EXPRESSION MICROARRAY ANALYSIS OF RENAL DEVELOPMENT AND HUMAN RENAL DISEASE

SCHWAB, KRISTOPHER R.

January 2006

No description available.

microarray

Wnt signaling

metanephros

kidney development

focal segmental glomerulosclerosis

Hox genes

gene knockout mice

Redundant roles of EGFR ligands in the ERK activation waves during collective cell migration / 細胞集団運動時のERK活性波におけるEGFRリガンドの重畳性

Lin, Shuhao

23 March 2022

京都大学 / 新制・課程博士 / 博士(医学) / 甲第23761号 / 医博第4807号 / 新制||医||1056(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 YOUSSEFIAN Shohab, 教授 羽賀 博典, 教授 安達 泰治 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

EGFR ligands

FRET biosensor

wound healing

gene knockout

MDCK cell line

490

Comparative genomic analysis and metabolic engineering of Clostridium acetobutylicum for enhanced n-butanol tolerance and production

Xu, Mengmeng

January 2014

No description available.

Biochemistry

Bioinformatics

Chemical Engineering

ABE fermentation

Clostridium acetobutylicum

comparative genomic analysis

solventogenesis

butanol tolerance

histidine kinase

gene knockout

metabolic engineering

Function of Argonaute proteins in Dictyostelium discoideum

Mazurek, Aleksander Józef

January 2024

Argonaute proteins play substantial roles in post-transcriptional regulation of gene expression within RNA interference (RNAi) pathways, making them crucial subjects for research, aimed at understanding their interactions with small non-coding RNAs (ncRNAs) and other RNAi components. This study focuses on investigating these properties of Argonaute proteins, particularly Argonaute protein A (AgnA), in the social amoeba Dictyostelium discoideum that is renowned for its broad genetic toolbox and unique life cycle. While previous studies have examined the disruption of three Argonaute genes (agnB, agnC, agnE) and their effect on mRNA levels and small ncRNA expression, this study extends to agnA gene, which remains less studied. Key questions surrounding the influence of AgnA on the cellular processes such as the cell growth rate, development, gene expression, as well as potential targets and small ncRNA binding, remain unanswered. A well-established approach that could provide the necessary answers is the disruption of the gene through traditional homologous recombination, by insertion of a drug-resistance cassette flanked by homology arms complementary to the target locus. However, the emerging CRISPR/Cas9 gene editing tool on contrary offers straightforward protocols for disruption of gene expression through efficient induction of genomic knockouts, point mutations and deletions. In this study, both approaches were applied in parallel to knockout the agnA gene, enabling comparison of knockout efficiency and further study of the growth rate, development and gene expression in the knockout strains. Moreover, important information regarding the growth patterns of both wild-type and agnE knockout strains were also elucidated, complementing the previous growth rate analyses. The obtained data from this research could provide valuable insights for future studies ofthe RNAi machinery components and particularly the function of Argonaute proteins in D. discoideum.

CRISPR/Cas9

Argonaute proteins

Dictyostelium discoideum

homologous recombination

gene knockout

Cell and Molecular Biology

Cell- och molekylärbiologi

Microbiology

Mikrobiologi

Genetics

Genetik

Molecular Targets of Psychedelics and Their Role in Behavioral Models of Hallucinogenic Action

Vohra, Hiba Z

01 January 2019

Psychedelics are a subset of hallucinogenic drugs that exert their characteristic effects through agonist activity at the serotonin receptor 2A (5-HT2A). In this study, I aimed to characterize the modulatory role of the metabotropic glutamate subtype 2 receptor (mGluR2) in the 5-HT2A-specific rodent model of hallucinogenic action, head-twitch response (HTR). Secondly, I aimed to explore if 5-HT2A agonist-induced deficits in prepulse inhibition (PPI) of the startle response, an additional model of hallucinogenic action, could be produced in mice. Though 5-HT2A agonist-induced PPI deficits, which represent interruptions in normal sensorimotor gating, have been described in both rats and humans, attempts to translate this behavior to mice are rare. In contrast to prior gene knockout studies suggesting the mGluR2 is necessary for 5-HT2A agonist-induced HTR, mGluR2 knockout (Grm2-/-) mice still displayed HTR upon administration of the psychedelic 2,5-dimethoxy-4-iodoamphetamine (DOI). Additionally, DOI and lysergic acid diethylamide (LSD) produced unexpected improvements in PPI in male 126S6/Sv wild-type mice, depending on the experimental protocol used and the origin of the animals. Sex differences were observed as DOI-induced improvements in PPI were present in female 129S6/Sv mice of the same origin and tested with the same protocol as their male counterparts; this effect in females was absent in 5-HT2A knockout (Htr2a-/-) mice. The results of this study shed light on issues with replicability and reproducibility in science, the importance of highlighting the origin and background of animal subjects, and potential sex differences in hallucinogenic drug action.

psychedelics

serotonin 2A receptor

head twitch response

prepulse inhibition

psychosis

gene knockout mice

Animal Experimentation and Research

Behavioral Neurobiology

Molecular and Cellular Neuroscience

Pharmacology

Physiology

Development of genetic tools for metabolic engineering of Clostridium pasteurianum

Pyne, Michael E

21 April 2015

Reducing the production cost of industrial biofuels will greatly facilitate their proliferation and co-integration with fossil fuels. The cost of feedstock is the largest cost in most fermentation bioprocesses and therefore represents an important target for cost reduction. Meanwhile, the biorefinery concept advocates revenue growth through complete utilization of by-products generated during biofuel production. Taken together, the production of biofuels from low-cost crude glycerol, available in oversupply as a by-product of bioethanol production, in the form of thin stillage, and biodiesel production, embodies a remarkable opportunity to advance affordable biofuel development. However, few bacterial species possess the natural capacity to convert glycerol as a sole source of carbon and energy into value-added bioproducts. Of particular interest is the anaerobe Clostridium pasteurianum, the only microorganism known to convert glycerol alone directly into butanol, which currently holds immense promise as a high-energy biofuel and bulk chemical. Unfortunately, genetic and metabolic engineering of C. pasteurianum has been fundamentally impeded due to a complete lack of genetic tools and techniques available for the manipulation of this promising bacterium. This thesis encompasses the development of fundamental genetic tools and techniques that will permit extensive genetic and metabolic engineering of C. pasteurianum. We initiated our genetic work with the development of an electrotransformation protocol permitting high-level DNA transfer to C. pasteurianum together with accompanying selection markers and vector components. The CpaAI restriction-modification system was found to be a major barrier to DNA delivery into C. pasteurianum which we overcame by in vivo methylation of the recognition site (5’-CGCG-3’) using the M.FnuDII methyltransferase. Systematic investigation of various parameters involved in the cell growth, washing and pulse delivery, and outgrowth phases of the electrotransformation procedure significantly elevated the electrotransformation efficiency up to 7.5 × 104 transformants µg-1 DNA, an increase of approximately three orders of magnitude. Key factors affecting the electrotransformation efficiency include cell-wall-weakening using glycine, ethanol-mediated membrane solubilization, field strength of the electric pulse, and sucrose osmoprotection. Following development of a gene transfer methodology, we next aimed to sequence the entire genome of C. pasteurianum. Using a hybrid approach involving 454 pyrosequencing, Illumina dye sequencing, and single molecule real-time sequencing platforms, we obtained a near-complete genome sequence comprised of 12 contigs, 4,420,100 bp, and 4,056 candidate protein-coding genes with a GC content of 30.0%. No extrachromosomal elements were detected. We provide an overview of the genes and pathways involved in the organism’s central fermentative metabolism. We used our developed electrotransformation procedure to investigate the use of established clostridial group II intron biology for constructing chromosomal gene knockout mutants of C. pasteurianum. Through methylome analysis of C. pasteurianum genome sequencing data and transformation assays of various vector deletion constructs, we identified a new Type I restriction-modification system that inhibits transfer of vectors harboring group II intron gene knockout machinery. We designated the new restriction system CpaAII and proposed a recognition sequence of 5’-AAGNNNNNCTCC-3’. Overcoming restriction by CpaAII, in addition to low intron retrohoming efficiency, allowed the isolation of a gene knockout mutant of C. pasteurianum with a disrupted CpaAI Type II restriction system. The resulting mutant strain should be efficienty transformed with plasmid DNA lacking M.FnuDII methylation. Lastly, we investigated the use of plasmid-based gene overexpression and chromosomal gene downregulation to alter gene expression in C. pasteurianum. Using a β-galactosidase reporter gene, we characterized promoters corresponding to the ferredoxin and thiolase genes of C. pasteurianum and show that both promoters permitted high-level, constitutive gene expression. The thiolase promoter was then utilized to drive transcription of an antisense RNA molecule possessing complementarity to mRNA of our β-galactosidase reporter gene. Our antisense RNA system demonstrated 52-58% downregulation of plasmid encoded β-galactosidase activity throughout the duration of growth. In an attempt to perturb the central fermentative metabolism of C. pasteurianum and enhance butanol titers, we prepared several antisense RNA constructs for downregulation of 1,3-propanediol, butyrate, and hydrogen production pathways. The resulting downregulation strains are expected to exhibit drastically altered central fermentative metabolism and product distribution. Taken together, we have demonstrated that C. pasteurianum is amendable to genetic manipulation through the development of methods for plasmid DNA transfer and gene overexpression, knockdown, and knockout. Further, our genome sequence should provide valuable nucleotide sequence information for the application of our genetic tools. Thus, the genome sequence, electrotransformation method, and associated genetic tools and techniques reported here should promote extensive genetic manipulation and metabolic engineering of this biotechnologically important bacterium.

Clonagem, expressão heteróloga e caracterização parcial da trealase periplasmática de Xanthomonas citri subsp. citri e do seu envolvimento com a fitopatogenicidade

Alexandrino, André Vessoni

03 March 2015

Submitted by Livia Mello (liviacmello@yahoo.com.br) on 2016-09-22T12:11:52Z No. of bitstreams: 1 DissAVA.pdf: 2653238 bytes, checksum: 6ed4edf2962eb1273324c54a2e900fa6 (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-10-10T14:38:43Z (GMT) No. of bitstreams: 1 DissAVA.pdf: 2653238 bytes, checksum: 6ed4edf2962eb1273324c54a2e900fa6 (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-10-10T14:38:51Z (GMT) No. of bitstreams: 1 DissAVA.pdf: 2653238 bytes, checksum: 6ed4edf2962eb1273324c54a2e900fa6 (MD5) / Made available in DSpace on 2016-10-10T14:38:59Z (GMT). No. of bitstreams: 1 DissAVA.pdf: 2653238 bytes, checksum: 6ed4edf2962eb1273324c54a2e900fa6 (MD5) Previous issue date: 2015-03-03 / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / Citrus canker imposes damages to citriculture by causing drop in productivity and fruit quality and the absence of effective control and cure. Thus, the economic potential of citrus is limited in part by this disease mainly caused by the bacterium Xanthomonas citri subsp. citri (XAC) that presents the greatest virulence and broad spectrum of citrus hosts, compared to bacteria Xanthomonas fuscans subsp. aurantifolii types B (XauB) and C (XauC). In a proteomic analysis previously performed by our research group, periplasmic trehalase was identified as a protein which expression differed between XAC e XauC in an in vitro induction of pathogenicity. Trehalase is an enzyme that catalyzes hydrolysis reaction of trehalose, a disaccharide composed of two glucose units, which role in the plant-pathogen interaction is poorly understood. One of the objectives of the study was to obtain this enzyme in purified form using an IPTG-inducible heterologous expression system in E. coli, for purposes of partial characterization of its structure and activity. The recombinant XAC periplasmic trehalase is a monomer bearing wide pH stability and showed Michaelian kinetics. The Michaelis-Menten constant (Km) for trehalose was 0,124 ± 0,015 mM and Vmax 17,319 ± 0,035 μMol glucose.min-1.mg protein-1 . Circular dichroism spectroscopy indicated the following composition of secondary structures: 42.7% α-helices and 13% β-sheets. A gene knockout method based on double homologous recombination between the genomic DNA and suicide vector pNPTS138 has made possible to obtain a strain deleted in the gene encoding the periplasmic trehalase (XACΔ0604), which enabled to evaluate the relationship between this gene and the XAC pathogenicity in Citrus aurantifolia. Infiltrated leaves with XACΔ0604 showed drenching and necrosis of plant tissue and intense brownish pustules compared with wild XAC, suggesting greater virulence of the mutant strain. The periplasmic trehalase activity was compared in XAC and XauC cell extracts from two culture mediums, non-pathogenicity-inducing (CN) and pathogenicity-inducing (XAM-M). Interestingly, XauC has showed higher enzyme activity compared to XAC in XAM-M. Thus, the noticeable higher XACΔ0604 pathogenicity and the greater activity of XauC periplasmic trehalase compared to XAC are indicatives that trehalose may promote pathogenicity. / O cancro cítrico impõe prejuízos ao setor citricultor por ocasionar queda na produtividade e qualidade dos frutos e pela ausência de medidas eficazes de controle e cura. Assim, o potencial econômico dos citros é limitado, em parte, por essa doença causada principalmente pela bactéria Xanthomonas citri subsp. citri (XAC), que apresenta maior virulência e largo espectro de hospedeiros cítricos, comparativamente às bactérias Xanthomonas fuscans subsp. aurantifolii tipos B (XauB) e C (XauC). Em um trabalho de análise proteômica anteriormente realizado por nosso grupo de pesquisa, a trealase periplasmática foi identificada como uma proteína cuja expressão foi diferencial entre XAC e XauC, em condição de indução da patogenicidade in vitro. A trealase é uma enzima que catalisa a reação de hidrólise da trealose, um dissacarídeo formado por duas unidades de glicose, cujo papel na interação planta-patógeno é ainda pouco compreendido. Um dos objetivos do trabalho foi obter esta enzima purificada, utilizando um sistema de expressão heteróloga induzível por IPTG (isopropil-β-D-tiogalactosídeo) em E. coli, para fins de caracterização parcial da sua estrutura e atividade. A trealase periplasmática de XAC de origem heteróloga apresentou-se como um monômero relativamente estável em relação ao pH, e de cinética Michaeliana,. A constante de Michaelis-Menten (Km) da enzima para a trealose foi de 0,124 ± 0,015 mM e a Vmáx 17,319 ± 0,035 μMol de glicose.min-1.mg de proteína-1. Análise de dicroísmo circular resultou na seguinte composição de estruturas secundárias: 42,7 % de α-hélices e 13 % de folhas-β. Uma metodologia de nocaute gênico baseada na dupla recombinação homóloga entre o DNA genômico e o vetor suicida pNPTS138 viabilizou a obtenção de uma linhagem mutante deletada no gene que codifica a trealase periplasmática (XAC∆0604), o que possibilitou avaliar a relação entre tal gene e a patogenicidade de XAC em Citrus aurantifolia. Folhas infiltradas com a suspensão de XAC∆0604 apresentaram maior encharcamento e necrose do tecido vegetal, além de intensas pústulas acastanhadas quando comparadas com as folhas infiltradas com XAC selvagem, sugerindo maior virulência da linhagem mutante. A atividade da trealase periplasmática foi comparada em extratos celulares brutos provenientes de cultivos de XAC e XauC em dois meios de cultura, não-indutor de patogenicidade (CN) e indutor de patogenicidade (XAM- M). A bactéria XauC apresentou maior atividade enzimática de trealase em relação à XAC em XAM-M. Sendo assim, a acentuada patogenicidade de XAC∆0604 em relação à linhagem selvagem XAC e a maior atividade da trealase periplasmática de XauC em relação à XAC reforçam os recentes trabalhos que indicam a trealose como promotora da patogenicidade em fitopatógenos.

Cancro cítrico

Xanthomonas citri subsp. citri

Expressão heteróloga

Trealase periplasmática

Trealose

Citrus canker

Heterologous expression

Periplasmic trehalase

Trehalose

Pathogenicity

Gene knockout

CIENCIAS BIOLOGICAS::GENETICA

Role of EFNBs and EphB4 in T cell development and function

Jin, Wei

08 1900

Eph kinases are the largest family of cell surface receptor tyrosine kinases. The ligands of Ephs, ephrins (EFNs), are also cell surface molecules. Ephs interact with EFNs and the receptors and ligands transmit signals in both directions, i.e., from Ephs to EFNs and from EFNs to Ephs. Ephs and EFNs are widely involved in various developmental, physiological pathophysiological processes. Our group and others have reported the roles of Ephs/EFNs in the immune system. To further investigate the function of EphBs/EFNBs in T cell development and responses, we generated EFNB1, EFNB2, EphB4 conditional gene knockout (KO) mice and EFNB1/2 double KO mice. In the projects using EFNB1 and EFNB2 knockout mice, we specifically deleted EFNB1 or EFNB2 in T cells. The mice had normal size and cellularity of the thymus and spleen as well as normal T cell subpopulations in these organs. The bone marrow progenitors from KO mice and WT mice repopulated the host lymphoid organs to similar extents. The activation and proliferation of KO T cells was comparable to that of control mice. Naïve KO CD4 cells differentiated into Th1, Th2, Th17 and Treg cells similar to naïve control CD4 cells. In EFNB2 KO mice, we observed a significant relative increase of CD4CD8 double negative thymocytes in the thymus. Flowcytometry analysis revealed that there was a moderate increase in the DN3 subpopulation in the thymus. This suggests that EFNB2 is involved in thymocyte development. Our results indicate that the functions of EFNB1 and EFNB2 in the T cell compartment could be compensated by each other or by other members of the EFN family, and that such redundancy safeguards the pivotal roles of EFNB1 and EFNB2 in T cell development and function. In the project using EFNB1/B2 double knockout (dKO) model, we revealed a novel regulatory function of EFNb1 and EFNb2 in stabilizing IL-7Rα expression on the T cell surface. IL-7 plays important roles in thymocyte development, T cell homeostasis and survival. IL-7Rα undergoes internalization upon IL-7 binding. In the dKO mice, we observed reduced IL-7Rα expression in thymocytes and T cells. Moreover, the IL-7Rα internalization was accelerated in dKO CD4 cells upon IL-7 stimulation. In T cell lymphoma cell line, EL4, over-expression of either EFNB1 or EFNB2 retarded the internalization of IL-7Rα. We further demonstrated compromised IL-7 signaling and homeostatic proliferation of dKO T cells. Mechanism study using fluorescence resonance energy transfer and immunoprecipitation demonstrated that physical interaction of EFNB1 and EFNB2 with IL-7Rα was likely responsible for the retarded IL-7Rα internalization. In the last project, using medullary thymic epithelial cell (mTEC)-specific EphB4 knockout mice, we investigated T cell development and function after EphB4 deletion in mTEC. EphB4 KO mice demonstrated normal thymic weight and cellularity. T cell development and function were not influenced by the EphB4 deletion. Lastly, the KO mice developed normal delayed type hypersensitivity. Overall, our results suggest that comprehensive cross interaction between Eph and EFN family members could compensate function of a given deleted member in the T cell development, and only simultaneous deletion of multiple EFNBs will reveal their true function in the immune system. In fact, such redundancy signifies vital roles of Ephs and EFNs in the immune system. / Kinases Eph est la plus grande famille de tyrosines kinases récepteurs Éphrines (EFN) est un ligand de Ephs. Eph et EFN sont toutes les molécules de surface cellulaire. L’interaction entre Ephs et EFNs permet de transmettre des signaux dans les deux directions (c.-à-d. partir de Ephs à EFNs, et de EFNs à Ephs.) Eph et EFNs sont largement impliqués dans divers processus développementaux, physiologiques et physiopathologiques. Notre groupe et d'autres groupes ont rapporté les rôles de Ephs / EFNs dans le système immunitaire. Pour approfondir la fonction de EphBs / EFNBs dans le développement des lymphocytes T et des réponses immunitaires, nous avons généré des souris EFNB1, EFNB2, et EphB4 knock-out conditionnel (KO) et des souris EFNB1 / 2 doubles KO. Dans les projets qui utilisent EFNB1 et EFNB2 comme souris knock-out, nous avons spécifiquement supprimé EFNB1 ou EFNB2 dans les cellules T. Les souris présentaient une taille normale, la cellularité du thymus et de la rate, ainsi que des sous-populations de cellules T étaient normales dans ces organes. Les progéniteurs de la moelle osseuse de souris KO et les souris WT ont repeuplé les organes lymphoïdes de l’hôte à des degrés similaires. L'activation et la prolifération des cellules KO T étaient comparables à celles des souris témoins. Les cellules CD4 naïves KO différenciées en Th1, Th2, Th17 et Treg étaient similaires aux cellules CD4 naïves de souris contrôle. Chez les souris KO EFNB2, nous avons observé une augmentation relative importante des thymocytes CD4CD8 : les double négatifs dans le thymus. L'analyse par cytométrie en flux a révélé qu'il y avait une augmentation modérée de la sous-population DN3 dans le thymus. Les résultats suggèrent qu’EFNB2 est impliqué dans le développement des thymocytes. Nos résultats indiquent que les fonctions de EFNB1 et EFNB2 dans le compartiment des cellules T pourraient être compensées entre eux ou par d'autres EFNB. La redondance des fonctions suggèrent le contrôle critique d’EFNB1 et EFNB2 dans le développement des cellules T. Dans le projet, en utilisant EFNB1/B2 (modèle double KO) (dKO), nous avons observé une fonction de régulation de EFNB1 et EFNB2. dans la stabilisation de l’expression l'IL-7R α , à la surface des cellules T, IL-7 joue un rôle important dans le développement des thymocytes, l'homéostasie des lymphocytes T , et leur survie. IL-7R α subit une internalisation i contraignante de IL-7. Chez les souris DKO, nous avons observé une perte d’expression de l’ IL-7Rα dans les thymocytes et les cellules T. En outre, l’ internalisation IL-7Rα a été accélérée dans les cellules CD4 dKO, suite à la stimulation IL-7. Dans la lignée cellulaire de lymphome T, EL4, la surexpression de EFNB1 ou EFNB2 retarde l'internalisation de l'IL-7Rα. Nous avons aussi démontré les signalisations compromises de l’ IL-7 et de la prolifération homéostatique des cellules T dKO. Les études du méchanisme qui utilisent la fluorescence de transfert d'énergie par résonance et immunoprécipitation ont montré que l'interaction physique de EFNB1 et EFNB2 avec IL-7R était probablement responsable du retard de l’ internalisation IL-7Rα. Dans le dernier projet, nous avons étudié le développement des cellules T et la fonction des cellules épithéliales médullaires du thymus (mTEC), chez les souris knock-out EphB4. Les souris KO EphB4 ont démontré un poids et une cellularité qui sont normaux. La fonction et le développement de cellules T ne sont pas influencés par la suppression de l’ EphB4. Enfin, les souris KO ont développé une hypersensibilité de type retardée normale. Dans l'ensemble, nos résultats suggèrent que l'interaction globale de croisement entre Eph et les membres de la famille EFN pourrir compenser la fonction d'un membre supprimé. Seule la suppression simultanée de plusieurs EFNBs va révéler leur vraie fonction dans le système immunitaire. En fait, une telle redondance montre les rôles vitaux d’Ephs et EFNS dans le système immunitaire.

Eph

EFNB

Conditional gene knockout

T cell development

T cell function

IL-7Ra

Thymic epithelial cells

IL-7Rα

Délétion génique conditionnelle

Développementdes cellules T

Fonction des cellules T

Effets cellulaires et moléculaires de l’invalidation conditionnelle du gène MTR au niveau du foie et du cerveau de souris / Cellular and molecular effects of conditional MTR gene knockdown in liver and mouse brain

Lu, Peng

14 December 2016

L’enzyme méthionine synthase (MTR) catalyse la reméthylation de l’homocystéine en méthionine, le précurseur du donneur universel de groupe méthyle S-Adenosylmethionine (SAM), impliqué dans des mécanismes de régulations épigénétiques. Des polymorphismes de MTR sont associés à des défauts métaboliques et des défauts de développement embryonnaire. Afin d’étudier les conséquences d’une déficience en MTR, nous avons généré des modèles murins d’invalidation conditionnelle du gène MTR de manière constitutive ou inductible dans le foie et dans le cerveau. L’invalidation constitutive ou inductible ciblée dans le foie pendant l’embryogenèse n’est pas viable, suggérant un rôle limitant de la méthionine synthase sur le développement précoce et l’organogenèse en lien probable avec les conséquences sur la prolifération cellulaire. Dans les périodes post-natales, nous avons utilisé le modèle inductible complété par une hépatectomie pour étudier les altérations de la régénération hépatique liée aux effets sur le stress cellulaire ainsi que l’expression et l’activation des cyclines. Le KO dans le cerveau induit principalement une perte des fonctions de mémorisation de l’apprentissage hippocampo-dépendant. Au total, nos résultats illustrent les effets différents de l’invalidation de MTR en fonction de l’organe considéré. Le foie est un organe très plastique avec une capacité de régénération très importante. Les effets sur les étapes de l’organogénèse et sur l’inhibition de la régénération confirment l’hypothèse du rôle majeur et limitant de la méthionine synthase dans la régulation du cycle cellulaire. Le modèle d’invalidation au niveau du cerveau confirme le rôle très important de la voie de reméthylation de l’homocystéine catalysée par la méthionine synthase, rôle qui a déjà été illustré par d’autres travaux sur les rats carencés en donneur de méthyle et sur la souris transgénique KO cd320 / The enzyme methionine synthase (MTR) catalyzes the remethylation of homocysteine to methionine, the precursor of the methyl donor S-universal Adenosylmethionine (SAM), involved in epigenetic regulation mechanisms. We generated mouse models with conditional invalidation of the mtr gene in a constitutive or inducible manner to delete the gene expression specifically in the liver and brain. Constitutive invalidation during embryonic life is not sustainable when targeted to the liver, suggesting a limiting role of methionine synthase in early organogenesis and probably on cell proliferation. We performed hepatectomy to study regeneration-related effects on the cellular stress and found dramatic effects on cell proliferation through altered expression and activation of cyclins. The constitutive model in brain highlighted the behavioral anomalies related to a loss of learning and memory. This suggested major effects in the hippocampus. Overall, our findings highlighted the specific effects of the invalidation of methionine synthase in both organs. The liver is a plastic member with a very high regenerative capacity. The effects on organogenesis and inhibition of regeneration confirm the hypothesis for a major role of methionine synthase in cell cycle regulation. The invalidation model in the brain confirms the important role of the remethylation pathway catalysed by methionine synthase, a role which has been shown by other studies in rats deprived in methyl donors and in cd320 KO transgenic mice

Vitamine B12

Méthionine Synthase

Invalidation génique conditionnelle

Régénération hépatique

Prolifération cellulaire

Cerveau

Stress Oxydant

SIRT1

RNA Binding Proteins

Vitamin B12

Methionine Synthase

Conditional Gene Knockout

Liver Regeneration

Cell Proliferation

Brain

Oxydative stress

SIRT1

RNA Binding Proteins

Methyl donors

572.8

612

Role of EFNBs and EphB4 in T cell development and function

Jin, Wei

08 1900

Eph kinases are the largest family of cell surface receptor tyrosine kinases. The ligands of Ephs, ephrins (EFNs), are also cell surface molecules. Ephs interact with EFNs and the receptors and ligands transmit signals in both directions, i.e., from Ephs to EFNs and from EFNs to Ephs. Ephs and EFNs are widely involved in various developmental, physiological pathophysiological processes. Our group and others have reported the roles of Ephs/EFNs in the immune system. To further investigate the function of EphBs/EFNBs in T cell development and responses, we generated EFNB1, EFNB2, EphB4 conditional gene knockout (KO) mice and EFNB1/2 double KO mice. In the projects using EFNB1 and EFNB2 knockout mice, we specifically deleted EFNB1 or EFNB2 in T cells. The mice had normal size and cellularity of the thymus and spleen as well as normal T cell subpopulations in these organs. The bone marrow progenitors from KO mice and WT mice repopulated the host lymphoid organs to similar extents. The activation and proliferation of KO T cells was comparable to that of control mice. Naïve KO CD4 cells differentiated into Th1, Th2, Th17 and Treg cells similar to naïve control CD4 cells. In EFNB2 KO mice, we observed a significant relative increase of CD4CD8 double negative thymocytes in the thymus. Flowcytometry analysis revealed that there was a moderate increase in the DN3 subpopulation in the thymus. This suggests that EFNB2 is involved in thymocyte development. Our results indicate that the functions of EFNB1 and EFNB2 in the T cell compartment could be compensated by each other or by other members of the EFN family, and that such redundancy safeguards the pivotal roles of EFNB1 and EFNB2 in T cell development and function. In the project using EFNB1/B2 double knockout (dKO) model, we revealed a novel regulatory function of EFNb1 and EFNb2 in stabilizing IL-7Rα expression on the T cell surface. IL-7 plays important roles in thymocyte development, T cell homeostasis and survival. IL-7Rα undergoes internalization upon IL-7 binding. In the dKO mice, we observed reduced IL-7Rα expression in thymocytes and T cells. Moreover, the IL-7Rα internalization was accelerated in dKO CD4 cells upon IL-7 stimulation. In T cell lymphoma cell line, EL4, over-expression of either EFNB1 or EFNB2 retarded the internalization of IL-7Rα. We further demonstrated compromised IL-7 signaling and homeostatic proliferation of dKO T cells. Mechanism study using fluorescence resonance energy transfer and immunoprecipitation demonstrated that physical interaction of EFNB1 and EFNB2 with IL-7Rα was likely responsible for the retarded IL-7Rα internalization. In the last project, using medullary thymic epithelial cell (mTEC)-specific EphB4 knockout mice, we investigated T cell development and function after EphB4 deletion in mTEC. EphB4 KO mice demonstrated normal thymic weight and cellularity. T cell development and function were not influenced by the EphB4 deletion. Lastly, the KO mice developed normal delayed type hypersensitivity. Overall, our results suggest that comprehensive cross interaction between Eph and EFN family members could compensate function of a given deleted member in the T cell development, and only simultaneous deletion of multiple EFNBs will reveal their true function in the immune system. In fact, such redundancy signifies vital roles of Ephs and EFNs in the immune system. / Kinases Eph est la plus grande famille de tyrosines kinases récepteurs Éphrines (EFN) est un ligand de Ephs. Eph et EFN sont toutes les molécules de surface cellulaire. L’interaction entre Ephs et EFNs permet de transmettre des signaux dans les deux directions (c.-à-d. partir de Ephs à EFNs, et de EFNs à Ephs.) Eph et EFNs sont largement impliqués dans divers processus développementaux, physiologiques et physiopathologiques. Notre groupe et d'autres groupes ont rapporté les rôles de Ephs / EFNs dans le système immunitaire. Pour approfondir la fonction de EphBs / EFNBs dans le développement des lymphocytes T et des réponses immunitaires, nous avons généré des souris EFNB1, EFNB2, et EphB4 knock-out conditionnel (KO) et des souris EFNB1 / 2 doubles KO. Dans les projets qui utilisent EFNB1 et EFNB2 comme souris knock-out, nous avons spécifiquement supprimé EFNB1 ou EFNB2 dans les cellules T. Les souris présentaient une taille normale, la cellularité du thymus et de la rate, ainsi que des sous-populations de cellules T étaient normales dans ces organes. Les progéniteurs de la moelle osseuse de souris KO et les souris WT ont repeuplé les organes lymphoïdes de l’hôte à des degrés similaires. L'activation et la prolifération des cellules KO T étaient comparables à celles des souris témoins. Les cellules CD4 naïves KO différenciées en Th1, Th2, Th17 et Treg étaient similaires aux cellules CD4 naïves de souris contrôle. Chez les souris KO EFNB2, nous avons observé une augmentation relative importante des thymocytes CD4CD8 : les double négatifs dans le thymus. L'analyse par cytométrie en flux a révélé qu'il y avait une augmentation modérée de la sous-population DN3 dans le thymus. Les résultats suggèrent qu’EFNB2 est impliqué dans le développement des thymocytes. Nos résultats indiquent que les fonctions de EFNB1 et EFNB2 dans le compartiment des cellules T pourraient être compensées entre eux ou par d'autres EFNB. La redondance des fonctions suggèrent le contrôle critique d’EFNB1 et EFNB2 dans le développement des cellules T. Dans le projet, en utilisant EFNB1/B2 (modèle double KO) (dKO), nous avons observé une fonction de régulation de EFNB1 et EFNB2. dans la stabilisation de l’expression l'IL-7R α , à la surface des cellules T, IL-7 joue un rôle important dans le développement des thymocytes, l'homéostasie des lymphocytes T , et leur survie. IL-7R α subit une internalisation i contraignante de IL-7. Chez les souris DKO, nous avons observé une perte d’expression de l’ IL-7Rα dans les thymocytes et les cellules T. En outre, l’ internalisation IL-7Rα a été accélérée dans les cellules CD4 dKO, suite à la stimulation IL-7. Dans la lignée cellulaire de lymphome T, EL4, la surexpression de EFNB1 ou EFNB2 retarde l'internalisation de l'IL-7Rα. Nous avons aussi démontré les signalisations compromises de l’ IL-7 et de la prolifération homéostatique des cellules T dKO. Les études du méchanisme qui utilisent la fluorescence de transfert d'énergie par résonance et immunoprécipitation ont montré que l'interaction physique de EFNB1 et EFNB2 avec IL-7R était probablement responsable du retard de l’ internalisation IL-7Rα. Dans le dernier projet, nous avons étudié le développement des cellules T et la fonction des cellules épithéliales médullaires du thymus (mTEC), chez les souris knock-out EphB4. Les souris KO EphB4 ont démontré un poids et une cellularité qui sont normaux. La fonction et le développement de cellules T ne sont pas influencés par la suppression de l’ EphB4. Enfin, les souris KO ont développé une hypersensibilité de type retardée normale. Dans l'ensemble, nos résultats suggèrent que l'interaction globale de croisement entre Eph et les membres de la famille EFN pourrir compenser la fonction d'un membre supprimé. Seule la suppression simultanée de plusieurs EFNBs va révéler leur vraie fonction dans le système immunitaire. En fait, une telle redondance montre les rôles vitaux d’Ephs et EFNS dans le système immunitaire.

Eph

EFNB

Conditional gene knockout

T cell development

T cell function

IL-7Ra

Thymic epithelial cells

IL-7Rα

Délétion génique conditionnelle

Développementdes cellules T

Fonction des cellules T