Mechanisms Regulating Survival of Effector and Memory CD8+ T Cells

Kurtulus, Sema

24 September 2013

No description available.

Immunology

CD8+ T cell

Bim

Bcl-2

effector T cell

memory T cell

apoptosis

Design and Analysis of End-Effector Systems for Scribing on Silicon

Cannon, Bennion Rhead

06 August 2003

This thesis investigates end-effector systems used in a chemomechanical scribing process. Chemomechanical scribing is a method of patterning silicon to selectively deposit a monolayer of material on the surface of the silicon. This thesis details the development of a unique end-effector for chemomechanical scribing using a compliant mechanism solution. The end-effector is developed to scribe lines that have uniform geometry and produce less chipping on the surface of the silicon. The resulting scribing mechanism is passively controlled, has high lateral stiffness, and low axial stiffness. The mechanism is analyzed using the pseudo-rigid-body model and linear-elastic beam method to determine the axial stiffness, finite element methods to determine the lateral stiffness, and fatigue analysis to determine mechanism cycle life. This thesis also investigates the significance of mechanical factors on the chemomechanical scribing process using the compliant end-effector. The factors examined are scribing force, scribing speed, tip geometry, wafer orientation, and wetting liquid. The factors are analyzed using a two-step approach: first, an analysis of the influence of the mechanical factors on line characteristics and second, an analysis of the influence of line characteristics on line performance.

chemomechanical

chemomechanical machining

end-effector

silicon machining

compliant mechanisms

scribing

Mechanical Engineering

MODULATION OF HOST ACTIN CYTOSKELETON BY THE LEGIONELLA EFFECTOR RAVJ

Yan Liu (14184635)

06 December 2022

<p>The actin cytoskeleton is involved in many essential cellular events such as mitosis, cell migration, control of epithelial barrier function, and adherence of immune cells. Given the essential roles of the actin cytoskeleton, it is not surprising that it is a common target for bacterial virulence factors. <em>Legionella pneumophila</em>, the causative agent of Legionnaire’s pneumonia, establishes a replicative compartment using effectors secreted by its Dot/Icm secretion system. At least four Dot/Icm effectors, VipA, Ceg14, LegK2 and RavK have been shown to modulate the host actin cytoskeleton. Here, we identified RavJ (lpg0944) as an additional effector that interferes with the actin cytoskeleton in mammalian cells. We demonstrated that RavJ is a transglutaminase that functions to induce crosslink between actin and members of the Motin protein family, leading to inhibition of the binding between actin and ADF/cofilin. We also found that LegL1 (lpg0945) is a metaeffector of RavJ, which suppresses the transglutaminase activity of RavJ by blocking its enzymatic domain. </p>

Infectious agents

Actin cytoskeleton modulation

effector proteins

Legionella pneumophila Dot/Icm

AMOT Proteins

Studies on host specificity of the cucurbit anthracnose pathogen Colletotrichum orbiculare via comparative analyses with closely related pathogens / 近縁菌との比較解析によるウリ類炭疽病菌の宿主特異性に関する研究

Ogawa, Taiki

23 March 2023

京都大学 / 新制・課程博士 / 博士(農学) / 甲第24674号 / 農博第2557号 / 新制||農||1099(附属図書館) / 学位論文||R5||N5455(農学部図書室) / 京都大学大学院農学研究科応用生物科学専攻 / (主査)教授 髙野 義孝, 教授 寺内 良平, 教授 吉田 健太郎 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DGAM

Colletotrichum orbiculare

Comparative study

Host specificity

Phytopathogenic fungi

Virulence effector

610

ROLES OF TYPE IV SECRETION EFFECTOR ECH0825 IN EHRLICHIA CHAFFEENSIS INFECTION

Liu, Hongyan

January 2013

No description available.

Cellular Biology

Microbiology

Molecular Biology

EHRLICHIA CHAFFEENSIS

TYPE IV SECRETION EFFECTOR

ECH0825

The Bacterial AvrE-Family Type-III Effector Proteins Modulate Plant Immunity via Targeting Plant Protein Phosphatase 2A Complexes

Jin, Lin

07 September 2016

No description available.

Plant Pathology

Molecular Biology

FUNCTIONAL GENOMICS OF PANTOEA STEWARTII SUBSP. STEWARTII AND PARTIAL GENOME SEQUENCE OF THE MAIZE STOLBUR PHYTOPLASMA SOLANI, TWO INSECT-TRANSMITTED BACTERIAL PATHOGENS OF MAIZE

Correa, Valdir Ribeiro, Mr.

17 December 2010

No description available.

Plant Pathology

T3SS

effector proteins

Pantoea stewartii

insect vector

colonization

maize stolbur

Illumina

genome sequencing.

Effector Th1 cells demonstrate self-regulation in a mouse model of Multiple Sclerosis

Huss, David J.

21 July 2011

No description available.

Immunology

Immune regulation

effector-memory T cell

EAE

MS

TGF-beta

IL-10

STRUCTURAL AND BIOCHEMICAL CHARACTERIZATION OF THE CHLAMYDIA PNEUMONIAE TYPE III SECRETION SYSTEM

Stone, Christopher B.

04 1900

<p><em>Chlamydia pneumoniae</em> is a Gram-negative intracellular pathogen that uses type III secretion to invade and survive within eukaryotic cells. The T3SS secretes specific effector proteins during the infection process to facilitate immune evasion and nutrient acquisition. Unfortunately, the genetic intractability and difficult culturing conditions of Chlamydiae has inhibited progress in the chlamydial T3S field. This thesis characterizes fundamental aspects of the <em>C. pneumoniae </em>injectisome such as the ATPase, the inner-membrane export apparatus, and a specific effector protein Cpn0803. Initially, we explored whether <em>C. pneumoniae</em> encodes a functional T3S ATPase and if it associates with other T3S components. We found that CdsN has enzymatic activity consistent with other Gram-negative T3S ATPases, and that CdsN associates with inner-membrane and soluble components such as CdsD, CdsQ, CopN and CdsL. We also found that CdsN has binding surfaces for either structural or putative effector / chaperone T3S proteins. Next, we explored the putative flagellar genes, which were of interest since <em>Chlamydia</em> is a non-motile bacteria that lacks flagellum. We found that the flagellar proteins associate with the T3S apparatus, suggesting that they play a role in T3S during the life-cycle. We extended this observation to show that CdsL, a T3S component, down-regulates both CdsN and FliI enzymatic activity, suggesting that the flagellar proteins are involved in T3S. Furthermore, we characterized Cpn0803 as an exemplary effector, which associates with both CdsN and FliI. We found that Cpn0803 is secreted into host cells upon<em> Chlamydia</em> infection. Cpn0803 was thought to be the T3S needle-tip protein; however, the crystal structure does not support this hypothesis. Presently, the actual role of Cpn0803 in the T3S apparatus remains unknown. Overall, our data suggests that CdsN and FliI both function during the chlamydial life-cycle in the T3S process, possibly coordinating effector proteins (such as Cpn0803) for secretion into host cells.</p> / Doctor of Philosophy (PhD)

type III secretion

chlamydia

ATPase

effector

needle-tip

chaperone

Bacteria

Biochemistry

Structural Biology

Bacteria

Maize R gene Rxo1 Confers Disease Resistance on Pepper and Nicotiana benthamiana

Li, Qi

03 March 2023

Pepper is a popular and important vegetable crop grown and consumed worldwide. However, pepper production is threatened by the gram-negative bacterium Xanthomonas euvesicatoria (Xe) which causes bacterial spot (BS) disease, one of the most common and destructive diseases on pepper. Due to limited genetic resistance resources in host species, a promising strategy for controlling BS disease is to transfer nonhost disease resistance (R) genes from other plant species into pepper plants to confer broad-spectrum and durable resistance. A maize R gene Rxo1 has been functionally transferred to rice plants and confers nonhost resistance to rice pathogen Xanthomonas oryzae pv. oryzicola (Xoc) carrying a type III effector (T3E) AvrRxo1. Most Xe strains carry a T3E Xe4428, a homolog of AvrRxo1. Therefore, Rxo1 could be potentially employed to develop Xe-resistant pepper. In addition, a better understanding of the virulence function of Xe4428 may provide insights into the pathogenesis of Xe and new strategies for crop improvement. In this dissertation, we transformed Rxo1 into the far-related dicot species Nicotiana benthamiana and pepper, and characterized the Rxo1-mediated disease resistance against Xe strains carrying AvrRxo1 or Xe4428. In addition, we explored the virulence function and mechanism of Xe4428. In the Rxo1-transgenic N. benthamiana, we demonstrated that Rxo1 could condition resistance to Xe harboring AvrRxo1 but not Xe4428. We revealed that AvrRxo1 could directly interact with the nucleotide-binding domain of Rxo1 in vivo and in vitro. We further demonstrated that the nucleus localization of AvrRxo1 was required for its avirulence and virulence functions. In addition, the cytosol localization of Rxo1 was also necessary to confer disease resistance. The downstream signaling component NbNDR1 was demonstrated to be involved in Rxo1/AvrRxo1-mediated disease resistance. By RNAseq-based gene expression profiling, we identified six candidate genes of interest up-regulated by the Rxo1-AvrRxo1 recognition. Through virus-induced gene silencing screening, a gene encoding phenylalanine ammonia-lyase 4 was demonstrated to be critical for Rxo1/AvrRxo1-mediated disease resistance in N. benthamiana. Rxo1-transgenic pepper plants were resistant to the Xe strain with the complementary Xoc effector AvrRxo1 but not the wild-type Xe strain that carries Xe4428. A Xe4428 mutant with only one nucleotide substitution could trigger the Rxo1-mediated disease resistance in pepper. Both wild-type and mutant Xe4428 had significant virulence functions that could promote the Xe bacterial proliferation on wild-type pepper plants. In addition, the mutant Xe4428 had a higher expression level than wild-type Xe4428 in Xe bacterial cells, which might explain why the mutant Xe4428 but not wild-type Xe4428, could trigger the Rxo1-mediated disease resistance in pepper. We identified 14 pepper cystatin genes (CaCys), among which two genes (CaCys1 and CaCys13) could be induced, and two genes (CaCys3 and CaCys5) were suppressed by Xe4428. Ectopically expressing one of the induced genes CaCys1 in N. benthamiana increased the stomatal opening and promoted the Xe growth in N. benthamiana plants. Thus, we illuminate one possible mechanism of Xe4428's virulence function is to regulate the stomata apertures in N. benthamiana. Bacterial fruit blotch (BFB) caused by the gram-negative bacterial pathogen Acidovorax citrulli (A. citrulli) is one of the most destructive diseases in cucurbit crops, including melon and watermelon. A better understanding of the virulence and avirulence functions of T3Es in A. citrulli helps breeders engineer crop resistance to BFB. To this end, a clean genetic background of A. citrulli with multiple effector genes deleted is desired. Here, we optimized a marker-exchange-based method for sequential effector deletion and generated an AAC00-1 mutant with five effector genes (Aave2166, Aave3626, Aave1548, Aave2938, Aave2708) deleted (AAC00-15). AAC00-15 was less virulent in watermelon but more virulent in N. benthamiana. Through complementation, we characterized the function of individual effectors and identified a promising R gene, Roq1, that could be used to control BFB disease. / Doctor of Philosophy / As an essential ingredient in almost all cuisines, pepper is grown and consumed worldwide, providing human beings with favorable flavor and nutrients. However, pepper production is threatened by the destructive bacterial spot (BS) disease caused by the bacterial pathogen Xanthomonas euvesicatoria (Xe). Due to limited genetic resistance resources in host species, nonhost resistance (R) genes from other plant species are desired to confer broad-spectrum and durable resistance to the pepper pathogen Xe. Previously, a maize (corn) R gene called Rxo1 was transferred to rice plants. This gene helped these rice plants resist a rice bacterial pathogen that causes leaf streak disease on rice. This rice pathogen has an effector (a virulent protein produced by bacteria to infect plants) that is required for the disease resistance. The pepper pathogen carries a similar effector, so transferring the maize R gene Rxo1 to pepper plants might similarly benefit peppers and help fight against the bacterial spot disease. In this dissertation, we successfully transferred the maize R gene Rxo1 into Nicotiana benthamiana and pepper plants. Our results indicate that this gene can help control disease caused by the pepper pathogen harboring the effector of the rice pathogen but not its native effector. We also illuminate how the disease resistance conferred by this maize gene happens in Nicotiana benthamiana plants. In addition, we explain how the corresponding effector helps infect plants. This research provides insights into the application of R gene transfer between far-related plant species and new tools to improve crop disease resistance.

Xanthomonas euvesicatoria

Rxo1

AvrRxo1

Xe4428

inter-species R gene transfer

Type III effector functions