Airway Dynamics and the Role of Zyxin

Rosner, Sonia Rebecca

06 June 2014

Morbidity and mortality attributable to asthma arise mainly from contraction of airway smooth muscle (ASM) and resulting bronchospasm. Bronchospasm that is induced in the laboratory is easily reversed by a spontaneous deep inspiration (DI) whereas bronchospasm that occurs spontaneously in asthma is not. In response to a spontaneous DI, contracted ASM fluidizes rapidly and then resolidifies slowly, but molecular mechanisms accounting for these salutary bronchodilatory responses -and their dramatic breakdown in asthma- are unknown. Using a multi-scale approach, I show here that both the baseline contractile force and the fluidization response of ASM are independent of the cytoskeletal protein zyxin, whereas the resolidification response is zyxin-dependent. At the levels of the stress fiber, the isolated cell, and the integrated airway, zyxin acts to stabilize the contractile apparatus and promote the resolidification response. More than just the motor of contraction, ASM is thus viewed in the broader context of a self-healing active material wherein resolidification and its molecular determinants contribute to the biology of bronchospasm.

Biology

Biophysics

Physiology

airway smooth muscle

cryopreservation

deep inspiration

PCLS

stretch

zyxin

Diverse functions for intern associated proteins in Drosophila adult muscle

Green, Hannah Jane

January 2017

The ability to adhere to the extracellular matrix (ECM) is critical for numerous cell types and tissues including epithelia and muscle. Cell-ECM adhesion is primarily mediated by integrins which provide a direct link between the ECM and the actin cytoskeleton. Integrin adhesions are frequently associated with a core of 60 different proteins (integrin-associated proteins, IAPs). Integrins are required for muscle attachment and in Drosophila, loss of integrins and several IAPs results in embryonic lethality and muscle detachment. However, the IAPs FAK, RSU1, tensin, vinculin and zyxin are not required for viability or embryonic muscle attachment. Furthermore, FAK, RSU1, tensin and vinculin have been observed to localise to muscle attachment sites in Drosophila, indicating that they have some function in muscle attachment. Unlike FAK, RSU1, tensin and vinculin, it was not previously known whether zyxin is expressed in Drosophila muscles. To test this, I generated a genomic zyxin-GFP construct that should contain most of the endogenous zyxin promotor. The genomic zyxin-GFP construct was not observed at muscle attachment sites, suggesting that it is not normally expressed in muscle. I wished to know whether FAK, RSU1, tensin and vinculin are required for muscle function. Various behavioural assays were employed to test for muscle function in larvae and adult flies. The results suggest that larval muscle function was normal in flies lacking these IAPs, but that adult muscle function might be impaired, although it proved difficult to demonstrate a clear functional defect. I then tested whether the IAPs FAK, RSU1, tensin and vinculin are required for normal morphology of adult muscles, focusing on the adult indirect flight muscles (IFMs). The IFMs are fibrillar muscles which attach to the cuticle via specialised epithelial cells known as tendon cells. At the end of the myofibril, where the myofibril attaches to the tendon cell, is a dense region of actin and IAPs known as the modified terminal Z-band (MTZ). I have found that the MTZ is not a homogenous zone of proteins, but is instead organised into at least three distinct layers. Because of the similarity between the structure of the MTZ with that of a hand, I refer to the layers as ‘fingers’, ‘palm’ and ‘wrist’. I discovered that the IAPs FAK, RSU1, tensin and vinculin are each required for the proper structure of the MTZ in unique ways. The fingers were elongated in IFMs lacking FAK, RSU1, tensin or vinculin, while the palm was disrupted in IFMs lacking RSU1, tensin or vinculin. Finally, I was intrigued by the enrichment of the actin-binding protein filamin/Cheerio in the palm and wished to know if it is required for palm function. Deletion of the C-terminus of filamin/Cheerio resulted in a reduction in palm length. Filamin/Cheerio is a mechanosensitive protein which exists in a closed and open conformation. I found that filamin/Cheerio must be open in order to help form a normal palm. Furthermore, vinculin is required to convert filamin/Cheerio from and closed to an open filamin/Cheerio state so that it can perform its function in the palm.

595.77

Zyxin Regulates Epithelial-Mesenchymal Transition by Mediating Actin-Membrane Linkages at Cell-Cell Junctions

Sperry, Liv Rebecca

04 August 2009

Development is punctuated by morphogenetic rearrangements of epithelial tissues, including complete detachment of individual motile cells during epithelial-mesenchymal transition (EMT). Dramatic actin rearrangements occur as cell-cell junctions are dismantled and cells become independently motile during EMT. Characterizing dynamic actin rearrangements and identifying actin machinery driving these rearrangements is essential for understanding basic mechanisms of cell-cell junction remodeling; yet, neither the precise series of actin rearrangements at cell-cell junctions that accompany EMT, nor the machinery that controls actin rearrangement during EMT, have been identified. This work represents a detailed study of junctional actin reorganization in cells undergoing EMT, identifies actin regulatory proteins that control this actin reorganization, and defines the specific function of one regulatory protein, zyxin, in EMT. Using immunofluorescence and live cell imaging of HGF induced scattering of MDCK cells, dynamic actin rearrangement events occurring during EMT are characterized. Junctional actin characteristic of cell-cell adherent cells is rearranged into contractile medial actin networks linked to the junctional membrane in the initial steps of cell scattering. This actin rearrangement is accompanied by dynamic redistribution of specific actin regulatory proteins, namely α-actinin and zyxin-VASP complexes. α-Actinin mediates higher order structure of junctional actin. Zyxin-VASP complexes mediate linkage of dynamic medial actin networks to adherens junction membranes. Zyxin regulation of actin-membrane linkage controls whether cell migration during EMT occurs independently in solitary cells or is coordinated through tissues. The functional analysis employed here uses novel, quantitative methods that define specific cellular EMT ‘phenotypes’ to reveal the precise role of zyxin in EMT. Constitutive active zyxin mutants exhibit persistent actin-membrane linkages and a scattering phenotype in which cells migrate without loss of cell-cell adhesion. Zyxin is proposed to regulate EMT progression by regulating disruption or maintenance of actin membrane linkages at cell-cell junctions. Zyxin alters the ability of cells to fully detach and migrate independently during EMT and may be an important regulator of morphogenetic plasticity.

zyxin

VASP

actin cytoskeleton

epithelial-mesenchymal transition

MDCK

cell-cell adhesion

Cell and Developmental Biology

Physiology

Estudo da expressão e participação de VASP e Zyxin na diferenciação hematopoiética, na leucemia mieloide crônica e na via de sinalização BCR-ABL / VASP and Zyxin expression and participation in hematopoietic differentiation, in chronic myeloid leukemia and BCR-ABL signaling pathway

Bernusso, Vanessa Aline, 1980-

07 February 2013

Orientadores: Karin Spat Albino Barcellos Silveira, Sara Teresinha Olalla Saad / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-23T03:35:28Z (GMT). No. of bitstreams: 1 Bernusso_VanessaAline_M.pdf: 2366309 bytes, checksum: d89f227d922fcfaba6696c0e1af0fdae (MD5) Previous issue date: 2013 / Resumo: VASP (Vasodilator-stimulated phosphoprotein) e Zyxin são proteínas reguladoras de actina que controlam a adesão célula-célula. Zyxin dirige a montagem da actina através da interação e recrutamento da VASP a sítios específicos da adesão. A fosforilação da VASP ou da Zyxin altera suas atividades nas junções aderentes. PKA fosforila VASP em serina 157, regulando, assim, importantes funções celulares de VASP. VASP interage com ABL e é substrato da oncoproteína BCR-ABL. A presença da proteína BCR-ABL promove a oncogênese em pacientes com leucemia mieloide crônica (LMC) devido à ativação constitutiva da atividade tirosina quinase. Apesar de já descrita alteração da expressão de VASP e Zyxin em diferentes tumores epiteliais, o papel de VASP e Zyxin na LMC, na via de sinalização BCR-ABL e a participação destas proteínas na hematopoiese são desconhecidos. Desta maneira, demonstramos aqui ausência de p-VASP ser157 em células de medula óssea de pacientes com LMC, em contraste com a presença de p-VASP ser157 em doadores saudáveis. Pacientes com LMC em remissão, responsivos a inibidores de tirosina quinase, apresentam p-VASP ser157, enquanto os pacientes resistentes não expressam p-VASP ser157. Utilizando células K562 inibidas para VASP ou Zyxin, observamos que VASP e Zyxin modulam as proteínas anti-apoptóticas BCL-2 e BCL-XL da via de sinalização do BCR-ABL. Em adição, células K562 silenciadas para a VASP apresentam diminuição na atividade de FAK y925 e demonstramos que VASP interage com FAK. A expressão de VASP e Zyxin e de suas formas ativas aumenta durante a diferenciação megacariocítica e a inibição de VASP implica em diminuição na expressão do marcador CD61. Identificamos no presente estudo a participação de VASP e Zyxin na via do BCR-ABL, regulando a expressão de proteínas efetoras anti-apoptóticas e, também, na diferenciação megacariocítica. Desta maneira, a expressão alterada da atividade de VASP nos pacientes com LMC pode contribuir para a patogênese da doença, seja afetando a diferenciação celular ou a adesão das células leucêmicas / Abstract: VASP (vasodilator-stimulated phosphoprotein) and Zyxin are actin regulatory proteins that control cell-cell adhesion. Zyxin directs actin assembly by interacting and recruiting VASP to specific sites of adhesion. The phosphorylation of VASP and Zyxin modifies their activity in cell-cell junctions. PKA phosphorylates VASP at serine 157 regulating VASP cellular functions. VASP interacts with ABL and VASP is a substrate of BCR-ABL oncoprotein. The presence of BCR-ABL protein drives oncogenesis in patients with chronic myeloid leukemia (CML) due to a constitutive activation of tyrosine kinase activity. It has been described an altered expression of VASP and Zyxin in different types of tumor; however the function of VASP and Zyxin in CML, in BCR-ABL pathway and in hematopoiesis remains unknown. We describe here the absence of p-VASP ser157 in CML bone marrow cells, in contrast to p-VASP ser157 expression in healthy donors. Patients responsive to tyrosine kinase inhibitors present p-VASP ser157, while resistant patients do not have p-VASP ser157. In K562 cells we observed that VASP and Zyxin modulate anti-apoptotic proteins BCL-2 and BCL-XL. VASP depletion in K562 cells decreases FAK y925 activity and VASP interacts with FAK. Expression of VASP, p-VASP, Zyxin and p-Zyxin increases during megakaryocyte differentiation and VASP inhibition affects this differentiation through reduced CD61 expression in VASP depleted cells. We identify here the participation of VASP and Zyxin in BCR-ABL pathway affecting anti-apoptotic proteins and, also, in megakaryocyte differentiation. Then, the altered expression of VASP activity in CML patients may contribute to CML pathogenesis, affecting cellular differentiation or leukemic cell adhesion / Mestrado / Fisiopatologia Médica / Mestra em Ciências

Leucemia mielóide crônica

Adesão celular

Diferenciação megacariocítica

VASP

Zixina

Chronic myeloid leukemia

Cell adesion

Megakaryocytic differentiation

VASP

Zyxin

Caractérisation moléculaire et cellulaire de la dégénérescence musculaire dépendante de la dystrophine chez le nématode Cænorhabditis elegans / Molecular and cellular characterisation of dystrophin-dependant muscle degeneration in the nematode Cænorhabditis elegans

Lecroisey-Leroy, Claire

20 September 2010

La Dystrophie Musculaire de Duchenne (DMD) est la plus fréquente et la plus sévère des maladies dégénératives du muscle. Elle se caractérise par une dégénérescence progressive des fibres musculaires due à l’absence de dystrophine fonctionnelle dans les muscles. Actuellement, le rôle physiologique de la dystrophine n’est pas clairement établi et il n’existe pas encore de traitement curatif pour cette maladie. La difficulté de mettre en évidence la fonction de la dystrophine et la physiopathologie de la DMD est en partie expliquée par la complexité moléculaire et cellulaire du muscle des modèles vertébrés utilisés dans les études actuelles. Notre équipe de recherche a développé un modèle de DMD chez le nématode Caenorhabditis elegans. Dans ce modèle, la mutation du gène de la dystrophine, provoque une dégénérescence progressive des muscles conduisant à une paralysie des animaux adultes. Nous utilisons ce modèle afin d’étudier la fonction de la dystrophine et les mécanismes impliqués dans la dégénérescence musculaire chez le nématode. Ce travail de thèse porte sur deux nouveaux acteurs de la dégénérescence musculaire dépendante de la dystrophine : la protéine DYC‐1 et son principal partenaire ZYX‐1. Ce travail présente la caractérisation de ces deux protéines et étudie leurs fonctions dans le muscle. Par ailleurs, ce travail de thèse présente les premiers résultats d’un projet de microscopie électronique ayant pour but de caractériser en détail les évènements subcellulaires du processus dégénératif au cours du cycle de vie du nématode dystrophique. À plus long terme, les études chez le nématode permettront de proposer de nouvelles hypothèses quant aux mécanismes moléculaires et cellulaires de la dégénérescence musculaire / Duchenne Muscular Dystrophy (DMD) is the most prevalent and one of the most severe muscular dystrophy. DMD is due to the absence of functional dystrophin in cardiac and skeletal muscle cells, this lack leads to a progressive muscle degeneration of contractile fibres. Currently, the physiological role of dystrophin is not yet clearly established and curative treatments for DMD are not yet available. The lack of knowledge about dystrophin function and DMD physiopathology can be partly attributed to the complexity of vertebrate muscle, and the absence of a simple model that emulates the human pathology. Our research team developed a model of muscle degeneration in the nematode Caenorhabditis elegans. In this model, the mutation of the dystrophin gene produces a progressive muscle degeneration leading to the paralysis of the adult worms. We use this model for investigating the role of dystrophin and the mechanisms of muscle degeneration in C. elegans. This PhD work concerns two new actors of dystrophin‐dependant muscle degeneration: The DYC‐1 protein and its main interactor ZYX‐1. This study aims to characterise these proteins and to study their muscle functions. Moreover, this PhD work presents preliminary results of an in depth characterisation of subcellular processes of muscle degeneration in dystrophic worms by electron microscopy. Our aim is to visualise first events and to observe the progression of degeneration until the death of muscle cell. These molecular and cellular approaches aims to get new insights in the mechanisms underlying muscle degeneration in order to propose new hypotheses for the understanding of DMD

Myopathie de Duchenne

Dystrophine

C. elegans

Nématode

Muscle

Dégénérescence musculaire

Zyxine

Microscopie électronique

Duchenne Muscular Dystrophy

Dystrophin

C. elegans

Nematode

Muscle

Muscle degeneration

Zyxin

Electron Microscopy

573.75

Effects of Shear Stress on the Distribution of Kindlins in Endothelial Cells

Jones, Sidney V.

29 May 2014

No description available.

Cellular Biology

Chemistry

Biochemistry

Biomechanics

integrin

kindlin

fibronectin

laminin

extracellular matrix

zyxin

tubulin

actin

clathrin

cytoskeletal rearrangment

hemodynamic

shear stress

endothelial cell

mechanotransduction

vinculin

cell-cell junction

atherosclerosis

colocalization