bims-ecemfi Biomed News
on ECM and fibroblasts
Issue of 2026–06–07
eight papers selected by
Badri Narayanan Narasimhan, University of California, San Diego
  1. Controlling 3D Contractility via Engineered Fibrous Hydrogel Composites.
  2. Engineering Apical Integrin-Binding Cellular Patches to Direct Cell Reprogramming via Mechanical Remodeling.
  3. Mechanically Programmable DNA Hydrogel Microparticles for 3D Cellular Systems.
  4. Fibronectin matrix remodelling modulates the active nematic dynamics of cancer-associated fibroblasts.
  5. Mechanical licensing of functional dendritic cell states for enhanced T cell priming.
  6. Hierarchical Programming of Peptide Hydrogels via Electrostatic Coassembly and Dityrosine Cross-Linking.
  7. Cell differentiation can underpin the reproducibility of morphogenesis.
  8. A novel reaction-diffusion architecture for engineering self-organized patterns in mammalian cells.
  1. Adv Funct Mater. 2026 May 04. pii: e24101. [Epub ahead of print]36(36):
    Controlling 3D Contractility via Engineered Fibrous Hydrogel Composites.
    Karen L Xu, Yuqi Zhang, Alysse DeFoe, Georgios Kotsaris, Brendan Stoeckl, Matthew D Davidson, Jason A Burdick, Robert L Mauck.
      Complex and dynamic mechanobiological crosstalk occurs between cells and their extracellular matrix (ECM) to support contraction, a process required for tissue morphogenesis and wound healing. In vitro models can be used to study this crosstalk by mimicking the ECM (collagen fibers within a ground substance) using controlled environments and defined mechanics. While useful, most in vitro models utilize poorly-defined natural hydrogels that lack independent control over hydrogel properties and contraction tunability. Here, a fully-defined hydrogel composite is introduced consisting of fragmented synthetic fibers (a collagen fiber mimic) that, when embedded within a synthetic hydrogel (a ground substance mimic), supports cell-mediated traction-based contraction in a manner similar to traditional collagen gels. Tuning this composite material by modulating fragmented fiber density and length and embedding hydrogel density and crosslinking enables control over contraction. Cells cultured within contraction-permissive constructs support microtissue cell alignment and local densification of fiber fragments, while culture in contraction-resistant composites (greater embedding hydrogel crosslinking) do not. This innovative composite material expands our ability to interrogate the complex cell-ECM interplay during tissue morphogenesis.
    Keywords:  contraction; electrospun fibers; hyaluronic acid; hydrogels; microtissues
    DOI:  https://doi.org/10.1002/adfm.202524101
  2. ACS Nano. 2026 Jun 05.
    Engineering Apical Integrin-Binding Cellular Patches to Direct Cell Reprogramming via Mechanical Remodeling.
    Junchao Zhi, Tianrui Zhao, Wenjing Hou, Qizheng Zhang, Zhen Gao, Jiancan Yu, Kai Wu, Chenjie Xu, Xunwu Hu, Ye Zhang.
      Engineering extracellular microenvironments to control stem cell fate remains a central challenge in regenerative medicine. Here, we develop ECM-mimetic cellular patches formed by the supramolecular assembly of laminin-derived, integrin-binding ligands. The resulting fibrillar networks exhibit well-defined molecular packing and nanoscale ligand distribution, enabling specific engagement of apical integrin β1 on mesenchymal stem cells. This controlled interface converts molecular assembly into hierarchical mechanotransduction, coordinating cytoskeletal remodeling, nuclear deformation, and chromatin reorganization to drive neuronal reprogramming without genetic or chemical induction. Mechanistic studies reveal that the interplay between ligand assembly, spatial orientation, and network stability governs integrin activation and downstream transcriptional regulation. These findings demonstrate how molecularly programmed assemblies can transform passive matrices into active, cell-instructive materials. This work establishes a framework for designing supramolecular systems that couple structural hierarchy with mechanotransductive control to direct stem cell fate and advance regenerative material strategies.
    Keywords:  cell reprogramming; cellular patches; integrin; mechanical remodeling; peptide assembly
    DOI:  https://doi.org/10.1021/acsnano.6c04114
  3. Adv Mater. 2026 May 31. e14218
    Mechanically Programmable DNA Hydrogel Microparticles for 3D Cellular Systems.
    Tobias Walther, Eleni Dalaka, Gotthold Fläschner, Manuel Gómez-González, Ilia Platzman, Sadaf Pashapour, Michelle Emmert, Pere Roca-Cusachs, Xavier Trepat, Kerstin Göpfrich.
      Hydrogel microparticles (HMPs) are powerful tools to study and manipulate cellular behavior in 3D cell culture systems and animal models. Here, fully DNA-based HMPs are presented, whose material properties can be precisely tuned by sequence-programmable design of self-assembling DNA nanostructures. These DNA-HMPs offer control over size, stiffness, viscoelasticity and ligand presentation. They are formed by microfluidic encapsulation of two types of orthogonal DNA nanostars and a sequence-complementary DNA linker in water-in-oil droplets. By varying the valency of the DNA nanostar designs, tunable mechanical properties are achieved - spanning three orders of magnitude in Young's modulus from 30Pa$30 \,\mathrm{Pa}$ to 6.5kPa$6.5 \,\mathrm{k}\mathrm{Pa}$ with distinct viscoelastic behavior. Click-chemistry based functionalization with the small fibronectin-derived peptide cyclic-RGD (c[RGD]) enables integration into fibroblast spheroids. DNA-HMPs are stably retained within the spheroids for several days and undergo remodeling, indicating active interactions between the cells and the DNA-HMPs. Combining programmable material properties and inherent biocompatibility of DNA with straightforward functionalization and stimuli-responsiveness, these DNA-HMPs represent a versatile tool to probe and manipulate tissue behaviors in 3D cell cultures.
    Keywords:  3D cell culture; DNA hydrogel; DNA nanotechnology; biomaterials; hydrogel microparticles; mechanobiology; microfluidics
    DOI:  https://doi.org/10.1002/adma.202514218
  4. Nat Mater. 2026 Jun 01.
    Fibronectin matrix remodelling modulates the active nematic dynamics of cancer-associated fibroblasts.
    Cécile Jacques, Louisiane Perrin, Joseph Ackermann, Samuel Bell, Olivier Zajac, Ambre Lapierre, Lucas Anger, Clément Hallopeau, Carlos Pérez-González, Lakshmi Balasubramaniam, Xavier Trepat, Benoît Ladoux, Ananyo Maitra, Raphael Voituriez, Danijela Matic Vignjevic.
      Cancer-associated fibroblasts are major architects of the tumour stroma, where their aligned, elongated morphology forms a capsule that mechanically restrains tumour expansion. However, it is unclear how this supracellular organization emerges and persists. Here we show that fibroblasts generate a fibronectin matrix that progressively acquires the same nematic order as the cell layer, and that this matrix in turn feeds back to immobilize both cells and topological defects. Using long-term live imaging, traction force microscopy, matrix microfabrication and hydrodynamic modelling, we find that this reciprocal coupling induces an ageing process in which cellular flows and defect motion slow dramatically and ultimately freeze. Despite this arrest, the monolayer remains active, with defects concentrating contractile forces that may represent mechanical weak points. Disrupting fibronectin production fluidizes the capsule, reactivates defect dynamics and compromises its barrier-like function. These findings reveal a self-organizing mechanism by which fibroblasts and their matrix co-evolve to create a mechanically stable, yet active, stromal architecture with direct implications for tumour dissemination.
    DOI:  https://doi.org/10.1038/s41563-026-02615-5
  5. bioRxiv. 2026 May 23. pii: 2026.05.19.725170. [Epub ahead of print]
    Mechanical licensing of functional dendritic cell states for enhanced T cell priming.
    Yu-Chang Chen, Amanda S Bluem, Fatemeh Tavakoli Joorabi, Kexin Zhang, Nghi M Tran, Shuchen Zhang, Hardik Makkar, Kyle H Vining.
      The plasticity of dendritic cell (DC) functional state is a major hurdle in DC therapy, yet how DCs acquire distinct states independent of ontogeny remains poorly understood. Here, we demonstrate that changes in matrix stress relaxation mechanically educate DCs to adopt distinct, persistent functional states even after the removal of mechanical cues. Stem cell-derived DCs cultured in a fast-relaxing environment exhibited enhanced antigen presentation, faster migration, and higher expression of T cell-recruiting chemokines. Slow-relaxing DCs, biased towards pro-inflammatory cytokine secretion, were enriched for gene signatures associated with lipid accumulation and stress response. These mechanical responses were conserved across human and murine DCs. Using ovalbumin (OVA) as the model antigen, fast-relaxing DCs elicited a CD8+-biased response in vitro, with higher antigen-specific CD8+ T cell activation and proliferation. In vivo adoptive cell transfer of mechanically educated DCs demonstrated that the fast-relaxing matrix licensed DCs to induce a potent draining lymph node T cell response with more antigen-specific T cells and higher restimulation potential. We further showed that DCs sensed matrix stress relaxation through PI3K signaling and actin branching, mediated by the concerted signaling of IL-4 and GM-CSF. Together, these findings demonstrate the role of matrix stress relaxation on the functional state of DCs and suggest a novel approach to enhance ex vivo cellular engineering by targeting mechanical signaling.
    DOI:  https://doi.org/10.64898/2026.05.19.725170
  6. ACS Appl Mater Interfaces. 2026 Jun 02.
    Hierarchical Programming of Peptide Hydrogels via Electrostatic Coassembly and Dityrosine Cross-Linking.
    Yuhan Qian, Xianan Li, Guoyao Shen, Feili Zhang, Huaimin Wang, Zhaoqianqi Feng.
      The extracellular matrix in living tissues undergoes dynamic mechanical changes that govern fundamental processes in development and disease, yet most synthetic hydrogels are mechanically static and cannot reproduce this programmability. Here, we report a covalent-supramolecular hybrid peptide hydrogel platform that enables two-stage, hierarchical stiffening. A family of short peptides undergoes electrostatic coassembly to form a supramolecular network, producing an order-of-magnitude increase in initial stiffness. Subsequent light-induced dityrosine cross-linking introduces a second, covalent stiffening phase. Remarkably, simple repositioning of tyrosine residues directs the final material architecture: one design yields stiffening fibrous hydrogels, whereas another generates cell-internalized nanospheres. This work demonstrates precise control over mechanical and structural outcomes, providing a programmable bioinspired building block for the development of dynamic biomaterials.
    Keywords:  dityrosine cross-linking; electrostatic coassembly; peptide; programmable assembly; self-assembly
    DOI:  https://doi.org/10.1021/acsami.6c02238
  7. PLoS Comput Biol. 2026 Jun 04. 22(6): e1014361
    Cell differentiation can underpin the reproducibility of morphogenesis.
    Dominic K Devlin, Austen R D Ganley, Nobuto Takeuchi.
      Morphogenesis of complex body shapes is reproducible despite the noise inherent in the underlying morphogenetic processes. However, how these morphogenetic processes work together to achieve this reproducibility remains unclear. Here, we ask how this reproducibility is achieved by evolving complex morphologies in a multi-scale, computational model. Each morphology consists of a population of cells on a two-dimensional grid using the Cellular Potts Model framework. Each cell contains a genome that encodes a gene regulatory network, morphogens for cell-cell signalling, and proteins that determine cell behaviours. By repeatedly simulating our model with different initial conditions under selection for shape complexity, we obtained a "zoo" of evolved morphologies. We find that these evolved, complex morphologies are reproducible in a sizeable fraction of simulations, despite no direct selection for reproducibility. We show that high reproducibility is caused by spatially segregating moving cells that "shape" morphologies from stationary cells that "maintain" morphologies during morphogenesis. Strikingly, most highly reproducible morphologies also evolved cell differentiation, where proliferative, moving progenitor cells irreversibly differentiate into non-dividing, stationary differentiated cells at tissue boundaries. These results suggest that cell differentiation observed in natural development plays a fundamental role in morphogenesis in addition to the production of specialised cell types. This previously unrecognised role of cell differentiation has major implications for our understanding of how morphologies are generated and regenerated.
    DOI:  https://doi.org/10.1371/journal.pcbi.1014361
  8. bioRxiv. 2026 May 25. pii: 2026.05.24.727552. [Epub ahead of print]
    A novel reaction-diffusion architecture for engineering self-organized patterns in mammalian cells.
    Benjamin Swedlund, John J Danan, Ting-Xin Jiang, Soha Ben Tahar, Kyle Poon, Pranav S Bhamidipati, Zachary A Kreiger, Sandra Murillo, Minnal Kunnan, Daniel J G Pearce, Cheng-Ming Chuong, Ian M Ehrenreich, Leonardo Morsut.
      Reaction-diffusion circuits generate self-organized spatial patterns through local activation and long-range inhibition, but synthetic implementations in mammalian cells have been limited by the differential-diffusion requirement. Here, we introduce a novel architecture, juxtacrine activation with paracrine inhibition (JAPI), where the activator propagates through cell-cell contacts rather than diffusion. We demonstrate mathematically and numerically that JAPI accesses the same patterning regimes as classical diffusion-based circuits with one fewer free parameter. We then engineer compact synNotch-based JAPI circuits in mammalian fibroblasts and demonstrate their sufficiency for self-organized patterning through tunable, size-limited signal propagation. Functionalized to spatially control morphogen secretion, these circuits perturb feather bud formation on adjacent embryonic chicken epidermis. Finally, we develop a library-based approach to explore coupled, dual-JAPI circuits with tunable cross-inhibition, enabling programmable interactions between patterns and access to a broad morphospace of spatial states. Together, JAPI provides a compact, modular platform for programming self-organized multicellular patterning.
    DOI:  https://doi.org/10.64898/2026.05.24.727552
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