bims-enlima Biomed News
on Engineered living materials
Issue of 2026–04–19
35 papers selected by
Rahul Kumar, Tallinna Tehnikaülikool
  1. Guidance of cellular nematic elastomers into shape-programmable living surfaces.
  2. Synthetic control of implanted engineered liver tissue growth.
  3. Programmable Steric Control of Collagen Peptide-to-Fiber Assembly.
  4. AI speeds up design of devices that turn waste heat into electricity.
  5. Biohybrid Robots with Embedded Conductive Fibers for Actuation, Sensing, and Closed-loop Control.
  6. High-strength liquid metal composite-hydrogel interfaces enable robust stretchable electronics.
  7. Synthetic microbial co-cultures for modular bioelectronic sensing in diverse environments.
  8. Morphable architected materials with topologically variable and volumetric reconfiguration.
  9. Cell-in-Shell Metacells in Single-Cell Nanoencapsulation.
  10. 4D-Printed Spin Crossover Metamaterials with Giant Programmable Positive or Negative Thermal Expansion.
  11. 3D Printed In Vitro Engineered Living Material Models for Antimicrobial Development.
  12. Lignin-Based Surface Adhesion Engineering Enables Tough Hydrogel for Flexible Epidermal Array Sensing.
  13. Artificial allosteric protein switches with machine-learning-designed receptors.
  14. tRNA-deacylase-directed discovery of biosynthetic pathways.
  15. Efficient genome editing with chimeric oligonucleotide-directed editing.
  16. Mechanical memory primes cells for confined migration.
  17. Strengthening biofilms with selective metal ions.
  18. Optogenetics.
  19. Rapid volumetric bioprinting of pristine protein-based (bio)inks.
  20. Thermo-Rheological Memory of κ-Carrageenan Fluid Gels Formed under Flow.
  21. A Structurally Decoupled Single-Layer Soft Electronic Skin for Fast, Reliable, and Simultaneous Temperature-Pressure Sensing.
  22. Understanding the Swelling Behavior of Polysaccharide-Based Hydrogels through a Kinetic Modeling.
  23. Lipoengineering of Biomolecular Condensates Controls Material Properties and Multiphase Hierarchy to Guide Organoid Morphogenesis.
  24. Measurement-induced phase transitions in informational active matter.
  25. Micro-comb 3D printing: Rapid fabrication of tissue-guiding substrates using micro-embossed nozzles.
  26. Tough Environmentally Robust Cellulose Nanofiber-Reinforced Dual-Network Eutectogel with an Intelligent Self-Calibrating System for Human-Machine Interfaces.
  27. Bio-inspired cellular aerogel fibers integrating high mechanical strength and softness for thermal insulation textiles.
  28. Generative design of intrinsically disordered protein regions with IDiom.
  29. A familiar newcomer to the thermogenetic toolset.
  30. Beyond the mean: genetic control of gene expression fidelity and dispersion.
  31. Multifunctional Hemostatic Hydrogels Based on Natural Ionic Polymers: Dual Crosslinking Strategy for Rapid Bleeding Control and Infected Wound Management.
  32. Bottom-Up Programming of Cell States in Cancer Organoids with Defined Synthetic Adhesion Cues.
  33. Actually, what is a gain-of-function mutation?
  34. A biosynthetic survey of hypocrealean biocontrol fungi.
  35. A biomimetic liquid metal cell.
  1. Science. 2026 Apr 16. 392(6795): 317-323
    Guidance of cellular nematic elastomers into shape-programmable living surfaces.
    Pau Guillamat, Waleed Mirza, Pradeep K Bal, Manuel Gómez-González, Pere Roca-Cusachs, Marino Arroyo, Xavier Trepat.
      Engineering living materials that autonomously morph into predetermined shapes holds potential for synthetic morphogenesis and soft robotics. Harnessing cellular tissues to self-organize and generate forces offers a promising route toward this goal. However, controlling tissue mechanics to direct morphogenesis remains challenging. We introduce a strategy to program tissue-shape transformations through nematic organization of cellular forces. By controlling nematic order and topological defects, we generate tissues programmed with specific stress fields. Using a theoretical framework coupling contractile nematics with thin-sheet mechanics, we show that nematically guided active stresses can drive morphogenesis through Gaussian morphing. Experimentally, detachment of nematic tissues triggers out-of-plane deformations, generating reproducible three-dimensional shapes. Integrating contractility and nematic patterning, our approach establishes a framework for designing shape-programmable living surfaces.
    DOI:  https://doi.org/10.1126/science.adz9174
  2. Sci Adv. 2026 Apr 17. 12(16): eadz8362
    Synthetic control of implanted engineered liver tissue growth.
    Amy E Stoddard, Vardhman Kumar, Constantine N Tzouanas, Veronica Hui, Jeffrey Li, Anisha Jain, Alanna Farrell, Sangeeta N Bhatia, Christopher S Chen.
      Despite the promise of engineered tissue implants for the treatment of organ failure, scaling of these constructs to sizes of therapeutic relevance remains a barrier to clinical translation. Here, we propose a strategy to circumvent this limitation: to instead implant a small-scale construct and then induce it to grow in situ after its engraftment into a host. Using engineered liver tissue as a proof-of-concept application, we integrated synthetic biology and tissue engineering tools to build liver tissues that can be expanded on-demand after implantation in vivo. To achieve this goal, we first identified the combination of Yes-associated protein (YAP) and growth factor (GF) signaling as sufficient to drive human hepatocyte proliferation in dense, three-dimensional engineered tissues. We then engineered control of these signaling axes using synthetic biology tools to drive human liver tissue expansion both in vitro and in vivo. As such, this work establishes a genetic strategy for generating large organ implants through bioengineered on-demand outgrowth via synthetic biology triggering (BOOST).
    DOI:  https://doi.org/10.1126/sciadv.adz8362
  3. J Am Chem Soc. 2026 Apr 16.
    Programmable Steric Control of Collagen Peptide-to-Fiber Assembly.
    Pengfei Jin, David M Chenoweth.
      Peptide-based collagen-mimetic materials have drawn growing interest as fibrillar collagen surrogates due to their accessibility and versatility. However, an efficient strategy for assembling collagen peptides into well-defined collagen filaments remains elusive, owing to the nonspecific intermolecular interactions in collagen triple-helix formation. Here, we develop a new strategy for designing peptides that form triple-helical collagen-mimicking filaments using a single-residue side-chain modification. By organizing the intermolecular steric interactions in a "bump-gap" design, the peptides self-assemble into interlocked, endlessly growing triple-helical filaments with exceptional specificity. The peptide filaments exhibit high aspect ratios with micrometer lengths and are capable of forming networked structures that build hydrogels. These collagen-mimicking hydrogels, triggered by pH-dependent self-assembly, demonstrate superior stiffness over natural collagen with remarkable shear-thinning properties.
    DOI:  https://doi.org/10.1021/jacs.6c00833
  4. Nature. 2026 Apr;652(8110): 570-572
    AI speeds up design of devices that turn waste heat into electricity.
    Jing Cao, Ady Suwardi.
      
    Keywords:  Energy; Engineering; Machine learning; Materials science
    DOI:  https://doi.org/10.1038/d41586-026-00907-z
  5. bioRxiv. 2026 Apr 06. pii: 2026.04.01.715915. [Epub ahead of print]
    Biohybrid Robots with Embedded Conductive Fibers for Actuation, Sensing, and Closed-loop Control.
    Xinran Xie, Yuhui Zhao, Ruiheng Wu, Wenjia Xu, Michael J Bennington, Rachel Daso, Junyi Liu, Abhijith Surendran, Josiah Hester, Victoria A Webster-Wood, Tingyu Cheng, Jonathan Rivnay.
      Living organisms achieve adaptive actuation through the seamless integration of neural motor control circuitry and proprioceptive feedback. While biohybrid robotics aims to replicate these capabilities by merging engineered muscle with synthetic scaffolds, the field remains limited by interfaces that lack the efficiency and closed-loop regulation of natural neuromuscular systems. Here, we introduce a biohybrid muscle actuator system featuring a bioelectronic interface based on soft poly(3,4-ethylenedioxythiophene) (PEDOT) fibers for stimulation and sensing. These fibers conformally couple to muscle tissues, eliciting robust contractions at voltages as low as 1 V-requiring ultra-low power (0.376 ± 0.034 mW) and preserving long-term tissue viability. By leveraging the independent addressability of these fibers, we demonstrate selective actuation of individual muscle units to achieve precise spatiotemporal control of a two-muscle-powered walking biohybrid robot, reaching a locomotion speed of 5.43 ± 0.79 mm/min. When configured as strain sensors, the fibers exhibit a high gauge factor of 155.45 ± 6.59 and resolve contractile displacements within tens of micrometers. We demonstrate that this sensing modality can be integrated into a closed-loop controller to autonomously modulate stimulation based on real-time feedback, significantly mitigating muscle fatigue (p = 0.038) during continuous operation. This work establishes a versatile platform for efficient actuation and intrinsic feedback sensing, providing a blueprint for efficient, autonomous, and adaptive biohybrid machines.
    Summary: Soft conductive fibers enable a bioelectronic interface for low-power actuation and closed-loop control in biohybrid robots.
    DOI:  https://doi.org/10.64898/2026.04.01.715915
  6. Nat Commun. 2026 Apr 16.
    High-strength liquid metal composite-hydrogel interfaces enable robust stretchable electronics.
    Bingqian Jiao, Wei Wang, Yang Feng, Dingze Zhou, Xinghua Wang, Yanmin Zhou, Xia Wang, Yinghui Shang, Qigang Wang.
      Stretchable conductors are essential building blocks for next-generation wearable electronics and soft robotics. Among them, liquid metal-based conductors offer exceptional deformability but suffer from poor interfacial adhesion to substrates, often resulting in leakage under mechanical stress that compromises electromechanical stability and device durability. Here we report a universal interface-fusion printing strategy for fabricating metal-particle semi-embedded hydrogels, in which interconnected liquid metal and silver particles are firmly anchored at the hydrogel surface. The resulting liquid metal-based composite layer achieves a high interfacial adhesion strength of 234.4 kPa to the hydrogel substrate and a conductivity of 1.18 × 106 S m-1. This robust interface prevents liquid metal leakage and ensures stable electrical connection under extreme conditions, including prolonged ultrasonication, 300 MPa impacts, and thousands of stretching cycles. The strategy forms an interpenetrating cross‑linked polymer network through cross-interfacial assembly, fusing the circuit and substrate into an integrated structure. This simple and scalable method enables the fabrication of high‑resolution circuits for a wide range of electronic devices. We demonstrate its performance in applications including stretchable circuits, on-skin biosensors, and underwater soft robots.
    DOI:  https://doi.org/10.1038/s41467-026-71920-z
  7. Nat Biotechnol. 2026 Apr 17.
    Synthetic microbial co-cultures for modular bioelectronic sensing in diverse environments.
    Siliang Li, Duolong Zhu, Kundan Saha, Biki Bapi Kundu, Sameer Sonkusale, Robert A Britton, Caroline M Ajo-Franklin.
      Whole-cell bioelectronic sensors are particularly well-suited for environmental and health monitoring as they can be integrated into compact electronic devices for field deployment over extended periods. However, current engineering strategies lack modularity, are limited to a few microbial chassis and depend on specialized instruments for signal detection. We present the electroactive co-culture sensing system (e-COSENS), a plug-and-play system for whole-cell bioelectronic sensor development. Here a 'sender' bacterium produces electron mediators in response to analytes and a 'receiver' bacterium utilizes the electron mediators to generate electrical signals via extracellular electron transfer. Modularly swapping the sender bacterium and its associated genetic sensing elements achieved bioelectronic sensing of metals, small molecules and peptides in distinct environments, such as urban waterways, milk, saliva and microbial communities. We designed a centimeter-sized bioelectronic device for portable signal readout using a household digital multimeter. The e-COSENS system simplifies the whole-cell bioelectronic sensor design and expands the potential of bioelectronic sensor applications.
    DOI:  https://doi.org/10.1038/s41587-026-03075-7
  8. Mater Horiz. 2026 Apr 13.
    Morphable architected materials with topologically variable and volumetric reconfiguration.
    Kai Xiao, Yuhao Wang, Chao Song, Bihui Zou, Zihe Liang, Heeseung Han, Qinyun Ding, Yilin Du, Shane Johnson, Arup Neogi, Jaehyung Ju.
      Morphable architected materials enable tunable mechanical and functional properties through geometry rather than material composition. However, existing morphing strategies are largely limited to one- or two-dimensional transformations, preserve topology during deformation, and often rely on material-level phase changes for shape retention, restricting volumetric tunability, structural stiffness, and material choice. Here, we present a general inverse design framework for topologically variable and volumetric morphing of 3D architected materials with shape locking capabilities. The proposed approach enables reversible morphing between flat two-dimensional configurations and a wide range of three-dimensional curvilinear and polyhedral geometries-including shapes with different Euler characteristics-while remaining functionally bistable, with stable undeployed and deployed configurations. The framework combines volumetric mapping of bistable modular origami unit cells with kinematic constraints for flat foldability and kinetic constraints that induce structural bistability, achieving shape locking through mechanical instability rather than material phase transitions. Volumetric morphing further enables access to a previously unexplored materials design space, allowing a single architected material to exhibit widely tunable bulk and shear moduli and programmable structural responses. This work establishes a unified paradigm for inverse-designed morphable architected materials and the energy-efficient fabrication of complex 3D structures.
    DOI:  https://doi.org/10.1039/d5mh02438b
  9. Chempluschem. 2026 Apr;91(4): e202500586
    Cell-in-Shell Metacells in Single-Cell Nanoencapsulation.
    Duc Tai Nguyen, Nayoung Kim, Sang Yeong Han, Hyunwoo Choi, Insung S Choi.
      Single-cell nanoencapsulation (SCNE) enables the direct integration of synthetic materials with living cells, forming cell-in-shell structures that augment native cellular functions without genetic modification. While SCNE has advanced applications in cytoprotection and cell-surface engineering, its full potential remains constrained by the absence of a unifying conceptual framework. In this Concept report, we introduce the term "metacells" to define a new class of engineered, living cell-in-shell systems endowed with dynamic functionality, environmental responsiveness, and programmable behavior. We propose that metacells are characterized by three core functional hallmarks-reconfigurability, loadability, and motility-which collectively distinguish them from conventional SCNE platforms. Through selected examples, we illustrate how these features enable metacells to sense and respond to external stimuli, carry and release functional payloads, and exhibit guided or autonomous motion. By establishing a foundational definition and organizing framework for metacells, this report provides a roadmap for future research at the intersection of materials science, synthetic biology, and cellular engineering, with implications for advanced therapeutics, microscale robotics, and interactive biohybrid systems.
    Keywords:  artificial spores; cell‐in‐shell structures; metacells; nanobiohybrids; single‐cell nanoencapsulation
    DOI:  https://doi.org/10.1002/cplu.202500586
  10. Adv Mater. 2026 Apr 14. e22073
    4D-Printed Spin Crossover Metamaterials with Giant Programmable Positive or Negative Thermal Expansion.
    Adelais Trapali, Yuteng Zhang, Seyed Ehsan Alavi, Nagham Mawassy, Raja Zulkarnain, Gábor Molnár, Lionel Salmon, Azzedine Bousseksou.
      In the past decade, 3D-printed cellular materials have witnessed an impressive advancement affording a wealth of remarkable mechanical properties, such as negative Poisson's ratio, negative compressibility, and negative coefficient of thermal expansion (CTE). Recent efforts in this field have been increasingly considered 4D-printed metastructures, which leverage shape-morphing properties of stimuli-responsive materials. Here, we introduce a new class of 4D-printed metamaterials based on bistable spin crossover (SCO) molecular materials. These systems synergistically couple dissimilar materials at different size scales to harness mismatched thermomechanical properties-specifically differential thermal expansion and stiffness-to generate large directional deformations upon heating or cooling. Through a combination of theoretical modeling and experimental validation, we demonstrate that our SCO-based 4D-printed structures can achieve programmable motions, including positive and negative expansion. The associated CTE reaches peak values of ca. +14400 and -11400 ppm/°C, respectively, more than 10 times greater than those reported in the literature for 3D-printed analogues. This work establishes a versatile and generalizable conceptual strategy for engineering multilevel, hierarchical architectures with programmable functionalities, advancing the design of energy-efficient soft actuators and reconfigurable/adaptive material systems.
    Keywords:  4D printing; coefficient of thermal expansion; fused deposition modelling; mechanical metamaterials; polymer composites; spin‐crossover
    DOI:  https://doi.org/10.1002/adma.202522073
  11. ACS Appl Bio Mater. 2026 Apr 13.
    3D Printed In Vitro Engineered Living Material Models for Antimicrobial Development.
    Emily Lazarus, Lynn M Sidor, Andrea Camacho-Betancourt, Reinaldo Dos Santos, Anne S Meyer, Iris V Rivero.
      3D printing has revolutionized the field of tissue engineering and regenerative medicine, emerging as a widely adoptable strategy for the fabrication of mammalian cell-laden constructs laden with complex microenvironments. More recently, 3D printed living materials containing microorganisms have been developed. The potential for engineered 3D living materials as in vitro models for biomedical applications, such as antimicrobial susceptibility testing, is extensive; however, the need for an in-depth understanding of the relationship between the complex construct and the microorganism response still exists. Additionally, there exists a lack of multispecies engineered living material models (ELMM), which more closely mimic naturally occurring biofilms. This work includes the successful development of 3D printed single and mixed species in vitro ELMM for the development of antimicrobial therapeutics. Results successfully demonstrated the effect of maturation age on response to antimicrobial agents. Additionally, a gelatin 3D printing bath was fabricated, characterized, and yielded biomimetic 3D ELMM that could not otherwise be fabricated with low viscosity bioinks. With (1) non-traditional scaffold fabrication techniques for low viscosity bioinks, (2) enhanced understanding of the effect of biofilm maturation age on antimicrobial susceptibility, and (3) investigation into the interaction of mixed species models, 3D printed engineered living materials could provide in vitro infectious disease models for the discovery of distinct antibiofilm drugs. The results show proof-of-concept in vitro multispecies ELMM to more accurately mimic naturally occurring conditions with confirmed cell viability and maturation.
    Keywords:  3D printing; alginate bioink; antimicrobial susceptibility; engineered living material; in vitro multispecies
    DOI:  https://doi.org/10.1021/acsabm.5c02213
  12. ACS Sens. 2026 Apr 17.
    Lignin-Based Surface Adhesion Engineering Enables Tough Hydrogel for Flexible Epidermal Array Sensing.
    Oudong Hu, Pang Zhu, MinKun Cai, Xueqing Qiu, Yong Qian.
      Biocompatible adhesive hydrogels demonstrate a promising potential to increase the sensing stability of wearable electronics. However, their application performance has been severely limited by the trade-off between interfacial adhesion and cohesion so far. Here, inspired by the robust adhesion of mussel foot proteins and the double-layer structure of spider silk, we propose a catechol lignin-based surface adhesion engineering strategy that enables in situ fabrication of tough adhesive hydrogels for wearable epidermal electrodes. The modified lignin stably binds to the hydrogel surface through multiple hydrogen bonds and electrostatic interactions and effectively overcomes the mechanical deterioration existing in conventional lignin bulk-doping hydrogels. The fabricated hydrogel exhibits strong adhesion to both skin and elastomer, with interfacial toughness values of 778 and 290 J·m-2, demonstrating 9.4- and 18.6-fold enhancements over unmodified hydrogels. Accordingly, a hydrogel-elastomer hybrid bioelectrode is developed for physiological signal monitoring, showing a higher electromyography (EMG) signal-to-noise ratio (SNR) than commercial electrodes. Furthermore, a 6 × 4 electrode array is constructed and can maintain stable electrode-tissue interaction and 100% signal retention during intense contraction of biceps. This strategy provides new insight into the design of biomimetic adhesive hydrogels and promotes their application in wearable electronics.
    Keywords:  adhesive hydrogel; biomimetic construction; epidermal sensing array; hybrid bioelectrode; sustainable lignin
    DOI:  https://doi.org/10.1021/acssensors.6c00347
  13. Nat Biotechnol. 2026 Apr 15.
    Artificial allosteric protein switches with machine-learning-designed receptors.
    Zhong Guo, Oleh Smutok, Gyu Rie Lee, Zhenling Cui, Haocheng Qianzhu, Monika Kish, Cagla Ergun Yva, Kejia Wu, Roxane Mutschler, Colin J Jackson, Maria M Fiorito, Andrew C Warden, Oliver B Smith, Alfredo Quijano-Rubio, Thomas Huber, Jonathan J Phillips, Gottfried Otting, Evgeny Katz, David Baker, Kirill Alexandrov.
      Protein allostery underlies most information and energy processing in biology and the development of artificial allosteric proteins is a key objective of synthetic biology and biotechnology. We show that machine-learning-engineered minimal ligand-binding domains act as efficient receptors in single-component allosteric switches, despite lacking global conformational change. Such colorimetric, luminescent and electrochemical biosensors of small molecules, peptides and proteins can be compiled into intramolecular YES and AND logic gates. Furthermore, we report fully synthetic allosteric switches composed of artificial receptor and reporter domains. Hydrogen/deuterium exchange mass spectrometry and 19F nuclear magnetic resonance analyses suggest that ligand binding reduces the conformation entropy of the system, increasing the catalytic activity of the reporter domain. The potential practical utility of this approach is demonstrated by engineering Escherichia coli cells with steroid-dependent antibiotic resistance and by developing bioelectronic devices capable of quantifying steroid hormones.
    DOI:  https://doi.org/10.1038/s41587-026-03081-9
  14. Nat Chem. 2026 Apr 13.
    tRNA-deacylase-directed discovery of biosynthetic pathways.
    Douglas C Millar, Yu Zhou, Jorge A Marchand, Helena Roberts-Mataric, Tavis Chen, Calvin X Hu, Jason Fang, Shannon Millar, Elizabeth A Stone, Jeffrey G Pelton, Max B Sosa, Michelle C Y Chang.
      Amino acids are one of nature's most privileged building blocks for generating molecular diversity on length scales ranging from small molecules to proteins. While amino acid products arising from certain class-defined biosynthetic pathways can be found with established bioinformatic strategies, those that fall outside of these types remain difficult to identify. Here, to address this challenge, we have developed an approach to find biosynthetic gene clusters (BGCs) that utilize and modify amino acid monomers while remaining agnostic to biosynthetic class. We demonstrate that tRNA deacylases specific for host-synthesized non-canonical amino acids (ncAAs) serve as a common genomic marker of ncAA metabolism. Using this approach, we show that thousands of cryptic BGCs can be identified and demonstrate the discovery of BGCs for several distinct ncAAs as well as a hydrazide-containing tripeptide. We anticipate this approach will have broad applications for discovering natural products with ncAAs and beyond.
    DOI:  https://doi.org/10.1038/s41557-026-02126-5
  15. Nat Commun. 2026 Apr 13.
    Efficient genome editing with chimeric oligonucleotide-directed editing.
    Long T Nguyen, Noah R Rakestraw, Brianna L M Pizzano, Rajan Iyyappan, Cullen B Young, Yujia Huang, Kate T Beerensson, Anne Fang, Sydney G Antal, Katerina V Anamisis, Coleen M D Peggs, Jun Yan, Yangwode Jing, Jordan G Lewis, Rebecca D Burdine, Britt Adamson, Zongliang Jiang, Jared E Toettcher, Cameron Myhrvold, Piyush K Jain.
      Prime editing has emerged as a precise and powerful genome editing tool, offering a favorable gene editing profile compared to other Cas9-based approaches. Here we report several nCas9-DNA polymerase fusion proteins and their engineered versions to create a simple and efficient two-component chimeric oligonucleotide-directed editing (CODE) system. CODE contains a derivative of Bst DNA polymerase engineered for increased thermostability and processivity as well as a chimeric pegRNA (cpegRNA) for programmable search and replace genome editing. Additionally, CODEMax(exo+) features a 5' to 3' exonuclease activity that promotes effective strand invasion and repair outcomes favoring the incorporation of the desired edit. We demonstrate that CODEs can perform small insertions, deletions, and substitutions with improved efficiency compared to PEMax at many loci in HEK293T cells with plasmid- and RNP-based delivery. We also show that CODEMax can successfully modify mouse and bovine embryos with up to 9.3% precise editing. Further optimization of CODEMax systems may enhance editing outcomes in embryos and other challenging contexts. Overall, CODEs complement existing prime editors to expand the toolbox for genome manipulations without double-stranded breaks.
    DOI:  https://doi.org/10.1038/s41467-026-71624-4
  16. Cell Rep. 2026 Apr 16. pii: S2211-1247(26)00345-1. [Epub ahead of print]45(4): 117267
    Mechanical memory primes cells for confined migration.
    Jia Wen Nicole Lee, Yeji Chang, Malhar S Chitnis, Yixuan Li, Xu Gao, Avery Rui Sun, Jin Zhu, Jennifer L Young, Andrew W Holle.
      When migratory cells move between stiffness niches in vivo, they encounter confined spaces imposed by extracellular matrix (ECM) networks. Cells from one niche possess mechanosensitive adaptations that influence their response to new environments, a concept known as mechanical memory. How this memory is acquired and how it influences migratory potential in confinement remain poorly understood. Here, we combine stiffness priming using polyacrylamide hydrogels with a confinement platform to screen memory across healthy and transformed cells. Using a dose-and-passage approach, we find that cells primed on soft substrates navigate confinement more efficiently. Bulk RNA sequencing identifies NFATC2 as a transcription factor mediating mechanical memory through genetic reprogramming. Inhibition of NFATC2 confirms that it is required for memory acquisition and enhanced confined migration. Highly invasive cancer cells fail to retain mechanically induced phenotypes following cue removal, suggesting differential adaptation strategies. These findings establish mechanical memory as a cell-intrinsic regulator of confined migration.
    Keywords:  CP: cell biology; NFATC2; cell migration; confined migration; mechanical memory; mechanotransduction; substrate stiffness; transcriptional regulation
    DOI:  https://doi.org/10.1016/j.celrep.2026.117267
  17. Soft Matter. 2026 Apr 13.
    Strengthening biofilms with selective metal ions.
    Kiera J Croland, R Kōnane Bay.
      Biofilms are structured microbial communities consisting of bacteria embedded in a self-produced extracellular polymeric substance (EPS) that enables survival in diverse environments. The EPS can integrate materials from the surrounding environment, such as metal ions, which can provide additional mechanical protection to the embedded bacteria from environmental stressors. While previous studies demonstrated that metal ions impact the erosion behavior of biofilms, key quantitative properties, such as failure strain, remain largely undocumented due to difficulties in handling these viscoelastic and soft biomaterials. In this work, we introduce a technique to characterize the impact of metal ions on the uniaxial stress-strain response of bulk bacterial biofilms. Through applying this method to Bacillus subtilis pellicles, we demonstrate that exposure to selective metal ions increases both the low strain elastic modulus and maximum stress, while decreasing failure strain. These effects are consistent with ion-mediated EPS crosslinking and are reversible through the introduction of a strong chelating agent, while variations in pH alone have a negligible impact on measured mechanical properties. We compare our results to previous biofilm erosion studies and provide insights into how metal ion interactions can alter the mechanical behavior of biofilms, which will aid in future biofilm mitigation strategies for biofouling or healthcare applications.
    DOI:  https://doi.org/10.1039/d5sm01096a
  18. Nat Biotechnol. 2026 Apr;44(4): 536
    Optogenetics.
      
    DOI:  https://doi.org/10.1038/s41587-026-03085-5
  19. Nat Protoc. 2026 Apr 13.
    Rapid volumetric bioprinting of pristine protein-based (bio)inks.
    Maobin Xie, Liming Lian, Zhenrui Zhang, Zeng Lin, Emilio Mireles Guajardo, Jugal Kishore Sahoo, Guosheng Tang, Gang Li, Khoon S Lim, David L Kaplan, Yu Shrike Zhang.
      Volumetric bioprinting (VBP) enables the rapid photopolymerization of 3D constructs by modifying the illumination patterns within a build volume. However, only a few unmodified, pristine protein-based bioinks can be used for VBP, making the resulting (bio)printed volumes sometimes incompatible with further modification steps required for extended applications and thus limiting the wider adoption of VBP. We have recently developed new methods for VBP, in which unmodified protein-based (bio)inks with tyrosine groups, including those based on silk, decellularized extracellular matrix (dECM) and gelatin, can be (bio)printed, in their pristine state, by using the tris(2,2-bipyridyl)dichlororuthenium(II) hexahydrate/sodium persulfate photoinitiator system to form sophisticated shapes and architectures. Here, we provide step-by-step instructions to complete the VBP process and include the characterization of these bioinks. After treatment, the volumetrically printed silk sericin constructs show properties including reversible shrinkage and expansion, or shape-memory, whereas the volumetrically printed silk fibroin constructs exhibit broadly tunable mechanical performances ranging from a few hundred pascals to hundreds of megapascals. Both types of silk-based (bio)inks as well as dECM (bio)inks are cytocompatible. We further cover several demonstrations that show the potential uses of volumetrically (bio)printed silk and dECM constructs in clinical and biomedical applications.
    DOI:  https://doi.org/10.1038/s41596-026-01341-1
  20. Biomacromolecules. 2026 Apr 16.
    Thermo-Rheological Memory of κ-Carrageenan Fluid Gels Formed under Flow.
    Julien Bauland, Tim J Wooster, Peter Fischer, Jan Vermant.
      Fluid gels are soft materials formed by shearing biopolymer solutions during the sol-gel transition. Their ability to yield and flow beyond a critical stress makes them attractive for designing versatile, biocompatible materials in food, health care and medical applications. Although it is well established that both microstructure and mechanical properties depend on the shear applied during gelation, a unified physical framework linking these features remains lacking. Here, using κ-carrageenan gels as a model system, we use a combination of rheology and confocal microscopy to tackle their shear-induced structuring in fluid gels. We identify a thermo-rheological memory in κ-carrageenan gels formed under flow and show that it arises from a competition between shear and interparticle adhesion, captured by an Adhesion number. The resulting microstructural evolution is reminiscent of the behavior of attractive particulate dispersions under simple shear flow, thereby bridging gels made of macromolecules and particulate gels. This framework provides a route to tune fluid gel properties without altering their composition.
    DOI:  https://doi.org/10.1021/acs.biomac.6c00198
  21. ACS Appl Mater Interfaces. 2026 Apr 14.
    A Structurally Decoupled Single-Layer Soft Electronic Skin for Fast, Reliable, and Simultaneous Temperature-Pressure Sensing.
    Hanul Kim, Hyukju Go, Jinsu Yoon, Yeeun Jeong, Yongtaek Hong.
      Multimodal electronic skin capable of fast, reliable, and simultaneous sensing of two stimuli, temperature and pressure, remains challenging. Here, we present a single-layer temperature-pressure multisensing soft electronic skin with simple structural decoupling strategy based on a ridge-valley shaped elastic structure (RVES) using a resistive sensing mechanism. The sensor employs magnetically aligned filamentous Ni-PDMS conduction pathways, exhibiting stable temperature sensing from 0 to 75 °C and linear pressure sensing up to 155 kPa, with an ultrafast response time of 92 ms (temperature) and 48 ms (pressure). The sensor further demonstrates excellent reliability, maintaining consistent performance over 200 thermal cycles (25-55 °C) and 1000 pressure cycles at 94 kPa. By integration of the RVES into a soft sensor array, temperature-only and pressure-sensitive pixels are spatially separated within a single layer, allowing independent extraction and spatial mapping of temperature and pressure distributions. These capabilities are demonstrated in an 11 × 11 soft sensor array under simultaneous multimodal stimuli, highlighting the simplicity, reliability, and scalability of the proposed electronic skin.
    Keywords:  electronic skin; multimodal sensing; sensor array; soft pressure sensor; soft temperature sensor; structural decoupling
    DOI:  https://doi.org/10.1021/acsami.6c00491
  22. ACS Polym Au. 2026 Apr 08. 6(2): 634-644
    Understanding the Swelling Behavior of Polysaccharide-Based Hydrogels through a Kinetic Modeling.
    Vinicius Duarte Machado, Michele Karoline Lima-Tenório, Ernandes Taveira Tenório-Neto.
      Hydrogels are versatile polymeric materials widely used in various applications, including drug delivery, agriculture, and environmental technologies. Their performance and applicability are mainly governed by the swelling behavior. As a result, an accurate description of swelling kinetics is crucial for understanding the transport mechanisms that guide the hydrogel design. However, the power-law model fails to describe the full swelling profile and transient phenomena, such as, nonmonotonic swelling. In this work, we propose a physical model based on a kinetic interpretation, which is capable of describing the entire swelling profile of hydrogels. The model is derived from fundamental transport concepts, and incorporates both Fickian diffusion and macromolecular relaxation within a unified framework. Importantly, several classical swelling equationsincluding the power law, first-order kinetic, Peppas-Sahlin, and Higuchi modelsare shown to emerge as particular cases of the proposed formulation. The model was validated using experimental swelling data of chemically cross-linked polysaccharide-based hydrogels with different compositions. The proposed equation accurately fitted the swelling curves, including the overshooting behavior, with high correlation coefficients. The model quantified the contribution of Fickian diffusion and macromolecular relaxation in the swelling mechanism. The proposed model offers a simple and comprehensive tool for analyzing hydrogel swelling kinetics. By describing the full swelling process with only three physical parameters, it enables improved mechanistic interpretation, providing valuable guidance for the rational design of hydrogels with tailored swelling and absorption properties.
    Keywords:  hydrogel; mathematical modeling; mechanism; overshoot; swelling
    DOI:  https://doi.org/10.1021/acspolymersau.5c00208
  23. bioRxiv. 2026 Apr 10. pii: 2026.04.08.717265. [Epub ahead of print]
    Lipoengineering of Biomolecular Condensates Controls Material Properties and Multiphase Hierarchy to Guide Organoid Morphogenesis.
    Zhiwei Huang, Md Mahbubul Alam, Mahtab Shokri, Harshavardhan C Savitrinarayana, Sisila Valappil, Tanushree Agarwal, Rob M Scrutton, Laiba Maryam, Asma Gulzar, Jinying Wang, Dominic J Tigani, Liege A Pascoalino, Akshay V Jadhav, Albert L Adhya, Alaji Bah, Zhao Qin, Zheng Shi, Michael R Blatchley, Jianhan Chen, Tuomas P J Knowles, Davoud Mozhdehi.
      Cells use post-translational modifications (PTMs) to reconfigure biomolecular condensates across length scales, space, and time. 1,2 While charged PTMs are well-known electrostatic switches, 3,4 how ubiquitous neutral PTMs shape condensate plasticity and hierarchy remains unclear. Here, we establish a set of design principles for using site-specific lipidation, a class of neutral hydrophobic PTMs, to rationally control properties and interactions of engineered biomolecular condensates. Through systematic analysis of over 80 lipidated synthetic intrinsically disordered proteins (IDPs), we uncovered two distinct axes of control. First, the interplay between the lipid and the local three-residue sequence of its attachment site acts as a programmable switch for cohesion -the homotypic interactions that define the material state of the condensed phase- directing assemblies toward dynamic liquids, arrested gels, or ordered fibrillar solids. Second, the lipid, together with the global properties of the IDP scaffold, tunes adhesion -the heterotypic interactions that govern condensate miscibility and hierarchical organization. We harnessed these principles to rationally engineer complex, multi-phase architectures and create hybrid hydrogels with programmed microstructure and material properties that guide the morphogenesis of functional intestinal organoids. These findings establish a new framework for lipoengineering advanced biomaterials and provide a blueprint for dissecting structure-property relationships across diverse classes of PTMs.
    DOI:  https://doi.org/10.64898/2026.04.08.717265
  24. PNAS Nexus. 2026 Apr;5(4): pgag077
    Measurement-induced phase transitions in informational active matter.
    Bryan VanSaders, Michel Fruchart, Vincenzo Vitelli.
      Various biological and synthetic media out of equilibrium can be viewed as many-ratchet systems that rectify environmental noise through local measurements and information processing, like Maxwell's prototypical demon. These systems pose a challenge to standard coarse-graining approaches because they are described in terms of decision-making protocols similar to computer programs rather than force laws. Here, we study a many-body generalization of the Maxwell demon problem: a fluid composed of adaptive particles that achieve collective behavior by biasing noise-driven scattering events subject to measurements. Using a combination of information-theoretic, kinetic, and hydrodynamic tools, we elucidate how microscopic decision-making protocols, rather than microscopic forces, generate macroscopic active states sustained by continuous measurements. These include an informational version of flocking whose order parameter is bounded by the information measured, and the onset of which may be viewed as a measurement-induced phase transition. We find that the signature of such microscopic choices is an "informational activity" that selectively compresses phase space, without work, and causes deviations from equilibrium scaling with the magnitude of environmental noise. We envision applications to noise-induced patterning performed by collections of microrobots guided by reinforcement learning or programmable phoretic colloids in turbulent flows that exploit local measurements and control actions to counteract the scrambling of information by chaos.
    Keywords:  active matter; flocking; information engines; measurement-induced phase transitions; reinforcement learning
    DOI:  https://doi.org/10.1093/pnasnexus/pgag077
  25. Biofabrication. 2026 Apr 15.
    Micro-comb 3D printing: Rapid fabrication of tissue-guiding substrates using micro-embossed nozzles.
    Sarkhan Butdayev, Stefan Leone, Shayla Nikzad, Janko Kajtez, Katrine Bech Lauritzen, Moises Di Sante, Francesco Pasqualini, Kirstine Calloe, Rodolphe Marie, Stephan S Keller, Anne Zebitz Z Eriksen, Johan Ulrik Lind.
      To replicate the function of native tissue in cell cultures, one must reproduce the structure of the native tissue. This can be achieved using tissue‑guiding architectures with cell‑scale dimensions, typically ranging from single to tens of microns. However, this spatial resolution exceeds the capabilities of many common fabrication methods, including extrusion‑based 3D printing. Indeed, although increasingly popular in bioengineering, extrusion-based 3D printing is not only limited by the properties of the print materials, but also by the inherent trade-off that smaller features require smaller nozzles. This, in turn, results in more toolpaths and longer build times. To overcome this limitation, we introduce nozzles with micro-scale structures at their orifice, fabricated through straightforward hot embossing of commercial polypropylene nozzles. This approach enables microstructure printing using large (≥0.4 mm inner diameter) nozzles. Specifically, we demonstrate rapid printing of microstructured soft substrates, capable of guiding skeletal and cardiac muscle cell cultures into physiomimetic, anisotropic tissues for electrophysiological assays and drug studies. Furthermore, we show that axonal growth in neuronal tissue cultures can also be directed. Thus, our approach may serve as a scalable and easily accessible method for fabricating human cell cultures and tissue models with enhanced physiological relevance.
    Keywords:  axonal guidance; biofabrication; cardiac tissue models; microextrusion 3D printing; skeletal tissue models; tissue-guiding substrates
    DOI:  https://doi.org/10.1088/1758-5090/ae5fd9
  26. ACS Appl Mater Interfaces. 2026 Apr 14.
    Tough Environmentally Robust Cellulose Nanofiber-Reinforced Dual-Network Eutectogel with an Intelligent Self-Calibrating System for Human-Machine Interfaces.
    Xuwei Wang, Junjing Ma, Shihai Wei, Jinlong Yu, Jisheng Yang, Liuting Mo.
      Hydrogels for next-generation human-machine interface (HMI) suffer from environmental instability and inconsistent signals, which limit their wearable deployment. We propose a comprehensive solution, spanning from material design to system integration, and develop a tough and environmentally tolerant dual-network conductive eutectogel. This gel introduces a deep eutectic solvent composed of choline chloride and acrylic acid as a multifunctional liquid phase, achieving high ionic conductivity (2.3 S/m), excellent antievaporation performance, antibacterial activity, and operational capability. A dual-network structure of poly(acrylic acid) and poly(vinyl alcohol) was synergistically reinforced with TEMPO-oxidized cellulose nanofibers, endowing the material with a tensile strength of up to 0.97 MPa and an elongation at break of 464%. To overcome challenges related to inconsistent signals among individual sensor variations, we developed an integrated multichannel self-calibration electronic system. The system actively calibrates and normalizes the signal from each sensor using an on-board digital potentiometer array and algorithm optimization. Based on the excellent performance of the material, the resulting multifunctional sensing platform enables visualization of different pressures, real-time gesture recognition, and control of the robotic hand. This work paves the way for the development of truly practical and highly reliable next-generation human-machine interfaces by integrating advanced material design with intelligent hardware engineering.
    Keywords:  deep eutectic solvent; eutectogel; human-machine interface; self-calibration; wearable flexible strain sensor
    DOI:  https://doi.org/10.1021/acsami.5c26105
  27. Nat Commun. 2026 Apr 17.
    Bio-inspired cellular aerogel fibers integrating high mechanical strength and softness for thermal insulation textiles.
    Yinghe Hu, Gongyu Zhang, Guang Yang, Ziyi Zhao, Chang Liu, Shuo Yang, Yunpeng Ding, Heyi Li, Luyun Xue, Youwei Ma, Xupin Zhuang, Bowen Cheng.
      Integrating high mechanical strength yet softness and effective thermal insulation into the same aerogel materials presents a significant challenge. Inspired by penguin feathers, here we assemble aramid nanofibers (ANFs) into aerogel fibers of hierarchical structures through delicate control of covalent and non-covalent interactions during a wet-spinning process. The process involves initial cross-linking of deprotonated ANF sol to form a cellular structure, followed by acid-induced gelation that produces a rigid shell through hydrogen bonding. The shell imparts high tensile strength of up to 74.6 MPa, while the cellular core enables good softness with ultralow bending and compression stresses of 33.8 and 39.8 kPa, respectively. The process is scalable, and allows fabrication of large fabrics with dyeability, hydrophobicity, flame retardancy, moisture and chemical resistances. Notably, the fabrics exhibit good thermal insulation, with a 0.9 mm-thick sample outperforming much thicker commercial counterparts, including a 2.5 mm sweater and a 15 mm jacket.
    DOI:  https://doi.org/10.1038/s41467-026-71723-2
  28. bioRxiv. 2026 Apr 11. pii: 2026.04.10.717777. [Epub ahead of print]
    Generative design of intrinsically disordered protein regions with IDiom.
    Jason Liu, Sebastian Ibarraran, Frank Hu, Abigail Park, Alexander Dunn, Grant Rotskoff.
      Intrinsically disordered protein regions are ubiquitous across all kingdoms of life. These structurally heterogeneous regions play central roles in cellular processes such as transcriptional regulation, cellular signaling, and subcellular organization, yet they have remained largely inaccessible to rational design. Structure-based generative methods are not applicable to proteins that lack a stable fold, and existing sequence-based approaches for disordered regions rely on sampling methods that do not capture the evolutionary statistics of natural disordered regions. Here, we introduce IDiom, an autoregressive protein language model trained on 37 million intrinsically disordered region sequences curated from the AlphaFold Database. Trained using a fill-in-the-middle data augmentation, IDiom generates disordered region sequences conditioned on their surrounding structured context, as well as fully disordered proteins without any context. The model generates diverse sequences that recapitulate biologically relevant sequence features of natural disordered regions, and we demonstrate that post-training via reinforcement learning with a subcellular localization reward model produces sequences with features which are consistent with known sequence determinants of compartment-specific localization. These results establish IDiom as a general platform for the generative design of intrinsically disordered proteins and regions.
    DOI:  https://doi.org/10.64898/2026.04.10.717777
  29. Nat Chem Biol. 2026 Apr 16.
    A familiar newcomer to the thermogenetic toolset.
    Zikang 'Dennis' Huang, Lukasz Bugaj.
      
    DOI:  https://doi.org/10.1038/s41589-026-02197-y
  30. bioRxiv. 2026 Apr 07. pii: 2026.04.01.715853. [Epub ahead of print]
    Beyond the mean: genetic control of gene expression fidelity and dispersion.
    Brendan Jamison, Alexander Chen, Erik McIntire, Xin He, Yoav Gilad.
      For decades, molecular biologists have interpreted gene regulation through measurements of mean gene expression, because they could not resolve regulatory variation among individual cells. The advent of single-cell genomics has now made that variation measurable, revealing pervasive differences in gene expression among apparently similar cells. Whether this variation mainly reflects stochastic noise or an informative regulatory property remains unclear. Here we show that mean-corrected gene expression dispersion is a reproducible and biologically structured feature of gene regulation that reflects regulatory fidelity. In heterogeneous differentiated cardiac cultures, genes with low dispersion are shared across cell types, enriched for housekeeping functions, depleted for expression quantitative trait loci, and more highly connected in transcriptional and protein interaction networks. In a comparative single-cell system spanning human, chimpanzee, and allotetraploid cells, a substantial subset of interspecies differences in regulatory dispersion persists in a shared trans environment, indicating that gene expression fidelity is often regulated in cis . Our findings establish gene expression dispersion as a genetically encoded dimension of gene regulation that is distinct from mean expression, and places dispersion along a fidelity-plasticity axis with implications for development, disease, and threshold-dependent cellular phenotypes.
    DOI:  https://doi.org/10.64898/2026.04.01.715853
  31. ACS Appl Bio Mater. 2026 Apr 14.
    Multifunctional Hemostatic Hydrogels Based on Natural Ionic Polymers: Dual Crosslinking Strategy for Rapid Bleeding Control and Infected Wound Management.
    Runxuan Liu, Sadaqat Ali Chattha, Qingshuang Song, Xu Zhang, Biyu Peng.
      Uncontrolled hemorrhage remains a critical challenge in emergency and trauma scenarios, with limited options that combine rapid hemostasis, robust wet-tissue adhesion, and infection prevention in a single platform. Herein, this study reports a dual-crosslinked hydrogel system fabricated from natural ionic polymers-chitosan (CS), gelatin, and sodium alginate (SA)-incorporated with silver nanoparticles (AgNPs). The synergistic application of ionic crosslinking (Ca2+-mediated carboxyl coordination) and covalent crosslinking (genipin-mediated amino coupling) constructs a mechanically robust and cohesively stable network, overcoming the common trade-off between swelling capacity and mechanical strength in polysaccharide-based hydrogels. Systematic orthogonal optimization yielded a formulation (4% CS, 28.5% gelatin, 25% SA, 3 mg/mL AgNPs, and 0.1 mol/L Ca2+) that achieves a compressive strength of 2.71 MPa and an adhesion strength of 168.83 kPa. In a mouse liver injury model, both in situ and ex situ-applied hydrogels significantly shortened bleeding time and reduced blood loss by approximately 47 ± 2.5% and 49 ± 1.9%, respectively, demonstrating rapid and effective hemostasis. Moreover, an in vitro cell relative growth rate exceeding 85% was obtained from cultures with hydrogel leachate, confirming excellent antibacterial activity and biocompatibility. This study presents a multifunctional hydrogel with potent hemostatic performance and favorable biological properties for potential emergency care applications.
    Keywords:  hemostasis; hydrogel; natural ionic polymers; orthogonal experiment; silver nanoparticles
    DOI:  https://doi.org/10.1021/acsabm.6c00266
  32. Adv Mater. 2026 Apr 14. e17390
    Bottom-Up Programming of Cell States in Cancer Organoids with Defined Synthetic Adhesion Cues.
    Ali Nadernezhad, Verena J Kast, Dagmar Pette, Franziska Baenke, Daniel E Stange, Carsten Werner, Daniela Loessner.
      Despite advances in defined culture systems, current organoid models lack programmable control of transcriptomic states beyond fixed genetic constraints or broadly specific microenvironmental conditions. Here, a bottom-up biomaterial-based platform is introduced to program cell state changes in pancreatic cancer organoids by tuning minimal adhesion cues within a synthetic matrix. A Design of Experiments framework is used to systematically model the patient-specific transcriptome-wide impact of matrix-presented adhesion cues. Focusing on epithelial-mesenchymal transition (EMT) as a proof-of-concept cellular program, a multiobjective optimization approach is applied to identify patient-specific matrix compositions that enrich EMT-associated transcriptional programs. Organoids cultured in these optimized matrices exhibit transcriptomic signatures consistent with EMT enrichment and coordinated shift in EMT-associated regulatory signatures. Secretome profiling further reveals changes in cytokines previously linked to EMT-associated inflammatory, hypoxia, and TGF-β signaling. Together, these findings demonstrate that quantitative and targeted modulation of defined adhesion cues enables programmable control of transcriptomic states in pancreatic cancer organoids.
    Keywords:  computational biomaterials design; organoid microenvironment engineering; patient‐derived cancer organoids; synthetic extracellular matrix; transcriptomic state programming
    DOI:  https://doi.org/10.1002/adma.202517390
  33. Genetics. 2026 Apr 08. pii: iyag059. [Epub ahead of print]
    Actually, what is a gain-of-function mutation?
    Tobias Warnecke.
      For more than a century, scientists have worked to characterize, understand, and predict the consequences of mutations. For almost as long, scientists-always on the lookout for general principles-have categorized these mutations, hoping that putting them into labeled boxes might help reveal the molecular logic that governs mutational effects. Here, I will dive into one of these boxes, labeled "gain-of-function", a term that will ring familiar to undergraduates, (clinical) geneticists, and virologists alike. I will emerge from the box with a profound sense of bewilderment and the conclusion that its contents appear to have very little in common. What is a gain-of-function mutation? What do we know (or can reasonably assume) about a mutation once it has attracted this label? Do gain-of-function mutations share anything in common in terms of their molecular features or the consequences they cause? I will argue that the answers to these three questions are "I don't know," "not much," and "not really," and that the term gain-of-function tells us rather little. Worse, it often misleads our intuition regarding what a given mutation is or does. I will suggest that this is because the gain-of-function label has historically been applied, with liberal abandon, across different levels of biological complexity, from the behavior of individual proteins, to protein complexes, to cells, to whole-organism physiology. I will discuss the implications (all bad…) of this heterogeneous labeling history for recent efforts to train machine learning algorithms to discriminate different types of mutations. Above all, I hope to highlight that the myriad ways in which mutational effects can percolate through biological systems often defy easy categorization and that, while classifying things is often useful, it is best not to forget that molecular biology is a glorious mess.
    Keywords:  gain-of-function; loss-of-function; mutation
    DOI:  https://doi.org/10.1093/genetics/iyag059
  34. Nat Chem Biol. 2026 Apr 16.
    A biosynthetic survey of hypocrealean biocontrol fungi.
    Ana Calheiros de Carvalho, Naiara Hurtado-Lopez, Carolina Cano Prieto, Miriam von Bargen, Luis Caleb Damas-Ramos, Agustina Undabarrena, Daniela Rago, Ling Chen, Adrian Enrique Gadar Lopez, Sidharth Jayachandran, Luisa Maria Trejo Alarcon, Xiaowei Li, Dushica Arsovska, Linda Ahonen, Vijayalakshmi Kandasamy, Line Sondt-Marcussenv, Mariana Arango Saavedra, Iason Karyofyllis, Kealan Peter Exley, Charissa de Bekker, Jeppe Schack Brogaard, Jay D Keasling, Pablo Cruz-Morales.
      Pests cause up to 40% of global crops losses. Pesticide overuse drives resistance and poses notable risks to public health and the environment. Many hypocrealean fungi form symbiotic relationships with plants while antagonizing pests, making them valuable sources of biocontrol agents and biopesticides. However, little is known about their biosynthetic capabilities. Here we use phylogenomics, metabolomics and heterologous expression to catalog the biosynthetic repertoire of 82 plant-associated and insect-associated Hypocreales species. Annotation of 5,221 biosynthetic gene clusters reveals that ~80% of them encode unknown products. By linking biosynthetic gene clusters to molecules, we investigate the biosynthesis of several natural products, including pyridones, dethiosecoemestrin and efrapeptin. Additionally, by combining our metabologenomics workflow with synthetic biology, we characterize four nonribosomal peptide synthetase-like synthetases involved in the biosynthesis of hitherto unknown products. We believe that this work lays the groundwork for future efforts toward sustainable pest control in agriculture.
    DOI:  https://doi.org/10.1038/s41589-026-02201-5
  35. Nanoscale. 2026 Apr 14.
    A biomimetic liquid metal cell.
    Jingyi Li, Mengwen Qiao, Minghui Guo, Zerong Xing, Yunlong Bai, Ju Wang, Yujia Song, Ren Xu, Xi Zhao, Jing Liu.
      Gallium-based liquid metals, as a broad category of emerging functional materials with unique physical, chemical, and biological properties, offer numerous possibilities for advancing intelligent systems. However, a basic query persistently remains for complex liquid metal systems: is there a minimal functional unit that can fully capture their diversity of morphology and function? Cells, as the most basic structural and functional units of life, are small in scale but have complex structures, functions, and life activities. Analogous to nature, this article proposes the concept of biomimetic liquid metal cells and systematically explores their construction routes, sensing capabilities, motion behaviors, and potential applications. We first construct a multi-phase composite structure with a liquid metal as the nucleus, an ionic solution as the cytoplasm, and a polymer as the cell membrane by developing a layered cryogenic molding method. Furthermore, we reveal that liquid metal cells exhibit inherently responsive characteristics and self-adaptive behaviors to thermal, pressure, chemical, electrical, and magnetic fields, indicating "small world, vast potential". Based on these fundamental findings, we finally demonstrate the feasibility of utilizing liquid metal cells as sensors, fluidic valves, and material transport carriers in flow channels through dynamic control.
    DOI:  https://doi.org/10.1039/d6nr00291a
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