Characterization of GBF1, Arfs and COPI at the ER-Golgi intermediate compartment and mitotic Golgi clusters

Chun, Justin

Unknown Date

No description available.

GBF1

Arf

COPI

Golgi complex

ERGIC

mitosis

brefeldin A

BFA

ADP ribosylation factor

immunofluorescence

live cell microscopy

Exo1

Characterization of GBF1, Arfs and COPI at the ER-Golgi intermediate compartment and mitotic Golgi clusters

Chun, Justin

11 1900

Protein trafficking between the endoplasmic reticulum (ER) and Golgi complex is regulated by the activity of ADP-ribosylation factors (Arfs). Arf activation by guanine nucleotide exchange factors (GEFs) leads to the recruitment of the coatomer protein COPI and vesicle formation. By using fluorescently-tagged proteins in live cells, we have been able to identify novel functions for Arfs and the Arf-GEF GBF1 at the ER-Golgi intermediate compartment (ERGIC) and mitotic Golgi clusters. We first focused on Arf function at the ERGIC after observing both class I (Arf1) and class II (Arfs 4 and 5) Arfs at this structure. We discovered that class II Arfs remain bound to ERGIC membranes independently of GBF1 activity following treatment with brefeldin A (BFA). Further characterization of the class II Arfs using additional pharmacological agents such as Exo1 and inactive mutant forms of Arf4 demonstrated that the class II Arfs associate with the ERGIC membrane via receptors distinct from GBF1. Our work suggests that GBF1 accumulation on membranes in the presence of BFA is due to loss of Arfs from the membrane rather than the formation of an abortive complex with Arf and GBF1. Next, while studying GBF1 in live cells, we unexpectedly observed GBF1 localizing to large fragmented structures during mitosis. We identified these structures as mitotic Golgi fragments that are positive for GBF1 and COPI throughout mitosis. Again using live cells treated with BFA and Exo1, we demonstrated that GBF1 concentrates on these mitotic fragments suggesting that they are derived from Golgi membranes. By colocalization studies and fluorescence recovery after photobleaching, we demonstrated that these mitotic fragments maintain a cis-to-trans subcompartmental Golgi polarization and membrane dynamics of GBF1 similar to interphase cells. Interestingly, inactivation of GBF1 and loss of COPI from the membranes of the mitotic Golgi fragments did not delay progressing through mitosis. Our results from our second project indicate for the first time that the mitotic Golgi clusters are bona fide Golgi structures that exist throughout mitosis with a functional COPI machinery.

GBF1

Arf

COPI

Golgi complex

ERGIC

mitosis

brefeldin A

BFA

ADP ribosylation factor

immunofluorescence

live cell microscopy

Exo1

Hepatocyte-specific deletion of TIPARP, a negative regulator of the aryl hydrocarbon receptor, is sufficient to increase sensitivity to dioxin-induced wasting syndrome

Hutin, D., Tamblyn, L., Gomez, A., Grimaldi, Giulia, Soedling, H., Cho, T., Ahmed, S., Lucas, C., Kanduri, C., Grant, D.M., Matthews, J.

04 June 2018

Yes / The aryl hydrocarbon receptor (AHR) mediates the toxic effects of dioxin (2, 3, 7, 8-tetrachlorodibenzo-p-dioxin; TCDD), which includes thymic atrophy, steatohepatitis, and a lethal wasting syndrome in laboratory rodents. Although the mechanisms of dioxin toxicity remain unknown, AHR signaling in hepatocytes is necessary for dioxin-induced liver toxicity. We previously reported that loss of TCDD-inducible poly(adenosine diphosphate [ADP]-ribose) polymerase (TIPARP/PARP7/ARTD14), an AHR target gene and mono-ADP-ribosyltransferase, increases the sensitivity of mice to dioxin-induced toxicities. To test the hypothesis that TIPARP is a negative regulator of AHR signaling in hepatocytes, we generated Tiparpfl/fl mice in which exon 3 of Tiparp is flanked by loxP sites, followed by Cre-lox technology to create hepatocyte-specific (Tiparpfl/flCreAlb) and whole-body (Tiparpfl/flCreCMV; TiparpEx3−/−) Tiparp null mice. Tiparpfl/flCreAlb and TiparpEx3−/− mice given a single injection of 10 μg/kg dioxin did not survive beyond days 7 and 9, respectively, while all Tiparp+/+ mice survived the 30-day treatment. Dioxin-exposed Tiparpfl/flCreAlb and TiparpEx3−/− mice had increased steatohepatitis and hepatotoxicity as indicated by greater staining of neutral lipids and serum alanine aminotransferase activity than similarly treated wild-type mice. Tiparpfl/flCreAlb and TiparpEx3−/− mice exhibited augmented AHR signaling, denoted by increased dioxin-induced gene expression. Metabolomic studies revealed alterations in lipid and amino acid metabolism in liver extracts from Tiparpfl/flCreAlb mice compared with wild-type mice. Taken together, these data illustrate that TIPARP is an important negative regulator of AHR activity, and that its specific loss in hepatocytes is sufficient to increase sensitivity to dioxin-induced steatohepatitis and lethality. / This work was supported by Canadian Institutes of Health Research (CIHR) operating grants (MOP-494265 and MOP-125919), CIHR New Investigator Award, an Early Researcher Award from the Ontario Ministry of Innovation (ER10-07-028), an unrestricted research grant from the DOW Chemical Company, the Johan Throne Holst Foundation, Novo Nordic Foundation and the Norwegian Cancer Society to J.M.

Aryl hydrocarbon receptor

Wasting syndrome

ADP-ribosylation

2, 3, 7, 8-tetrachlorodibenzo-p-dioxin

The Role of Specific Amino Acids in the Formation of Ternary Complexes in Nitrogenase Regulation in the Photosynthetic Bacterium Rhodobacter capsulatus

Choolaei, Zahra

08 1900

L'azote est l'un des éléments les plus essentiels dans le monde pour les êtres vivants, car il est essentiel pour la production des éléments de base de la cellule, les acides aminés, les acides nucléiques et les autres constituants cellulaires. L’atmosphère est composé de 78% d'azote gazeux, une source d'azote inutilisable par la plupart des organismes à l'exception de ceux qui possèdent l’enzyme nitrogénase, tels que les bactéries diazotrophique. Ces micro-organismes sont capables de convertir l'azote atmosphérique en ammoniac (NH3), qui est l'une des sources d'azote les plus préférables. Cette réaction exigeant l’ATP, appelée fixation de l'azote, est catalysée par une enzyme, nitrogénase, qui est l'enzyme la plus importante dans le cycle de l'azote. Certaines protéines sont des régulateurs potentiels de la synthèse de la nitrogénase et de son activité; AmtB, DraT, DraG, les protéines PII, etc.. Dans cette thèse, j'ai effectué diverses expériences afin de mieux comprendre leurs rôles détailés dans Rhodobacter capsulatus. La protéine membranaire AmtB, très répandue chez les archaea, les bactéries et les eucaryotes, est un membre de la famille MEP / Amt / Rh. Les protéines AmtB sont des transporteurs d'ammonium, importateurs d'ammonium externe, et ont également été suggéré d’agir comme des senseurs d'ammonium. Il a été montré que l’AmtB de Rhodobacter capsulatus fonctionne comme un capteur pour détecter la présence d'ammonium externe pour réguler la nitrogénase. La nitrogénase est constituée de deux métalloprotéines nommées MoFe-protéine et Fe-protéine. L'addition d'ammoniaque à une culture R. capsulatus conduit à une série de réactions qui mènent à la désactivation de la nitrogénase, appelé "nitrogénase switch-off". Une réaction critique dans ce processus est l’ajout d’un groupe ADP-ribose à la Fe-protéine par DraT. L'entrée de l'ammoniac dans la cellule à travers le pore AmtB est contrôlée par la séquestration de GlnK. GlnK est une protéine PII et les protéines PII sont des protéines centrales dans la régulation du métabolisme de l'azote. Non seulement la séquestration de GlnK par AmtB est importante dans la régulation nitrogénase, mais la liaison de l'ammonium par AmtB ou de son transport partiel est également nécessaire. Les complexes AmtB-GlnK sont supposés de lier DraG, l’enzyme responsable pour enlever l'ADP-ribose ajouté à la nitrogénase par DraT, ainsi formant un complexe ternaire. Dans cette thèse certains détails du mécanisme de transduction du signal et de transport d'ammonium ont été examinés par la génération et la caractérisation d’un mutant dirigé, RCZC, (D335A). La capacité de ce mutant, ainsi que des mutants construits précédemment, RCIA1 (D338A), RCIA2 (G344C), RCIA3 (H193E) et RCIA4 (W237A), d’effectuer le « switch-off » de la nitrogénase a été mesurée par chromatographie en phase gazeuse. Les résultats ont révélé que tous les résidus d'acides aminés ci-dessus ont un rôle essentiel dans la régulation de la nitrogénase. L’immunobuvardage a également été effectués afin de vérifier la présence de la Fe-protéine l'ADP-ribosylée. D335, D388 et W237 semblent être cruciales pour l’ADP-ribosylation, puisque les mutants RCZC, RCIA1 et RCIA4 n'a pas montré de l’ADP-ribosylation de la Fe-protéine. En outre, même si une légère ADP-ribosylation a été observée pour RCIA2 (G344C), nous le considérons comme un résidu d'acide aminé important dans la régulation de la nitrogénase. D’un autre coté, le mutant RCIA3 (H193E) a montré une ADP-ribosylation de la Fe-protéine après un choc d'ammonium, par conséquent, il ne semble pas jouer un rôle important dans l’ADP-ribosylation. Par ailleurs R. capsulatus possède une deuxième Amt appelé AmtY, qui, contrairement à AmtB, ne semble pas avoir des rôles spécifiques. Afin de découvrir ses fonctionnalités, AmtY a été surexprimée dans une souche d’E. coli manquant l’AmtB (GT1001 pRSG1) (réalisée précédemment par d'autres membres du laboratoire) et la formation des complexes AmtY-GlnK en réponse à l'addition d’ammoniac a été examinée. Il a été montré que même si AmtY est en mesure de transporter l'ammoniac lorsqu'il est exprimé dans E. coli, elle ne peut pass’ associer à GlnK en réponse à NH4 +. / Nitrogen is one of the most vital elements in the world for living creatures since it is essential for the production of the basic building blocks of the cell; amino acids, nucleic acids and other cellular constituents. The atmosphere is 78% nitrogen gas (N2), a source of nitrogen unusable by most organisms except for those possessing the enzyme nitrogenase, such as diazotrophic bacteria species. These microorganisms are capable of converting atmospheric nitrogen to ammonia (NH3), which is one of the most preferable nitrogen sources. This ATP demanding reaction, called nitrogen fixation, is catalysed by the nitrogenase enzyme, which is the most important enzyme in the nitrogen cycle. Some proteins are potential regulators of nitrogenase synthesis and activity; AmtB, DraT, DraG, PII proteins and etc. In this thesis I performed various experiments in order to better understand their roles in Rhodobacter capsulatus, in more detail. The membrane protein AmtB, which is widespread among archaea, bacteria and eukaryotes, is a member of the MEP/Amt/Rh family. The AmtB proteins are ammonium transporters, taking up external ammonium, and have also been suggested to sense the presence of ammonium. It has been shown that in Rhodobacter capsulatus AmtB functions as a sensor for the presence of external ammonium in order to regulate nitrogenase. Nitrogenase consists of two metalloprotein components named MoFe-protein and Fe-protein. The addition of ammonium to R. capsulatus culture medium leads to a series of reactions which result in the deactivation of nitrogenase, called “nitrogenase switch-off”. A critical reaction in this process is one in which DraT adds an ADP-ribose group to the Fe-protein of nitrogenase. The entrance of ammonia through the AmtB pore is regulated by GlnK sequestration. GlnK is a PII protein and PII proteins are one of the central proteins in the regulation of nitrogen metabolism. Not only is GlnK-AmtB sequestration important in nitrogenase regulation, but binding of ammonium by AmtB or its partial transport is also necessary. AmtB-GlnK complexes are thought to bind DraG, which is responsible for removing the ADP-ribose that DraT adds to nitrogenase, to form a ternary complex. In this thesis details of the signal transduction mechanism and ammonium transport were examined by generating and characterizing RCZC, a (D335A) site- directed mutant of AmtB. The ability of this mutant, as well as previously constructed mutants RCIA1 (D338A), RCIA2 (G344C), RCIA3 (H193E) and RCIA4 (W237A), to “switch-off” nitrogenase activity was measured by gas chromatography. The results revealed that all the above amino acid residues have critical roles in nitrogenase regulation. Immunoblotting was also carried out to check the presence of ADP-ribosylated Fe-protein. D335, D388 and W237 seem to be crucial for NifH ADP-ribosylation, since their mutants (RCZC, RCIA1 and RCIA4 respectively) didn't show ADP-ribosylation on Fe-protein. In addition, although a slight ADP-ribosylation was observed for RCIA2 (G344C) we still consider it as an important amino acid residue in this matter whereas the remaining mutant RCIA3 (H193E) showed Fe-protein ADP-ribossylation after an ammonium shock, therefore it doesn't seem to be important in NifH ADP-ribosylation. In addition R. capsulatus possesses a second Amt called AmtY, which in contrast to AmtB, doesn't appear to have any specific roles. In order to find out its functionality, AmtY was overexpressed in an E. coli strain lacking AmtB (GT1001 pRSG1) (which was carried out previously by other lab members) and AmtY-GlnK complex formation in response to ammonium addition was examined. It was shown that even though AmtY is able to take up ammonia when expressed in E. coli it fails to associate with GlnK in response to NH4+.

AmtB

AmtY

Le transport d'ammonium

Mutagenèse dirigée

ADP ribosylation

Fixation de l'azote

Ammonium transport

Site directed mutagenesis

Nitrogen fixation

Identification and characterization of novel FE65-interacting proteins.

January 2009

Cheng, Wai Hang. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2009. / Includes bibliographical references (leaves 76-88). / Abstract also in Chinese. / Acknowledgement --- p.i / 摘要 --- p.iii / List of Abbreviations --- p.iv / List of Figures --- p.vi / List of Tables --- p.vii / Chapter Chapter 1 --- Introduction --- p.1 / Chapter 1.1 --- FE65 --- p.1 / Chapter 1.1.1 --- FE65 Protein Family and Their Structures --- p.2 / Chapter 1.1.1.2 --- PTB domains --- p.5 / Chapter 1.1.2 --- Expression Pattern of FE65 Proteins --- p.6 / Chapter 1.1.3 --- FE65 Family-Transgenic Animals --- p.7 / Chapter 1.1.4 --- Interacting Partners of FE65 --- p.8 / Chapter 1.1.4.1 --- "APP, APLPl and APLP2" --- p.9 / Chapter 1.1.4.2 --- LRP1 and ApoEr2 --- p.10 / Chapter 1.1.4.3 --- c-Abl --- p.11 / Chapter 1.1.4.4 --- Mena and EVL --- p.11 / Chapter 1.1.4.5 --- Tip60 --- p.12 / Chapter 1.1.4.6 --- SET --- p.12 / Chapter 1.1.4.7 --- Estrogen Receptor a --- p.13 / Chapter 1.1.4.8 --- Teashirt --- p.13 / Chapter 1.1.4.9 --- CP2/LSF/LBP1 --- p.13 / Chapter 1.1.4.10 --- Dexra sl --- p.14 / Chapter 1.1.4.11 --- P2X2-receptor subunit --- p.14 / Chapter 1.1.4.12 --- Tau --- p.15 / Chapter 1.1.4.13 --- Notchl --- p.15 / Chapter 1.1.4.14 --- Alcadein --- p.16 / Chapter 1.1.4.15 --- CD95/Fas/Apo -1 ligand --- p.16 / Chapter 1.1.4.16 --- p68 subunit of pre -mRNA cleavage and polyadenylation factor Im (p68 CFIm) --- p.17 / Chapter 1.1.4.17 --- Ataxinl --- p.17 / Chapter 1.1.5.1 --- FE65 as an adaptor protein --- p.20 / Chapter 1.1.5.2 --- FE65 and Alzheimer´ةs disease --- p.20 / Chapter 1.1.5.3 --- Transcriptional / Post-transcriptional regulation --- p.22 / Chapter 1.1.5.4 --- Apoptosis and cell cycle regulation --- p.23 / Chapter 1.1.5.5 --- Neuronal positioning and cell migration --- p.23 / Chapter 1.1.5.6 --- Learning and memory --- p.25 / Chapter 1.2 --- Objectives --- p.26 / Chapter Chapter 2 --- Investigation of the interaction between FE65 and Arf6 --- p.27 / Chapter 2.1 --- Materials --- p.27 / Chapter 2.1.1 --- DNA contructs --- p.27 / Chapter 2.1.2 --- Cell culture --- p.27 / Chapter 2.1.3 --- Immunoblotting --- p.28 / Chapter 2.1.4 --- Miscellaneous --- p.28 / Chapter 2.2 --- Methods --- p.29 / Chapter 2.2.1 --- Preparation of Escherichia coli competent cells --- p.29 / Chapter 2.2.2 --- DNA preparation with Intron Plasmid DNA --- p.30 / Chapter 2.2.3 --- DNA preparation with Macherey-Nagel NucleoBond Xtra Midi --- p.30 / Chapter 2.2.4 --- DNA preparation by the alkaline lysis method --- p.31 / Chapter 2.2.5 --- Spectrophotometric analysis of DNA --- p.32 / Chapter 2.2.6 --- Agarose gel electrophoresis --- p.32 / Chapter 2.2.7 --- Cell culture and transfection --- p.33 / Chapter 2.2.8 --- Bacterial GST-pull down assay --- p.33 / Chapter 2.2.9 --- GST-pull down assay for testing direct interaction between FE65 and Arf6 --- p.34 / Chapter 2.2.10 --- Mammalian GST-pull down assay --- p.35 / Chapter 2.2.11 --- Immunoprecipitation --- p.36 / Chapter 2.2.12 --- SDS-PAGE --- p.36 / Chapter 2.2.13 --- Immunoblotting --- p.39 / Chapter 2.3 --- Results --- p.40 / Chapter 2.3.1 --- Interaction between Arf6 and FE65 --- p.40 / Chapter 2.3.2 --- Determination of the interacting domain of FE65 with Arf6 --- p.43 / Chapter 2.3.3 --- Determination if FE65 and Arf6 interact directly --- p.45 / Chapter Chapter 3 --- Production of Antisera against Arf6 and Immunostaining of FE65-Arf6 --- p.47 / Chapter 3.1 --- Materials --- p.47 / Chapter 3.1.1 --- Protein expression and purification --- p.47 / Chapter 3.1.2 --- Immunization and harvest of antisera --- p.48 / Chapter 3.1.3 --- Immunostaining --- p.48 / Chapter 3.2 --- Methods --- p.48 / Chapter 3.2.1 --- Protein expression and purification --- p.48 / Chapter 3.2.2 --- Bradford assay --- p.50 / Chapter 3.2.3 --- Immunization --- p.50 / Chapter 3.2.4 --- Antibody purification --- p.51 / Chapter 3.2.5 --- Immunostaining --- p.52 / Chapter 3.3 --- Results --- p.53 / Chapter 3.3.1 --- Recombinant Arf6 expression and purification --- p.53 / Chapter 3.3.2 --- Titering of antisera --- p.57 / Chapter 3.3.3 --- Determination of antisera specificity --- p.59 / Chapter Chapter 4 --- Discussion --- p.68 / Chapter Chapter 5 --- Future Perspectives --- p.73 / References --- p.76

Nerve tissue proteins

Nuclear proteins

Membrane proteins

G proteins

Nerve Tissue Proteins

Nuclear Proteins

Amyloid beta-Protein Precursor

ADP-Ribosylation Factors

Regulation of TGF-β Signaling by Post-Translational Modifications

Lönn, Peter

January 2010

Transforming growth factor-β (TGF-β) signaling is initiated when the ligand binds to type II and type I serine/threonine kinase receptors at the cell surface. Activated TGF-β type I receptors phosphorylate R-Smads which relocate, together with co-Smads, to the cell nucleus and regulate transcription. Enhancement or repression of Smad-specific gene targets leads to intracellular protein compositions which organize functional complexes and thus govern cellular processes such as proliferation, migration and differentiation. TGF-β/Smad signaling relays are regulated by various post-translational modifications. From receptors to gene promoters, intricate interplays between phosphorylation, acetylation, ubiquitination and numerous other modifications, control Smad signaling initiation and duration. However, many steps in the cascade, including receptor internalization, Smad nuclear shuttling and transcriptional termination, still remain elusive. The open gaps in our understanding of these mechanisms most likely involve additional post-translational regulations. Thus, the aim of the present investigation was to identify novel modulators of TGF-β/Smad signaling. In the first part of this thesis, we show the importance of ADP-ribosylation in Smad-mediated transcription. We identified poly(ADP-ribose) polymerase 1 (PARP-1) as a Smad interacting protein. Our work revealed that PARP-1 forms direct interactions with Smad3/4, and PARylates residues in their MH1 domains. This modification restricts Smads from binding to DNA and attenuates Smad-activated transcription. PARylation is reversed by the glycohydrolase PARG. We provide evidence that PARG can de-ADP-ribosylate Smads, which enhances Smad-promoted gene regulation. In the second part, we examine a Smad-dependent gene target of TGF-β signaling, salt inducible kinase 1 (SIK). After induction, SIK cooperates with Smad7 and Smurf2 to downregulate the TGF-β type I receptor. The mechanism relies on both the kinase and UBA domain of SIK as well as the E3-ligase activity of Smurf2. In summary, we have unveiled two enzyme-dependent TGF-β/Smad modulatory mechanisms; SIK promoted receptor turnover and PARP-1/PARG-regulated Smad signaling.

TGF-β

Smad

PARP-1

PARG

ALK5

SIK

signal transduction

transcription

post-translational modification

phosphorylation

ubiquitin

ADP-ribosylation

DNA-binding

receptor degradation

Cell and molecular biology

Cell- och molekylärbiologi

The Effect Of Indole Acetic Acid, Abscisic Acid, Gibberellin And Kinetin On The Expression Of Arf1 Gtp Binding Protein Of Pea (pisum Sativum L. Cv. Araka)

Ertekin, Ozlem

01 September 2007

ADP Ribosylation Factor 1 (ARF1) is a universal small GTP binding protein which has an important role in vesicular trafficking between endoplasmic reticulum and Golgi. ARF1 is a basic component of Coat Protein I (COPI) vesicles which have functions in both formation of coatomer complex and recruitment of cargo proteins. In this study, the expression ARF1 was analyzed in pea (P. sativum L. cv. Araka) grown at different developmental stages. Because of the differential hormonal levels at corresponding stages, the effects of hormones on ARF1 expression were also studied. The results of present research show that ARF1 expression in embryos and 2 days grown plants after germination is lower when compared to 6 days grown plants. In order to see the hormonal effect, 3 weeks old plants were supplied with 50&micro / M of each hormone for 3 times on alternate days. Protein extraction, cell fractionation,Western blot was carried out and immunoblot analysis was conducted with AtARF1 polyclonal antibodies. It was shown that, in pea shoots, abscisic acid and gibberellin increases the inactive GDP bound ARF1 by hydrolyzing ARF-GTP through activating ARFGTPase activating protein (ARF-GAP) or partially inhibiting ARF-Guanine Nucleotide Exchange Factor (ARF-GEF). In roots, ARF-GDP (cytosolic fraction), ARF-GTP (microsomal fraction) and total amount of ARF1 (13.000 x g supernatant fraction) were down regulated by ~11, ~19 and ~11 fold respectively with the application of gibberellin / and by ~11, ~7 and ~3 fold respectively with the application of abscisic acid / when compared to control plants. These results indicate the importance of plant hormones in the regulation of ARF1 in pea.

The Role of Specific Amino Acids in the Formation of Ternary Complexes in Nitrogenase Regulation in the Photosynthetic Bacterium Rhodobacter capsulatus

Choolaei, Zahra

08 1900

L'azote est l'un des éléments les plus essentiels dans le monde pour les êtres vivants, car il est essentiel pour la production des éléments de base de la cellule, les acides aminés, les acides nucléiques et les autres constituants cellulaires. L’atmosphère est composé de 78% d'azote gazeux, une source d'azote inutilisable par la plupart des organismes à l'exception de ceux qui possèdent l’enzyme nitrogénase, tels que les bactéries diazotrophique. Ces micro-organismes sont capables de convertir l'azote atmosphérique en ammoniac (NH3), qui est l'une des sources d'azote les plus préférables. Cette réaction exigeant l’ATP, appelée fixation de l'azote, est catalysée par une enzyme, nitrogénase, qui est l'enzyme la plus importante dans le cycle de l'azote. Certaines protéines sont des régulateurs potentiels de la synthèse de la nitrogénase et de son activité; AmtB, DraT, DraG, les protéines PII, etc.. Dans cette thèse, j'ai effectué diverses expériences afin de mieux comprendre leurs rôles détailés dans Rhodobacter capsulatus. La protéine membranaire AmtB, très répandue chez les archaea, les bactéries et les eucaryotes, est un membre de la famille MEP / Amt / Rh. Les protéines AmtB sont des transporteurs d'ammonium, importateurs d'ammonium externe, et ont également été suggéré d’agir comme des senseurs d'ammonium. Il a été montré que l’AmtB de Rhodobacter capsulatus fonctionne comme un capteur pour détecter la présence d'ammonium externe pour réguler la nitrogénase. La nitrogénase est constituée de deux métalloprotéines nommées MoFe-protéine et Fe-protéine. L'addition d'ammoniaque à une culture R. capsulatus conduit à une série de réactions qui mènent à la désactivation de la nitrogénase, appelé "nitrogénase switch-off". Une réaction critique dans ce processus est l’ajout d’un groupe ADP-ribose à la Fe-protéine par DraT. L'entrée de l'ammoniac dans la cellule à travers le pore AmtB est contrôlée par la séquestration de GlnK. GlnK est une protéine PII et les protéines PII sont des protéines centrales dans la régulation du métabolisme de l'azote. Non seulement la séquestration de GlnK par AmtB est importante dans la régulation nitrogénase, mais la liaison de l'ammonium par AmtB ou de son transport partiel est également nécessaire. Les complexes AmtB-GlnK sont supposés de lier DraG, l’enzyme responsable pour enlever l'ADP-ribose ajouté à la nitrogénase par DraT, ainsi formant un complexe ternaire. Dans cette thèse certains détails du mécanisme de transduction du signal et de transport d'ammonium ont été examinés par la génération et la caractérisation d’un mutant dirigé, RCZC, (D335A). La capacité de ce mutant, ainsi que des mutants construits précédemment, RCIA1 (D338A), RCIA2 (G344C), RCIA3 (H193E) et RCIA4 (W237A), d’effectuer le « switch-off » de la nitrogénase a été mesurée par chromatographie en phase gazeuse. Les résultats ont révélé que tous les résidus d'acides aminés ci-dessus ont un rôle essentiel dans la régulation de la nitrogénase. L’immunobuvardage a également été effectués afin de vérifier la présence de la Fe-protéine l'ADP-ribosylée. D335, D388 et W237 semblent être cruciales pour l’ADP-ribosylation, puisque les mutants RCZC, RCIA1 et RCIA4 n'a pas montré de l’ADP-ribosylation de la Fe-protéine. En outre, même si une légère ADP-ribosylation a été observée pour RCIA2 (G344C), nous le considérons comme un résidu d'acide aminé important dans la régulation de la nitrogénase. D’un autre coté, le mutant RCIA3 (H193E) a montré une ADP-ribosylation de la Fe-protéine après un choc d'ammonium, par conséquent, il ne semble pas jouer un rôle important dans l’ADP-ribosylation. Par ailleurs R. capsulatus possède une deuxième Amt appelé AmtY, qui, contrairement à AmtB, ne semble pas avoir des rôles spécifiques. Afin de découvrir ses fonctionnalités, AmtY a été surexprimée dans une souche d’E. coli manquant l’AmtB (GT1001 pRSG1) (réalisée précédemment par d'autres membres du laboratoire) et la formation des complexes AmtY-GlnK en réponse à l'addition d’ammoniac a été examinée. Il a été montré que même si AmtY est en mesure de transporter l'ammoniac lorsqu'il est exprimé dans E. coli, elle ne peut pass’ associer à GlnK en réponse à NH4 +. / Nitrogen is one of the most vital elements in the world for living creatures since it is essential for the production of the basic building blocks of the cell; amino acids, nucleic acids and other cellular constituents. The atmosphere is 78% nitrogen gas (N2), a source of nitrogen unusable by most organisms except for those possessing the enzyme nitrogenase, such as diazotrophic bacteria species. These microorganisms are capable of converting atmospheric nitrogen to ammonia (NH3), which is one of the most preferable nitrogen sources. This ATP demanding reaction, called nitrogen fixation, is catalysed by the nitrogenase enzyme, which is the most important enzyme in the nitrogen cycle. Some proteins are potential regulators of nitrogenase synthesis and activity; AmtB, DraT, DraG, PII proteins and etc. In this thesis I performed various experiments in order to better understand their roles in Rhodobacter capsulatus, in more detail. The membrane protein AmtB, which is widespread among archaea, bacteria and eukaryotes, is a member of the MEP/Amt/Rh family. The AmtB proteins are ammonium transporters, taking up external ammonium, and have also been suggested to sense the presence of ammonium. It has been shown that in Rhodobacter capsulatus AmtB functions as a sensor for the presence of external ammonium in order to regulate nitrogenase. Nitrogenase consists of two metalloprotein components named MoFe-protein and Fe-protein. The addition of ammonium to R. capsulatus culture medium leads to a series of reactions which result in the deactivation of nitrogenase, called “nitrogenase switch-off”. A critical reaction in this process is one in which DraT adds an ADP-ribose group to the Fe-protein of nitrogenase. The entrance of ammonia through the AmtB pore is regulated by GlnK sequestration. GlnK is a PII protein and PII proteins are one of the central proteins in the regulation of nitrogen metabolism. Not only is GlnK-AmtB sequestration important in nitrogenase regulation, but binding of ammonium by AmtB or its partial transport is also necessary. AmtB-GlnK complexes are thought to bind DraG, which is responsible for removing the ADP-ribose that DraT adds to nitrogenase, to form a ternary complex. In this thesis details of the signal transduction mechanism and ammonium transport were examined by generating and characterizing RCZC, a (D335A) site- directed mutant of AmtB. The ability of this mutant, as well as previously constructed mutants RCIA1 (D338A), RCIA2 (G344C), RCIA3 (H193E) and RCIA4 (W237A), to “switch-off” nitrogenase activity was measured by gas chromatography. The results revealed that all the above amino acid residues have critical roles in nitrogenase regulation. Immunoblotting was also carried out to check the presence of ADP-ribosylated Fe-protein. D335, D388 and W237 seem to be crucial for NifH ADP-ribosylation, since their mutants (RCZC, RCIA1 and RCIA4 respectively) didn't show ADP-ribosylation on Fe-protein. In addition, although a slight ADP-ribosylation was observed for RCIA2 (G344C) we still consider it as an important amino acid residue in this matter whereas the remaining mutant RCIA3 (H193E) showed Fe-protein ADP-ribossylation after an ammonium shock, therefore it doesn't seem to be important in NifH ADP-ribosylation. In addition R. capsulatus possesses a second Amt called AmtY, which in contrast to AmtB, doesn't appear to have any specific roles. In order to find out its functionality, AmtY was overexpressed in an E. coli strain lacking AmtB (GT1001 pRSG1) (which was carried out previously by other lab members) and AmtY-GlnK complex formation in response to ammonium addition was examined. It was shown that even though AmtY is able to take up ammonia when expressed in E. coli it fails to associate with GlnK in response to NH4+.

AmtB

AmtY

Le transport d'ammonium

Mutagenèse dirigée

ADP ribosylation

Fixation de l'azote

Ammonium transport

Site directed mutagenesis

Nitrogen fixation

PI(4)-dependent recruitment of clathrin adaptors to the trans-Golgi Network

Wang, Jing.

January 2005

Thesis (Ph. D.) -- University of Texas Southwestern Medical Center at Dallas, 2005. / Vita. Bibliography: 106-116.

Caracterização molecular da interação entre proteínas de citros envolvidas no controle da expressão gênica e a proteína efetora bacteriana PthA, indutorra do cancro cítrico / Molecular characterization of the interaction between citrus proteins involved in gene transcription control and the effector protein PthA, a citrus canker disease inductor

Souza, Tiago Antonio de

16 August 2018

Orientador: Celso Eduardo Benedetti / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-16T01:56:52Z (GMT). No. of bitstreams: 1 Souza_TiagoAntoniode_M.pdf: 8040684 bytes, checksum: 0b9836df8d96343f09503df5056436cd (MD5) Previous issue date: 2010 / Resumo: O cancro cítrico, causado pela bactéria Xanthomonas axonopodis pv. citri (Xac), é uma doença que afeta a maioria das espécies do gênero Citrus, ocorrendo praticamente em todos os continentes, e se destaca como uma das ameaças à citricultura brasileira. O mecanismo molecular pelo qual Xac causa o cancro não é inteiramente conhecido, entretanto, sabe-se que a bactéria ao infectar a planta, utiliza o sistema secretório tipo ??? (TTSS) para injetar proteínas de patogenicidade, entre elas PthAs da família AvrBs3/PthA. Quando expresso na célula hospedeira, PthA induz lesões características do cancro como hipertrofia e hiperplasia. Estudos recentes demonstram que membros dessa família atuam como fatores de transcrição. Portanto, a elucidação de como PthA ativa a transcrição é de grande importância para o entendimento do seu mecanismo de ação e desenvolvimento das lesões do cancro. Neste contexto, o presente projeto teve como objetivo caracterizar interações entre a proteína PthA de Xac e as proteínas CsARF (Auxin Response Factor) e CsHMG (High-mobility group) de laranja doce (Citrus sinensis), previamente identificadas em ensaios de duplo híbrido de leveduras. CsARF tem elevada similaridade com AtARF2, um repressor transcricional envolvido na via de sinalização por auxinas. Hormônios vegetais desempenham um importante papel na interação planta-patógeno e em nosso laboratório verificamos que auxinas são importantes para o desenvolvimento dos sintomas do cancro. CsARF foi capaz de interagir com a maioria das variantes de PthA tanto in vitro quanto em ensaios de duplo-híbrido de leveduras. A interação de CsARF com PthA se dá através dos domínios C-terminal Aux/IAA e B3 de ligação ao DNA. Verificamos que o promotor do gene de uma expansina de citros, induzido por Xac e auxina, apresenta possíveis sítios de ligação das proteínas CsARF e PthA. Dados de EMSA indicam que PthA e CsARF ligam em sítios adjacentes no promotor da expansina de citros e que a interação de PthA com CsARF poderia deslocá-la do promotor. A proteína CsHMG é semelhante a AtHMGB1 de Arabidopsis thaliana, envolvida em crescimento celular. CsHMG interagiu com todas as variantes de PthA, sendo que essa interação envolve uma região rica em leucinas (LRR), idêntica nas quatro variantes de PthA. Verificou-se também que CsHMG é capaz de ligar DNA de forma inespecífica. Por outro lado, CsHMG ligou RNA in vitro, com especificidade para RNAs ricos em uridina (poly-U). Como PthA age como fator de transcrição eucarioto, não é surpreendente que proteínas do hospedeiro envolvidas com regulação gênica sejam capazes de interagir com esse efetor, sugerindo um novo modo de ação de proteínas efetoras bacterianas. / Abstract: Citrus canker disease, caused by Xanthomonas axonopodis pv. citri (Xac), affects almost all citrus species and represents a major threat to the Brazilian citriculture. The molecular mechanism by which Xac causes citrus canker disease is poorly understood, however the bacterium injects pathogenicity proteins through a type III secretion system (TTSS) including proteins of AvrBs3/PthA family proteins. When transiently expressed in host cells, PthAs alter transcription of the host cell to the benefit of the pathogen, leading to the development of the cancer lesions, including hypertrophy and hyperplasia. These proteins are thought to acts as eukaryotic transcriptional factors, binding and activating directly promoters of host genes. Therefore, elucidating how activates PthA transcription is very important to understanding the mechanisms governing the development of canker lesions. To elucidate how PthA activates transcription and to establish its molecular mode of action, a two-hybrid approach was used to identify host proteins that interact with PthA and therefore could be important for the development of the canker lesions. Among the citrus proteins identified, we selected for studies a CsARF (Auxin Response Factor) and a CsHMG (High-mobility group), both involved in regulation of gene transcription. CsARF shares high similarity to the Arabidopsis thaliana ARF2, involved in the auxin signaling pathway. This is in line with our previous studies showing that auxin is required for canker development. The interactions between all variants of PthA were analyzed both in vivoand in vitro and depend on the repeat domain of PthAs. The B3 DNA binding and the Aux/IAA domains of CsARF are both involved in protein-protein interactions. Interestingly, the citrus promoter of a citrus expansin gene that is up-regulated by Xac and auxin contains putative CsARF and PthA binding sites. Since these sites are located adjacent in this promoter, it is suggested that the interaction of PthA with CsARF might somehow affect the regulation of the expansin promoter. CsHMG is highly similar to the A. thaliana HMGB1 involved in cell growth. CsHMG interacts with all PthA variants and its interaction was shown to be mediated primarly by the leucine-rich repeat (LRR) region of PthAs. CsHMG binds to DNA in a non-specific fashion; surprisingly, however, CsHMG shows an as yet unreported ability to bind to synthetic RNA forms with an apparent specificity to poly-U probes. PthA acts like an eukaryotic transcription factor and is not surprising that host proteins involved with gene regulation can interact with this effector, suggesting a new mode of action of these bacterial effector proteins. / Mestrado / Genetica Vegetal e Melhoramento / Mestre em Genética e Biologia Molecular

Proteína PthA, Xanthomonas campestris

Xanthomonas axopodis pv. citri

Proteinas de grupo de alta mobilidade

PthA protein, Xanthomonas campestris

Xanthomonas axopodis pv. citri

ADP-Ribosylation factors

High mobility group proteins