Discovery Of Intracellular Growth Requirements of the Fungal Pathogen <i>Histoplasma capsulatum</i>

Zemska, Olga

28 August 2012

No description available.

Genetics

Microbiology

Molecular Biology

Parasitology

Histoplasma capsulatum

fungal pathogen

insertional mutagenesis

intramacrophage replication

HSP82

de novo vitamin biosynthesis

riboflavin

folate

antifungal drug therapy

FTIR-spektroskopische Untersuchungen am Phytochrom Agp2

Piwowarski, Patrick

18 May 2017

In der vorliegenden Arbeit wurde der lichtinduzierte Reaktionszyklus des bakteriellen Phytochroms Agp2 aus Agrobacterium tumefaciens mit FTIR‑ und UV‑Vis‑Spektroskopie untersucht. Der Photorezeptor besteht aus einem photosensorischen Modul und einer signalgebenden Histidin-Kinase-Domäne. Das photosensorische Modul bindet das Tetrapyrrol Biliverdin als Chromophor. Der Grundzustand von Agp2 (Pfr, 750 nm) ist gegenüber dem lichtaktivierten Zustand (Pr, 700 nm) rotverschoben, weshalb Agp2 den Bathyphytochromen zugeordnet wird. Die Untersuchungen erfolgten unter Verwendung von Isotopenmarkierung, H/D-Austauschexperimenten und ortsspezifischer Mutagenese. Daraus ließen sich folgende molekulare Änderungen charakterisieren, welche im Reaktionszyklus von Agp2 erfolgen: Die lichtinduzierte Isomerisierung des Chromophors führt zu einem Übergang vom Pfr- in den Pr-Zustand, wobei zwei Intermediate, Lumi‑F und Meta‑F, durchlaufen werden. Neben der Konformationsänderung des Chromophor‑D‑Rings ist auch die C‑Ring-Propionsäureseitenkette an der Photoreaktion beteiligt. Die C-Ring-Propionsäureseitenkette ist im Pfr-Zustand protoniert und wird im Übergang von Meta-F zu Pr deprotoniert. Der Pr-Zustand weist eine pH-Abhängigkeit auf, welche auf die pH-abhängige Ladung des Histidins 278 der Chromophortasche zurückzuführen ist. Je nach Ladung des Histidins 278 wird die Keto‑ bzw. Enolform der C(19)=O‑Gruppe des D‑Rings stabilisiert. Die Keto/Enol-Tautomerie ist auf eine innerhalb des Chromophors erfolgende Protontranslokation zurückzuführen und moduliert die Relaxation in den Pfr-Zustand. Änderungen der Amid-I-Absorption im Pfr-Pr-Übergang werden der Umstrukturierung der Tongue-Region des photosensorischen Moduls von einer Alpha-helikalen zu einer Beta‑Faltblatt-Struktur zugeordnet. Diese Strukturänderung wird als möglicher Weg der proteininternen Signaltransduktion zwischen photosensorischem und signalgebendem Modul vorgeschlagen. / In this thesis the light-induced reaction cycle of the bacterial phytochrome Agp2 from Agrobacterium tumefaciens was investigated using FTIR and UV‑vis spectroscopy. The photoreceptor comprises a photosensitive module and a signalling histidine kinase domain. The photosensitive module binds the biliverdin tetrapyrrol as chromophore. The Agp2 ground state (Pfr, 750 nm) is red-shifted in comparison with its light-activated state (Pr, 700 nm). Therefore, Agp2 is assigned to the group of bathy phytochromes. The investigations were conducted using isotopically labelled protein, labelled chromophore as well as hydrogen‑deuterium (H‑D) exchange and site-directed mutagenesis. Based on these the following molecular changes could be characterized that occur in the reaction cycle of Agp2: The light-induced isomerization of the chromophore leads to a transition from the Pfr to the Pr state, involving two intermediates, Lumi-F and Meta-F. Besides conformational changes of the chromophore D-ring, the C-ring propionic side chain is involved in the photoreaction as well. The C-ring propionic side chain is protonated in the Pfr state and gets deprotonated in the Meta-F to Pr transition. The Pr state exhibits pH‑dependent alterations which can be explained by pH dependent polarity changes of histidine 278 in the chromophore pocket. Depending on the charge of histidine, the D‑ring C(19)=O group is stabilized either in keto or enol form. The keto/enol tautomerism involves a proton translocation within the chromophore and modulates the relaxation to the Pfr state. The changes in the amide I region in the Pfr-Pr transition are associated with an alpha‑helix to beta‑sheet secondary structure change of the PHY domain tongue‑region. This structural change is proposed as the potential path of signal transduction between the photosensitive and the signalling module.

FTIR-Spektroskopie

UV/Vis-Spektroskopie

ortsspezische Mutagenese

Agp2

Phytochrom

Bathyphytochrom

Photozyklus

Isotopenmarkierung

Histidin

Agrobacterium tumefaciens

UV/Vis-spectroscopy

site-directed mutagenesis

Agp2

FTIR-spectroscopy

phytochrome

bathy phytochrome

photo cycle

isotopic labelling

Histidine

Agrobacterium tumefaciens

570 Biowissenschaften, Biologie

32 Biologie

WD 5380

WD 2800

WF 5200

ddc:570

Molecular cloning of the soybean phototropins

Roy, Pallabi

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / The phototropin photoreceptors are important regulators of plant growth and development and can therefore affect the photosynthetic activity of plants. Phototropin1 and Phototropin2 are versatile protein kinases that become activated when exposed to blue light. Their photobiological actions are best understood in the model plant Arabidopsis thaliana, where they are known to trigger several responses to blue light, one of which is phototropism, the bending of plant organs towards light. Additionally, phot1 and phot2 drive stomatal opening, chloroplast arrangement in leaf cells, leaf expansion, and leaf orientation. The phot1-specific response is rapid inhibition of hypocotyl growth, leaf positioning and mRNA stability whereas phot2 mediates the chloroplast avoidance response to high light. These responses impact a plant’s ability to capture light for photosynthesis, therefore the phototropins play important roles in optimizing a plant’s photosynthetic activity. Soybean (Glycine max) is a very important crop plant in Indiana known for its nutritional versatility and is also utilized for biodiesel production.In spite of soybean being a key crop, there is currently no information about the functionality of soybean phototropins. Also, being a legume, soybean has many structural and functional features that are not present in Arabidopsis. Interestingly, PsPHOT1A (a photoreceptor from garden pea) was found to be a functional phototropin as it was able to complement the phot1 mutation in Arabidopsis. The roles of these proteins in soybean will be elucidated based on the hypothesis that soybean phototropins play essential roles in regulating photosynthetic activity as do the Arabidopsis phototropins. To date, five soybean phototropins, 3 PHOT1s and 2 PHOT2s, are believed to exist. These GmPHOT protein coding regions were amplified by RT-PCR and cloned into pCR8/TOPO or pENTR-D/TOPO vectors via TOPO cloning to utilize Gateway cloning technology to create plant transformation constructs subsequently. The cloned GmPHOT cDNAs from each of the 5 GmPHOTs were sequenced and compared to the GmPHOT sequences from the Phytozome database to assess the accuracy of the gene models. The gene models of all the GmPHOTs were found to be accurate except that of GmPHOT1B-2. The high level of sequence identity between the GmPHOTs and AtPHOTs and the conservation of LOV domains and catalytic domains indicate structural resemblance between them. This suggests that soybean phototropins should encode active photoreceptors. The cloned protein coding regions from soybean were then recombined into a plant expression vector via Gateway technology,which were then used for transformation of Agrobacterium tumefaciens. These plant expression constructs will be utilized in the future to determine the functionality of soybean phototropins in Arabidopsis.

Plants -- Photomorphogenesis -- Research

Plants -- Effect of light on

Growth (Plants) -- Molecular aspects

Photosynthesis

Plant photoreceptors

Plant regulators -- Analysis

Plants -- Effect of blue light on

Blue light -- Physiological effect

Soybean -- Biotechnology -- Methodology

Soybean -- Indiana

Arabidopsis -- Molecular aspects

Agrobacterium tumefaciens -- Research

Biocatalysis -- Research -- Methodology

Phototropism -- Research

Molecular cloning -- Research

Biotechnology -- Research

Transformação genética de cana-de-açúcar por biolística e Agrobacterium tumefaciens visando estudar o mecanismo de morte celular programada / Genetic transformation of sugarcane by biolistic and Agrobacterium tumefaciens to study the mechanism of programmed cell death

Melotto-Passarin, Danila Montewka

08 April 2009

A cana-de-açúcar é uma das principais culturas agrícolas plantadas no Brasil e apresenta significativa importância sócio-econômica e agroindustrial ao país. O cenário mundial encontrase bastante favorável no que concerne à comercialização de seus dois principais produtos derivados, o açúcar e o álcool, impulsionando o desenvolvimento do setor sucroalcooleiro nacional. Neste sentido, o melhoramento genético da cana-de-açúcar aparece como base fundamental para o desenvolvimento de novas variedades para a manutenção e incremento dos agronegócios da agroindústria sucroalcooleira. Técnicas de engenharia genética, como a transformação genética nuclear, estão trazendo excelentes resultados no melhoramento genético da cultura, permitindo diminuir o custo e o tempo de obtenção de novas variedades. Baseando-se na importância em se obter variedades tolerantes a diferentes estresses bióticos e abióticos que induzem perturbações metabólicas e ativam o processo de morte celular programada, o presente trabalho teve por objetivo transformar geneticamente a variedade de cana-de-açúcar RB835089 com o cDNA do gene AtBI-1 isolado de Arabidopsis thaliana, visando suprimir a indução do mecanismo de morte celular sob condição de estresse. Para isto, calos embriogênicos foram utilizados como explante alvo, empregando-se dois métodos de transformação, a cotransformação por biolística, e o mediado por Agrobacterium tumefaciens no qual foram testadas duas técnicas: (a) inoculação direta dos calos em suspensão bacteriana; e (b) agrobiolística que é o bombardeamento dos calos com partículas de tungstênio seguido da inoculação em suspensão bacteriana. A proteína AtBI-1 (Bax inhibitor-1) apresenta homólogos em outros organismos e está localizada na membrana do retículo endoplasmático. Ela apresenta funções citoprotetoras modulando o mecanismo de morte celular programada induzida por estresses bióticos e abióticos. Como resultados deste trabalho, diferentes taxas de eficiência da transformação genética foram obtidas pelo método mediado por A. tumefaciens nas duas técnicas testadas, sendo que suas taxas foram superiores às alcançadas pelo método de co-transformação por biolística. A expressão heteróloga do cDNA do gene AtBI-1 em cana-de-açúcar atenuou a indução das vias de morte celular em presença do antibiótico tunicamicina, indutor do estresse no retículo endoplasmático, sendo comprovado pela maior tolerância ao estresse das plantas transgênicas quando comparadas com as plantas não transformadas que foram afetas no crescimento do sistema radicular, conteúdo de clorofila total, apresentando sintomas típicos de morte celular programada como clorose foliar e morfologia irregular das raízes, com consequente morte do sistema radicular. / Sugarcane is one of the main crops planted in Brazil and presents significant socioeconomic and agribusiness importance to the country. The world scene is quite favorable as regards the marketing of its two main products, sugar and alcohol, driving the development of the national sugar-alcohol sector. Therefore, the sugarcane genetic breeding appears as the fundamental base for developing new varieties for the maintenance and increase of agribusiness in the sugarcane agroindustry. Genetic engineering techniques, such as the nuclear genetic transformation, are providing excellent results in genetic breeding of this crop allowing reducing the cost and time to obtain new varieties. Based on the importance of obtaining varieties tolerant to different biotic and abiotic stresses that induce metabolic disturbances and activate the process of programmed cell death, this work aimed to transform sugarcane variety RB835089 with the cDNA of AtBI-1 gene, isolated from Arabidopsis thaliana, to suppress the induction of the cell death mechanism under stress condition. For this, embryogenic calli were used as target explant, by using two methods of transformation, the cotransformation by biolistic, and mediated by Agrobacterium tumefaciens in which two techniques were tested: (a) direct inoculation of calli in bacterial suspension; (b) agrobiolistic which is the bombardment of calli with tungstein particles followed by inoculation in bacterial suspension. The AtBI-1 protein (Bax inhibitor-1) presents homologs in other organisms and is located in the endoplasmic reticulum membranes. It has cytoprotective functions by modulating the mechanism of programmed cell death induced by biotic and abiotic stresses. As results of this work, different efficiency rates in genetic transformation were obtained in the method mediated by A. tumefaciens in the two techniques tested, and that their rates were higher than those achieved using the cotransformation by biolistic. The heterologous expression of cDNA of AtBI-1 gene in sugarcane attenuated the induction of cell death pathways in the presence of tunicamycin antibiotic, an inducer of stress in the endoplasmic reticulum, being proven by the increased stress tolerance of transgenic plants compared with sugarcane wild type that were affected in the root growth, total chlorophyll content, showing typical symptoms of programmed cell death such as leaf chlorosis and irregular morphology of the roots, with subsequent death of the root system.

Abiotic stress

Agrobacterium tumefaciens

AtBI-1 gene

Bactérias gram-negativas

biolistic

Biolística

Biologia molecular vegetal

Cana-de-açúcar

Genetic transformation

Genética molecular vegetal

Programmed cell death

Sugarcane

Tunicamycin antibiotic.

Variação genética em plantas.

Analyse du rôle de l’interaction de VirB6 avec VirB10 dans le système de sécrétion de type IV

Mary, Charline

04 1900

No description available.

Agrobacterium tumefaciens

Système de sécrétion de type IV

Interaction protéine-protéine

Protéines membranaires

VirB6

VirB10

Fonctionnalité

Virulence

Type IV secretion system

Protein-protein interaction

Membranes proteins

Functionality

Transformação genética de cana-de-açúcar por biolística e Agrobacterium tumefaciens visando estudar o mecanismo de morte celular programada / Genetic transformation of sugarcane by biolistic and Agrobacterium tumefaciens to study the mechanism of programmed cell death

Danila Montewka Melotto-Passarin

08 April 2009

A cana-de-açúcar é uma das principais culturas agrícolas plantadas no Brasil e apresenta significativa importância sócio-econômica e agroindustrial ao país. O cenário mundial encontrase bastante favorável no que concerne à comercialização de seus dois principais produtos derivados, o açúcar e o álcool, impulsionando o desenvolvimento do setor sucroalcooleiro nacional. Neste sentido, o melhoramento genético da cana-de-açúcar aparece como base fundamental para o desenvolvimento de novas variedades para a manutenção e incremento dos agronegócios da agroindústria sucroalcooleira. Técnicas de engenharia genética, como a transformação genética nuclear, estão trazendo excelentes resultados no melhoramento genético da cultura, permitindo diminuir o custo e o tempo de obtenção de novas variedades. Baseando-se na importância em se obter variedades tolerantes a diferentes estresses bióticos e abióticos que induzem perturbações metabólicas e ativam o processo de morte celular programada, o presente trabalho teve por objetivo transformar geneticamente a variedade de cana-de-açúcar RB835089 com o cDNA do gene AtBI-1 isolado de Arabidopsis thaliana, visando suprimir a indução do mecanismo de morte celular sob condição de estresse. Para isto, calos embriogênicos foram utilizados como explante alvo, empregando-se dois métodos de transformação, a cotransformação por biolística, e o mediado por Agrobacterium tumefaciens no qual foram testadas duas técnicas: (a) inoculação direta dos calos em suspensão bacteriana; e (b) agrobiolística que é o bombardeamento dos calos com partículas de tungstênio seguido da inoculação em suspensão bacteriana. A proteína AtBI-1 (Bax inhibitor-1) apresenta homólogos em outros organismos e está localizada na membrana do retículo endoplasmático. Ela apresenta funções citoprotetoras modulando o mecanismo de morte celular programada induzida por estresses bióticos e abióticos. Como resultados deste trabalho, diferentes taxas de eficiência da transformação genética foram obtidas pelo método mediado por A. tumefaciens nas duas técnicas testadas, sendo que suas taxas foram superiores às alcançadas pelo método de co-transformação por biolística. A expressão heteróloga do cDNA do gene AtBI-1 em cana-de-açúcar atenuou a indução das vias de morte celular em presença do antibiótico tunicamicina, indutor do estresse no retículo endoplasmático, sendo comprovado pela maior tolerância ao estresse das plantas transgênicas quando comparadas com as plantas não transformadas que foram afetas no crescimento do sistema radicular, conteúdo de clorofila total, apresentando sintomas típicos de morte celular programada como clorose foliar e morfologia irregular das raízes, com consequente morte do sistema radicular. / Sugarcane is one of the main crops planted in Brazil and presents significant socioeconomic and agribusiness importance to the country. The world scene is quite favorable as regards the marketing of its two main products, sugar and alcohol, driving the development of the national sugar-alcohol sector. Therefore, the sugarcane genetic breeding appears as the fundamental base for developing new varieties for the maintenance and increase of agribusiness in the sugarcane agroindustry. Genetic engineering techniques, such as the nuclear genetic transformation, are providing excellent results in genetic breeding of this crop allowing reducing the cost and time to obtain new varieties. Based on the importance of obtaining varieties tolerant to different biotic and abiotic stresses that induce metabolic disturbances and activate the process of programmed cell death, this work aimed to transform sugarcane variety RB835089 with the cDNA of AtBI-1 gene, isolated from Arabidopsis thaliana, to suppress the induction of the cell death mechanism under stress condition. For this, embryogenic calli were used as target explant, by using two methods of transformation, the cotransformation by biolistic, and mediated by Agrobacterium tumefaciens in which two techniques were tested: (a) direct inoculation of calli in bacterial suspension; (b) agrobiolistic which is the bombardment of calli with tungstein particles followed by inoculation in bacterial suspension. The AtBI-1 protein (Bax inhibitor-1) presents homologs in other organisms and is located in the endoplasmic reticulum membranes. It has cytoprotective functions by modulating the mechanism of programmed cell death induced by biotic and abiotic stresses. As results of this work, different efficiency rates in genetic transformation were obtained in the method mediated by A. tumefaciens in the two techniques tested, and that their rates were higher than those achieved using the cotransformation by biolistic. The heterologous expression of cDNA of AtBI-1 gene in sugarcane attenuated the induction of cell death pathways in the presence of tunicamycin antibiotic, an inducer of stress in the endoplasmic reticulum, being proven by the increased stress tolerance of transgenic plants compared with sugarcane wild type that were affected in the root growth, total chlorophyll content, showing typical symptoms of programmed cell death such as leaf chlorosis and irregular morphology of the roots, with subsequent death of the root system.

Bactérias gram-negativas

Biolística

Biologia molecular vegetal

Cana-de-açúcar

Genética molecular vegetal

Variação genética em plantas.

Abiotic stress

Agrobacterium tumefaciens

AtBI-1 gene

biolistic

Genetic transformation

Programmed cell death

Sugarcane

Tunicamycin antibiotic.

Estudio de los factores de patogenicidad/virulencia de Penicillium digitatum sobre frutos cítricos

López Pérez, Mario

02 December 2013

Las pérdidas causadas por podredumbres durante la post-cosecha de frutos cítricos suelen suponer entre un 5 y un 10 % de la producción, siendo Penicillium digitatum el principal hongo patógeno, responsable de hasta el 80 % de las pérdidas causadas por podredumbres en frutos almacenados a temperatura ambiente. A pesar de la importancia económica de este patógeno nuestro conocimiento sobre los mecanismos de patogenicidad/ virulencia son muy escasos, en contraste con el avance experimentado en los últimos años en el conocimiento de las respuestas de defensa del fruto a la infección por este patógeno. Así, en el grupo de Fisiología y Biotecnología Postcosecha del IATA se está trabajando en la caracterización a nivel bioquímico y molecular de las respuestas de los frutos cítricos frente a la infección por P. digitatum y en el proceso de inducción de resistencia en frutos cítricos frente a la infección. Por este motivo en esta Tesis se han desarrollado un conjunto de herramientas esenciales para poder abordar la caracterización funcional de genes involucrados en virulencia/patogenicidad: transformación de P. digitatum mediada por Agrobacterium tumefaciens, utilización de la proteína verde fluorescente como marcadora, metodología para la obtención de mutantes de deleción de genes específicos, incluyendo mutantes nulos ¿ku80, vectores para silenciamiento génico mediante RNAi y la construcción de una genoteca de DNA genómico de P. digitatum. Se ha secuenciado y analizado el factor de transcripción PacC, que controla la expresión de un grupo de genes regulados por el pH ambiental. En P. digitatum se produce una acidificación del medio para adaptarlo al pH óptimo de su arsenal de enzimas. Se han obtenido mutantes de expresión constitutiva de PacC que presentan una disminución la capacidad infectiva en un 20 %. Mediante el empleo de técnicas de alto rendimiento se ha construido una genoteca substractiva de cDNA para obtener fragmentos de genes de P. digitatum que se inducen durante la infección de frutos de naranja y se ha analizado la expresión génica de los mismos y se ha elaborado una macromatriz conteniendo más de 1330 clones de la genoteca. El grupo de genes con mayor representación en la genoteca y con altos valores de inducción, corresponde a genes que codifican cinco proteasas diferentes. Además, en la genoteca substractiva también hay una alta representación de genes que codifican enzimas de degradación de la pared celular, y otras proteínas implicadas en glucólisis, respuesta a estrés o detoxificación. La ya demostrada importancia de las enzimas de degradación de la pared celular en la virulencia de hongos fitopatógenos, su abundancia y niveles de inducción en la macromatriz nos llevaron a estudiar más en profundidad algunos de estos genes (dos poligalacturonasas y una pectin liasa). Para comprobar su implicación en el proceso de infección se secuenciaron y se obtuvieron mutantes de P. digitatum en los que se eliminó el gen. La disminución de la virulencia de estos mutantes sobre frutos de naranja con respecto a la cepa silvestre fue de aproximadamente un 25 %. Del conjunto de genes relacionados con el metabolismo redox se seleccionó por su patrón de expresión el gen ris1, que codifica una naftaleno dioxigenasa posiblemente implicada en la detoxificación de compuestos aromáticos. A diferencia de los mutantes nulos en los genes de las poligalacturonasas o de la pectin liasa, los mutantes nulos ¿ris1 no presentaron ninguna alteración en su capacidad patogénica. / López Pérez, M. (2013). Estudio de los factores de patogenicidad/virulencia de Penicillium digitatum sobre frutos cítricos [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/34176

Penicillium digitatum

Post-cosecha de frutos cítricos

Podredumbre verde

Mecanismos de patogenicidad

Proteína verde fluorescente

Obtención de mutantes de deleción

Mutantes nulos

Ku80

Factor de transcripción PacC

Genoteca substractiva de cDNA

Macromatriz

Poligalacturonasas

Pectin liasa

Naftaleno dioxigenasa

SSH