Molly Lowndes scite author profile

During normal development and in disease, cohesive tissues undergo rearrangements that require integration of signals from cell adhesions to neighboring cells and to the extracellular matrix (ECM). How a range of cell behaviors is coordinated by these different adhesion complexes is unknown. To analyze epithelial cell motile behavior in response to combinations of cell-ECM and cell-cell adhesion cues, we took a reductionist approach at the single-cell scale by using unique, functionalized micropatterned surfaces comprising alternating stripes of ECM (collagenIV) and adjustable amounts of E-cadherin-Fc (EcadFc). On these surfaces, individual cells spatially segregated integrin-and cadherin-based complexes between collagenIV and EcadFc surfaces, respectively. Cell migration required collagenIV and did not occur on surfaces functionalized with only EcadFc. However, E-cadherin adhesion dampened lamellipodia activity on both collagenIV and EcadFc surfaces and biased the direction of cell migration without affecting the migration rate, all in an EcadFc concentration-dependent manner. Traction force microscopy showed that spatial confinement of integrin-based adhesions to collagenIV stripes induced anisotropic cell traction on collagenIV and migration directional bias. Selective depletion of different pools of αE-catenin, an E-cadherin and actin binding protein, identified a membrane-associated pool required for E-cadherin-mediated adhesion and down-regulation of lamellipodia activity and a cytosolic pool that down-regulated the migration rate in an E-cadherin adhesion-independent manner. These results demonstrate that there is crosstalk between E-cadherin-and integrin-based adhesion complexes and that E-cadherin regulates lamellipodia activity and cell migration directionality, but not cell migration rate.D uring development, cohesive tissues exhibit extensive rearrangements that range from en masse migration, such as in wound healing (1), to complex local cell rearrangements, such as cell intercalation (2). In extreme cases in development (3) and in diseases such as metastatic cancers (4), tissue cohesion is lost and single-cell migration enabled, which results in cells populating distant sites. These morphogenetic processes reveal the importance of a fine coregulation, or crosstalk, between tissue cohesion (cadherin-based cell-cell adhesion) and cell migration [integrinbased extracellular matrix (ECM) adhesion] in the maintenance of tissue integrity and function.Interest in the crosstalk between cell-cell adhesion and cell migration dates back to the pioneering studies of Abercrombie and Heaysman in the 1950s (5, 6) and even earlier (7). Abercrombie coined the term "contact inhibition" to describe how cell-cell interactions between fibroblasts initially inhibited and then redirected their migration. Whether cell-cell contact inhibition of cell migration results from cell-cell contact-dependent spatial redistribution or down-regulation of the cell migration machinery, or both remains unknown.A major component of inte...

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Different roles of cadherins in the assembly and structural integrity of the desmosome complex

Lowndes

Rakshit

Shafraz

et al. 2014

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Adhesion between cells is established by the formation of specialized intercellular junctional complexes, such as desmosomes. Desmosomes contain isoforms of two members of the cadherin superfamily of cell adhesion proteins, desmocollins (Dsc) and desmogleins (Dsg), but their combinatorial roles in desmosome assembly are not understood. To uncouple desmosome assembly from other cell-cell adhesion complexes, we used micro-patterned substrates of Dsc2aFc and/or Dsg2Fc and collagen IV; we show that Dsc2aFc, but not Dsg2Fc, was necessary and sufficient to recruit desmosome-specific desmoplakin into desmosome puncta and produce strong adhesive binding. Single-molecule force spectroscopy showed that monomeric Dsc2a, but not Dsg2, formed Ca 2+ -dependent homophilic bonds, and that Dsg2 formed Ca 2+ -independent heterophilic bonds with Dsc2a. A W2A mutation in Dsc2a inhibited Ca 2+ -dependent homophilic binding, similar to classical cadherins, and Dsc2aW2A, but not Dsg2W2A, was excluded from desmosomes in MDCK cells. These results indicate that Dsc2a, but not Dsg2, is required for desmosome assembly through homophilic Ca 2+ -and W2-dependent binding, and that Dsg2 might be involved later in regulating a switch to Ca 2+ -independent adhesion in mature desmosomes.

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Cell-state transitions and collective cell movement generate an endoderm-like region in gastruloids

Hashmi

Tlili

Perrin

et al. 2022

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Shaping the animal body plan is a complex process that involves the spatial organization and patterning of the different germ layers. Recent advances in live imaging have started to unravel the cellular choreography underlying this process in mammals, however, the sequence of events transforming an unpatterned cell ensemble into structured territories is largely unknown. Here, using gastruloids -3D aggregates of mouse embryonic stem cells- we study the formation of one of the three germ layers, the endoderm. We show that the endoderm is generated from an epiblast-like homogeneous state by a three-step mechanism: (i) a loss of E-cadherin mediated contacts in parts of the aggregate leading to the appearance of islands of E-cadherin expressing cells surrounded by cells devoid of E-cadherin, (ii) a separation of these two populations with islands of E-cadherin expressing cells flowing toward the aggregate tip, and (iii) their differentiation into an endoderm population. During the flow, the islands of E-cadherin expressing cells are surrounded by cells expressing T-Brachyury, reminiscent of the process occurring at the primitive streak. Consistent with recent in vivo observations, the endoderm formation in the gastruloids does not require an epithelial-to-mesenchymal transition, but rather a maintenance of an epithelial state for a subset of cells coupled with fragmentation of E-cadherin contacts in the vicinity, and a sorting process. Our data emphasize the role of signaling and tissue flows in the establishment of the body plan.

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Immobilized WNT Proteins Act as a Stem Cell Niche for Tissue Engineering

et al. 2016

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SummaryThe timing, location, and level of WNT signaling are highly regulated during embryonic development and for the maintenance of adult tissues. Consequently the ability to provide a defined and directed source of WNT proteins is crucial to fully understand its role in tissue development and to mimic its activity in vitro. Here we describe a one-step immobilization technique to covalently bind WNT3A proteins as a basal surface with easy storage and long-lasting activity. We show that this platform is able to maintain adult and embryonic stem cells while also being adaptable for 3D systems. Therefore, this platform could be used for recapitulating specific stem cell niches with the goal of improving tissue engineering.

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Molly Lowndes

Regulation of cell motile behavior by crosstalk between cadherin- and integrin-mediated adhesions

Different roles of cadherins in the assembly and structural integrity of the desmosome complex

Cell-state transitions and collective cell movement generate an endoderm-like region in gastruloids

Immobilized WNT Proteins Act as a Stem Cell Niche for Tissue Engineering

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