Plasticité des génomes des pucerons des céréales et de leur plante hôte : recherche in silico et in vitro des éléments transposables des superfamilles Tc1-mariner-IS630 et piggyBac / Plasticity of the genomes of cereal aphids and their host plant : in silico and in vitro analyses of Tc1-mariner-IS630 and piggyBac superfamilies of transposable elements

Bouallègue, Maryem

27 March 2017

La céréaliculture occupe une place importante dans l’agriculture mondiale et contribue à la sécurité alimentaire des populations. Pour assurer la production des céréales (orge, blé, avoine), il est nécessaire de lutter contre ses ravageurs, essentiellement les pucerons qui sont capables de transmettre plusieurs virus. L’analyse des génomes des pucerons tels que Rhopalosiphum padi, R. maidis, Sitobion avenae, Schizaphis graminum, de leur évolution et de leur relation avec les plantes hôtes (céréales) pourrait contribuer à la mise en place de moyens de lutte pour contrôler les populations de ces ravageurs. Dans ce contexte, cette étude s’est focalisée sur la recherche des éléments transposables des deux superfamilles Tc1-mariner-IS630 et des piggyBac. Les ETs, considérés comme des moteurs de la plasticité génomique et de l’évolution des espèces, sont utilisés en biotechnologie pour développer des outils de transfert de gènes. Dans un premier temps, nous avons recherché des éléments de la famille mariner, ou apparentés à cette famille, dans les génomes séquencés de trois espèces de pucerons : Acyrthosiphon pisum, Myzus persicae et Diuraphis noxia. Sur la base de similitude de séquences, nous avons pu caractériser 183 éléments répartis en trois clades. Le premier, commun aux trois espèces, correspond au clade de la sous-famille irritans DD34D. Il est subdivisé en trois tribus Macrosiphinimar, Batmar-like elements et Dnomar-like elements. Le deuxième comprend l’élément rosa DD41D qui appartient à une famille phylogénétiquement proche de mariner. Le troisième comprend des séquences avec de longues répétitions terminales inversées et inclut deux tribus DD40-41D. Ces deux derniers clades, plus répandus chez A. pisum, dérivent vraisemblablement d’un ancêtre commun et formeraient une nouvelle famille.Dans un deuxième temps, nous avons exploité les résultats de la recherche in silico pour identifier in vitro des éléments de la sous-famille irritans chez les pucerons des céréales et chez leur plante hôte. Deux types d’éléments délétées (MITEs) ont été identifiés chez les pucerons, l’un commun à toutes les espèces avec un pourcentage d’identité supérieur à 98% (Aphidmar) et l’autre spécifique à S. avenae (Samar2). Par ailleurs, les génomes des céréales (orge, blé, brachypodium, égilope) ont été analysés en utilisant comme requêtes des séquences d’éléments de la sous-famille irritans trouvés chez les aphides. Un seul contig de l’orge cultivar barke comprend un élément tronqué de 320 pb, flanqué par de l’ADN génomique de pucerons. La vérification in vitro de la présence de cette séquence chez plusieurs cultivars d’orge révèle deux types de séquences. Le premier est similaire à celui trouvé in silico chez l’orge, le second correspond à l’élément Samar2 délété de 7 nucléotides au niveau du point de cassure de la délétion initiale. Ceci suggère l’existence d’un transfert horizontal entre pucerons des céréales et l’orge. Enfin, l’abondance de données génomiques et la rareté des travaux approfondis portant sur les membres de la superfamille piggyBac, nous ont amenés à analyser in silico leurs caractéristiques, leur distribution et leur évolution. Un total de 117 séquences protéiques de PBLE (éléments autonomes) et de PGBD (éléments domestiqués), ont été utilisées comme requêtes. Quatre groupes structuraux de PBLE ont été définis en fonction de la présence ou absence de répétitions sub-terminales (directes/inversées). Toutefois, il n'existe aucune relation entre ces quatre groupes et la phylogénie des PBLE. Les PGBD soumis à une forte sélection purifiante, sont clairement structurés en neuf groupes dont un correspondant à un nouvel ensemble d’éléments domestiqués trouvé chez les Néopterygiens. L’analyse fine des PGBD révèle que le domaine catalytique de la transposase ancestrale n'est pas toujours conservé. La phylogénie générale des PBLE et des PGBD suggère des événements multiples de domestication des PGBD à partir de différents ancêtres PBLE. / Cereal farming plays an important role in world agriculture and contributes to the food security of the populations. To improve the production of cereals (barley, wheat, oats ...), it is necessary to fight against their pests, especially aphids, able to transmit several viruses. The analysis of aphid’s genomes such as Rhopalosiphum padi, R. maidis, Sitobions avenae and Schizaphis graminum, their evolution and their relationships with their host plants could contribute to define strategies against pest populations. In this context, this work focused on the analysis of transposable elements belonging to Tc1-mariner-IS630 and piggyBac superfamilies. Indeed, TEs are involved in genomic plasticity and evolution of species, and are also used in biotechnology to develop gene transfer tools. In the first chapter, we investigate three available genomes of aphids, namely Acyrthosiphon pisum, Myzus persicae and Diuraphis noxia, to search for elements of the mariner family or close to it. Based on sequence similarities, we were able to characterize 183 elements distributed in three clades. The first one, common to the three species, corresponds to the clade of irritans subfamily DD34D, and is subdivided into three tribes Macrosiphinimar, Batmar-like elements and Dnomar-like elements. The second one includes the rosa element DD41D belonging to a group close to the mariner family. The third one includes sequences with long Terminal Inverted Repeats and is subdivided into two DD40-41D tribes. These two latter clades, more common in A. pisum, likely derive from a common ancestor and would form a new family. In the second chapter, the results of in silico research were exploited, to identify in vitro, elements of the irritans subfamily in cereal aphids and in their host plants as well. Two types of deleted elements (MITEs) have been identified in aphids, one common to all species with a percentage of identity higher than 98% (Aphidmar) and the other one specific to S. avenae (Samar2). In addition, the genomes of cereals (barley, wheat, brachypodium, aegilops) were investigated using as queries sequences of irritans subfamily found in aphids. A single contig identified in Hordeum vulgare (cultivar barke) contains a 320 bp truncated element flanked by genomic DNA of aphids. The presence of this sequence was checked in several barley cultivars by an in vitro approach. Two types of sequences were found. The first one similar to that found in barley from the in silico approach, the second one corresponding to Samar2 element, lacking seven nucleotides at the breaking points of the initial deletion. This suggests a possible horizontal transfer between cereal aphids and barley. In the last chapter, the abundance of genomic data and the scarcity of in-depth research covering all members of the piggyBac superfamily led us to determine in silico their characteristic, their distribution and their evolution. A total of 117 proteic sequences of the PBLE (autonomous elements) and PGBD (domesticated elements) have been used as queries. Four structural groups of PBLE have been identified depending on the presence or absence of sub-terminal repeats (direct / inverted). However, there is no relationship between the structural groups and the phylogeny of these PBLE elements. PGBD are clearly structured into nine main groups including a new group of domesticated elements found in Neopterygii. The catalytic domain of the ancestral transposase is not always preserved, but all these domesticated elements are subjected to a strong purifying selection. The general phylogeny of PBLEs and PGBD suggests multiple and independent domestication events of PGBD from different PBLE ancestors.

Pucerons des céréales

Plantes hôtes (céréales)

Mariner

PiggyBac

Éléments transposables

Cereal aphids

Host plants (cereals)

Mariner

PiggyBac

Transposable elements

Strukturní studium potkaního NK buněčného receptoru NKR-P1B a jeho ligandu Clrb / Structural studies of rat NK cell receptor NKR-P1B and its ligand Clrb

Skořepa, Ondřej

January 2016

Natural killer (NK) cells are an intensively studied part of immune system possessing unique ability to recognize and induce death of tumor and virus-infected cells without prior antigen sensitization. Their function is regulated by a fine balance of signals induced by multiple activating and inhibitory cell surface receptors and their interaction with the ligands present on the target cell. This can be illustrated on the homodimeric rat inhibitory receptor NKR-P1B and its ligand Clrb which play, besides other things, crucial role in the immunological response of NK cells to the infection with rat cytomegalovirus (RCMV), one of the most studied NK cell function model in rat model organism. During RCMV infection the target cell downregulates cell surface expression of Clrb, thus decreasing inhibitory signal transmitted through the NKR-P1B receptor to the NK cell, which would ideally lead to NK cell activation and lysis of the infected cell. However, RCMV carries a gene for "decoy" surface receptor - RCTL that mimics Clrb and thus helps to escape the immunological response of NK cells. Moreover, while this escape strategy was demonstrated in the WAG rat strain, it has been shown that the NKR-P1B homologue from SD rat strain binds only Clrb and does not recognize RCTL. Thus the SD rat strain is less...

Integrating viral vectors as a gene therapy approach for cystic fibrosis

Cooney, Ashley L.

01 May 2018

Cystic fibrosis (CF) is the most common autosomal recessive genetic disease in Caucasian populations. CF affects multiple organ systems including pancreas, liver, intestines, sweat glands, and male reproductive organs, however the leading cause of morbidity and mortality in CF patients is chronic lung disease. CF is caused by a mutant cystic fibrosis transmembrane conductance regulator (CFTR) gene which leads to chloride (Cl-) and bicarbonate (HCO3-) anion dysregulation at the airway surface. Without adequate anion exchange, thick, viscous mucus accumulates at the airway surface allowing bacterial colonization to occur. Complementing CFTR in the appropriate airway cells restores the anion channel activity in CFTR-deficient cells. The ultimate goal for CF gene therapy is to design an integrating vector that would lead to persistent and efficient expression of CFTR in the airways. Performing gene therapy experiments is dependent upon a relevant animal model. The CF pig is a large animal model similar in size, anatomy, and physiology to humans. Importantly, the CF pig recapitulates human lung disease. From the CF pig, we have learned much about CF lung disease and have developed relevant assays to measure anion channel correction. We have learned that loss of CFTR leads to a decreased airway surface ASL pH, bacterial killing ability, and increased mucus viscosity. Standardized assays have been developed to evaluate the change in current by Ussing chambers, ASL pH, bacterial killing in vivo and ASL pH and viscosity on primary airway cultures in vitro. Ultimately, these metrics allow us to make conclusions about the efficiency of CFTR restoration. Viral vectors are promising candidates for CF gene therapy. Viral vectors such as adenovirus (Ad), adeno-associated virus (AAV), and pseudotyped lentiviral vectors such as feline immunodeficiency virus (FIV) or human immunodeficiency virus (HIV) can efficiently transduce airway cells and express CFTR. Ad and AAV have both been tested in CF clinical trials, but CFTR expression was transient, if detected at all. Understanding vector biology and overcoming barriers in the lung have allowed us to improve vector delivery to the airways. However, the next major hurdle was achieving persistent expression. Ad and AAV are both transiently expressing vectors, and vector readministration is implausible due to the presence of neutralizing antibodies that develop against the vector. Creating a hybrid nonviral/viral vector in which the integrating nonviral piggyBac transposon system is delivered by an Ad or AAV vector has allowed us to achieve persistent expression in mice. In a third integrating vector system, lentiviral vectors have historically been challenging to work with due to low titer levels. However, improvement in vector purification methods have allowed us to validate a lentiviral vector as a viable gene therapy option. In total, we have validated three integrating vector systems by restoring CFTR to CF pigs to correct the phenotypic defect.

CF pig

cystic fibrosis

gene therapy

gene transfer

piggyBac transposon

viral vectors

Microbiology

Pathogenic mechanisms and signaling pathways in Plasmodium falciparum

Sedillo, Jennifer L

31 March 2014

Plasmodium falciparum is a human intracellular parasite that is the causative agent of a deadly form of malaria. This species alone is responsible for 200 million cases of malaria annually resulting in over 1 million deaths worldwide. The excessive mortality due to P. falciparum infection is due to its ability to cause severe pathogenesis through hyperparasitemia and cytoadherence defined as the ability of infected red blood cells to adhere to host vasculature. Cytoadherence is mediated through the export of parasite proteins to the surface of the infected red blood cell (RBC). Exported proteins have been identified but the pathway for protein export is still being elucidated. Many protein coding genes in the P. falciparum genome are hypothetical and therefore still need to be studied. Random transposon mutagenesis using the piggyBac transposable element in P. falciparum has given us a library of mutants to use for forward genetic studies. In this work, we describe a novel approach for screening P. falciparum piggyBac mutants to look for differences in cytoadherence. We utilized an image-based approach in order to quantify cytoadherence in P. falciparum NF54 wild-type and thirty-four piggyBac mutants. We found cytoadherence to be affected by the expression of genes with specific gene ontologies including nucleic acid metabolism and post-translational modification. Many of these genes are annotated as hypothetical or putative and this work may result in further revelations of a role for these genes in parasite pathogenesis. We further characterized a piggyBac mutant that was increased in cytoadherent abilities as an atypical mitogen-activated protein kinase phosphatase (MKP) named PfMKP1. We were able to demonstrate phosphatase activity in a generic substrate-based assay and identify a putative substrate as mitogen-activated protein kinase 1 (Pfmap1). Furthermore, we found Pfmap1 to be differentially phosphorylated and a difference in localization (through immunofluorescence assay) in the PfMKP1 mutant line compared to the wild-type and complemented mutant. This adds to the recent work characterizing this gene as important in cell cycle progression within the erythrocytic cycle and lends to the hypothesis of a functioning mitogen-activated protein kinase (MAPK) pathway in P. falciparum for which it is currently unknown. Supplementary work focused on the development of tools to further investigate the MAPK pathway and the role for PfMKP1 as an atypical MKP of Pfmap1 in this pathway. A mass spectrometry-based technique was developed to look at Pfmap1 and its potential active state based on its phosphorylation status. This approach needs further development but the methods are described here within. In addition, the tools needed to further characterize the binding interaction between PfMKP1 and Pfmap1 were established. The mass spectrometry screen and immunofluorescence screening of Pfmap1 can further our knowledge of the MAPK pathway in P. falciparum and lead to the identification of external stimuli that can induce growth or stress response in the parasite. Taken together, the elucidation of mechanisms for cytoadherence and signal transduction pathways in the parasite can lead to new drug target identification.

cytoadherence

malaria

MAPK

PfMKP1

phosphatase

piggyBac

Molecular Biology

Parasitology

Public Health

Direct Delivery of piggyBac CD19 CAR T Cells Has Potent Anti-tumor Activity against ALL Cells in CNS in a Xenograft Mouse Model / piggyBac CD19 CAR T細胞の直接注入は、異種移植マウスモデルにおいて中枢神経内の急性リンパ性白血病細胞に対して、効果的に抗腫瘍効果を発揮する

Tanaka, Kuniaki

25 January 2021

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22882号 / 医博第4676号 / 新制||医||1047(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 髙折 晃史, 教授 濵﨑 洋子, 教授 羽賀 博典 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

CD19 CAR T cells

xenograft mouse model

CNS-ALL

intraventricular delivery

piggyBac transposon system

490

Generation of non-viral, transgene-free hepatocyte like cells with piggyBac transposon. / 非ウィルスベクターであるpiggyBac transposonを用いた挿入遺伝子の遺残のない肝細胞様細胞の作製

Katayama, Hokahiro

24 July 2017

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第20605号 / 医博第4254号 / 新制||医||1023(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 川口 義弥, 教授 浅野 雅秀, 教授 中川 一路 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

direct reprogramming

hepatocyte like cells

piggyBac

mesenchymal stem cells

iHeps

490

Příprava a charakterizace chimerických antigenních receptorů / Construction and characterization of chimeric antigen receptors

Ptáčková, Pavlína

January 2021

Background: The CD19 chimeric antigen receptor (CAR) adoptive T-cell therapy for B-cell leukemia is a promising treatment for relapsed or refractory malignities. The overall response rate of CD19 CAR-T cells in clinical trials was greater than 80% for patients with B-cell acute lymphoblastic leukemia (B-ALL) and non-Hodgkin's lymphoma (NHL). However, CAR-T cell therapy of leukemias and solid tumors has been limited by a lot of factors such as antigen loss of tumor escape variants, reduced proliferation, persistence and tumor-infiltration of CAR-T cells in vivo, immunosuppressive tumor environment, absence of ideal antigens and on-target, off-tumor toxicities. Therefore, new strategies improving the safety and efficacy of CAR-T cells, including further T-cell modification to overcome the immune suppression, are tested. Aims: (i) Bispecific CARs designed to express two antigen-binding domains prevent of antigen escape. (ii) T-cells were genetically modified to express CAR along with an inducible IL-21 gene cassette driven by NFAT-responsive promoter. IL-21 directly enhances CAR-T cell activity and anti-tumor effects. (iii) Applying suicide epitope modification in CAR enables significantly increasing the therapeutic safety of CAR-T cells. Methods: CARs were constructed by using molecular biology...

Modifying the common marmoset monkey (Callithrix jacchus) genome: transgenesis and targeted gene modification in vivo and in vitro

Kahland, Tobias Sören

20 November 2015

No description available.

570

Common marmoset

Transgenesis

Targeted gene modification

In vitro fertilization

CRISPR/Cas9

hTERT

Immortalization

EOS-EiP

piggyBac

iPS cells

Biologie (PPN619462639)

Development of Transgenic Sterile Insect Technique Strains for the Invasive Fruit Pest Drosophila suzukii

Ahmed, Hassan Mutasim Mohammed

18 December 2021

No description available.

570

Gene drive

Molecular entomology

Insect pests

Genome editing

CRISPR/Cas

Genetic engineering

piggyBac

Transgenesis

Drosophila suzukii

Biologie (PPN619462639)

Evaluation of genetic engineering and genome editing tools to develop multifactorial reproductive sterility or killing sperm systems for the improvement of the Sterile Insect Technique

Eckermann, Kolja Neil

19 October 2021

No description available.

570

pest and vector control

genetic engineering

genome editing

sterile insect technique

gene drive

CRISPR/Cas

piggyBac

Biologie (PPN619462639)