More Like this

1. Chemotaxis of Drosophila border cells is modulated by tissue geometry through dispersion of chemoattractants

   https://doi.org/10.1016/j.isci.2025.111959  

   George, Alexander; Akhavan, Naghmeh; Peercy, Bradford E; Starz-Gaiano, Michelle (March 2025, iScience)

   Cell migration is critical throughout a multicellular organism’s life from embryogenesis to immune response and tissue repair and can even go aberrantly wrong in diseases like metastatic cancer. In vitro, graded concentrations of diffusible chemoattractants can guide migrating cells, but less is known about chemoattractant distribution and chemotaxis within living organisms, which have complex tissue geometries. Using the border cells, which migrate collectively in the Drosophila egg chamber during oogenesis, we studied how tissue structure affects chemotaxis in vivo. Live-imaged border cells exhibited variations in their chemotactic migration, which correlated positionally within distinct tissue architectures, specifically acellular gaps at cell-cell intersections. To determine how different regions in the egg chamber’s geometry affect chemical cues, we developed a partial differential equation (PDE) model of chemoattractant distribution within a relevant in silico domain. Using a hybrid mathematical model that couples the chemoattractant PDE and an agent-based motion of the cluster, we found that larger extracellular volumes within intersections could locally dampen chemoattractant gradient magnitudes and slow cluster speed in simulations. In vivo, in response to genetically increasing the levels of a chemoattractant, PDGF- and VEGF-related factor 1, border cells exhibited delayed migration and behaved differently within specific architectural regions, consistent with results in silico. We next altered the architectural regions in the migration domain in half pint (hfp) mutant egg chambers and observed migration behaviors that still correlated with tissue features. Importantly, the abnormal tissue geometry was sufficient to rescue defects due to high levels of chemoattractant and resulted in punctual border cell migration indicating chemoattractant distribution can depend on tissue structure. Our modeling data indicate that chemoattractants are more concentrated in certain tissue architectures and dispersed in other regions, likely informing cell migration speeds and favoring clustered cell movements in tissue that contain varied architectures in vivo. Our results shed light on the intricate interplay between tissue geometry and the local distribution of important signaling molecules in orchestrating the essential process of cell migration. 

   more » « less
2. Epithelial Layer Fluidization by Curvature-Induced Unjamming

   https://doi.org/10.1103/PhysRevLett.134.138402  

   De_Marzio, Margherita; Das, Amit; Fredberg, Jeffrey J; Bi, Dapeng (April 2025, Physical Review Letters)

   The transition of an epithelial layer from a stationary, quiescent state to a highly migratory, dynamic state is required for wound healing, development, and regeneration. This transition, known as the unjamming transition (UJT), is responsible for epithelial fluidization and collective migration. Previous theoretical models have primarily focused on the UJT in flat epithelial layers, neglecting the effects of strong surface curvature characteristic of the epithelium in vivo. In this Letter, we investigate the role of surface curvature on tissue plasticity and cellular migration using a vertex model embedded on a spherical surface. Our findings reveal that increasing curvature promotes the UJT by reducing the energy barriers to cellular rearrangements. Higher curvature favors cell intercalation, mobility, and self-diffusivity, resulting in epithelial structures that are malleable and migratory when small, but become more rigid and stationary as they grow. Together, these results provide a conceptual framework to better understand how cell shape, cell propulsion, and tissue geometry contribute to tissue malleability, remodeling, and stabilization. 

   more » « less
3. Cell-mediated matrix deformations and cell–cell adhesions determine epithelial collective cell migration phenotypes

   https://doi.org/10.1063/5.0295506  

   Leonard, Corinne E; Lichtenberg, Jessanne Y; Sterling, Hazel R; Rolston, Jesse; Tran, Sydnie K; Hwang, Priscilla Y (December 2025, APL Bioengineering)

   Successful development of tissue structures requires different collective cell migration patterns or phenotypes. Two examples of collective migration phenotypes in epithelial morphogenic processes, such as tubulogenesis, are rotational and invasive. Rotational collective migration phenotypes (RCM) typically lead to acinar structures, and invasive collective migration (ICM) phenotypes lead to duct-like structures. How cells adopt these different phenotypes is still largely unknown. Here, we investigate how cell–cell adhesion marker P-cadherin (CDH3) and mechanical cell–matrix interactions, including matrix deformations, protrusions, and focal adhesions, control rotational or invasive phenotypes during tubulogenesis. To accomplish our objective, we created a custom 3D microfluidic assay to perform live-cell imaging of epithelial clusters or cysts [wild-type (WT) and CDH3-depleted (CDH3-/-)] undergoing tubulogenesis, while simultaneously measuring matrix deformation rates. Our findings reveal WT epithelial cysts maintain rotational phenotypes, but transition to an invasive phenotype to undergo tubulogenesis. Furthermore, we demonstrate ICM phenotypes correlate with higher matrix deformation rates compared to rotational phenotypes. Our studies reveal CDH3 is required for epithelial cysts to transition from rotational to ICM phenotypes, associated with decreased matrix deformation rates. Without CDH3, epithelial cysts lose their ability to adopt ICM phenotypes, which can be rescued by RhoA activation. Finally, we demonstrate that the RhoA-rescued ICM phenotype is mediated, in part, by increased matrix deformation rates and vinculin recruitment to focal adhesion sites. 

   more » « less
4. A geometric-tension-dynamics model of epithelial convergent extension

   https://doi.org/10.1073/pnas.2321928121  

   Claussen, Nikolas; Brauns, Fridtjof; Shraiman, Boris I (October 2024, Proceedings of the National Academy of Sciences)

   Convergent extension of epithelial tissue is a key motif of animal morphogenesis. On a coarse scale, cell motion resembles laminar fluid flow; yet in contrast to a fluid, epithelial cells adhere to each other and maintain the tissue layer under actively generated internal tension. To resolve this apparent paradox, we formulate a model in which tissue flow in the tension-dominated regime occurs through adiabatic remodeling of force balance in the network of adherens junctions. We propose that the slow dynamics within the manifold of force-balanced configurations is driven by positive feedback on myosin-generated cytoskeletal tension. Shifting force balance within a tension network causes active cell rearrangements (T1 transitions) resulting in net tissue deformation oriented by initial tension anisotropy. Strikingly, we find that the total extent of tissue deformation depends on the initial cellular packing order. T1s degrade this order so that tissue flow is self-limiting. We explain these findings by showing that coordination of T1s depends on coherence in local tension configurations, quantified by a geometric order parameter in tension space. Our model reproduces the salient tissue- and cell-scale features of germ band elongation duringDrosophilagastrulation, in particular the slowdown of tissue flow after approximately twofold elongation concomitant with a loss of order in tension configurations. This suggests local cell geometry contains morphogenetic information and yields experimentally testable predictions. Defining biologically controlled active tension dynamics on the manifold of force-balanced states may provide a general approach to the description of morphogenetic flow. 

   more » « less
5. A deficiency screen of the X chromosome for Rap1 GTPase dominant interacting genes in Drosophila border cell migration

   https://doi.org/10.1093/g3journal/jkaf040  

   Messer, C Luke; Burghardt, Emily; McDonald, Jocelyn A (February 2025, G3: Genes, Genomes, Genetics)

   Bergstralh, D (Ed.)

   Abstract Collective cell migration is critical to embryonic development, wound healing, and the immune response, but also drives tumor dissemination. Understanding how cell collectives coordinate migration in vivo has been a challenge, with potential therapeutic benefits that range from addressing developmental defects to designing targeted cancer treatments. The small GTPase Rap1 has emerged as a regulator of both embryogenesis and cancer cell migration. How active Rap1 coordinates downstream signaling functions required for coordinated collective migration is poorly understood. Drosophila border cells undergo a stereotyped and genetically tractable in vivo migration within the developing egg chamber of the ovary. This group of 6–8 cells migrates through a densely packed tissue microenvironment and serves as an excellent model for collective cell migration during development and disease. Rap1, like all small GTPases, has distinct activity state switches that link extracellular signals to organized cell behaviors. Proper regulation of Rap1 activity is essential for successful border cell migration yet the signaling partners and other downstream effectors are poorly characterized. Using the known requirement for Rap1 in border cell migration, we conducted a dominant suppressor screen for genes whose heterozygous loss modifies the migration defects observed upon constitutively active Rap1V12 expression. Here, we identified 7 genomic regions on the X chromosome that interact with Rap1V12. We mapped three genomic regions to single Rap1-interacting genes, frizzled 4, Ubiquitin-specific protease 16/45, and strawberry notch. Thus, this unbiased screening approach identified multiple new candidate regulators of Rap1 activity with roles in collective border cell migration. 

   more » « less