3) qui peuvent jouer des rôles cruciaux dans divers processus biologiques tels que la coordination de la mitose et de la morphogenèse, la maturation des ovocytes et la prolifération cellulaire. Cependant, leurs rôles exacts dans la fonction des cellules de granulosa et leurs effets sur les voies de signalisation impliquées dans la croissance folliculaire et l'ovulation restent inconnus. Nous avons émis l'hypothèse que les pseudo-kinases TRIB jouent des rôles cruciaux dans la régulation de la fonction et de l'activité des cellules de granulosa au cours des dernières étapes du développement folliculaire et peuvent activer des voies de signalisation distinctes. L'objectif de la présente étude était donc d'examiner les fonctions des membres TRIB dans les cellules de granulosa bovine avec les objectifs spécifiques suivants : 1) Analyser l'expression et la régulation des membres TRIB dans différents types cellulaires folliculaires et modèles de culture ; 2) Étudier les fonctions des membres TRIB dans les cellules GC en utilisant l'approche CRISPR/Cas9. En utilisant un modèle d'étude in vivo composé de cellules GC obtenues à partir de follicules à différents stades de développement, nous avons confirmé la régulation négative de TRIB2 par l'hormone lutéinisante (LH) / hormone chorionique gonadotrope humaine (hCG) et la régulation positive de TRIB1 et TRIB3 aux niveaux de l'ARN et des protéines par la LH. Nous avons montré que TRIB2 est presque exclusivement présent dans les cellules GC et dans les follicules dominants (DF) alors qu'il est absent dans les cellules de la thèque (TC) et régulé négativement dans les follicules ovulatoires (OF) par hCG, tandis que TRIB1 et TRIB3 sont présents dans les cellules TC des DF ou OF. TRIB1 et TRIB3 sont exprimés dans les cellules GC uniquement dans les OF post-hCG et non dans les DF. Les résultats suggèrent que la contribution des cellules TC à l'expression de TRIB2 dans l'ovaire bovin est très limitée par rapport aux cellules GC. Nos données ont montreé que TRIB1 et TRIB3 sont induits par hCG, suggérant des rôles significatifs, respectivement, dans le processus d'ovulation ou la formation et la fonction du corps jaune. Les résultats d'immunohistochimie ont montré la présence de TRIB2 dans la couche GC des DF par rapport à la couche TC et absente dans les OF post-hCG. L'analyse par Western blot a montré que TRIB2 et TRIB3 sont induits par la FSH mais à des moments différents. De plus, les données in vitro ont confirmé que la LH supprime l'expression de TRIB2, tandis que l'expression de TRIB3 est induite par la LH, en particulier 6 heures après le traitement avec LH. L'inhibition de TRIB3 via CRISPR/Cas9 suggère que, bien que TRIB3 puisse avoir un effet positif sur la voie de signalisation AKT dans les cellules GC, il a des effets négatifs sur la voie de signalisation P38MAPK. Nos données actuelles fournissent des preuves que TRIB2 pourrait être impliqué dans la prolifération des cellules GC et le développement folliculaire, tandis que TRIB1 et TRIB3 pourraient être impliqués respectivement dans les processus d'ovulation et de lutéinisation. En conclusion, les TRIB jouent des rôles cruciaux dans la régulation de la fonction et de l'activité des cellules de granulosa au cours du développement folliculaire et peuvent activer des voies de signalisation distinctes. / Abnormal follicular growth, anestrus and anovulation are among the main causes of declining fertility in high-yielding dairy cattle. During follicular growth and ovulation, steroidogenic cells, including granulosa cells (GC), play a crucial role in the maturation and release of the oocyte. It is therefore essential to describe in more details the physiological and pathological processes regulating the ovarian function. Previous studies from our laboratory identified and characterized for the first time a tribbles pseudokinase family member (namely TRIB2) in ovarian GC. The Tribbles family includes widely expressed serine-threonine kinase-like proteins (TRIB1, TRIB2 and TRIB3) that may play crucial roles in various biological processes such as coordination of mitosis and morphogenesis, oocyte maturation and cell proliferation. However, their exact roles in GC function and effects on the signaling pathways involved in follicular growth and ovulation remained to be defined. We hypothesized that TRIB pseudokinases play crucial roles in regulating the function and activity of granulosa cells during the final stages of follicular development and may activate separate signaling pathways. The aim of the present study was therefore to investigate the functions of TRIB members in bovine GC with the following specific objectives: 1) Analyze the expression and regulation of TRIB members in different follicular cell types and culture models; 2) to study TRIB members functions in GC cells using the CRISPR/Cas9 approach. Using an in vivo study model consisting of GC obtained from follicles at different stages of development, we confirmed down-regulation of TRIB2 by luteinizing hormone (LH) and human chorionic gonadotropin (hCG) and up-regulation of TRIB1 and TRIB3 at both RNA and protein levels. We showed that, TRIB2 is almost exclusively present in GC and in dominant follicles (DF) while it is absent in theca cells (TC) and downregulated in ovulatory follicles (OF) by hCG while TRIB1 and TRIB3 are present in TC whether of DF or OF. Both TRIB1 and TRIB3 are expressed in GC only in OF post-hCG and not in DF. The results suggest that TC contribution to TRIB2 expression in the ovary is very limited as compared to GC. Our data show that TRIB1 and TRIB3 are induced by hCG suggesting significant roles in the ovulation process (TRIB1) or the formation and function of the corpus luteum. Results from immunohistochemistry, showed the presence of TRIB2 in the GC layer of DF as compared to TC layer and absent in OF post hCG injection. Western blot analysis showed that TRIB2 and TRIB3 are induced by FSH but at different times. Moreover, in vitro data confirmed that LH suppresses TRIB2 expression, whereas TRIB3 expression is induced by LH, particularly 6 hours post-LH treatment. Inhibition of TRIB3 via CRISPR-Cas9 suggested that while TRIB3 might have positive effect on AKT signaling pathway in GC, it has negative effects on P38 signaling pathway. Our current data provide evidence that TRIB2 could be involved in GC proliferation and follicular development while TRIB1 and TRIB3 could be involved in the ovulation and luteinization processes, respectively. Overall, TRIBs play crucial roles in regulating the function and activity of granulosa cells follicular development and may activate separate signaling pathways. Bovin Fertilité Ovaire Développement folliculaire Cellules de granulosa Ovulation TRIB Prolifération CRISPR/Cas9 MAPK Bovine Follicular development Granulosa cells
214	Caractérisation des fonctions des modifications post-traductionnelles de PCNA à l'aide d'un nouvel outil génétique / Characterization of PCNA’s post-translational modification functions using a new genetic tool Dietsch, Frank 09 April 2019 (has links) PCNA est une protéine essentielle qui intervient dans de nombreux mécanismes cellulaires et qui possède de nombreuses modifications post-traductionnelles (MPTs) dont les fonctions de certaines, restent encore inconnues. Afin d’étudier la fonction de ces MPTs, nous avons développé un nouvel outil génétique permettant in cellulo, de substituer la protéine endogène PCNA par une version mutée de la protéine appelée version de complémentation. La technique consiste à cotransfecter des cellules en culture avec deux types de plasmides. Un premier plasmide permet l’invalidation du gène de PCNA endogène dans les cellules transfectées par le système CRISPR-Cas9. Le deuxième plasmide dit de complémentation permet l’expression d’une forme mutée de PCNA. Sur l’ensemble d’une banque de mutants testés, deux mutants de PCNA se sont avérés être létaux (D122A et E124A). Nous avons démontré que ces deux sites sont impliqués dans l’initiation d’une voie de dégradation ubiquitine dépendante CRL4Cdt2 essentielle pour la mise en place de la protéolyse d’un cocktail de protéines (cdt1, p21, set8) durant la phase S. Nous avons démontré que les cellules mutantes pour PCNA (D122A et E124A) accumulent la protéine p21. Ce défaut de dégradation de p21 provoque alors des évènements de re-réplication menant à terme à la mort des cellules mutantes. / PCNA is an essential protein that is involved in many cellular mechanisms and has many post-translational modifications (PTMs). The functions of some PTMs, still remain unknown. In order to study the function of these PTMs, we have developed a new genetic tool allowing, in cellulo, the substitution of endogenous PCNA protein with a mutated version of the protein named complementation version. The technique involves cotransfection of the cells in culture with two types of plasmids. A first plasmid allows invalidation of the endogenous PCNA gene in transfected cells by the CRISPR-Cas9 system. The second plasmid, named complementation plasmid allows the expression of a mutated form of PCNA. In the whole bank of tested mutants, two PCNA mutants were found to be lethal (D122A and E124A). We have demonstrated that these two sites are involved in the initiation of an ubiquitin-dependent protein degradation CRL4Cdt2 pathway essential for the proteolysis of a protein cocktail (cdt1, p21, set8) during the S phase. We demonstrated that PCNA mutant cells (D122A and E124A) accumulate p21 protein. This lack of degradation of p21 then causes re-replication events leading ultimately to the mutant cells death. PCNA Modifications post-traductionnelles Nouvel outil génétique CRISPR-Cas9 Plasmide de complémentation Mutants PCNA D122A et E124A CRL4Cdt2 P21 Re-réplication Mort cellulaire PCNA Post-translational modifications New genetic tool CRISPR-Cas9 Complementation plasmid Mutants PCNA D122A and E124A Ubiquitin-dependent protein degradation CRL4Cdt2 P21 Re-replication Cell death 572.8
215	CRISPR-Cas9 versus Prime Editing : en metodjämförelse, kliniska prövningar och etiska aspekter / CRISPR-Cas9 versus Prime Editing : a method comparison, clinical trials and ethical aspects Olsson, Anna January 2020 (has links) Det finns idag flera tusen genetiska sjukdomar som inte kan botas med hjälp av dagens läkemedelsbehandlingar. Detta är något forskarna försöker finna en lösning på. Två nya potenta genredigeringsverktyg har utvecklats och tros kunna bota och behandla många av de idag kända genetiska sjukdomarna. Detta är clustered regularly interspaced short palindromic repeats med CRISPR-associerade proteiner, CRISPR/Cas9 och prime editing. Tekniker som utvecklats från det adaptiva immunförsvaret hos prokaryoter. Både CRISPR/Cas9 och prime editing är RNA-guidade system med DNA som mål, de är även möjliga att programmera. Syftet med denna litteratursökning var att: 1) Jämföra teknikerna CRISPR/Cas9 och prime editing, 2) Undersöka vilka idag pågående kliniska prövningar som finns där någon av teknikerna används vid behandling av sjukdom. 3) Undersöka vilka sjukdomstillstånd som tros kunna botas och/eller behandlas med hjälp av någon av teknikerna samt 4) undersöka hur forskare ser på de etiska aspekterna av dessa tekniker. Information har hämtats under arbetets gång, främst från PubMed, Google och clinicaltrials.gov. Det finns idag 16 pågående studier där CRISPR/Cas9 används som behandlingsmetod. För prime editing finns det inga pågående studier. Sjukdomarna som forskarna hoppas kunna behandla med hjälp av metoderna är många, men de har kommit längst i utvecklingen av läkemedel för cancer, blodsjukdomar och ögonsjukdomar. De etiska diskussionerna har varit många och den stora frågan som diskuteras är hur tekniken skall regleras för att inte utnyttjas till sådant som potentiellt kan vara skadligt. Detta är två tekniker med hopp om nya behandlingsmetoder för genetiska sjukdomar, dock är de endast i början av sin utveckling och mer forskning och förfining av metoderna krävs innan de kan tillämpas kliniskt. / Today, there are thousands of genetic diseases that cannot be cured with the help of today's drug treatments. This is something the researchers are trying to find a solution to. Two new potent gene editing tools have been developed and are believed to be able to treat or cure many of today's genetic diseases. These are Clustered regularly interspaced short palindromic repeats with CRISPR-associated proteins, CRISPR/Cas9 and prime editing. Techniques developed from the adaptive immune system of prokaryotes. Both CRISPR/Cas9 and prime editing are RNA-guided DNA-targeted systems that are programmable. The purpose of this literature search was to: 1) compare the CRISPR/Cas9 and prime editing techniques, 2) investigate the current clinical trials in which any of the techniques are used to treat disease. 3) investigate which diseases that are believed to be cured and/or treated by using one of the techniques, and 4) investigare how researchers view the ethical aspects of these techniques. Information was gathered during a period between January to May 2020, mainly from PubMed, Google and clinicaltrials.gov. There are currently 16 ongoing studies using CRISPR/Cas9 as a treatment method. For prime editing there are no ongoing studies. The diseases that the researchers hope to be able to treat using the methods are many, but they have come the farthest in the development of a drug for cancer, blood diseases and eye diseases. There have been many discussions about the ethical side, but the big question being discussed is how the technology should be regulated so that it may not be used to harm instead of treat. These two techniques give hope of new treatment methods of genetic diseases, however, they are in the early stages of their development and more research and refinement of the methods is required before they can be applied clinically. CRISPR/Cas9 Prime editing Clinical trials Ethical aspects CRISPR/Cas9 Prime editing Kliniska prövningar Etiska aspekter Other Medical Biotechnology Annan medicinsk bioteknologi Medical Ethics Medicinsk etik
216	O gene Aire pode controlar mRNAs bem como os lncRNAs em células tímicas epiteliais medulares como evidenciado pela edição do genoma por CRISPR-Cas9 / Aire gene can control mRNAs as well as lncRNAs in medullary thymic epitelial cells as evidentiated by genome editing by CRISPR-Cas9 Duarte, Max Jordan de Souza 26 November 2018 (has links) O timo é um órgão linfoide primário essencial para a manutenção da tolerância central através da seleção e eliminação de células T autoreativas. Precursores de células T, oriundas da medula óssea, chegam ao timo e migram do córtex para região da medula. As células epiteliais medulares tímicas (mTECs) expressam em sua superfície antígenos de tecidos periféricos (em inglês tissue-restricted antigens ou TRAs) que representam autoantígenos de todos os tecidos do corpo. Atuando como um fator de transcrição não clássico em células mTEC, o gene Autoimmune Regulator (Aire) desempenha um papel na expressão dos TRAs, cuja proteína codificada libera a RNA polimerase II (RNA Pol II) ancorada na cromatina e regula a expressão de mRNAs na glândula timo. A função biológica deste gene está ligada à indução de tolerância imunológica central impedindo o aparecimento de doenças autoimunes. Isso é resultado da seleção negativa de timócitos (precursores de células T) autoreativos que interagem fisicamente com as mTECs. Os timócitos autoreativos que reconhecem os TRAs como elementos estranhos são eliminados por apoptose. O co-cultivo de mTECs com timócitos representa um sistema-modelo in vitro adequado para se aproximar da interação celular que ocorre dentro do timo. Os resultados anteriores do nosso laboratório demonstraram que além do controle de mRNA de TRAs, o gene Aire também participa da modulação de miRNAs em mTECs uma vez que estas espécies de RNA são transcritas pela RNA Pol II. Continuando com essa linha de estudos, neste trabalho nós demonstramos pela primeira vez que Aire também modula a expressão de long noncoding RNAs (lncRNAs) em mTECs. Para isto fizemos uso da estratégia da perda de função analisando a expressão dessa espécie de RNA, assim como de mRNAs, em células mTEC Aire +/+ e mTEC Aire nocautes (KO Aire -/-) obtidas pela edição gênica por Crispr-Cas9. O transcriptoma dessas células que passaram ou não por adesão com timócitos, foi então analisado por hibridizações com microarrays. Isso evidenciou que Aire e adesão celular influenciam a expressão tanto de mRNAs como de lncRNAs. A reconstrução de redes de interação lncRNAs-mRNAs possibilitou evidenciar uma nova via de regulação pós-transcricional em células mTEC. / The thymus is a primary lymphoid organ essential for the maintenance of central tolerance through the selection and elimination of autoreactive T cells. Precursors of T cells, originating from the bone marrow, reach the thymus and migrate from the thymic cortex to the medullary region. Thymic medullary epithelial cells (mTECs) express on their surface tissue-restricted antigens (TRAs) that represent autoantigens of all tissues in the body. Acting as a non-classical transcription factor in mTEC cells, the Autoimmune regulator (Aire) gene plays a role in the expression of TRAs, whose encoded protein releases the RNA polymerase II (RNA Pol II) anchored in the chromatin and regulates the expression of mRNAs in the thymus gland. The biological function of this gene is associated to the induction of central immune tolerance preventing the onset of autoimmune diseases. This is a result of negative selection of autoreactive thymocytes (T cell precursors) that interact physically with mTECs. Self-reactive thymocytes that recognize TRAs as foreign elements are eliminated by apoptosis. The co-culture of mTECs with thymocytes represents an appropriate in vitro model system to approximate the cellular interaction that occurs within the thymus. Previous results from our laboratory demonstrated that in addition to the control of TRA mRNAs, Aire also participates in the modulation of miRNAs in mTECs since these RNA species are transcribed by RNA Pol II. Continuing with this line of studies, in this study we demonstrate for the first time that Aire also modulates the expression of long non-coding RNAs (lncRNAs) in mTECs. For this, we used the loss-of-function strategy to analyze the expression of this RNA species, as well as mRNAs in mTEC Aire + / + or Aire knockout mTEC cells (KO Aire - / -) obtained by the gene editing by Crispr-Cas9. The transcriptome of these cells, whether or not adhered to thymocytes, was then analyzed by microarray hybridizations. This demonstrated that Aire and cell adhesion influence the expression of both mRNAs and lncRNAs. The reconstruction of lncRNAs-mRNAs interaction networks made possible to evidence a new post-transcriptional regulation pathway in mTEC cells. Adesão Celular Autoimmune Regulator (AIRE) Cell adhesion CRISPR-Cas9 CRISPRCas9 Expressão Gênica Gene Autoimmune Regulator (Aire) Gene expression Long noncoding RNA Long noncoding RNA
217	World Automatic (((((The Really Real Project))))) Mayer, Jonna January 2019 (has links) In a prospective post-work society, a select group of citizens participate in a cross-temporal project. As we follow along their journeys, questions arise. How does time move when it is no longer a commodity? What is design in the age of rampant robotics? How do we define creativity? What is wasted potential, and is it possible to be a failure? Most importantly, can fiction teach us anything about reality? work post-work creativity automation commodification de-commodification marxism UBI universal basic income communism posthumanism fiction artefacts future history ai artificial intelligence graphic design design self-design CRISPR-cas9 unemployment capitalism postcapitalism anthropocene Design Design
218	Research towards the effective disruption of reproductive competence in Nile tilapia Oreochromis niloticus Jin, Yehwa January 2018 (has links) Reproductive containment in farmed fish is highly desired for sustainable aquaculture to prevent genetic introgression with wild conspecifics and enhance productivity by suppressing sexual maturation. A number of strategies have already been implemented or have been tested in commercially important fish (e.g. triploidy, monosexing, hormonal therapies); however, they either do not result in 100% containment, or they cannot be applied to all species. One promising new approach consists in disrupting primordial germ cells (PGCs), at the origin of germline cells, to induce sterility. The work carried out in this doctoral thesis aimed to investigate the genes involved in the survival of germ cells and subsequently conduct a functional analysis of candidate genes using CRISPR/Cas9 gene editing system to ultimately provide the basis for the development of a novel sterilisation technique. Nile tilapia was chosen as the experimental animal as it is a major aquaculture species worldwide and the control of reproduction plays a critical role in the farming productivity in this species. In addition, the species has clear advantages as its whole genome sequence is accessible, the generation time is relatively short and zygotes can be available all year round. Initially, a panel of 11 candidate genes with reported roles in survival of PGCs was investigated during the ontogenic development which led to the selection of piwi-like (piwil) gene as a target for genome editing. Then, high temperature was tested as a means to induce germ cell loss to better understand the mechanism underlying germ cell survival and apoptosis, and this study confirmed the functional importance of piwil genes in relation to germ cell loss and proliferation. In addition, the study suggested potential subfunctionalisation within the Bcl-2 gene family which requires further investigation. The next step aimed to optimise the CRISPR/Cas9 gene editing method by improving the microinjection system and testing different concentrations of sgRNAs. Over 95% of injected embryos showed on-target mutation in piwil2 via zygote injection of CRISPR/Cas9 reagents and complete KO larvae were shown in half of the mutants, producing putative sterile fish. However, there was no clear association between the phenotypes in PGCs and the mutation rate. Further comparative studies of mutant screening methods including T7E1, RGEN, HRMA, fragment analysis and NGS revealed that the genotypes of F0 are highly mosaic, suggesting that deep sequencing is recommended for accurate and high throughput F0 screening and further improvement for predictable genome editing is required for a reliable gene functional analysis in F0. In summary, the current thesis provided new scientific knowledge and supporting evidence for the use of the CRISPR/Cas9 gene editing platform to study gene function associated with sterility, with the ultimate goal to develop an alternative sterilisation method in fish. 639
219	Modélisations de maladies des motoneurones en utilisant le poisson zébré Lissouba, Alexandra 08 1900 (has links) No description available. Sclérose latérale amyotrophique paraplégie spastique familiale poisson zébré stress RE TDP-43 FUS spastin CRISPR/Cas9 calpain 1 Amyotrophic lateral sclerosis hereditary spastic paraplegia zebrafish ER stress
220	Analysis of splice-defect associated cardiac diseases using a patient-specific iPSC-cardiomyocyte system Rebs, Sabine 28 September 2021 (has links) No description available. 570 RBM20-mutations DCM and LVNC Missplicing Sarcomere irregularity iPSC-CMs Ca2+ cycling CRISPR/Cas iPSC-cardiomyocytes RBM20-based cardiomyopthies Calcium-cycling Sarcomere Missplicing DCM and LVNC CRISPR/Cas9 Biologie (PPN619462639)

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