Identification and characterization of Drosophila homolog of Rho-kinase

Mizuno, Tomoaki, Amano, Mutsuki, Kaibuchi, Kozo, Nishida, Yasuyoshi

01 October 1999

No description available.

Rho effector

actin cytoskeleton

morphogenesis

low stringency PCR

two-hybrid analysis

in vitro kinase assay

Genome Engineering Technology and Its Application in Mammalian Cells

Cong, Le

06 June 2014

The advancement of high-throughput, large-scale biochemical, biophysical, and genetic technologies has enabled the generation of massive amounts of biological data and allowed us to synthesize various types of biomaterial for engineering purposes. This enabled improved observational methodologies for us to navigate and locate, with unprecedented resolution, the potential factors and connections that may contribute to biological and biomedical processes. Nonetheless, it leaves us with the increasing demand to validate these observations to elucidate the actual causal mechanisms in biology and medicine. Due to the lack of powerful and precise tools to manipulate biological systems in mammalian cells, these efforts have not been able to progress at an adequate pace.

Biology

Molecular biology

Genetics

Bioengineering

Cas9

CRISPR

Genome Engineering

Molecular Biology

TAL effector

Regulation and Programming of Antibody Effector Function through IgG Glycosylation

Mahan, Alison Emilia

01 January 2015

Antibodies are the defining characteristic of the humoral immune response. Their functions are diverse, including direct neutralization of pathogens and recruitment of other immune molecules or cells. While most successful vaccines induce protective neutralizing antibody responses, effective vaccine-elicited neutralizing antibodies against some pathogens, including HIV, HCV, malaria, and TB, remain elusive. Thus, researchers have begun to focus on how vaccines can elicit strong non-neutralizing antibody functions, including recruitment of innate immune factors for antibody-dependent cellular cytotoxicity, complement deposition, and anti\-body-dependent phagocytosis. The antibody's constant region (Fc) mediates most effector functions through isotype and subclass selection or alteration of the structure of the Fc-attached N-glycan, which controls function with exquisite specificity. Glycan modifications are naturally induced during inflammatory conditions such as autoimmune disease and natural infection however, the specific signals that regulate Fc-glycosylation remain unknown. This dissertation sought to understand how antibody glycosylation is regulated and how it can be programmed through vaccination. To do this, we first developed a technique to analyze antibody glycan structures both of bulk Fc and antigen-specific antibodies. Using this technique, we observed significant modulation of antibody glycans during viral infection as well as in vaccine-elicited antibodies. To identify specific signals important for altering the antibody glycan, we transcriptionally profiled stimulated B cells and identified a set of innate and adaptive stimuli that regulate the genes responsible for antibody glycosylation. The results described in this dissertation begin to define the specific mechanism(s) by which infection and vaccination modulate antibody glycosylation to elicit functional antibodies that can ultimately provide effective and sustained protection from infection.

Biology

Immunology

Virology

effector function

Fc function

glycosylation

HIV

IgG

IgG-glycan

Directing cell migration by dynamic control of laminar streams

Moorjani, Samira Gian

03 February 2011

Interactions of cells with their chemical microenvironments are critical to many polarized processes, including differentiation, migration, and pathfinding. To investigate such cellular events, tools are required that can rapidly reshape the microscopic chemical landscapes presented to cultured cells. Existing chemical dosing technologies rely on use of pre-fabricated chemical gradients, thus offering static cell-reagent interactions. Such interactions are particularly limiting for studying migration and chemotaxis, during which cells undergo rapid changes in position, morphology, and intracellular signaling. This dissertation describes the use of laminar streams, containing cellular effector molecules, for precise delivery of effectors to selected subcellular regions. In this approach, cells are grown on an ultra-thin polymer membrane that serves as a barrier to an underlying reagent reservoir. By using a tightly-focused pulsed laser beam, micron-diameter pores can be ablated in the membrane upstream of desired subcellular dosing sites. Emerging through these pores are well-defined reagent streams, which dose the targeted regions. Multiple pores can be ablated to allow parallel delivery of effector molecules to an arbitrary number of targets. Importantly, both the directionality and the composition of the reagent streams can be changed on-the-fly under a second to present dynamically changing chemical signals to cells undergoing migration. These methods are applied to study the chemotactic responses of neutrophil precursor cells. The subcellular localization of the chemical signals emerging through pores is found to influence the morphological evolution of these motile cells as they polarize and migrate in response to rapidly altered effector gradients. / text

Microfluidics

Laminar streams

Neutrophil migration and chemotaxis

Chemical dosing

Chemical gradients

Laser-induced ablation

Laminar flow

Effector

Identification and Characterization of Pseudomonas syringae Type Three Effectors that Alter Auxin Responses.

Nievas, Maria Soledad

13 January 2014

Plant hormones act in a complex network where their pathways regulate and interact to control different mechanisms, such as development and stress responses. This crosstalk between hormones can be exploited by pathogens to suppress plant defense responses and thereby increase pathogen growth. Pseudomonas syringae pathogenicity is reliant on a Type III secretion system (TTSS) that acts as a specialized injection apparatus to deliver virulence proteins, known as type III effectors (TTEs), into the plant cell cytosol. In my work, I have screened hormone inducible promoter::GUS transgenic Arabidopsis thaliana lines against a P. syringae TTE library in order to identify TTEs involved in the perturbation of hormone signaling in planta. Through this screen I identified two P. syringae TTEs, HopAK1 and HopAL1, both belonging to the same bacterial strain P. syringae pv. maculicola ES4326. I found that HopAK1 can sensitize A. thaliana plants to auxin. On the other hand, HopAL1 activates auxin signaling. Monitoring of auxin signaling was done using transgenic DR5::GUS plants. Both TTEs render the plant susceptible to bacterial infection, highlighting a potential relationship between increased auxin signaling and virulence.

auxin

type three effector

plant hormones

Pseudomonas syringae

high-throughput screening

0480

Identification and Characterization of Pseudomonas syringae Type Three Effectors that Alter Auxin Responses.

Nievas, Maria Soledad

13 January 2014

Plant hormones act in a complex network where their pathways regulate and interact to control different mechanisms, such as development and stress responses. This crosstalk between hormones can be exploited by pathogens to suppress plant defense responses and thereby increase pathogen growth. Pseudomonas syringae pathogenicity is reliant on a Type III secretion system (TTSS) that acts as a specialized injection apparatus to deliver virulence proteins, known as type III effectors (TTEs), into the plant cell cytosol. In my work, I have screened hormone inducible promoter::GUS transgenic Arabidopsis thaliana lines against a P. syringae TTE library in order to identify TTEs involved in the perturbation of hormone signaling in planta. Through this screen I identified two P. syringae TTEs, HopAK1 and HopAL1, both belonging to the same bacterial strain P. syringae pv. maculicola ES4326. I found that HopAK1 can sensitize A. thaliana plants to auxin. On the other hand, HopAL1 activates auxin signaling. Monitoring of auxin signaling was done using transgenic DR5::GUS plants. Both TTEs render the plant susceptible to bacterial infection, highlighting a potential relationship between increased auxin signaling and virulence.

auxin

type three effector

plant hormones

Pseudomonas syringae

high-throughput screening

0480

Studies on Mechanisms of Skin Graft Rejection: Examination of Effector Cells and Molecules Required for Destruction of Epithelial Tumours

Mrs Rachel De Kluyver

Unknown Date

No description available.

Studies on Mechanisms of Skin Graft Rejection: Examination of Effector Cells and Molecules Required for Destruction of Epithelial Tumours

Mrs Rachel De Kluyver

Unknown Date

No description available.

Analyse fonctionnelle de trois effecteurs RXLR de l'oomycète Phytophthora parasitica sécrétés au cours de la pénétration de la plante hôte / Functional analysis of three RXLR effectors from the oomycete Phytophthora parasitica that are secreted during the penetration of host cells

Evangelisti, Édouard

29 November 2013

L'agriculture mondiale a connu de profonds changements qui lui ont permis de faire face à l'augmentation constante de la demande alimentaire. Cependant, les conséquences de ces nouvelles pratiques agricoles sur l'environnement et la santé humaine font l'objet de préoccupations croissantes. Notamment, les politiques sanitaires actuelles visent à réduire l'utilisation des produits phytosanitaires. Aussi de nouvelles stratégies de protection des cultures doivent-elles être développées. Une meilleure compréhension des échanges moléculaires qui contribuent au succès des bioagresseurs est nécessaire. Ces échanges impliquent notamment la sécrétion de protéines qui interfèrent avec le métabolisme de l'hôte : les effecteurs. Certains d'entre elles sont accumulés au cours de la pénétration des premières cellules végétales, une étape décisive pour le succès de la tentative d'infection. Les travaux menés au cours de cette thèse se sont concentrés sur 3 de ces effecteurs, sécrétés par l'oomycète Phytophthora parasitica. L'analyse des lignées de surexpression chez Arabidopsis thaliana a permis de mettre en évidence des perturbations du développement et de la physiologie de certaines hormones végétales en réponse à l'accumulation de ces effecteurs. Ces données confirment l'importance de la manipulation des voies hormonales dans le cadre des interactions plantes-pathogènes et soutiennent l'hypothèse récente selon laquelle des effecteurs sécrétés par les agents pathogènes interfèrent avec un petit nombre de cibles clefs du métabolisme de l'hôte. Ces cibles constituent des candidats de choix pour développer des variétés plus résistantes. / Agriculture has undergone deep changes that have allowed to cope with the ever-increasing demand for food. However, the consequences of the new agricultural practices on the environment and human health are the subject of increasing concern. Notably, current health policies aimed at reducing the use of pesticides in agriculture. Thus, new strategies need to be developed for efficient crop protection. In particular, a better understanding of molecular exchanges that contribute to the success of pathogens is required. These exchanges include the secretion of proteins that interfere with host metabolism : the effectors. Some of them are accumulated during the penetration of the first plant cells, a crucial step for the success of the infection attempt. This thesis work focused on three of these effectors, secreted by the oomycete Phytophthora parasitica. The analysis of transgenic Arabidopsis thaliana lines highlighted perturbations of plant development and hormone physiology in response to the accumulation of these effectors. These data confirm the pivotal role of hormonal balance during plant-pathogen interactions and support the recent hypothesis that effectors secreted by evolutionarily distant plant pathogens interfere with a small number of key target host metabolism. These targets are good candidates to develop varieties that are more resistant to infection.

Effecteur

RXLR

Phytophthora parasitica

Arabidopsis thaliana

Pénétration

Hormones

Effector

RXLR

Phytophthora parasitica

Arabidopsis thaliana

Penetration

Hormones

Enterobacterial type three secretion system effectors and their interference with host innate immunity

Wu, Miaomiao

January 1900

Doctor of Philosophy / Department of Diagnostic Medicine/Pathobiology / Philip R. Hardwidge / Microbial pathogens have evolved secretion systems to deliver arsenals of virulence proteins (effectors) to disrupt host homeostasis and manipulate host immune defenses. The best-characterized system mediating effector delivery into host cells is type III secretion system (T3SS) expressed by Gram-negative bacteria, including enteric pathogens enteropathogenic/enterohemorrhagic Escherichia coli (EPEC/EHEC), Shigella, Yersinia, and Salmonella. Pathogen-host cell protein interactions within the host cell alter host cell signaling and ultimately subvert pathogen-induced inflammatory response. In the first project, we identified the Salmonella Secreted Effector L (SseL) that deubiquitinated ribosomal protein S3 (RPS3) to inhibit its nuclear translocation. RPS3 guides the nuclear factor kappa-light-chain-enhancer of activated B cells (NF-B) subunits to specific B sites and plays an important role in the innate response to bacterial infection. Two E. coli effectors block RPS3 nuclear translocation. Non-locus-of-enterocyte-effacement (non-LEE) encoded effector NleH1 inhibits RPS3 phosphorylation by IKK-, an essential aspect of the RPS3 nuclear translocation process. NleC proteolysis of p65 generates an N-terminal p65 fragment that competes for full-length p65 binding to RPS3, thus also inhibiting RPS3 nuclear translocation. Thus, E. coli has multiple mechanisms by which to block RPS3-mediated transcriptional activation. With this in mind, we considered whether other enteric pathogens also encode T3SS effectors that impact this important host regulatory pathway. In this study, we report that SseL, which was previously shown to function as a deubiquitinase and inhibit NF-B signaling, also inhibits RPS3 nuclear translocation by deubiquitinating this important host transcriptional co-factor. RPS3 deubiquitination by SseL was restricted to K63-linkages and mutating the active-site cysteine of SseL abolished its ability to deubiquitinate and subsequently inhibit RPS3 nuclear translocation. Thus, Salmonella also encodes at least one T3SS effector that impacts RPS3 activities in the host nucleus. In the second project, we attempted to identify a cofactor involved in the interaction between E. coli effector NleH1 and host kinase the IB kinase- (IKK). The EHEC NleH1 effector inhibits NF-B pathway by reducing the nuclear translocation of RPS3. NleH1 prevents RPS3 phosphorylation by IKKIKK is a central kinase in the NF-B signaling pathway, yet the EHEC NleH1 effector only restricts the phosphorylation of a subset of the IKK substrates. We hypothesized that a protein cofactor might dictate the inhibitory specificity of NleH1 on IKK. We used mass spectrometry and determined that heat shock protein 90 (Hsp90) interacts with both NleH1 and IKK, and that inhibiting Hsp90 activity reduces RPS3 nuclear translocation. In the third project, we focused on the crystal structures of Salmonella secreted effector SseK1 and SseK2 from Salmonella typhimurium SL1344, and non-LEE encoded effector NleB2 from E. coli O145:H28 and propose catalytic residues for arginine glycosylation. Salmonella SseK1 and SseK2 are E. coli NleB1 orthologs that behave as NleB1-like glycosyltransferases, although they differ in protein substrate specificity. The bacterial effectors SseK and NleB1 glycosylate host cell death domain target proteins on arginine residues that inhibits death receptor signaling. We report crystal structures of SseK1, SseK2, and NleB2 and found they are highly similar to each other and comprises three domains including helix-loop-helix (HLH), lid, and catalytic domain. His-Glu-Asn (HEN) motif in the active site is essential for enzyme catalysis. We observe differences between SseK1 and SseK2 in interactions with substrates and identify substrate residues that are important for enzyme recognition.

pathogen

type three secretion system

effector

NF-kB

RPS3

SseL

Hsp90