Exogenous FNIII 12-14 Regulates TGF-β1-Induced Markers

Humeid, Hilmi M

01 January 2018

The extracellular matrix protein Fibronectin (FN) plays an important role in cell contractility, differentiation, growth, adhesion, and migration. The 12th -14th Type III repeats of FN (FNIII 12-14), also referred to as the Heparin-II domain, comprise a highly promiscuous growth factor (GF) binding region. This binding domain aids in cellular signaling initiated from the ECM. Additionally, FN has the ability to assemble into fibrils under certain conditions, mostly observed during cell contractile processes such as those that initiate due to upregulation of Transforming Growth Factor Beta 1 (TGF-β1) [1], [2]. Previous work from our lab has shown that self-assembly of FN into insoluble fibrils is crucial for Epithelial-Mesenchymal Transition (EMT) [3]. The transition from epithelial to mesenchymal cell type has been implicated as an early event in tumor formation and breast cancer. We were previously able to find that upregulation of FN fibrils drive EMT through contractility due to the increase of the GF latent TGF-β complex concentration at the cell membrane [3]. The challenge in the current work is to exploit the role of Heparin-II binding domain and to concentrate growth factors of interest, such as those that are pro-EMT or anti-EMT at the signaling sites of the cell membrane. Initially, we investigated the localization of the fragments FNIII 12-14 delivered to cell membrane using FITC conjugated protein. We then investigated the effects of exogenous FNIII 12-14 on EMT using breast epithelial cells (MCF10A) in the presence or absence of TGF-β1 to determine whether FNIII 12-14 alters EMT signaling. Quantification of mRNA expression, for EMT markers such as Slug, Snail, Twist, and ZEB1 were analyzed. Results showed that dosage increase of FNIII 12-14 appears to inhibit EMT transcription factors. This study will develop a new understanding of disease and gene control using ECM proteins. The exploitation of ECM natural protein interactions could become a new method in turning on/off genes of interest. While we are currently investigating this as a mechanism of blocking EMT, it could also have implications in wound healing, fibrosis, and tissue engineering, where EMT is an important aspect of the physiologic progression.

EMT

Fibronectin

FNIII 12-14

LTBP1

TGF-β1

Slug

Snail

Twist

ZEB1

Animal Diseases

Biological Engineering

Biology

Etude de l’auto-assemblage de la fibronectine plasmatique humaine : mécanismes et réponses cellulaires / Study of human plasma fibronectin self-assembly : mechanisms and cell responses

Bascetin, Rumeyza

20 November 2014

La matrice extracellulaire est un réseau enchevêtré de macromolécules variées, en étroite relation avec les cellules qu'elle environne. Les interactions bidirectionnelles qui s'établissent entre les cellules et leur microenvironnement matriciel régulent mutuellement leur comportement et devenir. La diversité biochimique des constituants moléculaires de la matrice, leurs propriétés biophysiques, leur architecture tout comme leur dynamique représentent autant de signaux régulateurs. Parmi les constituants de la matrice, la fibronectine (FN) est une glycoprotéine structurale et fonctionnelle majeure intervenant dans de nombreux processus physiologiques et pathologiques. Ces fonctions diverses sont directement liées à la dynamique structurale de cette protéine et à sa capacité à interagir avec les autres molécules matricielles, dont elle-même. Retrouvée sous forme soluble dans les fluides biologiques, la FN est incorporée dans les matrices insolubles sous forme d'assemblages supramoléculaires principalement fibrillaires mais aussi sous forme d'agrégats. Ces assemblages sembleraient être impliqués dans des processus physiologiques et pathologiques distincts.Si l'étude des assemblages de FN est rendue possible par l'élaboration de modèles in vitro, les mécanismes de polymérisation et l'effet d'assemblages de structures définies sur le comportement cellulaire restent cependant à mieux élucider et constituent le cœur de ce travail.Les travaux ont donc consisté à élaborer des assemblages de FN, à caractériser les mécanismes et structures impliqués dans leur polymérisation, et à étudier leur influence sur un modèle de cellules cancéreuses ovariennes. D'autre part, des études préliminaires comparatives ont été menées avec un analogue végétal de la FN.L'irréversibilité de la dénaturation thermique de la FN entraîne la formation d'agrégats de type amyloïde. Deux populations d'agrégats coexistent en solution. Cette agrégation est corrélée à une diminution de l'accessibilité des sites de liaison à la gélatine et des sites RGD, et à une diminution de l'incorporation dans les réseaux matriciels. De plus, si la FN sous sa forme agrégée n'est pas cytotoxique pour les cellules étudiées, la modification de la conformation de la FN favorise leur migration isolée et aléatoire.Ces résultats soulèvent la question de l'implication de ces agrégats de FN dans des processus pathologiques tels que le développement tumoral. / Extracellular matrix is a complex meshwork of various macromolecules that have a tight relationship with the surrounding cells. Bidirectional interactions between cells and the microenvironment control their respective behaviors and fate. The biochemical diversity of matrix molecular components, their biophysical properties, their architecture but also their dynamic represent as many regulator signals. Among the components of the matrix, fibronectin (FN) is a major structural and functional glycoprotein involved in numerous physiological and pathological processes. These various functions are directly linked to the structural dynamic of this protein and its ability to interact with others matrix components, in particular with itself. Found as a soluble protein in biological fluids, FN is also incorporated in insoluble matrix as supramolecular assemblies, mainly fibrils but also aggregates. These assemblies could be involved in distinct physiological and pathological processes.If the study of the assembly of the FN is possible with the help of in vitro models, the mechanism of polymerization and the effects of defined assemblies on the cell behavior still have to be better defined.Therefore, this work consisted in elaborating FN assemblies, in characterizing the mechanisms and structures involved in their polymerization and in studying their influence on behaviors of a model of ovarian cancer cells. Besides, preliminary comparative studies have been performed with a plant analogous of FN.We show that irreversible thermal unfolding of FN triggers amyloid-like aggregation. Two states of aggregates could coexist in solution. FN aggregation correlates with a decrease of gelatin-binding domain and RGD sequence accessibility, and a decrease of the incorporation in the matrix network. Moreover, if aggregates are not cytotoxic for the studied cells, conformation change of FN promotes their single-cell and random migration.These results raise questions about the role of FN aggregates in pathological processes like tumor development.

Matrice extracellulaire

Fibronectine

Auto-Assemblage

Migration cellulaire

Cellule cancéreuse

Analogue végétal de la fibronectine

Extracellular matrix

Fibronectin

Self-Assembly

Cell migration

Cancer cell

Self-Assembly

Mecanisme d'activació de fibronectina i LEF1 per Snail1 durant la transició epili-mesènquima

Agustí Benito, Cristina

28 May 2007

La transició Epiteli-Mesènquima es dóna durant el desenvolupament embrionari i en els estadis tardans de la progressió tumoral permetent que es produeixi la metàstasi. Aquestes transicions necessiten una repressió de l'E-Cadherina i es pot reproduir en cèl·lules en cultiu amb l'expressió ectòpica de Snail1, un repressor de l'E-Cadherina. Durant la transició produïda per Snail es produeix la ràpida activació de gens mesenquimals com Fibronectina i LEF1. L'expressió forçada d'E-Cadherina fa disminuir els nivells de RNA de Fibronectina i LEF1, indicant que en l'activació d'aquests dos gens està implicat un cofactor sensible a l'E-Cadherina. En concordança, la transcripció de Fibronectina i LEF1 és depenent de -Catenina i NFB. La sobreexpressió d'E-Cadherina inhibeix l'activitat transcripcional d'aquests dos factors i disminueix la seva interacció amb el promotor de Fibronectina. De manera similar a la -Catenina, NFB es detecta associat a l'E-Cadherina i altres components dels contactes intercel·lulars. Quan es trenquen les unions adherents, com quan es sobreexpressa Snail, la interacció E-Cadherina-NFB disminueix i augmenta l'activitat transcripcional de NFB i-Catenina. / Epithelial to mesenchymal transitions takes place during embryo development and in the late stages of tumorigenesis allowing metastasis formation. These transitions require E-Cadherin downregulation and can be reproduced in cell culture by ectopic expression of Snail1, an E-Cadherin gene repressor. During Snail-induced transition a rapid upregulation of mesenchymal genes such as Fibronectin and LEF1 has been characterized. Forced expression of E-Cadherin strongly down-regulates Fibronectin and LEF1 RNA levels, indicating that an E-Cadherin sensitive cofactor is involved in the activation of these genes. Accordingly, transcription of Fibronectin and LEF1 was dependent on -Catenin and NFB. E-Cadherin over-expression downregulated the transcriptional activity of both factors and decreased their interaction to Fibronectin promoter. Similarly to -Catenin, NFB was detected associated to E-Cadherin and other cell adhesion components. Association of NFB to E-Cadherin required the integrity of this complex; conditions that disrupts adherens junctions, such as Snail over-expression, decreased E-Cadherin-NFB interaction and up-regulates NFB and -Catenin transcriptional activity. Therefore, -Catenin and NFB transcriptional activities are required for expression of the studied mesenchymal genes and these activities are inactivated by immobilizing -Catenin and NFB to functional E-Cadherin structures.

Fibronectin

b-Catenin

E-Cadherin

SOX7

SOX9

Fibronectina

LEF1

NFB

-Catenina

E-Cadherina

Snail1

MET

EMT

575

576

Collagen- and Fibronectin-Mimetic Integrin-Specific Surfaces That Promote Osseointegration

Reyes, Catherine Diane

10 July 2006

Cell adhesion to the extracellular matrix through cell-surface integrin receptors is essential to development, wound healing, and tissue remodeling and therefore represents a central theme in the design of bioactive surfaces that successfully interface with the body. This is especially significant in the areas of integrative implant coatings since adhesion triggers signals that regulate cell cycle progression and differentiation in multiple cellular systems. The interactions of osteoblasts with their surrounding extracellular matrix are essential for skeletal development and homeostasis and the maintenance of the mature osteoblastic phenotype. Our objective was to engineer integrin-specific bioactive surfaces that support osteoblastic differentiation and promote osseointegration by mimicking these interactions. We target two specific integrins essential to osteoblast differentiation the type I collagen receptor alpha2beta1 and the fibronectin receptor alpha5beta1. The central hypothesis of this project was that the controlled presentation of type I collagen and fibronectin binding domains onto well-defined substrates would result in integrin-specific bioadhesive surfaces that support osteoblastic differentiation, matrix mineralization, and osseointegration. We have demonstrated that these biomimetic peptides enhance bone formation and mechanical osseointegration on titanium implants in a rat tibia cortical bone model. We have also shown that the presentation of multiple integrin-binding ligands synergize to enhance intracellular signaling and proliferation. Finally, we demonstrate the advantage of the short biomimetic peptides over the native ECM proteins. This research is significant because it addresses current orthopaedic implant limitations by specifically targeting cellular responses that are critical to osteoblastic differentiation and bone formation. This biomolecular approach provides a versatile and robust strategy for developing bioactive surfaces that enhance bone repair and osseointegration of orthopaedic implants.

Biomimetics

Bone

Implants

Peptides

Cell adhesion

Titanium

Osteoblast

Biomaterials

Collagen

Fibronectin

Differentiation

Mineralization

Osseointegration

Osseointegration

Biomedical materials

Biomimetics

Cell adhesion

Integrins

Orthopedic implants

Adhesion

FAK Modulates Cell Adhesion Strengthening Via Two Distinct Mechanisms: Integrin Binding and Vinculin Localization

Michael, Kristin E.

16 November 2006

Cell adhesion to the extracellular matrix (ECM) provides tissue structure and integrity as well as triggers signals that regulate complex biological processes such as cell cycle progression and tissue-specific cell differentiation. Hence, cell adhesion is critical to numerous physiological and pathological processes, including embryonic development, cancer metastasis, and wound healing, as well as biotechnological applications, such as host responses to implanted devices and integration of tissue-engineered constructs. During the adhesion process, integrin surface receptors bind ECM proteins, cluster, and associate with the actin cytoskeleton. Subsequent strengthening of the integrin/actin cytoskeleton interaction occurs via complexes of proteins known as focal adhesions. Due to the close association between biochemical and biophysical processes within adhesion complexes, mechanical analyses can provide important new insights into structure/function relationships involved in regulating the adhesion process. The objective of this project was to investigate the role of the protein tyrosine kinase FAK in cell adhesion strengthening. Our central hypothesis was that FAK regulates adhesion strengthening by modulating interactions between integrins and FA structural components. Using a novel combination of genetically engineered cells to control the interactions of FAK, a spinning disk adhesion assay with micropatterned substrates to obtain reproducible and sensitive measurements of adhesion strength, and quantitative biochemical assays for analyzing changes in adhesive complexes, we demonstrate that FAK modulates adhesion strengthening via two distinct mechanisms: (1) FAK expression results in elevated integrin activation leading to regulation of strengthening rate and (2) FAK regulates steady-state adhesion strength via vinculin recruitment to focal adhesions. We also show that the autophosphorylation and catalytic sites of FAK are critical to this regulation of adhesion strengthening. This work is significant because it both identifies functional mechanisms of FAK and provides the first evidence that focal adhesion signaling regulates the adhesion strengthening process. Furthermore, this research demonstrates that the dependency of migration on adhesion strength is highly complex and establishes a need for adhesion strengthening metrics in analyzing the functional mechanisms of molecules within adhesion complexes.

Focal adhesion kinase

Extracellular matrix

Integrins

Cell adhesion

Cell mechanics

Force

Migration

Fibronectin

Extracellular matrix

Integrins

Fibronectins

Immobilized proteins

Focal adhesion kinase

Cell adhesion

Substratinduzierte Differenzierung von Endothelzellen

Herklotz, Manuela

19 August 2008

Der Erfolg neuer Strategien in der Regenerativen Medizin und im Tissue Engineering hängt maßgeblich von einem gut entwickeltem vaskulären Netzwerk ab, welches die auf den Implantaten wachsenden Zellen und Gewebe versorgen. Oberflächeneigenschaften der Implantate sowie die Präsentation verschiedener Liganden für extrazelluläre Matrixproteine spielen bei der Besiedlung der Implantate, als auch bei der Bildung versorgender Blutgefäße durch die Endothelzellen eine wesentliche Rolle. In dieser Arbeit konnte durch Variation der Anbindungsstärke (kovalent oder physisorptiv) des extrazellulären Matrixproteins Fibronektins an die MSA-Copolymere der Einfluss des Aufbaus der extrazellulären Matrix auf das Differenzierungsverhalten der Endothelzellen gezeigt werden. Auch die initiale Konzentration von Adhäsionsproteinen an der Substratoberfläche zeigte sich bedeutend für das Verhalten der Zellen. Optimal für eine gute Adhäsion, native Entwicklung und Kapillarbildung der Endothelzellen war die stabile (kovalente) Anbindung weniger Adhäsionsproteine (hier Fibronektin) an die Substratoberfläche, so dass die Zellen problemlos adhärieren konnten. Erfolgte die weiter Proteinadsorption an die Oberflächen in einem nativen Zustand (hier auf den hydrophilen Oberflächen) so waren die Endothelzellen in der Lage, die extrazelluläre Matrix zu reorganisieren und ein dem in vivo Zustand ähnlicher Aufbau der extrazellulären Matrix konnte realisiert werden. Dies ermöglichte den Zellen wiederum ein natürliches Verhalten. Die Ausbildung einer moderaten Anzahl von Adhäsionsstellen der Zellen, sowie der in vivo ähnliche Aufbau der Adhäsionspunkte ermöglichte den Zellen einen eher lockeren Kontakt zum Substrat. Daher waren sie sehr flexibel in ihrer Morphologieanpassung. Unter diesen Bedingungen war es möglich, dass die Endothelzellen bei Stimulierung der Angiogenese kapillarähnliche Strukturen ausbildeten. Die Verwendung dreidimensionaler Zellkulturträger zeigte eine Unterstützung der Kapillarbildung der Endothelzellen in Abhängigkeit unter den beschrieben Bedingungen. / The success of tissue engineering strategies using artificial scaffolds crucially depends on a controlled formation of well-developed vascular networks in growing tissues. The presentation of extracellular matrix ligands on scaffolds is often envisioned as an appropriate strategy to support capillary formation. We show that the control of primary coupling mode — covalent versus physisorbed — as well as of secondary interactions of cell-secreted extracellular matrix proteins have a strong impact on endothelial cell development. A set of maleic anhydride copolymer thin films was used as planar model substrates. They exhibit a switchable mode of primary matrix coupling combined with a gradation of secondary matrix–substrate interactions due to a variation of surface hydrophobicity and polarity. We found that the cells adhere in a more native state at a low amount of covalent primary coupled fibronectin ligands in conjunction with weak interactions of secondarily adsorbed adhesion ligands on hydrophilic surfaces. These substrates allow for a formation of capillary-like networks of endothelial cells. High ligand densities and strong secondary hydrophobic interactions inhibit a pronounced capillary formation. The composition and structure of the formed extracellular matrix correlates well with the specific integrin expression pattern. From these results it is concluded that the formation of blood capillaries in artificial scaffolds can be triggered by controlling primary and secondary coupling of cell adhesion ligands to implant materials. 2

Endothelzellen

Fibronektin

Angiogenense

Extrazelluläre Matrix

Integrine

Maleinsäureanhydridcopolymer

endothelial cells

fibronectin

angiogenesis

extracellular matrix

integrins

maleic anhydride copolymers

ddc:620

rvk:ZM 7070

Identification and characterization of a new adhesin involved in the binding of Streptococcus suis to the extracellular matrix proteins

Esgleas Izquierdo, Miriam

January 2008

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal

S. suis

S. Suis

MEC

ECM

Fibronectine

Fibronectin

Enolase

Enolase

IgG

IgG

HSP

HSP

Adhésion

Adhesion

Invasion

Invasion

Cellules endothéliales

Endothelial cells

Vaccin

Vaccine

Mediation of Osteoblast Responses to Titanium Roughness by Adsorbed Proteins

Wilson, Cameron

January 2005

Stable fixation of implants such as artificial teeth depends on the direct apposition of bone to the implanted material. While endosseous implants were traditionally allowed to "osseointegrate" over several months without carrying load, clinical and experimental data show that prostheses with roughened surfaces allow successful integration when subject to earlier loading and more challenging implant sites. However, to design implant surfaces for an optimal biological response requires an understanding of the mechanism by which roughened surfaces promote osseointegration. Research into this mechanism has, to date, focussed primarily on the response of osteoblastic cells to surface topography in vitro. While these have demonstrated some consistent trends in cell behaviour, the fundamental means by which cells sense and respond to roughness remain unclear. It has been suggested that cell responses to changes in topography may relate to differences in the proteins adsorbed from serum (in vitro). While experimental evidence indirectly suggests that physical features can affect protein adsorption, few studies have examined this with respect to surface roughness, particularly as a mediator of cell responses. To address this issue, cell culture and protein adsorption experiments were conducted on a limited range of surface textures. Titanium samples were ground to produce morphologically similar surfaces with three grades of roughness. A duplicate set of specimens were heated at 600°C for one hour, with the aim of masking potential variations in physicochemical properties with differing degrees of grinding. Osteoblast attachment and proliferation studies were conducted over a short time-frame of 48 hours or less, to highlight the effects of proteins adsorbed from serum rather than secreted by adherent cells. Gel electrophoresis provided a profile of the proteins adsorbed to each surface after 15 minutes, corresponding to the time by which the cells had settled onto the surface. Finally, confocal microscopy was used to examine cell morphology on each surface, and to visualize specific interactions between cellular structures and adsorbed adhesion-mediating proteins. Although the effects were inconsistent, attachment assays showed some indications that fewer cells attached in the first 90 minutes as roughness increased. This inverse cell number-roughness trend was significant at 48 hours; however, the variability in attachment assays prevented reliable separation of attachment and proliferation rate effects. While the reduction in cell number with increasing roughness is consistent with previous reports, it is typically observed at later time points, and thus may be increasingly confounded by contact inhibition and differentiation. Thermal oxidation of the titanium did not impact on osteoblast responses to roughness, although it significantly slowed cell proliferation. The latter result was unexpected on the basis of previous reports. One-dimensional gel electrophoresis revealed no significant differences in the composition of adsorbed layers with variations in roughness. However, as expected on account of wettability changes, the heat-treatment did correspond to significant changes in the adsorption profile. While this was not a highly sensitive analysis, it suggests that the cell responses to roughness changes were not governed by broadscale differences in the proteins initially available to adhering cells. In addition to the composition of the adsorbed layer, the distribution of proteins may also vary with topography. The immunofluorescence methods were not sufficiently sensitive to reveal the distribution of adsorbed adhesion proteins (vitronectin and fibronectin). However, the lack of clear labelling does suggest an absence of large accumulations due to specific topographic features. Further work is required to address this issue conclusively. Observations of cell morphology were consistent with widely-reported contact guidance phenomena on grooved surfaces, with elongation and alignment (with topography) increasing with groove depth. Cell elongation was also enhanced on the more hydrophilic, heat-treated titanium, but this effect diminished over time. Although increased elongation at 90 minutes corresponded to lower cell numbers at 48 hours, no causal relationship has yet been established.

Biomaterials

Cell attachment

Cell morphology

Cell proliferation

Cell spreading

Fibronectin

Heat treatment

Osteoblasts

Protein adsorption

Roughness

Surface topography

Thermal oxidation

Titanium

Vitronectin.

Propriedades adesivas a substratos abióticos e bióticos, invasão e indução de apoptose celular de Corynebacterium pseudodiphtheriticum / Adhesive properties to abiotic and biotic substrates, invasion and induction of apoptosis of Corynebacterium pseudodiphtheriticum

Monica Cristina de Souza

20 March 2013

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / A ocorrência de fenótipos multirresistentes de Corynebacterium pseudodiphtheriticum e sua associação a infecções graves, com elevada mortalidade em pacientes imunocomprometidos, aliados ao escasso conhecimento da virulência e patogenia destas infecções, motivou esta pesquisa, que teve como objetivo investigar mecanismos de virulência e resistência microbiana deste agente entre pacientes de um hospital universitário brasileiro. Um total de 113 amostras de C. pseudodiphtheriticum identificadas por métodos bioquímicos convencionais e sistema API-Coryne isoladas de pacientes de diferentes grupos etários. Os micro-organismos eram, em sua maioria, relacionados a infecções no trato respiratório (27,45%), urinário (29,20%) e sitios intravenosos (18,60%) e cerca de 32,70% das amostras foram provenientes de pacientes com pelo menos uma das condições predisponentes: insuficiência renal; transplante renal, tuberculose em paciente HIV+, câncer, cirrose hepática, hemodiálise e uso de cateter. As amostras testadas revelaram-se multirresistentes sendo a maioria resistente à oxacilina, eritromicina e clindamicina. A adesão das cepas ao poliestireno e ao poliuretano indicou o envolvimento de hidrofobicidade da superfície celular na fase inicial da formação de biofilmes. O crescimento subsequente conduziu à formação de microcolônias, agregados bacterianos densos incorporados na matriz exopolimérica rodeada por espaços vazios, típica de biofilmes maduros. Adicionalmente, a interação do micro-organismo com fibrinogênio e fibronectina humana indica o envolvimento destes componentes séricos na formação de biofilme, sugerindo a participação de diferentes adesinas neste processo e a capacidade deste agente formar biofilme in vivo. A afinidade por esses componentes e a formação de biofilme podem contribuir para o estabelecimento e disseminação da infecção no hospedeiro. Adicionalmente, as cepas de C. pseudodiphtheriticum isoladas de pacientes com infecções localizadas (ATCC10700/Pharyngitis) e sistêmicas (HHC1507/Bacteremia) exibiram um padrão de aderência agregativa-like a células HEp-2, caracterizado por aglomerados de bactérias com aparência de um "empilhado de tijolos". Através do teste FAS e ensaios de interação na presença de inibidores de citoesqueleto, demonstramos o envolvimento da polimerização de actina na internalização das cepas testadas. A internalização bacteriana e rearranjo do citoesqueleto pareceu ser parcialmente desencadeado pela ativação da tirosina-quinase. Finalmente, C. pseudodiphtheriticum foi capaz de sobreviver no ambiente intracelular e embora não tenha demonstrado capacidade de replicar intracelularmente, células HEp-2 foram incapazes de eliminar o patógeno completamente no ambiente extracelular no período de 24 horas. Todas as cepas estudadas foram capazes de induzir apoptose em células epiteliais 24 horas pós-infecção evidenciada pelo aumento significativo no número de células mortas e pela ocorrência de alterações nucleares reveladas através dos métodos de coloração pelo azul Trypan, pelo DAPI e microscopia electrônica de transmissão. Alterações morfológicas incluindo a vacuolização, a fragmentação nuclear e a formação de corpos apoptóticos foram observadas neste período. A citometria de fluxo demonstrou ainda uma diminuição significativa no tamanho das células infectadas e a utilização de dupla marcação (iodeto de propídio / anexina V) permitiu a detecção da ocorrência de necrose e apoptose tardia. Em conclusão, o conhecimento de tais características contribuiu para a compreensão de mecanismos envolvidos no aumento da frequência de infecções graves com elevada mortalidade em pacientes no ambiente hospitalar, por C. pseudodiphtheriticum, um patógeno rotineiramente subestimado em países em desenvolvimento. / The occurrence of multiresistant phenotypes and associated with severe infections, with high mortality in immunocompromised hosts due to Corynebacterium pseudodiphtheriticum, allied to little known about virulence and pathogenesis these infections, led to present investigation. The investigation aims to examine the virulence mechanisms and resistance to antimicrobial agents of C. pseudodiphtheriticum among patients with bacterial infections at a Brazilian teaching hospital. A total of 113 C. pseudodiphtheriticum strains identified by conventional biochemical methods and API-Coryne System were recovered from patients from different age groups. Micro-organisms were mostly related to infections in the respiratory tracts (27.45%), urinary (29.20%) and intravenous sites (18.60%) and approximately 32.70% samples were obtained of patients presenting at least one of the pre-disposing conditions: end-stage renal disease; renal transplant; AIDS and Mycobacterium tuberculosis infection; cancer, hepatic cirrhosis; haemodialysis and catheter use. Antimicrobial susceptibility tests identified multiresistant phenotypes. Most strains were resistant to oxacillin, erythromycin and clindamycin. Adherence to polystyrene and polyurethane indicated the involvement of cell surface hydrophobicity in the initial stage of biofilm formation. Further growth led to the formation of dense bacterial aggregates embedded in the exopolymeric matrix surrounded by voids, typical of mature biofilms. Data also showed C. pseudodiphtheriticum recognizing human fibrinogen (Fbg) and fibronectin (Fn) and involvement of these sera components in biofilm formation in conditioning films. These findings suggest that biofilm formation may be associated with the expression of different adhesins. C. pseudodiphtheriticum may form biofilm in vivo possibly by an adherent biofilm mode of growth in vitro currently demonstrated on hydrophilic and hydrophobic abiotic surfaces. The affinity to Fbg and Fn and the biofilm-forming ability may contribute to the establishment and dissemination of infection caused by C. pseudodiphtheriticum. Additionally, C. pseudodiphtheriticum strains isolated from patients with localized (ATCC10700/Pharyngitis) and systemic (HHC1507/Bacteremia) infections exhibited an aggregative adherence-like pattern to HEp-2 cells characterized by clumps of bacteria with a stacked-brick appearance. The fluorescent actin staining test demonstrated that actin polymerization is involved in the internalization of the C. pseudodiphtheriticum strains. Bacterial internalization and cytoskeletal rearrangement seemed to be partially triggered by the activation of tyrosine kinase activity. Although C. pseudodiphtheriticum strains did not demonstrate an ability to replicate intracellularly, HEp-2 cells were unable to fully clear the pathogen within 24 hours. All samples were able to induce apoptosis in HEp-2 cells 24 h post-infection, evidenced by significant increase in the number of dead cells and nuclear alterations were observed by the Trypan blue assay, DAPI and transmission electron microscopy. Morphological changes in HEp-2 cells observed 24 h post-infection included vacuolization, nuclear fragmentation and the formation of apoptotic bodies. Flow cytometry revealed an significant decrease in cell size of infected HEp-2 cells. Furthermore, a double-staining assay using Propidium Iodide/Annexin V gave information about the numbers of vital vs. early apoptotic cells and late apoptotic or secondary necrotic cells. In conclusion, these characteristics may contribute to understanding of mechanisms involved on increase of severe infection, with high mortality in nosocomial enviroment patients by C. pseudodiphtheriticum, a pathogen usually overlooked in emerging countries.

Corynebacterium pseudodiphtheriticum

Multirresistência

HEp-2 cells

Agregativa

Internalização

Biofilme

Fibrinogênio

Fibronectina

Apoptose

Necrose

Corynebacterium pseudodiphtheriticum

Multiresistance

HEp-2 cells

Aggregative

Internalization

Biofilm

Fibrinogen

Fibronectin

Apoptosis

Necrosis

MICROBIOLOGIA MEDICA

Vliv složek extracelulární matrix na buňky kultivované in vitro / The Influence of Extracellular Matrix Components to Cells Cultured In Vitro

Peterová, Eva

January 2017

Myofibroblast expansion is a critical event in the pathogenesis of liver fibrosis. The activation of hepatic stellate cells (HSC) to myofibroblast (MFB) results in the enhanced production of extracellular matrix (ECM). We have studied the effect of fibroblast growth factor 1 (FGF-1) on liver MFB. In the second part we investigated effect of transforming growth factor β1 (TGF-β1) and FGF-1 on cell line HSC-T6. Cells were cultured on plastic dishes and in 3D collagen gel mimicking fibrotic tissue. MFB were isolated by repeated passaging of nonparenchymal liver cell fraction. The transfer of MFB from plastic dishes to collagen gel resulted in the change in their shape and phenotype. The expression of cytokine TGF-β1 and of MFB markers, α-smooth muscle actin (α-SMA) and cellular fibronectin (EDA-FN) on protein level was significantly decreased in collagen gel. The experiments with SB 431542, the inhibitor of TGF-β receptor type I, showed that EDA-FN and α-SMA are differently regulated. EDA-FN expression is dependent on TGF-β1, while the expression of α-SMA is primarily determined by the environment and modified by TGF-β1. EDA-FN is more sensitive to the U0126, the inhibitor of protein kinases MEK 1 and 2. Collagen gel does not change the expression of metalloproteinase MMP-2 but activates the proenzyme....