Investigations of the spreading and closure mechanisms of phagocytosis in J774a.1 macrophages

Kovari, Daniel T.

27 May 2016

Phagocytosis is the process by which cells engulf foreign bodies. It is the hallmark behavior of white blood cells, being the process through which those cells ingest and degrade pathogens and debris. To date a large amount of research has focused on documenting the existence and role of biochemical components involved with phagocytosis. Scores of signaling molecules have been implicated in the complex signal cascade which drives the process. These molecules are small (typically no larger than 5 nanometers) and operate in a crowded, chemically “noisy,” environment, yet they coordinate the cell's activity over comparatively expansive distances (as large as 20 micrometers). How these molecular processes scale-up to coordinate the activities of the cell over such massive distances is largely unknown. Using a planar analog of phagocytosis termed “frustrated phagocytosis,” we experimentally demonstrate that phagocytosis occurs in three distinct phases: initial cell-antigen binding, symmetric spreading, and late-stage contraction. Initial binding and symmetric spreading appears to be both mechanically and chemically similar to the quasi-universal cellular behaviors of adhesion and migration. Adhesion and migration have received extensive attention from the biophysics community in recent years. Leveraging these similarities, we adapt the biomechanical frameworks used in models of migration to phagocytosis. We show that macroscopic properties such as a cell's effective viscosity and membrane cortical tension can be used to model cell behavior during phagocytosis. Our experiments reveal that late-stage contraction distinguishes frustrated phagocytosis from other spreading behaviors. This contraction is myosin dependent. Additionally we demonstrate, for the first time, that late-stage contraction corresponds with formation of a contractile F-actin belt. Based on the dynamic contraction model (DC) developed to explain actin structure during cell migration we propose a DC model of phagocytosis which posits that contractile belt formation is the result of a late-stage myosin activity coupled with F-actin.

Phagocytosis

Frustrated phagocytosis

Actin

Cytoskeleton

Traction force microscopy

Dynamic contraction model

Structure illumination microscopy

Cell spreading

Cell adhesion

Evolutionary history of clathrin-mediated endocytosis and the eisosome

Cibrario, Luigi

January 2011

Endocytosis is both an ancient and a diverse feature of the eukaryotic cell. Studying how it evolved can provide insight into the nature of the last common eukaryotic ancestor, and the diversification of eukaryotes into the known extant lineages. In this thesis, I present two studies on the evolution of endocytosis. In the first part of the thesis I report results from a large-scale, phylogenetic and comparative genomic study of clathrin-mediated endocytosis (CME). The CME pathway has been studied to a great level of detail in yeast to mammal model organisms. Several protein families have now been identified as part of the complex set of protein-protein and protein-lipid interactions which mediate endocytosis. To investigate how such complexity evolved, first, I defined the modular nature of the CME interactome (CME-I) by literature review, and then I carried out a systematic phylogenetic and protein domain architecture analysis of the proteins involved. These data were used to construct a model of the evolution of the CME-I network, and to map the expansion of the network's complexity to the eukaryotic tree of life. In the second part of the thesis, I present results from evolutionary and functional studies of the eisosome, a protein complex which has been proposed to regulate the spatial distribution of endocytosis in S. cerevisiae. The phylogeny of eisosomes components Pil1 and Lsp1 reported here, suggests that eisosomes are likely to have originated at the base of the fungi, and then diversified significantly via multiple gene duplications. I thus studied the localisation and function of Pil1 and Lsp1 homologues in Magnaporthe oryzae to investigate the role of eisosomes in filamentous fungi. Results suggests that eisosomes are linked with septal formation and integrity in M. oryzae, and that the septal specific Pil2 paralogue was lost in budding yeasts. Together, the data presented in this thesis describe the evolutionary history of a complex biological system, but also highlights the problem of asymmetry in the understanding of endocytic diversity in the eukaryotes.

571.6

Intracellular pH, the Proximate Signal for Cell Volume Changes that are Mediated by the Actin Cytoskeleton

Pasley, William

01 January 2005

The relationship between initial intracellular pH (pHi) and associated cell volume change was investigated by simultaneous measurement of pHi and cell volume with fluorescence imaging in polarized fungiform taste receptor cells (TRCs) loaded with BCECF in vitro. Ammonium pulses caused a brief, reversible alkalinization in pHi and induced cell swelling. Sodium-acetate pulses reversible decreased TRC pHi and induced cell shrinkage. Removal weak acids and return to Control Ringer's solution (CR) causedTRC pHi and volume to overshoot baseline levels before fully recovering. Replacing CR with zero-sodium solution resulted in irreversible acidification of TRC pHi and induced cell swelling. Addition of sodium allowed reversal of TRC pHi and volume and return to baseline levels. Treating TRCs with cytoskeleton inhibitors, phalloidin and cytochalasin, before acidic stimulation did not affect TRC pHi, but did result in an altered TRC volume change. I conclude that a decrease in TRC pHi induces cell shrinkage via the actin cytoskeleton. Cell shrinkage as a result of a change in pHi activates NHE1 to restore TRC pHi and volume.

gustation

taste receptors

actin

intracellular

cytoskeleton

taste

papillia

pHi

TRC

taste bud

sodium

phalloidin

cytochalsin

Psychology

Social and Behavioral Sciences

Influence de l’assemblage du VIH-1 et de l’organisation du cytosquelette sur la dynamique et la répartition membranaire des tétraspanines CD9 et CD81analysée à l’échelle de la molécule unique / Influence of HIV-1 assembly and cytoskeleton integrityon tetraspanins CD9 and CD81 dynamics and partitioninganalysed at the single molecule level

Rassam, Patrice

25 October 2012

Les mécanismes moléculaires d'assemblage et de bourgeonnement des virus tels que le VIH-1 dans les cellules infectées sont encore relativement mal connus. Toutefois, il semble établi que la multimérisation de la protéine Gag s'effectue à la membrane plasmique et que le bourgeonnement des particules virales a lieu au niveau de zones enrichies en tétraspanines. Ces protéines transmembranaires forment un réseau d'interactions protéiques à la surface de la cellule et s'organisent en microdomaines différents des radeaux lipidiques, bien qu'enrichis en cholestérol.En utilisant la technique de suivi de molécules uniques fluorescentes sur des cellules HeLa exprimant la protéine Gag, l'objectif de mon travail de thèse était d'abord de déterminer l'influence de l'assemblage et le bourgeonnement de pseudoparticules virales sur la dynamique et la répartition membranaires des tétraspanines CD9 et CD81. Nos résultats renforcent l'émergence d'un nouveau concept, selon lequel les composants cellulaires et viraux, plutôt que de se regrouper au niveau de plateformes membranaires préexistantes, s'organisent en structures de taille croissante où les tétraspanines sont peu à peu concentrées avec leurs partenaires pour former une architecture propice à l'assemblage et la sortie du VIH-1.Par ailleurs, nous avons montré que CD81 était plus confiné et moins dynamique que CD9 et avons donc étudié les mécanismes moléculaires expliquant cette différence de comportement membranaire. L'utilisation du pistage en molécule unique couplé à des marquages d'ensemble, l'emploi de protéines chimériques et de drogues spécifiques ont permis de révéler que la dynamique membranaire de CD81 est restreinte par le réseau d'actine, via l'ezrine, mais implique aussi EWI-2 et CD9P-1, deux partenaires membranaires de CD9 et de CD81. Enfin, cette étude montre que cette interaction avec le cytosquelette est impliquée dans le recrutement de CD81 et indirectement de CD9, lors de l'assemblage du VIH. / Molecular mechanisms of assembly and budding of HIV-1 particles in infected cells are still a matter of debate. However it is now well established that Gag assembly occurs at the plasma membrane and that budding involves tetraspanin-enriched areas. Tetraspanins are transmembrane proteins that form a network of protein interaction at the cell surface organized into microdomains enriched in cholesterol but distinct from rafts.Using single molecule tracking of fluorescent markers with Gag-expressing HeLa cells, the aim my PhD thesis was first to determine the influence of Gag assembly and budding of pseudo particles on the dynamics and partitioning of the tetraspanins CD9 and CD81 at the plasma membrane. Our results support an emerging concept that cellular and viral components, instead of clustering at preexisting microdomains or platforms, direct the organization of growing structures where tetraspanins are more and more concentrated with their partners, in order to form a membrane scaffold that helps HIV-1 assembly and egress.In a second work, we showed that CD81 is more confined and less dynamic than CD9, and tried to clarify the molecular mechanisms involved in this differential behavior at the plasma membrane. Single molecule tracking, in addition to ensemble labeling experiments, CD9/CD81 chimeric proteins, as well as specific drugs, demonstrated that CD81 membrane dynamics is restricted by the actin network through ezrin proteins, but also implicates EWI-2 and CD9P-1, primary partners of CD9 and CD81. Finally, this study reveals that this interaction with the cytoskeleton is in part responsible of the recruitment of CD81 and indirectly of CD9 during HIV-1 assembly.

Suivi de molécule unique

Diffusion

Tétrapanines

Membrane

Vih-1

Cytosquelette

Single molecule tracking

Diffusion

Tetraspanins

Membrane

Hiv-1

Cytoskeleton

Vizualizace buněčných struktur listu Malus domestica pro účely studia interakce s patogenem Venturia inaequalis / Visualization of cell structures in leaf cells of Malus domestica as a tool for study of Malus-Venturia inaequalis interactions

Zajícová, Iveta

January 2016

Apple scab, the most serious disease of apple is caused by fungal pathogen Venturia inaequalis. Knowledge about the apple response to apple scab attack on the cellular and tissue level is insufficient. For studies of Malus-Venturia interaction on the cellular and tissue level, the establishment of methods for cell structures visualization in apple leaves is necessary. In this work, the experimental plant material grown in vitro and ex vitro was successfully established and the method of apple infection by conidia of V. inaequalis was optimized. Various methods of cell components visualization such as vital staining, in situ immunolocalization, transformation, environmental scanning electron microscopy and confocal microscopy, were tested. Cell structures, such as the cytoskeleton, the cell wall and the cuticle were visualized in apple leaves. Preliminary experiments following specific the changes of cell wall structures induced by V. inaequalis attack were performed. Further, changes of cuticle structure, the first barrier for penetration of pathogen to plant tissues during infection, were observed during the leaf ontogenesis. Powered by TCPDF (www.tcpdf.org)

Caractérisation du modèle murin de la Neuropathie à Axones Géants : rôle de la gigaxonine dans la survie neuronale et l'organisation du cytosquelette

Ganay, Thibault

30 September 2011

La Neuropathie à Axones Géants (NAG) est une maladie neurodégénérative rare et fatale caractérisée par une détérioration du système nerveux central et périphérique, impliquant les fonctions motrices et sensorielles. La détérioration massive du système nerveux est accompagnée d'une désorganisation générale des Filaments Intermédiaires ce qui la différencie de nombreuses maladies neurodégénératives où seuls les neurofilaments(NFs) sont affectés. La protéine déficiente, la gigaxonine, est la sous-unité d'une ubiquitine ligase E3, responsable de la reconnaissance spécifique des substrats MAP1B, MAP1S et TBCB, seuls connus à ce jour.Dans le but d'étudier le rôle de la gigaxonine sur la survie neuronale, la désorganisation du cytosquelette et d'avoir un modèle animal suffisamment fort pour envisager des tests thérapeutiques, j'ai caractérisé un modèle murin de NAG. Pour ce faire, j'ai réalisé une étude comportementale des fonctions motrices et sensorielles ainsi qu'une étude histopathologique. Les souris NAG (129/SvJ) développent un phénotype moteur modéré dès 60 semaines alors que les souris NAG (C57BL/6) présentent un phénotype sensoriel dès 60 semaines. Les données histopathologiques ne présentent pas de mort neuronale mais les NFs sont sévèrement altérés. Les NFs sont plus abondant, leur diamètre est augmenté et leur orientation hétérogène, comme c'est observé chez les patients NAG.Nos résultats montrent que l'absence de gigaxonine induit un phénotype moteur et sensoriel modéré mais par contre reproduit la désorganisation massive des NFs observée chez les patients. Ce modèle va nous permettred'étudier le rôle de la gigaxonine, une ligase E3, sur l'organisation des NFs et ainsi comprendre les processus pathologiques impliqués dans d'autres maladies neurodégénératives caractérisée par une accumulation des NFs et un dysfonctionnement du système ubiquitine-protéasome comme les maladies d'Azheimer, de Parkinson etd'huntington ou la sclérose latérale amyotrophique. / Giant Axonal Neuropathy (GAN) is a rare and fatale neurodegenerative disorder characterized by a deterioration of the peripheral and central nervous system. The broad deterioration of the nervous system is accompanied with a general disorganization of the Intermediate Filaments which makes it different from other neurodegenerative disorders wherein only neurofilaments (NFs) are affected. The defective protein, gigaxonin, is the substrate adaptator of an E3 ubiquitin ligase, in charge of the specific recognition of MAP1B, MAP1S and TBCB. In order to study the role of gigaxonin on neuronal survival, the cytoskeleton disorganization and to have a relevant GAN animal model to evaluate efficacy of GAN treatments, I have characterized a GAN mouse model. I did a motor and sensory behavioural study and an histopathologic study. The GAN mice (129/SvJ) shown mild motordeficits starting at 60 weeks of age while sensory deficits were evidenced in C57BL/6 GAN mice. No apparent neurodegeneration was evidenced in GAN mice, but dysregulation of NFs was massive. NFs were more abundant, they shown the abnormal increased diameter and misorientation that are characteristics of the human pathology. Our results show that gigaxonin depletion induces mild motor and sensory deficits but recapitulates the severe NFs dysregulation seen in patients. Our model will allow us to study the role of the gigaxonin-E3 ligase in organizing NFs and understand the pathological processes engaged in other neurodegenerative disorders characterized by accumulation of NFs and dysfunction of the Ubiquitin Proteasome System, such as Amyotrophic Lateral Sclerosis, Huntington's, Alzheimer's and Parkinson's diseases.

Neuropathie à Axones Géants

Gigaxonine

Modèle murin

Neurodégénérescence

Cytosquelette

Ligase E3.

Giant Axonal Neuropathy

Gigaxonin

Mouse model

Neurodegenerescence

Cytoskeleton

E3 ligase.

The structural basis of the disabling of the actin polymerization machinery by Yersinia

Lee, Wei Lin

January 2013

Yersinia pestis is a human pathogen and the causative agent of bubonic plague, responsible for causing three massive pandemics, resulting in hundreds of millions of deaths in the 14th century alone. Yersinia’s virulence stems from its ability to overcome host immune defences by the injection of six Yersinia outer proteins (Yops) into the host cells via its Type III secretion system. One of these Yops, YopO specifically disables the actin polymerization machinery, leading to the crippling of phagocytosis. YopO consists of a GDI domain which sequesters Rac and Rho, and a kinase domain, the activity of which is dependent on host actin. Little is known about the targets of the kinase domain and the mechanism of function of YopO remains incomplete. In this work, YopO was crystallized in complex with actin, revealing that YopO binds to actin on subdomain 4, away from the 'hotspot’ between subdomains 1 and 3 which is involved in binding most actin-binding proteins. The structure reveals how recruitment of YopO-bound actin monomers stalls actin polymerization by steric hindrance. The structure also demonstrates how YopO uses actin for self-activation and suggests that actin is being used by YopO as bait for recruitment into actin machineries. Using SILAC mass spectrometry, actin cytoskeletal machineries within macrophages that recruit YopO are identified and these include, amongst others: VASP family proteins, gelsolin family proteins, formins and WASP. Of these, VASP, EVL, diaphanous1, WASP and gelsolin have been identified to be phosphorylated by YopO and were validated by in vitro phosphorylation. This work demonstrates that YopO uses actin as a scaffold for selection of kinase substrates, enabling targeted phosphorylation of the actin machinery and provides insight into the regulation of the actin cytoskeleton by phosphorylation under non-pathogenic conditions.

579.3

Dynamique des réseaux d'actine d'architecture contrôlée / Dynamics of controlled actin network's architecture

Reymann, Anne-Cécile

11 July 2011

Mon travail fut de développer différents projets en vue de mieux comprendre la dynamique et l'organisation des réseaux d'actine et les mécanismes moléculaires à l'origine de la production de force, cela en systèmes reconstitués bio-mimétiques. Dans un premier temps je me suis intéressée à l'étude de l'organisation spatio-temporelle des réseaux d'actine et de ses protéines associées durant la motilité de particules recouverte de promoteurs de nucléation (Achard et al, Current Biology, 2010 et Reymann et al, sous presse à MBOC). J'ai suivi en temps réel l'incorporation de deux régulateurs de l'actine (capping protein et ADF/cofiline) et montré que leur contrôle biochimique sur l'actine gouverne également ces propriétés mécaniques. Afin de mieux caractériser les propriétés mécaniques de ces réseaux d'actine en expension, j'ai ensuite développé un système biomimétique novateur utilisant un set-up de micro-patterning permettant un contrôle spatial reproductible des sites de nucléation d'actine. Cela m'a permis de montrer comment des barrières géométriques, semblables à celles trouvées dans les cellules, peuvent influencer la formation dynamique de réseaux organisés d'actine et ainsi contrôler la localisation de la production de forces. (Reymann et al, Nature Materials, 2010). De plus l'addition de moteurs moléculaires sur ce système versatile nous a permis d'étudier la contraction induite par des myosines. En particulier les myosines VI-HMM interagissent de manière sélective sur différentes architectures d'actine (organisation parallèle ou antiparallèle, réseau enchevêtré), aboutissant à un processus en trois phase : tension puis déformation des réseaux d'actine fortement couplé à un désassemblage massif des filaments. Ce phénomène est intimement dépendant de l'architecture du réseau d'actine et pourrait donc jouer un rôle essentiel dans la régulation spatiale des zones d'expansion et de contraction du cytosquelette in vivo. (Travail en cours d'écriture). / I have developed different projects in order to tackle the problem of actin network dynamics and organization as well as the molecular mechanism at the origin of force production in biomimetic reconstituted systems. My first interest concerned the spatiotemporal organization of actin networks and actin-binding proteins during actin based motility of nucleation promoting factor-coated particles (Achard et al, Current Biology, 2010 and Reymann et al, in press at MBOC). I tracked in real time the incorporation of two actin regulators and showed that their biochemical control of actin dynamics also governs its mechanical properties. To further characterize mechanical properties of expanding actin networks, I used an innovative micro-patterning set-up allowing a reproducible spatial control of actin nucleation sites. It allowed me to show that geometrical boundaries, such as those encountered in cells, affect the dynamic formation of highly ordered actin structures and hence control the location of force production (Reymann et al, Nature Materials, 2010). Finally the addition of molecular motors on this tunable system allowed me to study implications for myosin-induced contractility. In particular, HMM-MyosinVI selectively interact with the different actin network architectures (parallel, anti-parallel organization or entangled networks) and leads to a selective three-phase process of tension, deformation of actin networks tightly coupled to massive filament disassembly. This phenomenon being highly dependent on actin network architecture could therefore play an essential role in the spatial regulation of expanding and contracting regions of actin cytoskeleton in cells. (Work in writing process).

Cytoskelette actine

Biophysique

Production de force

Myosine

Systèmes biomimétiques

Actin cytoskeleton

Biophysics

Force production

Myosin

Biomimetic sytems

530

Etude d'architecture multicellulaire avec le microenvironnement contrôlé / Study of multicellular architecture with controlled microenvironment

Tseng, Qingzong

01 July 2011

Ce manuscrit de thèse est composé de trois parties dédiées aux développements technologiques nécessaires à l'étude de la polarité et des contraintes mécaniques dans les cellules épithéliales. La première partie décrit les développements technologiques et méthodologiques qui ont été réalisés en micro-fabrication et traitement de surface, acquisition et analyse d'image, et mesure des forces de traction. La deuxième partie décrit l'étude de l'organisation spatiale du système d'adhérence des cellules épithéliales. De la régulation de leur polarité à celle de leur fonction, l'architecture des cellules épithéliales est profondément liée à leur système d'adhérence. Nous avons utilisé les micropatrons adhésifs pour contrôler la géométrie de la matrice extra-cellulaire pour examiner l'effet de l'adhérence des cellules avec la matrice sur la position des zones d'adhérence intercellulaire. Nos résultats montrent que l'organisation spatiale de l'adhérence cellule-matrice joue un rôle déterminant sur celle de l'adhérence intercellulaire. Ils montrent également que cette organisation dirige ensuite la position du centrosome et l'orientation de l'ensemble de la polarité interne. Lors d'une réorganisation spatiale de l'épithélium, comme c'est le cas au cours de la transition épithélium-mésenchyme, les systèmes d'adhérence et la polarité interne subissent tous les deux de profondes modifications. Néanmoins, les cellules semblent capables de les réguler de façon indépendante selon le type de stimulus qui induit la réorganisation. La dernière partie est une analyse des paramètres physiques impliqués dans l'architecture épithéliale. En parallèle des régulations biochimiques, les contraintes mécaniques jouent également un rôle fondamental dans la régulation des processus morphogenétiques. L'association de l'ensemble de nos développements technologiques (patterning de substrat déformable, logiciel de détection et de mesure de force, contrôle du positionnement des cellules) nous a permis d'analyser précisément les propriétés mécaniques des architectures multicellulaires. Nous avons découvert que l'organisation spatiale du système adhérence était un régulateur majeur de l'intensité et de la répartition des forces intra-cellulaires. Cette observation nous a permis de proposer une modification du modèle actuel de distribution des contraintes dans un épithélium qui prend en compte l'anisotropie des forces inter-cellulaires en réponse à l'hétérogénéité de la matrice extra-cellulaire. Ce nouveau modèle physique permet de rendre compte des positions adoptées par les cellules en réponse aux différentes géométries de la matrice extra-cellulaire. / This thesis dissertation is comprised of three major parts. The first part devotes to all the technological developments that have been realized in my thesis study. These developments in microfabrication, in image acquisition and analysis, and in the traction force analysis had solved various problems we have encountered during our study of epithelial architecture. The second part describes the study of the spatial organization of the adhesion systems in epithelia. From their polarity, their functioning, to their remodeling, the epithelial architecture is deeply linked with the adhesion systems. With the capability to well define the location of cell-matrix interaction, we examined how the intercellular adhesion was organized according to the cell-matrix adhesion. Our results highlighted the instructive role of cell-matrix adhesion in organizing the intercellular adhesion. This organization subsequently governed the internal polarity which was indicated by the centrosome positioning. During epithelial remodeling, both the adhesion system and internal polarity were subjected to modification. Nevertheless they could be regulated differently depending on the context of remodeling. The last part is focused on the physical aspect of the epithelial architecture. Apart from the biochemical signaling network, mechanical force is also a substantial ingredient in morphogenesis. Together with our techniques in micropatterning the soft gel, the development of software for traction force microscope, and our knowledge of cell-cell positioning, we were able to analyze precisely the mechanical property of the multicellular architecture. We found that the cellular contractility was modulated by the spatial organization of the adhesion system. It permitted us to complete the current physical model of epithelial geometry with an anisotropic term for contractility. This new physical model could effectively account for the cell positioning on various matrix geometries.

Micropattern

Morphogènese

Analyse d'image

Microscopie du Traction Force

Cytosquelette

Polarité

Micropattern

Morphogenesis

Image analysis

Traction force microscope

Cytoskeleton

Polarity

530

Interação parasita-célula hospedeira: modificação de proteínas de Tripanosoma cruzi durante adesão à matriz extracelular / Parasite-host cell interaction: modifications of Trypanosoma cruzi proteins during the adhesion to extracelular matrix

Mattos, Eliciane Cevolani

24 January 2014

A doença de Chagas foi incialmente descrita em 1090 e após mais de 100 anos de investigações sobre essa doença, ainda pouco se sabe sobre os mecanismos ativados no parasita durante sua adesão e invasão à célula hospedeira. Glicoproteínas de massa molecular de 85kDa localizadas na membrana do parasita foram identificadas como principais elementos responsáveis pela interação com o hospedeiro. Essas proteínas também são capazes de se ligar a elementos da matriz extracelular (ECM) da célula hospedeira e esse evento parece ser crucial para modulação da adesão e invasão do parasita e consequente avanço da infecção. Embora diferentes elementos tenham sido identificados no hospedeiro como componentes da via de resposta a adesão ao parasita, as modificações induzidas pela sua ligação ao hospedeiro é ainda pouco conhecida. Modificações pós-traducionais de proteínas, incluindo a fosforilação, têm sido utilizadas por diferentes organismos na transdução de sinais extracelulares. Dessa forma, a identificação de proteínas diferencialmente fosforiladas durante a adesão de tripomastigotas de T. cruzi a ECM, fibronectina e laminina foi o objetivo dessa tese. Tripomastigotas foram incubados com ECM, fibronectina-, laminina- ou BSA- previamente aderidos em placas de cultura de células. Em seguida, os parasitas foram coletados e suas proteínas extraídas e separadas por 2D-PAGE. Os géis de eletroforese foram corados com Pro-Q Diamond (para identifiicação de proteínas fosforiladas) e posteriormente com coomassie colloidal (identificação de proteínas totais). Os spots com diferença significativa na coloração com Pro-Q Diamond (p< 0,05) foram identificados por LC-MS/MS. 54 spots foram diferencialmente fosforilados durante a adesão dos parasitas a ECM, dos quais 39 sofreram um aumento da intensidade de fosforilação e 15 uma redução. Já dos 43 spots diferencialmente fosforilados durante incubação com laminina, 16 aumentaram a fosforilação enquanto 27 sofreram redução da intensidade de fosforilação. Por fim, após incubação com fibronectina, dos 50 spots selecionados, 15 spots sofreram aumento da intensidade de fosforilação e 35 sofreram redução. Após identificação dos spots, as modificações por fosforilação/desfosforilação de proteínas de função desconhecida (hypothetical proteins), proteínas do citoesqueleto, proteínas do choque térmico (HSPs) e proteínas componentes do proteassomo do parasita foram as mais evidentes. A validação por immonoblotting de algumas proteínas identificadas indicou que a desfosforilação de proteínas do citoesqueleto junto com a fosforilação de proteínas do choque térmico são os principais eventos durante a resposta do parasita a adesão a ECM e a seus elementos. Além disso, a desfosforilação de ERK 1/2 observada indicou uma inativação dessa proteína em parasitas aderidos a fibronectina e laminina. Os resultados obtidos nessa tese sugerem uma provável relação entre modificações de proteínas do citoesqueleto e HSPs com a capacidade de internalização dos parasitas na célula hospedeira. / The Chagas disease was firstly described in 1909. After more than 100 years of investigation about this sickness much less is known about the mechanism triggered in the parasite during the adhesion and invasion to the host cell. 85kDa glycoproteins were identified as the major element responsible for the attachment to the host. In addition, these proteins are able to binding to extracellular matrix elements and host cytoskeletal proteins and it event appears to be an essential step in host cell invasion by T. cruzi. Although downstream signal modifications have been studied in host cells upon parasite binding, the molecular changes induced on the parasite by ligand binding are largely unknown. Since post-translational modification of proteins by phosphorylation is one of the most important mechanisms employed by organisms to transduce external signals, identification of proteins modified upon adhesion of T. cruzi trypomastigotes to ECM, laminin and fibronectin of the host cell was pursued. Trypomastigotes (Y strain) were incubated with ECM, laminin-, fibronectin- or BSA-coated surfaces, followed by 2D-PAGE stained with Pro-Q Diamond (phosphorylated protein detection) followed by colloidal coomassie stain (total protein identification). Proteins with significant differences in Pro-Q Diamond stain (p<0.05) were identified by LC-MS/MS. 54 spots were differentially phosphorylated during parasite adhesion to ECM, in which 39 spots have increased their phosphorylation level and 15 have decreased their phosphorylation. From the 43 spots presenting modification to the phosphorylation on incubation with laminin, 16 corresponded to cases of increase of phosphorylation and 27 to cases of dephosphorylation. After incubation with fibronectin: from the 50 spots selected, 15 corresponded to increase of phosphorylation and 35 to dephosphorylation. The results show phosphorylation/dephosphorylation modifications of unknown proteins, parasite cytoskeletal proteins (alpha and beta tubulin and paraflagellar-rod proteins), heat shock proteins and proteasome proteins. The validation by immunoblotting of proteins and their phosphorylation intensities indicates that cytoskeletal protein dephosphorylation in addition to heat shock proteins phosphorylation are the most important event during the trypomastigotes adhesion to the ECM. Looking for downstream signaling, dephosphorylation of ERK1/2 was also shown in trypomastigotes adhered to fibronectin or laminin, suggesting its inactivation. Thereby, those results suggest a possible correlation between cytoskeletal proteins and HSPs modification and the ability of parasite to internalize into host cells

Citoesqueleto

Extracellular matrix

Fosforilação

Heat shock proteins

Matriz extracelular

Parasite cytoskeleton

Phosphorylation

Proteínas do choque térmico

Trypanosoma cruzi

Trypanosoma cruzi