scholarly journals Vinculin anchors contractile actin to the cardiomyocyte adherens junction

2019 ◽  
Author(s):  
Chelsea D. Merkel ◽  
Yang Li ◽  
Qanber Raza ◽  
Donna B. Stolz ◽  
Adam V. Kwiatkowski
Keyword(s):  
Mechanical Stability ◽  
Mechanical Load ◽  
Adherens Junction ◽  
Actin Binding ◽  
Cellular Organization ◽  
Dynamic Changes ◽  
Actin Networks ◽  
Tissue Organization ◽  
Physiological Demands ◽  
Critical Link

AbstractThe adherens junction (AJ) couples the actin cytoskeletons of neighboring cells to allow mechanical integration and tissue organization. The physiological demands of intercellular adhesion require that the AJ be responsive to dynamic changes in force while maintaining mechanical load. These demands are tested in the heart, where cardiomyocyte AJs must withstand repeated cycles of actomyosin-mediated contractile force. Here we show that force-responsive cardiomyocyte AJs recruit actin-binding ligands to selectively couple actin networks and promote contact maturation. We employed a panel of N-cadherin-αE-catenin fusion proteins to rebuild AJs with specific actin linkages in N-cadherin-null cardiomyocytes. In this system, vinculin recruitment was required to rescue myofibril integration and desmosome assembly at nascent contacts. In contrast, loss of vinculin disrupted junction morphology and blocked myofibril integration. Our results identify vinculin as a critical link to contractile actomyosin and offer insight to how actin integration at the AJ is regulated to provide mechanical stability and cellular organization.

scholarly journals Vinculin anchors contractile actin to the cardiomyocyte adherens junction

2019 ◽  
Vol 30 (21) ◽  
pp. 2639-2650 ◽  
Author(s):  
Chelsea D. Merkel ◽  
Yang Li ◽  
Qanber Raza ◽  
Donna B. Stolz ◽  
Adam V. Kwiatkowski
Keyword(s):  
Fusion Proteins ◽  
Mechanical Load ◽  
Adherens Junction ◽  
Contractile Force ◽  
Actin Binding ◽  
Dynamic Changes ◽  
Actin Networks ◽  
Tissue Organization ◽  
Physiological Demands ◽  
Critical Link

The adherens junction (AJ) couples the actin cytoskeletons of neighboring cells to allow mechanical integration and tissue organization. The physiological demands of intercellular adhesion require that the AJ be responsive to dynamic changes in force while maintaining mechanical load. These demands are tested in the heart, where cardiomyocyte AJs must withstand repeated cycles of actomyosin-mediated contractile force. Here we show that force-responsive cardiomyocyte AJs recruit actin-binding ligands to selectively couple actin networks. We employed a panel of N-cadherin-αE-catenin fusion proteins to rebuild AJs with specific actin linkages in N-cadherin-null cardiomyocytes. In this system, vinculin recruitment was required to rescue myofibril integration at nascent contacts. In contrast, loss of vinculin from the AJ disrupted junction morphology and blocked myofibril integration at cell–cell contacts. Our results identify vinculin as a critical link to contractile actomyosin and offer insight to how actin integration at the AJ is regulated to provide stability under mechanical load.

scholarly journals Tropomyosin 3.5 protects F-actin networks required for tissue biomechanical properties

2018 ◽  
Author(s):  
Catherine Cheng ◽  
Roberta B. Nowak ◽  
Michael B. Amadeo ◽  
Sondip K. Biswas ◽  
Woo-Kuen Lo ◽  
...  
Keyword(s):  
Mechanical Load ◽  
Biomechanical Properties ◽  
Tissue Mechanics ◽  
Actin Binding ◽  
Eye Lens ◽  
Lens Fiber ◽  
Load Bearing ◽  
Actin Networks ◽  
Fiber Cells

AbstractTropomyosins (Tpms) stabilize F-actin and regulate interactions with other actin-binding proteins. The eye lens changes shape in order to fine focus light to transmit a clear image, and thus lens organ function is tied to its biomechanical properties, presenting an opportunity to study Tpm functions in tissue mechanics. The major mouse lens Tpm is Tpm3.5 (TM5NM5), a previously unstudied isoform. Decreased levels of Tpm3.5 lead to softer and less mechanically resilient lenses that are unable to resume their original shape after compression. While cell organization and morphology appear unaffected, Tmod1 dissociates from the membrane in Tpm3.5-deficient lens fiber cells resulting in reorganization of the spectrin-F-actin and α-actinin-F-actin networks at the membrane. These rearranged F-actin networks appear to be less able to support mechanical load and resilience leading to an overall change in tissue mechanical properties. This is the firstin vivoevidence that Tpm is essential for cell biomechanical stability in a load-bearing non-muscle tissue and indicates that Tpm3.5 protects mechanically stable, load-bearing F-actinin vivo.SummaryTropomyosin 3.5 stabilizes F-actin in eye lens fiber cells and promotes normal tissue biomechanical properties. Tpm3.5 deficiency leads to F-actin network rearrangements and decreased lens stiffness and resilience.

scholarly journals Filamin A Regulates Cardiovascular Remodeling

2021 ◽  
Vol 22 (12) ◽  
pp. 6555
Author(s):  
Sashidar Bandaru ◽  
Chandu Ala ◽  
Alex-Xianghua Zhou ◽  
Levent M. Akyürek
Keyword(s):  
Transcription Factors ◽  
Respiratory Diseases ◽  
Cell Function ◽  
Actin Binding ◽  
Cardiovascular Development ◽  
Filamin A ◽  
Cardiovascular Malformations ◽  
Experimental Animal Models ◽  
Actin Networks ◽  
Cardiovascular Remodeling

Filamin A (FLNA) is a large actin-binding cytoskeletal protein that is important for cell motility by stabilizing actin networks and integrating them with cell membranes. Interestingly, a C-terminal fragment of FLNA can be cleaved off by calpain to stimulate adaptive angiogenesis by transporting multiple transcription factors into the nucleus. Recently, increasing evidence suggests that FLNA participates in the pathogenesis of cardiovascular and respiratory diseases, in which the interaction of FLNA with transcription factors and/or cell signaling molecules dictate the function of vascular cells. Localized FLNA mutations associate with cardiovascular malformations in humans. A lack of FLNA in experimental animal models disrupts cell migration during embryogenesis and causes anomalies, including heart and vessels, similar to human malformations. More recently, it was shown that FLNA mediates the progression of myocardial infarction and atherosclerosis. Thus, these latest findings identify FLNA as an important novel mediator of cardiovascular development and remodeling, and thus a potential target for therapy. In this update, we summarized the literature on filamin biology with regard to cardiovascular cell function.

scholarly journals CapZ integrates several signaling pathways in response to mechanical stiffness

2019 ◽  
Vol 151 (5) ◽  
pp. 660-669 ◽  
Author(s):  
Christopher Solís ◽  
Brenda Russell
Keyword(s):  
Mechanical Load ◽  
Phosphorylation Site ◽  
Tight Binding ◽  
Neonatal Rat ◽  
Actin Binding ◽  
Mechanical Stimuli ◽  
Muscle Adaptation ◽  
Capping Protein ◽  
Actin Capping Protein ◽  
Actin Capping

Muscle adaptation is a response to physiological demand elicited by changes in mechanical load, hormones, or metabolic stress. Cytoskeletal remodeling processes in many cell types are thought to be primarily regulated by thin filament formation due to actin-binding accessory proteins, such as the actin-capping protein. Here, we hypothesize that in muscle, the actin-capping protein (named CapZ) integrates signaling by a variety of pathways, including phosphorylation and phosphatidylinositol 4,5-bisphosphate (PIP2) binding, to regulate muscle fiber growth in response to mechanical load. To test this hypothesis, we assess mechanotransduction signaling that regulates muscle growth using neonatal rat ventricular myocytes cultured on substrates with the stiffness of the healthy myocardium (10 kPa), fibrotic myocardium (100 kPa), or glass. We investigate how PIP2 signaling affects CapZ using the PIP2 sequestering agent neomycin and the effect of PKC-mediated CapZ phosphorylation using the PKC-activating drug phorbol 12-myristate 13-acetate (PMA). Molecular simulations suggest that close interactions between PIP2 and the β-tentacle of CapZ are modified by phosphorylation at T267. Fluorescence recovery after photobleaching (FRAP) demonstrates that the kinetic binding constant of CapZ to sarcomeric thin filaments in living muscle cells increases with stiffness or PMA treatment but is diminished by PIP2 reduction. Furthermore, CapZ with a deletion of the β-tentacle that lacks the phosphorylation site T267 shows increased FRAP kinetics with lack of sensitivity to PMA treatment or PIP2 reduction. Förster resonance energy transfer (FRET) probes the molecular interactions between PIP2 and CapZ, which are decreased by PIP2 availability or by the β-tentacle truncation. These data suggest that CapZ is bound to actin tightly in the idle, locked state, with little phosphorylation or PIP2 binding. However, this tight binding is loosened in growth states triggered by mechanical stimuli such as substrate stiffness, which may have relevance to fibrotic heart disease.

scholarly journals Control of microtubule dynamics using an optogenetic microtubule plus end–F-actin cross-linker

2017 ◽  
Vol 217 (2) ◽  
pp. 779-793 ◽  
Author(s):  
Rebecca C. Adikes ◽  
Ryan A. Hallett ◽  
Brian F. Saway ◽  
Brian Kuhlman ◽  
Kevin C. Slep
Keyword(s):  
Blue Light ◽  
Actin Binding ◽  
Cross Linking ◽  
Dependent Manner ◽  
Exclusion Zone ◽  
Actin Networks ◽  
Drosophila Melanogaster S2 Cells ◽  
Actin Binding Domain ◽  
Specific Factors ◽  
Insight Into

We developed a novel optogenetic tool, SxIP–improved light-inducible dimer (iLID), to facilitate the reversible recruitment of factors to microtubule (MT) plus ends in an end-binding protein–dependent manner using blue light. We show that SxIP-iLID can track MT plus ends and recruit tgRFP-SspB upon blue light activation. We used this system to investigate the effects of cross-linking MT plus ends and F-actin in Drosophila melanogaster S2 cells to gain insight into spectraplakin function and mechanism. We show that SxIP-iLID can be used to temporally recruit an F-actin binding domain to MT plus ends and cross-link the MT and F-actin networks. Cross-linking decreases MT growth velocities and generates a peripheral MT exclusion zone. SxIP-iLID facilitates the general recruitment of specific factors to MT plus ends with temporal control enabling researchers to systematically regulate MT plus end dynamics and probe MT plus end function in many biological processes.

scholarly journals Ezrin is an Actin Binding Protein That Regulates Sertoli Cell and Spermatid Adhesion During Spermatogenesis

Endocrinology ◽  
2014 ◽  
Vol 155 (10) ◽  
pp. 3981-3995 ◽  
Author(s):  
N. Ece Gungor-Ordueri ◽  
Elizabeth I. Tang ◽  
Ciler Celik-Ozenci ◽  
C. Yan Cheng
Keyword(s):  
Sertoli Cell ◽  
Sertoli Cells ◽  
Adherens Junction ◽  
Actin Binding ◽  
Permeability Barrier ◽  
Tight Junction Permeability ◽  
Residual Bodies ◽  
Cell Interface

Abstract During spermatogenesis, the transport of spermatids and the release of sperms at spermiation and the remodeling of the blood-testis barrier (BTB) in the seminiferous epithelium of rat testes require rapid reorganization of the actin-based cytoskeleton. However, the mechanism(s) and the regulatory molecule(s) remain unexplored. Herein we report findings that unfold the functional significance of ezrin in the organization of the testis-specific adherens junction at the spermatid-Sertoli cell interface called apical ectoplasmic specialization (ES) in the adluminal compartment and the Sertoli cell-cell interface known as basal ES at the BTB. Ezrin is expressed at the basal ES/BTB in all stages, except from late VIII to IX, of the epithelial cycle. Its knockdown by RNA interference (RNAi) in vitro perturbs the Sertoli cell tight junction-permeability barrier via a disruption of the actin microfilaments in Sertoli cells, which in turn impeded basal ES protein (eg, N-cadherin) distribution, perturbing the BTB function. These findings were confirmed by a knockdown study in vivo. However, the expression of ezrin at the apical ES is restricted to stage VIII of the cycle and limited only between step 19 spermatids and Sertoli cells. A knockdown of ezrin in vivo by RNAi was found to impede spermatid transport, causing defects in spermiation in which spermatids were embedded deep inside the epithelium, and associated with a loss of spermatid polarity. Also, ezrin was associated with residual bodies and phagosomes, and its knockdown by RNAi in the testis also impeded the transport of residual bodies/phagosomes from the apical to the basal compartment. In summary, ezrin is involved in regulating actin microfilament organization at the ES in rat testes.

scholarly journals Contribution of Filopodia to Cell Migration: A Mechanical Link between Protrusion and Contraction

2010 ◽  
Vol 2010 ◽  
pp. 1-13 ◽  
Author(s):  
Fei Xue ◽  
Deanna M. Janzen ◽  
David A. Knecht
Keyword(s):  
Cell Migration ◽  
Actin Polymerization ◽  
Myosin Ii ◽  
Temporal Distribution ◽  
Leading Edge ◽  
Distal Portion ◽  
Actin Binding ◽  
Actin Networks ◽  
Motile Cells ◽  
A Cell

Numerous F-actin containing structures are involved in regulating protrusion of membrane at the leading edge of motile cells. We have investigated the structure and dynamics of filopodia as they relate to events at the leading edge and the function of the trailing actin networks. We have found that although filopodia contain parallel bundles of actin, they contain a surprisingly nonuniform spatial and temporal distribution of actin binding proteins. Along the length of the actin filaments in a single filopodium, the most distal portion contains primarily T-plastin, while the proximal portion is primarily bound byα-actinin and coronin. Some filopodia are stationary, but lateral filopodia move with respect to the leading edge. They appear to form a mechanical link between the actin polymerization network at the front of the cell and the myosin motor activity in the cell body. The direction of lateral filopodial movement is associated with the direction of cell migration. When lateral filopodia initiate from and move toward only one side of a cell, the cell will turn opposite to the direction of filopodial flow. Therefore, this filopodia-myosin II system allows actin polymerization driven protrusion forces and myosin II mediated contractile force to be mechanically coordinated.

scholarly journals Actin Cytoskeleton Manipulation by Effector Proteins Secreted by DiarrheagenicEscherichia coliPathotypes

2013 ◽  
Vol 2013 ◽  
pp. 1-22 ◽  
Author(s):  
Fernando Navarro-Garcia ◽  
Antonio Serapio-Palacios ◽  
Paul Ugalde-Silva ◽  
Gabriela Tapia-Pastrana ◽  
Lucia Chavez-Dueñas
Keyword(s):  
Actin Cytoskeleton ◽  
Host Cell ◽  
Virulence Factors ◽  
Cell Biology ◽  
Bacterial Species ◽  
Effector Proteins ◽  
Actin Binding ◽  
E Coli ◽  
Tissue Organization ◽  
Epithelial Barriers

The actin cytoskeleton is a dynamic structure necessary for cell and tissue organization, including the maintenance of epithelial barriers. Disruption of the epithelial barrier coincides with alterations of the actin cytoskeleton in several disease states. These disruptions primarily affect the paracellular space, which is normally regulated by tight junctions. Thereby, the actin cytoskeleton is a common and recurring target of bacterial virulence factors. In order to manipulate the actin cytoskeleton, bacteria secrete and inject toxins and effectors to hijack the host cell machinery, which interferes with host-cell pathways and with a number of actin binding proteins. An interesting model to study actin manipulation by bacterial effectors isEscherichia colisince due to its genome plasticity it has acquired diverse genetic mobile elements, which allow having differentE. colivarieties in one bacterial species. TheseE. colipathotypes, including intracellular and extracellular bacteria, interact with epithelial cells, and their interactions depend on a specific combination of virulence factors. In this paper we focus onE. colieffectors that mimic host cell proteins to manipulate the actin cytoskeleton. The study of bacterial effector-cytoskeleton interaction will contribute not only to the comprehension of the molecular causes of infectious diseases but also to increase our knowledge of cell biology.

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