bims-enlima 2025-03-16 papers

bims-enlima

Biomed News

on Engineered living materials

Issue of 2025–03–16
fifty-two papers selected by
Rahul Kumar, Tallinna Tehnikaülikool

Chaotic Direct Ink Writing (ChDIW) of Hybrid Hydrogels: Implication for Fabrication of Micro-ordered Multifunctional Cryogels.
Mechanical and Light Activation of Materials for Chemical Production.
Synchronizing Multicolor Changes and Shape Deformation Into Structurally Homogeneous Hydrogels via a Single Photochromophore.
Synthesis of Abiotic Supramolecular Polymers Inside Living Cells via Organocatalysis-Mediated Self-Assembly.
Advances in bioinspired polymer hydrogel systems with biomedical functionalities.
Bioconversion of CO2 into valuable bioproducts via synthetic modular co-culture of engineered Chlamydomonas reinhardtii and Escherichia coli.
Designing single-polymer-chain nanoparticles to mimic biomolecular hydration frustration.
Responsive DNA artificial cells for contact and behavior regulation of mammalian cells.
Multiplexed dynamic control of temperature to probe and observe mammalian cells.
Noncanonical amino acids as prophage inducers for protein regulation in bacteria-based delivery systems.
3D Printing of Silicone Organogel Elastomers for Structured Soft Biomaterials.
SubtiToolKit: a bioengineering kit for Bacillus subtilis and Gram-positive bacteria.
Intra- and Interbead Communications by an Anchored DNA Structure and Cascaded DNA Reactions.
Genetically encoded protein oscillators for FM streaming of single-cell data.
Metabolic growth-coupling strategies for in vivo enzyme selection systems.
Mechanical, Thermal, and Rheological Properties of Fish-Porcine Gelatin Microparticle Composites for Advanced 3D Biofabrication.
Enabling three-dimensional architected materials across length scales and timescales.
Engineering Protein-Polyelectrolyte Interactions for Cellular Applications.
Multiscale Mechanical Characterization of Mineral-Reinforced Wood Cell Walls.
Identification of EcpK, a bacterial tyrosine pseudokinase important for exopolysaccharide biosynthesis in Myxococcus xanthus.
Homochiral Helical Poly(thiophene)s Accessed via Living Catalyst-Transfer Polymerization.
Engineering Chromatin Regulation of Xylose Utilization in Budding Yeast Saccharomyces cerevisiae for Efficient Bioconversion.
Bio-Inspired Retina by Regulating Ion-Confined Transport in Hydrogels.
High strength kami-ito yarns from microbial cellulose biofilms.
Sustainable Biopolymer Colloids: Advances in Morphology for Enhanced Functionalities.
Upcycling waste commodity polymers into high-performance polyarylate materials with direct utilization of capping agent impurities.
Aging-dependent evolving electrochemical potentials of biomolecular condensates regulate their physicochemical activities.
Artificial Intelligence and Multiscale Modeling for Sustainable Biopolymers and Bioinspired Materials.
Orthogonal Host-Guest Interactions Enable Programming of Protocell Membranes for Cellular High-Order Assembly and Enhanced Immunogenicity.
Sustainable 4D Printed Meta Biocomposite Materials for Programmable Structural Shape Changing.
AggreBots: configuring CiliaBots through guided, modular tissue aggregation.
Recent advances in genetic engineering and chemical production in yeast species.
Using Colour to Control Conformation in a Chemical System Containing Multiple Tricyanofuran Photoacids.
Dynamic Regulation of 5-Formylcytidine on tRNA.
Plug-and-play assembly of biodegradable ionizable lipids for potent mRNA delivery and gene editing in vivo.
Combination of Dynamic and Permanent Cross-Linking: A Pathway to Enhance Elasticity and Recyclability.
Cell Contractile Force-Mediated Morphodynamical Tissue Engineering via 4D Printed Degradable Hydrogel Scaffolds.
The TissueTractor: A Device for Applying Large Strains to Tissues and Cells for Simultaneous High-Resolution Live Cell Microscopy.
Metals squeezed to thickness of just two atoms.
Fusion of enzymatic proteins: Enhancing biological activities and facilitating biological modifications.
Move over graphene! Scientists forge bismuthene and host of atoms-thick metals.
Enhancing visible light-induced 3D bioprinting: alternating extruded support materials for bioink gelation.
Database of Nonaqueous Proton-Conducting Materials.
Protocol for chromatin immunoprecipitation of chromatin-binding proteins in Schizosaccharomyces pombe using a dual-crosslinking approach.
Single-molecule tracking in living microbial cells.
Linker histone H1.0 loads onto nucleosomes through multiple pathways that are facilitated by histone chaperones.
Class I histone deacetylases catalyze lysine lactylation.
Development of an enzymatic cascade for semi de novo ATP production using thermophilic enzymes.
POSA for fast, amplified and multiplexed protein imaging.
Myxosortase: an intramembrane protease that sorts MYXO-CTERM proteins to the cell surface.
Massively parallel assessment of designed protein solution properties using mass spectrometry and peptide barcoding.
Stiff and self-healing hydrogels by polymer entanglements in co-planar nanoconfinement.

Small Methods. 2025 Mar 13. e2500349

Chaotic Direct Ink Writing (ChDIW) of Hybrid Hydrogels: Implication for Fabrication of Micro-ordered Multifunctional Cryogels.

Shakiba Samsami, Zahra Monsef Khoshhesab, Juan Felipe Yee-de León, Diego Alonso Quevedo Moreno, Mario Moisés Alvarez, Grissel Trujillo-de Santiago, Kam C Tam, Milad Kamkar.

  The modern era demands multifunctional materials to support advanced technologies and tackle complex environmental issues caused by these innovations. Consequently, material hybridization has garnered significant attention as a strategy to design materials with prescribed multifunctional properties. Drawing inspiration from nature, a multi-scale material design approach is proposed to produce 3D-shaped hybrid materials by combining chaotic flows with direct ink writing (ChDIW). This approach enables the formation of predictable multilayered filaments with tunable microscale internal architectures using just a single printhead. By assigning different nanomaterials to each layer, 3D-printed hydrogels and cryogels with diverse functionalities, such as electrical conductivity and magnetism are successfully produced. Furthermore, control over the microscale pore morphology within each cryogel filament is achieved, resulting in a side-by-side dual-pore network sharing a large interfacial area. The ChDIW is compatible with different types of hydrogels as long as the rheological features of the printing materials are well-regulated. To showcase the potential of these multilayered cryogels, their electromagnetic interference shielding performance is evaluated, and they reveal an absorption-dominant mechanism with an excellent absorption coefficient of 0.71. This work opens new avenues in soft matter and cryogel engineering, demonstrating how simplicity can generate complexity.

Keywords:  chaotic flows; direct ink writing; electromagnetic interference shielding; multilayered cryogel; multimaterial printing

DOI:  https://doi.org/10.1002/smtd.202500349
Adv Mater. 2025 Mar 12. e2418137

Mechanical and Light Activation of Materials for Chemical Production.

Luka Đorđević, Tyler J Jaynes, Hiroaki Sai, Marianna Barbieri, Jacob E Kupferberg, Nicholas A Sather, Steven Weigand, Samuel I Stupp.

  Mechanical expansion and contraction of pores within photosynthetic organisms regulate a series of processes that are necessary to manage light absorption, control gas exchange, and regulate water loss. These pores, known as stoma, allow the plant to maximize photosynthetic output depending on environmental conditions such as light intensity, humidity, and temperature by actively changing the size of the stomal opening. Despite advances in artificial photosynthetic systems, little is known about the effect of such mechanical actuation in synthetic materials where chemical reactions occur. It is reported here on a hybrid hydrogel that combines light-activated supramolecular polymers for superoxide production with thermal mechanical actuation of a covalent polymer. Superoxide production is important in organic synthesis and environmental remediation, and is a potential precursor to hydrogen peroxide liquid fuel. It is shown that the closing of pores in the hybrid hydrogel results in a substantial decrease in photocatalysis, but cycles of swollen and contracted states enhance photocatalysis. The observations motivate the development of biomimetic photosynthetic materials that integrate large scale motion and chemical reactions.

Keywords:  energy materials; hybrid materials; hydrogen peroxide; photocatalysis; self‐assembly; supramolecular polymers

DOI:  https://doi.org/10.1002/adma.202418137
Adv Mater. 2025 Mar 10. e2500857

Synchronizing Multicolor Changes and Shape Deformation Into Structurally Homogeneous Hydrogels via a Single Photochromophore.

Xuehan Yang, Mengqi Du, Zhaomiao Chu, Chuang Li.

  The design of synthetic hydrogels that can mimic their biological counterparts in the simultaneous production of multicolor change and shape transformation in response to environmental stimuli is of great importance toward intelligent camouflage, encryption, and actuation. Previous efforts have focused primarily on developing heterogeneous hydrogels that highly rely on respective mechanisms to achieve color and shape changes separately, and synergistically synchronizing such two variations into structurally homogenous hydrogels via a single chromophore has been challenging. Here, the molecular design of a structurally homogenous hydrogel simultaneously exhibiting synchronized multicolor change and shape deformation triggered by a single stimulus of light is reported. The synchronization mechanism originates from a coupled alteration upon irradiation in the fluorescence emission and charge states of a spiropyran photochromophore covalently incorporated into the hydrogel network, thus leading to macroscale color change and shape variation in the hydrogel, respectively. Following this principle, both positive and negative phototropic deformation are obtained concomitantly with synchronized but flexibly tunable multicolor changes upon light illumination and demonstrated the ingenious application of biomimetic actuation, encryption, and camouflage by the rational combination of these two systems. This work represents an innovative molecular design strategy for developing bioinspired materials with synchronized functions via a single compound.

Keywords:  color change; hydrogel; photochromphore; shape deformation; spiropyran

DOI:  https://doi.org/10.1002/adma.202500857
Angew Chem Int Ed Engl. 2025 Mar 10. e202500998

Synthesis of Abiotic Supramolecular Polymers Inside Living Cells via Organocatalysis-Mediated Self-Assembly.

Hucheng Wang, Ya-Ting Zheng, Jiahao Zhang, Yuliang Gao, Jingjing Chen, Peiwen Cai, Junyou Wang, Jan H van Esch, Xuhong Guo, Hui Li, Yiming Wang.

  Cells execute mesmerizing functions using supramolecular polymers (SPs) formed through the self-assembly of biological precursors. Integration of the vast array of synthetic SPs with living cells would offer a powerful way to remold cellular functions and bridge the gap between synthetic materials and biological realm, yet remains a challenge because of the lack of robust abiotic SP systems that can be triggered to self-assemble inside cells. Here, we report how fully abiotic SPs can be synthesized inside living cells via an organocatalysis-responsive self-assembly strategy, and how the in situ-generated SPs are capable of interfering with cellular functions. The incorporation of a nucleophilic organocatalyst (CAT) into living cells accelerates the intracellular conversion of hydrazide (H) and aldehyde-derived precursors (A) to hydrazone-based monomers (HA3) that locally self-assemble into SPs. Interestingly, the in situ-generated SPs possess ignorable effects on cell viability and proliferation but remarkably hinder the cell migration. Furthermore, the presence of SPs is found to retard intracellular diffusion and alter the organization of actin cytoskeleton, both of which are suggested to be responsible for the hindered cellular migration. In considering of the vastly wide range of synthetic SPs, tremendous non-natural cellular functionalities can be obtained by in situ-synthesizing SPs.

Keywords:  gelation; intracellular self-assembly; local catalysis; supramolecular polymers

DOI:  https://doi.org/10.1002/anie.202500998
Sci Technol Adv Mater. 2025 ;26(1): 2469490

Advances in bioinspired polymer hydrogel systems with biomedical functionalities.

Kazuhiko Ishihara.

  The concepts of bioinspiration and biomimetics that seek to elucidate the morphology and functions of living organisms and specific reactions within cells, and extraction of important elements from these concepts to design functional molecules and high-performance materials are becoming more and more widespread. This review summarizes the progress in research on hydrogels inspired by the stimuli-responsiveness of cell functions. For application to a self-regulated release system of insulin to regulate blood glucose levels, various polymer hydrogels have been designed using bioactive molecules such as enzymes and lectins to sense glucose concentrations. In addition, as a fully synthetic glucose-responsive hydrogel, a complex of a polymer having phenylboronic acid groups that form reversible bonds with sugars and a multivalent hydroxyl group polymer has been researched. This reversible hydrogel system can be further developed to act as an extracellular matrix in which cells can preferably reside. The proliferation and differentiation of encapsulated cells in hydrogels are controlled by reversible changes in the hydrogel properties in response to sugar. Another advantage is that cells can be safely retrieved by adding sugar to dissociate the hydrogel. These bioinspired polymer hydrogels can serve as important materials for the development of new medical technologies, such as the controlled release of bioactive molecules, regulated cell culture environmental matrices, and applications in layered and three-dimensional cell culture systems to create organized tissue structures.

Keywords:  Stimuli-responsive hydrogel; cell encapsulation; cytocompatibility; drug delivery system; tissue engineering

DOI:  https://doi.org/10.1080/14686996.2025.2469490
Metab Eng. 2025 Mar 07. pii: S1096-7176(25)00034-5. [Epub ahead of print]90 57-66

Bioconversion of CO2 into valuable bioproducts via synthetic modular co-culture of engineered Chlamydomonas reinhardtii and Escherichia coli.

Nam Kyu Kang, Hyun Gi Koh, Yujung Choi, Hyunjun Min, Donald R Ort, Yong-Su Jin.

  With increasing concern over environmental problems and energy crises, interest in the biological conversion of CO2 into bioproducts is growing. Although microalgae efficiently utilize CO2, their metabolic engineering remains challenging. In contrast, while synthetic biology tools are advanced for many heterotrophic bacteria, these organisms cannot directly utilize CO2. As such, a modular co-culture system with a glycolate dehydrogenase 1 (GYD1) deficient Chlamydomonas reinhardtii mutant and Escherichia coli was developed. The GYD1 mutant secretes glycolic acid via photorespiration, which E. coli metabolizes via the glyoxylate cycle. E. coli growth was improved by implementing two-stage continuous systems to 2.0 mg L-1 h-1 on CO2. The production of green fluorescent protein (0.52 ng L-1 h-1) and lycopene (6.3 μg L-1 h-1) was also demonstrated. This study represents a successful case of a synthetic modular co-culture with a microalga and a heterotrophic bacterium, potentially contributing to sustainable industrial processes and reducing environmental impact.

Keywords:  GFP; Heterotrophic bacteria; Lycopene; Microalgae; Microbial consortium

DOI:  https://doi.org/10.1016/j.ymben.2025.03.004
Nat Chem. 2025 Mar 12.

Designing single-polymer-chain nanoparticles to mimic biomolecular hydration frustration.

Tianyi Jin, Connor W Coley, Alfredo Alexander-Katz.

Native folded proteins rely on sculpting the local chemical environment of their active or binding sites, as well as their shapes, to achieve functionality. In particular, proteins use hydration frustration-control over the dehydration of hydrophilic residues and the hydration of hydrophobic residues-to amplify their chemical or binding activity. Here we uncover that single-polymer-chain nanoparticles formed by random heteropolymers comprising four or more components can display similar levels of hydration frustration. We categorize these nanoparticles into three types based on whether either hydrophobic or hydrophilic residues, or both types, display frustrated states. We propose a series of physicochemical rules that determine the state of these nanoparticles. We demonstrate the generality of these rules in atomistic and simplified Monte Carlo models of single-polymer-chain nanoparticles with different backbones and residues. Our work provides insights into the design of single-chain nanoparticles, an emerging polymer modality that achieves the ease and cost of fabrication of polymeric material with the functionality of biological proteins.

DOI: https://doi.org/10.1038/s41557-025-01760-9
Nat Commun. 2025 Mar 11. 16(1): 2410

Responsive DNA artificial cells for contact and behavior regulation of mammalian cells.

Miao Wang, Hexin Nan, Meixia Wang, Sihui Yang, Lin Liu, Hong-Hui Wang, Zhou Nie.

Artificial cells have emerged as synthetic entities designed to mimic the functionalities of natural cells, but their interactive ability with mammalian cells remains challenging. Herein, we develop a generalizable and modular strategy to engineer DNA-empowered stimulable artificial cells designated to regulate mammalian cells (STARM) via synthetic contact-dependent communication. Constructed through temperature-controlled DNA self-assembly involving liquid-liquid phase separation (LLPS), STARMs feature organized all-DNA cytoplasm-mimic and membrane-mimic compartments. These compartments can integrate functional nucleic acid (FNA) modules and light-responsive gold nanorods (AuNRs) to establish a programmable sense-and-respond mechanism to specific stimuli, such as light or ions, orchestrating diverse biological functions, including tissue formation and cellular signaling. By combining two designer STARMs into a dual-channel system, we achieve orthogonally regulated cellular signaling in multicellular communities. Ultimately, the in vivo therapeutic efficacy of STARM in light-guided muscle regeneration in living animals demonstrates the promising potential of smart artificial cells in regenerative medicine.

DOI: https://doi.org/10.1038/s41467-025-57770-1
Cell Syst. 2025 Mar 07. pii: S2405-4712(25)00067-5. [Epub ahead of print] 101234

Multiplexed dynamic control of temperature to probe and observe mammalian cells.

William Benman, Pavan Iyengar, Thomas R Mumford, Zikang Huang, Manya Kapoor, Grace Liu, Lukasz J Bugaj.

  Temperature is an important biological stimulus, yet there is a lack of approaches to modulate the temperature of biological samples in a dynamic and high-throughput manner. The thermoPlate is a device for programmable control of temperature in a 96-well plate, compatible with cell culture and microscopy. The thermoPlate maintains feedback control of temperature independently in each well, with minutes-scale heating and cooling through ΔT = 15-20°C. We first used the thermoPlate to characterize the rapid temperature-dependent phase separation of a synthetic elastin-like polypeptide (ELP53). We then examined stress granule (SG) formation in response to dynamic heat stress, revealing adaptation of SGs to persistent heat and formation of a memory of stress that prevented SG formation in response to subsequent heat shocks. The capabilities and open-source nature of the thermoPlate will empower the study and engineering of a wide range of thermoresponsive phenomena. A record of this paper's transparent peer review process is included in the Supplemental information.

Keywords:  adaptation; devices; elastin-like polypeptides; heat shock; open source; stress dynamics; stress granules; stress signaling; temperature modulation; thermogenetics

DOI:  https://doi.org/10.1016/j.cels.2025.101234
mBio. 2025 Mar 14. e0398824

Noncanonical amino acids as prophage inducers for protein regulation in bacteria-based delivery systems.

Hongfang Liu, Sijia Shen, Qi Xu, Yuyang Wang, Kejing Qi, Bowen Lu, Bing Tang, Min Wu, Fei Gan.

  Genetically engineered bacteria represent a promising drug delivery tool for disease treatment. The development of new strategies for specific and independent protein regulation is necessary, especially for combination protein drug therapy. Using the well-studied Escherichia coli phage λ as a model system, we applied noncanonical amino acids (ncAAs) as novel inducers for protein regulation in a bacteria-based delivery system. Screening the permissive sites of the Cro protein revealed that incorporation of AlocK at the K8 site with the MbPylRS-349F/tRNAPyl system produced a functional Cro-K8AlocK variant. Using an engineered λ lysogen expressing the MbPylRS-349F/tRNAPyl pair, Cro-8X, and the reporter mNeonGreen, in vitro and in vivo experiments showed that AlocK led to bacterial lysis through prophage activation and the release of mNeonGreen. If mNeonGreen was integrated into the λ prophage genome, λ phages released due to AlocK induction delivered the reporter gene into the recipient E. coli strain, enabling mNeonGreen expression. Furthermore, insertion of pIF at the F14 site with the AfpIFRS/tRNATyr pair produced a functional Cro-F14pIF variant. Importantly, AfpIFRS/tRNATyr and MbPylRS-349F/tRNAPyl pairs were confirmed to be mutually orthogonal. In a mixture of two engineered λ lysogens expressing different aaRS/tRNAs, Cro-ncAAs, and reporter proteins, AlocK and pIF independently induced bacterial lysis and activated the expression of mNeonGreen and mCherry in the recipient E. coli strain. Collectively, the proposed bacteria-based delivery system provides two options for protein delivery and enables independent regulation of multiple proteins with ncAAs, offering a novel approach for in situ protein regulation and combination therapy.
IMPORTANCE: The use of genetically engineered bacteria as drug delivery vectors has attracted more and more attention in recent years. A key issue with bacteria-based delivery systems is how to regulate multiple protein drugs. Based on genetic code expansion technology, we developed a new strategy of using ncAAs as small molecular inducers for in situ protein regulation and engineered λ phage lysogen into a bacteria-based delivery system that can function in two delivery modes. Furthermore, this strategy enables independent regulation of multiple proteins by different ncAAs, offering important implications for combination therapy. This approach requires minimal genetic engineering efforts, and similar strategies can be applied to engineer other prophage-bacteria systems or study phage biology. This work expands the therapeutic applications of ncAAs and lysogenic phages.

Keywords:  bacteria-based delivery system; genetic code expansion; noncanonical amino acid; λ phage

DOI:  https://doi.org/10.1128/mbio.03988-24
ACS Biomater Sci Eng. 2025 Mar 10. 11(3): 1806-1817

3D Printing of Silicone Organogel Elastomers for Structured Soft Biomaterials.

Yiqun Li, Gloria Nieva-Esteve, Salvador Borrós, Robert Texidó Bartés, Abdon Pena-Francesch.

  Creating customizable soft medical implants and devices tailored to patient-specific anatomy represents a significant challenge in healthcare, requiring 3D-printable materials with viscoelastic properties similar to those of natural tissue, high adaptability, and biocompatibility. Here, we develop a family of silicone organogel inks for 3D printing of tunable soft biomaterials via direct ink writing (DIW). We have developed a set of ink formulations comprising photo-cross-linkable silicone polymers, silicone oil, and fumed silica nanoparticles to modify the rheological behavior of the inks, optimize their printability, and control the viscoelastic properties of the printed organogel materials. The formulation approach decouples ink viscosity and shear-thinning behavior from the properties of the printed organogel materials, yielding soft elastomeric materials spanning 3 orders of magnitude in moduli. These organogel inks were used in multimaterial DIW to print soft-structured materials with nonlinear behavior, leveraging graded spatial heterogeneity to introduce stress dissipation and out-of-plane deformation mechanisms. The biocompatibility of these organogel materials was analyzed through a variety of cytotoxicity assays with human dermal fibroblasts, showing no significant toxicity, even in formulations with high silicone oil content. Due to their wide tunability, biocompatibility, and easy printability, these silicone organogel materials show great potential for 3D printing customizable soft devices useful in many applications, including patient-specific implants, prosthetics, wearable devices, medical phantoms, soft robotics, and medical devices.

Keywords:  3D printing; direct ink writing (DIW); medical device; organogel; rheology; silicone

DOI:  https://doi.org/10.1021/acsbiomaterials.4c01441
Trends Biotechnol. 2025 Mar 11. pii: S0167-7799(25)00041-1. [Epub ahead of print]

SubtiToolKit: a bioengineering kit for Bacillus subtilis and Gram-positive bacteria.

Joaquin Caro-Astorga, Matt Rogan, Koray Malcı, Hia Ming, Erika Debenedictis, Paul James, Tom Ellis.

  Building DNA constructs of increasing complexity is key to synthetic biology. Golden Gate (GG) methods led to the creation of cloning toolkits - collections of modular standardized DNA parts hosted on hierarchic plasmids, developed for yeast, plants, Gram-negative bacteria, and human cells. However, Gram-positive bacteria have been neglected. Bacillus subtilis is a Gram-positive model organism and a workhorse in the bioindustry. Here, we present the SubtiToolKit (STK), a high-efficiency cloning toolkit for B. subtilis and Gram-positive bacteria. Its design permits DNA constructs for transcriptional units (TUs), operons, and knockin and knockout applications. The STK contains libraries of promoters, ribosome-binding site (RBSs), fluorescent proteins, protein tags, terminators, genome integration parts, a no-leakage genetic device to control the expression of toxic products during Escherichia coli assembly, and a toolbox for industrially relevant strains of Geobacillus and Parageobacillus as an example of the STK versatility for other Gram-positive bacteria and its future perspective as a reference toolkit.

Keywords:  Bacillus subtilis; Geobacillus; Golden Gate; Gram-positive; SubtiToolKit; bioengineering; cloning; genetic engineering; genetic tool kit; synthetic biology

DOI:  https://doi.org/10.1016/j.tibtech.2025.02.004
ACS Synth Biol. 2025 Mar 14.

Intra- and Interbead Communications by an Anchored DNA Structure and Cascaded DNA Reactions.

Ibuki Kawamata, Satoru Yoshizawa, Keita Abe, Masahiro Takinoue, Shin-Ichiro M Nomura, Satoshi Murata.

  In nature, communication between compartments, such as cells and organelles, gives rise to biological complexity. Two types of chemical communication play important roles in achieving this complexity: intra- and intercompartment communication. Building a bioinspired synthetic system that can exhibit such communication is of interest for realizing microscale artificial robots with the complexity of actual cells. In this study, we aimed to demonstrate intra- and interbead communication using microbeads made of hydrogels as compartments. We employed the diffusion and reaction of programmed DNA molecules as a medium for chemical communication. As a result of the reaction-diffusion dynamics of DNA, the spatiotemporal development of fluorophore-labeled DNAs was observed under fluorescence microscopy, showing both intra- and interbead communication. Our simple, robust, and scalable methodology will accelerate the fabrication of synthetic microsystems that may have complex functionalities from various local interactions.

Keywords:  DNA computing; intra- and interbead communication; molecular cybernetics; molecular robotics; pattern formation; reaction−diffusion system

DOI:  https://doi.org/10.1021/acssynbio.4c00709
bioRxiv. 2025 Feb 28. pii: 2025.02.28.640587. [Epub ahead of print]

Genetically encoded protein oscillators for FM streaming of single-cell data.

Rohith Rajasekaran, Thomas M Galateo, Zhejing Xu, Dennis T Bolshakov, Elliott W Z Weix, Scott M Coyle.

Radios and cellphones use frequency modulation (FM) of an oscillating carrier signal to reliably transmit multiplexed data while rejecting noise. Here, we establish a biochemical analogue of this paradigm using genetically encoded protein oscillators (GEOs) as carrier signals in circuits that enable continuous, real-time FM streaming of single-cell data. GEOs are constructed from evolutionarily diverse MinDE-family ATPase and activator modules that generate fast synthetic protein oscillations when co-expressed in human cells. These oscillations serve as a single-cell carrier signal, with frequency and amplitude controlled by GEO component levels and activity. We systematically characterize 169 ATPase/activator GEO pairs and engineer composite GEOs with multiple competing activators to develop a comprehensive platform for waveform programming. Using these principles, we design circuits that modulate GEO frequency in response to cellular activity and decode their responses using a calibrated machine-learning model to demonstrate sensitive, real-time FM streaming of transcription and proteasomal degradation dynamics in single cells. GEOs establish a dynamically controllable biochemical carrier signal, unlocking noise-resistant FM data-encoding paradigms that open new avenues for dynamic single-cell analysis.

DOI: https://doi.org/10.1101/2025.02.28.640587
Metab Eng Commun. 2025 Jun;20 e00257

Metabolic growth-coupling strategies for in vivo enzyme selection systems.

Tobias B Alter, Pascal A Pieters, Colton J Lloyd, Adam M Feist, Emre Özdemir, Bernhard O Palsson, Daniel C Zielinski.

  Whole-cell biocatalysis facilitates the production of a wide range of industrially and pharmaceutically relevant molecules from sustainable feedstocks such as plastic wastes, carbon dioxide, lignocellulose, or plant-based sugar sources. The identification and use of efficient enzymes in the applied biocatalyst is key to establishing economically feasible production processes. The generation and selection of favorable enzyme variants in adaptive laboratory evolution experiments using growth as a selection criterion is facilitated by tightly coupling enzyme catalytic activity to microbial metabolic activity. Here, we present a computational workflow to design strains that have a severe, growth-limiting metabolic chokepoint through a shared class of enzymes. The resulting chassis cell, termed enzyme selection system (ESS), is a platform for growth-coupling any enzyme from the respective enzyme class, thus offering cross-pathway application for enzyme engineering purposes. By applying the constraint-based modeling workflow, a publicly accessible database of 25,505 potential and experimentally tractable ESS designs was built for Escherichia coli and a broad range of production pathways with biotechnological relevance. A model-based analysis of the generated design database reveals a general design principle that the target enzyme activity is linked to overall microbial metabolic activity, not just the synthesis of one biomass precursor. It can be observed that the stronger the predicted coupling between target enzyme and metabolic activity, the lower the maximum growth rate and therefore the viability of an ESS. Consequently, growth-coupling strategies with only suboptimal coupling strengths, as are included in the ESS design database, may be of interest for practical applications of ESSs in order to circumvent overly restrictive growth defects. In summary, the computed design database, which is accessible via https://biosustain.github.io/ESS-Designs/, and its analysis provide a foundation for the generation of valuable in vivo ESSs for enzyme optimization purposes and a range of biotechnological applications in general.

Keywords:  Constraint-based metabolic modeling; Enzyme engineering; Growth-coupling; Microbial cell factories; Microbial strain design

DOI:  https://doi.org/10.1016/j.mec.2025.e00257
ACS Appl Bio Mater. 2025 Mar 03.

Mechanical, Thermal, and Rheological Properties of Fish-Porcine Gelatin Microparticle Composites for Advanced 3D Biofabrication.

Syed M Q Bokhari, Mecit A Alioglu, Grace L Voronin, Jeffrey M Catchmark.

  Driven by the increasing need for the biofabrication of complex hydrogels, this work introduces a class of fish-porcine composite hydrogels that combine rapid, tunable photo-cross-linking with microparticle reinforcement for advanced 3D printing. Here, precross-linked porcine gelatin (methacrylated porcine gelatin, MPG) microparticles are incorporated into a methacrylated fish gelatin (MFG) matrix to produce robust yet easily processable hydrogels. Nuclear magnetic resonance (NMR) confirmed the degree of methacrylation, while scanning electron microscopy (SEM) revealed the hierarchical porosity vital for tissue integration. Detailed Mastersizer measurements characterized the size distributions of the MPG microparticles, and rheological tests demonstrated the composite hydrogels' strong shear-thinning behavior, an essential trait for extrusion-based and embedded 3D printing. Thermal (TGA, DSC) and mechanical (compression) analyses show that the microparticle-reinforced hydrogels achieve improved thermal stability, adjustable mass swelling ratio, and customizable compressive moduli. As a proof of concept, these composites are validated in digital light processing (DLP) printing of microfluidic constructs and as a support bath for embedded printing of complex geometries. This platform provides a unique synergy of easy UV cross-linkability, tunable mechanical features, and 3D printing versatility. This advancement underscores the potential of these materials as a foundational platform in tissue engineering, opening new avenues for creating complex, biocompatible structures with customizable properties.

Keywords:  GelMA; composite hydrogels; gelatin microparticles; mechanical analysis; photo-cross-linking; rheology; thermal analysis

DOI:  https://doi.org/10.1021/acsabm.4c01977
Nat Mater. 2025 Mar 12.

Enabling three-dimensional architected materials across length scales and timescales.

James Utama Surjadi, Carlos M Portela.

Architected materials provide a pathway to defy the limitations of monolithic materials through their engineered microstructures or geometries, allowing them to exhibit unique and extreme properties. Thus far, most studies on architected materials have been limited to fabricating periodic structures in small tessellations and investigating them under mostly quasi-static conditions, but explorations of more complex architecture designs and their properties across length scales and timescales will be essential to fully uncover the potential of this materials system. In this Perspective, we summarize state-of-the-art approaches to realizing multiscale architected materials and highlight existing knowledge gaps and opportunities in their design, fabrication and characterization. We also propose a roadmap to accelerate the discovery of architected materials with programmable properties via the synergistic combination of experimental and computational efforts. Finally, we identify research opportunities and open questions in the development of next-generation architected materials, intelligent devices and integrated systems that can bridge the gap between the conception and implementation of these materials in real-world engineering applications.

DOI: https://doi.org/10.1038/s41563-025-02119-8
Annu Rev Chem Biomol Eng. 2025 Mar 13.

Engineering Protein-Polyelectrolyte Interactions for Cellular Applications.

Rachel S Fisher, Jane Liao, So Yeon Ahn, Nisha Modi, Aaron K Kidane, Allie C Obermeyer.

Protein-polyelectrolyte interactions are fundamental interactions in biology that occur at every length scale, from protein-DNA complexes to phase-separated organelles. They drive processes ranging from gene transcription and DNA synthesis to viral assembly. Protein engineering is a powerful way to modulate these interactions, both to probe endogenous function and to engineer novel interactions between species. In this review, we consider the various noncovalent interactions that govern the formation and behavior of these complexes, and we discuss how protein modifications such as changes to structure, charge, and charge patterning affect them. We highlight recent examples where engineering changes to protein-polyelectrolyte interactions have helped elucidate biological function, and we then focus on recent efforts toward de novo material design of synthetic biomolecular condensates and functional nanoassemblies.

DOI: https://doi.org/10.1146/annurev-chembioeng-100722-105929
ACS Appl Mater Interfaces. 2025 Mar 12.

Multiscale Mechanical Characterization of Mineral-Reinforced Wood Cell Walls.

Steven A Soini, Inam Lalani, Matthew L Maron, David Gonzalez, Hassan Mahfuz, Neus Domingo-Marimon, Vivian Merk.

  Studying the multiscale mechanics of bio-based composites offers unique perspectives on underlying structure-property relations. Cellular materials, such as wood, are highly organized, hierarchical assemblies of load-bearing structural elements that respond to mechanical stimuli at the microscopic, mesoscopic and macroscopic scale. In this study, we modified oak wood with nanocrystalline ferrihydrite, a widespread ferric oxyhydroxide mineral, and characterized the resulting mechanical properties of the composite at various levels of organization. Ferrihydrite nanoparticles were deposited inside the wood cell wall by an in situ chemical reaction, resulting in increased stiffness and hardness of the functionalized secondary cell wall, as evidenced by region-specific nanoindentation tests under an electron microscope. Chemically modified and pristine wood samples were characterized by using atomic force microscopy in the bimodal frequency modulation mode, which produced topographical images from the cellular ultrastructure with high lateral resolution and localized nanomechanical information across distinct cell wall layers. Despite mineral reinforcement at the cell wall level, the macroscopic fracture behavior examined through three-point flexural testing remained unchanged upon modification, as cell-cell adhesion could be impaired by harsh chemical conditions.

Keywords:  bimodal atomic force microscopy; ferrihydrite; iron oxide; lignocellulose; nanoindentation; three-point bending; wood modification

DOI:  https://doi.org/10.1021/acsami.4c22384
J Bacteriol. 2025 Mar 11. e0049924

Identification of EcpK, a bacterial tyrosine pseudokinase important for exopolysaccharide biosynthesis in Myxococcus xanthus.

Luca Blöcher, Johannes Schwabe, Timo Glatter, Lotte Søgaard-Andersen.

  Bacteria synthesize chemically diverse capsular and secreted polysaccharides that function in many physiological processes and are widely used in industrial applications. In the ubiquitous Wzx/Wzy-dependent biosynthetic pathways for these polysaccharides, the polysaccharide co-polymerase (PCP) facilitates the polymerization of repeat units in the periplasm, and in Gram-negative bacteria, also polysaccharide translocation across the outer membrane. These PCPs belong to the PCP-2 family, are integral inner membrane proteins with extended periplasmic domains, and functionally depend on alternating between different oligomeric states. The oligomeric state is determined by a cognate cytoplasmic bacterial tyrosine kinase (BYK), which is either part of the PCP or a stand-alone protein. Interestingly, BYK-like proteins, which lack key catalytic residues and/or the phosphorylated Tyr residues, have been described. In Myxococcus xanthus, the exopolysaccharide (EPS) is synthesized and exported via the Wzx/Wzy-dependent EPS pathway in which EpsV serves as the PCP. Here, we confirm that EpsV lacks the BYK domain. Using phylogenomics, experiments, and computational structural biology, we identify EcpK as important for EPS biosynthesis and show that it structurally resembles canonical BYKs but lacks residues important for catalysis and Tyr phosphorylation. Using proteomic analyses, two-hybrid assays, and structural modeling, we demonstrate that EcpK directly interacts with EpsV. Based on these findings, we suggest that EcpK is a BY pseudokinase and functions as a scaffold, which by direct protein-protein interactions, rather than by Tyr phosphorylation, facilitates EpsV function. EcpK and EpsV homologs are present in other bacteria, suggesting broad conservation of this mechanism and establishing a phosphorylation-independent PCP-2 subfamily.IMPORTANCEBacteria produce a variety of polysaccharides with important biological functions. In Wzx/Wzy-dependent pathways for the biosynthesis of secreted and capsular polysaccharides in Gram-negative bacteria, the polysaccharide co-polymerase (PCP) is a key protein that facilitates repeat unit polymerization and polysaccharide translocation across the outer membrane. PCP function depends on assembly/disassembly cycles that are determined by the phosphorylation/dephosphorylation cycles of an associated bacterial tyrosine kinase (BYK). Here, we identify the BY pseudokinase EcpK as essential for exopolysaccharide biosynthesis in Myxococcus xanthus. Based on experiments and computational structural biology, we suggest that EcpK is a scaffold protein, guiding the assembly/disassembly cycles of the partner PCP via binding/unbinding cycles independently of Tyr phosphorylation/dephosphorylation cycles. We suggest that this novel mechanism is broadly conserved.

Keywords:  PCP protein; Wzc; Wzy polymerase; Wzy protein; Wzz; bacterial tyrosine kinase; bacterial tyrosine pseudokinase; capsular polysaccharide; polysaccharide co-polymerase; polysaccharides

DOI:  https://doi.org/10.1128/jb.00499-24
Angew Chem Int Ed Engl. 2025 Mar 03. e202502104

Homochiral Helical Poly(thiophene)s Accessed via Living Catalyst-Transfer Polymerization.

Matthew D Hannigan, Jada A Sampson, Lasya Damaraju, Marcus Weck.

  Synthetic helical polymers form compact, ordered, and inherently chiral structures, enabling their uses in biomimetic applications as well as catalysis. A challenge in using synthetic helical polymers, however, is their tendency to be sensitive to pH and the presence of nucleophiles, Lewis-acids, or metal ions. We report a strategy to overcome these shortcomings by adapting catalyst-transfer polymerization, a living chain-growth polymerization typically used to access linear conjugated polymers, for the synthesis of helical poly(thiophene)s. We demonstrate that the helical poly(thiophene)s can be synthesized with a single helicity, incorporated into block copolymers, and functionalized at the chain-ends, enabling further conjugation and functionalization. The helical poly(thiophene)s are stable to a variety of conditions, providing benefits over other helical polymers which contain sensitive imine or carbonyl-based functional groups. We anticipate that the ability to access homochiral, heterotelechelic helical conjugated polymers and copolymers will enable new uses of these materials in optoelectronics as well as in applications for mimicking biomacromolecules and other polymers with precisely defined sequences.

Keywords:  Catalyst‐transfer polymerization; Helical polymers; Homochirality; Poly(thiophene)s

DOI:  https://doi.org/10.1002/anie.202502104
ACS Synth Biol. 2025 Mar 10.

Engineering Chromatin Regulation of Xylose Utilization in Budding Yeast Saccharomyces cerevisiae for Efficient Bioconversion.

Wei-Bin Wang, Rui-Qi Tang, Bing Yuan, Yue Wang, Guo-Dong Liu, Dong-Min Li, Hong-Jia Zhang, Xin-Qing Zhao, Feng-Wu Bai.

  Utilization of xylose as a renewable carbon source has received constant interest. Considering that the structure and state of eukaryotic chromatin are inextricably intertwined, it is significant to explore chromatin regulation for engineering xylose metabolism in yeast. Here, we show that two chromatin remodelers, namely, Swr1 and Isw1, affect xylose utilization in recombinant budding yeastSaccharomyces cerevisiae. Overexpressing SWR1 showed the highest increase in xylose utilization, up to 29.3%, compared to that of the parent strain. Furthermore, comparative transcriptome and chromatin immunoprecipitation sequencing (ChIP-seq) analyses revealed significantly different changes of gene expression by elevated expression of Swr1 and Isw1. Reduced histone H2A.Z occupancy in two key carbon-metabolism regulators of Mig2 and Sip2 was further observed in the engineered yeast. Further tests showed improved xylose utilization of the engineered yeast in the presence of corncob hydrolysate. Our results suggest that chromatin regulators are critical genetic elements in recombinant S. cerevisiae for engineering xylose metabolism.

Keywords:  ChIP-seq analysis; H2A.Z occupancy; S. cerevisiae; bioconversion of lignocellulosic hydrolysate; chromatin remodelers; xylose utilization

DOI:  https://doi.org/10.1021/acssynbio.4c00730
Adv Mater. 2025 Mar 12. e2500809

Bio-Inspired Retina by Regulating Ion-Confined Transport in Hydrogels.

Hongjie Zhang, Song Wang, Li Wang, Shengke Li, Haowen Liu, Xinyi Zhu, Yuanxia Chen, Guoheng Xu, Mingming Zhang, Quanying Liu, Ruibing Wang, Kai Xiao.

  The effective and precise processing of visual information by the human eye primarily relies on the diverse contrasting functions achieved through synaptic regulation of ion transport in the retina. Developing a bio-inspired retina that uses ions as information carriers can more accurately replicate retina's natural signal processing capabilities, enabling high-performance machine vision. Herein, an ion-confined transport strategy is proposed to construct a bio-inspired retina by developing artificial synapses with inhibitory and excitatory contrasting functions. By fine-tuning the ionic hydrogel structures to control ion transport across the heterogeneous interfaces, inhibitory and excitatory synapses are realized to negatively or positively modulate the optical signal. The integration of these synapses facilitates advanced tasks such as image recognition and motion analysis. Moreover, as a proof of concept, guiding robot vehicles to perform path planning is demonstrated. This work offers a new idea for constructing the bio-inspired retina by precisely regulating ion transport, allowing it to reach a level closer to the biological retina.

Keywords:  artificial synapses; hydrogels; ion‐confined transport; neuromorphic computing; retinas

DOI:  https://doi.org/10.1002/adma.202500809
Int J Biol Macromol. 2025 Mar 07. pii: S0141-8130(25)02412-2. [Epub ahead of print] 141861

High strength kami-ito yarns from microbial cellulose biofilms.

Ayako Takagi, Xun Niu, Peipei Wang, Marina Mehling, Samantha Pritchard, Samuel Hahn, Heather Young, Tianyu Guo, Yi Lu, Orlando J Rojas.

  We present a method for developing high-strength, sustainable yarns from microbial biofilms with minimal processing and chemical use. Inspired by the japanese "kami-ito" () technique for creating yarns from paper, we introduce an eco-friendly alternative to cotton and industrially-produced man-made cellulose fibers using a microbial cellulose source. We culture and dye bacterial cellulose biofilms that we used to produce yarns with tensile strengths of up to 200 MPa (55 MPa in the wet state). These bacterial cellulose (BC) yarns exhibit significant stretchability, with elongation reaching 23 % in dry conditions, which is a remarkable improvement when considering the stiffness of typical mane-made cellulose filaments and dried BC films. The BC yarns are shown to absorb up to 24 % water at 100 % relative humidity, comparable to natural fibers like hemp and flax. Our findings further underscore a multidisciplinary exploration that integrates biology, art, and design to develop durable, dyeable, and environmentally sustainable textile yarns.

Keywords:  Bacterial cellulose yarns; Biofilms; Bioproducts; Kami-ito; Natural dyes; Paper textiles

DOI:  https://doi.org/10.1016/j.ijbiomac.2025.141861
Langmuir. 2025 Mar 12.

Sustainable Biopolymer Colloids: Advances in Morphology for Enhanced Functionalities.

Mesbah Ahmad, Byeunggon Kim, Orlin D Velev.

Biobased polymers such as cellulose, chitin/chitosan, starch, alginate, and lignin are making inroads as sustainable, environmentally safe and biodegradable alternatives to synthetic colloidal materials. This perspective summarizes recent developments in preparation techniques, identifies critical barriers, and proposes future directions for improving the performance and applicability of biopolymer colloidal structures. A major focus is the sustainable colloids morphology as a means of introducing functionality without chemical modification. We discuss the strategies for fabrication of four distinct classes of colloidal morphologies from biobased materials: spherical and nonspherical particles, fibers/fibrils, and films. Their preparation methods can be categorized into physical and chemical approaches. Despite advancements in these methods, challenges persist regarding uniformity, scalability, desired properties, and the need to enhance environmental sustainability. Addressing these challenges is essential for facilitating the transition from synthetic polymers to greener, more sustainable, and microplastic-free colloidal alternatives.

DOI: https://doi.org/10.1021/acs.langmuir.5c00013
Nat Commun. 2025 Mar 12. 16(1): 2482

Upcycling waste commodity polymers into high-performance polyarylate materials with direct utilization of capping agent impurities.

Cheng Li, Guangming Yan, Zhongwen Dong, Gang Zhang, Fan Zhang.

Commodity polymers are ubiquitous in our society, having replaced many inorganic and metal-based materials due to their versatile properties. However, their functionality heavily relies on the addition of various components known as additives, making it challenging to recycle the polymer fraction of plastic materials effectively. Thus, it is crucial to develop efficient chemical recovery strategies for commodity polymers and additives to facilitate the direct utilization of recovered monomers and additives without additional purification. Here, we develop a strategy for co-upcycling two types of waste commodity polymers, polycarbonate, and polyethylene terephthalate into polyarylate, a high-performance transparent engineering plastic. By incorporating a highly active metal-free ionic liquids catalyst for methanolysis and a two-stage interface polymerization technique with variable temperature control, we successfully prepare polyacrylate film materials from real end-of-life plastics with direct utilization of capping agent impurities in recovered monomers. These materials exhibit excellent thermal performance (Tg = 192.8 °C), transmittance (reach up to 86.73%), and flame-retardant properties (V-0, UL-94), equivalent to those of commercial polyarylate (U-100, about $10000/ton), and could be further easily close-loop recycled. Demonstrated in kilogram-scale experiments and life cycle assessments, this approach offers a low-carbon, environmentally friendly, and economically feasible pathway for upcycling waste commodity polymers.

DOI: https://doi.org/10.1038/s41467-025-57821-7
Nat Chem. 2025 Mar 12.

Aging-dependent evolving electrochemical potentials of biomolecular condensates regulate their physicochemical activities.

Wen Yu, Xiao Guo, Yu Xia, Yuefeng Ma, Zhongli Tong, Leshan Yang, Xiaowei Song, Richard N Zare, Guosong Hong, Yifan Dai.

A passive consequence of macromolecular condensation is the establishment of an ion concentration gradient between the dilute and dense phases, which in turn governs distinct electrochemical properties of condensates. However, the mechanisms that regulate the electrochemical equilibrium of condensates and their impacts on emergent physicochemical functions remain unknown. Here we demonstrate that the electrochemical environments and the physical and chemical activities of biomolecular condensates, dependent on the electrochemical potential of condensates, are regulated by aging-associated intermolecular interactions and interfacial effects. Our findings reveal that enhanced dense-phase interactions during condensate maturation continuously modulate the ion distribution between the two phases. Moreover, modulating the interfacial regions of condensates can affect the apparent pH within the condensates. To directly probe the interphase and interfacial electric potentials of condensates, we have designed and implemented electrochemical potentiometry and second harmonic generation-based approaches. Our results suggest that the non-equilibrium nature of biomolecular condensates might play a crucial role in modulating the electrochemical activities of living systems.

DOI: https://doi.org/10.1038/s41557-025-01762-7
Adv Mater. 2025 Mar 10. e2416901

Artificial Intelligence and Multiscale Modeling for Sustainable Biopolymers and Bioinspired Materials.

Xing Quan Wang, Zeqing Jin, Dharneedar Ravichandran, Grace X Gu.

  Biopolymers and bioinspired materials contribute to the construction of intricate hierarchical structures that exhibit advanced properties. The remarkable toughness and damage tolerance of such multilevel materials are conferred through the hierarchical assembly of their multiscale (i.e., atomistic to macroscale) components and architectures. Here, the functionality and mechanisms of biopolymers and bio-inspired materials at multilength scales are explored and summarized, focusing on biopolymer nanofibril configurations, biocompatible synthetic biopolymers, and bio-inspired composites. Their modeling methods with theoretical basis at multiple lengths and time scales are reviewed for biopolymer applications. Additionally, the exploration of artificial intelligence-powered methodologies is emphasized to realize improvements in these biopolymers from functionality, biodegradability, and sustainability to their characterization, fabrication process, and superior designs. Ultimately, a promising future for these versatile materials in the manufacturing of advanced materials across wider applications and greater lifecycle impacts is foreseen.

Keywords:  artificial intelligence; bioinspired materials; biopolymer; computational mechanics; machine learning; multiscale modeling

DOI:  https://doi.org/10.1002/adma.202416901
ACS Appl Mater Interfaces. 2025 Mar 11.

Orthogonal Host-Guest Interactions Enable Programming of Protocell Membranes for Cellular High-Order Assembly and Enhanced Immunogenicity.

Shuhan Xiong, Vincent Mukwaya, Xiaolei Yu, Yirong Zeng, Li Wang, Weili Zhao, Hongjing Dou.

  The complement system's distinguishing feature is its cell-specific surface ligands. However, the limited scalability and complexity of incorporating surface-customizable ligands into membrane-bound cell-like microassemblages have hindered their widespread adoption in synthetic biology and bioengineering. Here, we present a method for the batch construction of polysaccharide-based microcapsules (polysaccharidosomes, P-somes) with intrinsic functional host membranes capable of docking guest ligands via facile host-guest interactions. β-Cyclodextrin (β-CD) conjugated to the microcapsule membrane building block serves as the host entity for guest adamantane-linked functional molecules Cyanine5 (Cy5) and Pam3CSK4 (PAM). Interactive docking of either an aggregation agent, Cy5, or a Toll-like receptor agonist, Pam3CSK4, on P-somes followed by incubation with macrophages resulted in aggregation and immune activation of macrophages, respectively. The specificity of host-guest interactions allows for the expedited incorporation of additional functionalities into microassemblages. This can be instrumental in engineering cell-like membrane surfaces that replicate genuine cell-cell interactions, offering a unified platform for the development of micrometer-sized programmable therapeutic protocells.

Keywords:  high-order assembly; host−guest interaction; immunotherapy; orthogonal synergistic; protocells

DOI:  https://doi.org/10.1021/acsami.4c20476
Adv Mater. 2025 Mar 12. e2418656

Sustainable 4D Printed Meta Biocomposite Materials for Programmable Structural Shape Changing.

Melvin Josselin, Michael Castro, Noélie Di Cesare, Fabrizio Scarpa, Antoine Le Duigou.

  Biological structures provide inspiration for developing advanced materials from sustainable resources, enabling passive structural morphing. Despite an increasing interest for parsimony-oriented innovation, sustainable shape-changing materials based on renewable resources remain underexplored. In this work, the architecture of a single plant fiber cell wall (S2, for instance) is simplified to design novel concepts of 4D printed tubular moisture-driven structural actuators, using the hygromorphic properties of continuous flax fiber (cFF) reinforced materials. This new class of bioinspired active materials is referred to as metabiocomposites. Before bioinspired design, the materials are produced with a customized rotary 3D printer, qualified, and tested for sorption behavior. A parametric experimental, analytical, and FEA analysis highlights the programmability of the material through the effects of mesostructural parameters (printing inclination α) and geometric factors (operational length L, inner diameter D, and thickness h) on the actuation authority. The overall performance is a trade-off between rotation and torque, with energy density comparable to that of the source of inspiration: natural fibers cell wall. The potential applications are illustrated through a proof of concept for a meteosensitive rotative structure that transmits motion to an external device, such as a solar tracker.

Keywords:  4D‐printing; biocomposites; biomimicry; metamaterials; meteosensitive

DOI:  https://doi.org/10.1002/adma.202418656
bioRxiv. 2025 Feb 27. pii: 2025.02.22.639695. [Epub ahead of print]

AggreBots: configuring CiliaBots through guided, modular tissue aggregation.

D Bhatttaram, K Golestan, X Zhang, S Yang, Z Gong, S L Brody, A Horani, V A Webster-Wood, A B Farimani, X Ren.

Ciliated biobots, or CiliaBots, are a class of engineered multicellular tissues that are capable of self-actuated motility propelled by the motile cilia located on their exterior surface. Correlations have been observed between CiliaBot motility patterns and their morphology and cilia distribution. However, precise control of these structural parameters to generate desired motility patterns predictably remains lacking. Here, we developed a novel Aggregated CiliaBot (AggreBot) platform capable of producing designer motility patterns through spatially controlled aggregation of epithelial spheroids made from human airway cells (referred to as CiliaBot Building Blocks or CBBs), yielding AggreBots with configurable geometry and distribution of active cilia. Guided multi-CBB aggregation led to the production of rod-, triangle-, and diamond-shaped AggreBots, which consistently effected greater motility than traditional single-spheroid CiliaBots. Furthermore, CBBs were found to maintain internal boundaries post-aggregation through the combined action of pathways controlling cellular fluidity and tissue polarity. This boundary fidelity, combined with the use of CBBs with immotile cilia due to mutations in the CCDC39 gene, allowed for the generation of hybrid AggreBots with precision control over the coverage and distribution of active cilia, further empowering control of motility patterns. Our results demonstrate the potential of AggreBots as self-propelling biological tissues through the establishment of morphological "levers" by which alterations to tissue motility can be theoretically planned and experimentally verified.

DOI: https://doi.org/10.1101/2025.02.22.639695
FEMS Yeast Res. 2025 Mar 13. pii: foaf009. [Epub ahead of print]

Recent advances in genetic engineering and chemical production in yeast species.

Sangdo Yook, Hal S Alper.

  Yeasts have emerged as well-suited microbial cell factory for the sustainable production of biofuels, organic acids, terpenoids, and specialty chemicals. This ability is bolstered by advances in genetic engineering tools, including CRISPR-Cas systems and modular cloning in both conventional (Saccharomyces cerevisiae) and non-conventional (Yarrowia lipolytica, Rhodotorula toruloides, Candida krusei) yeasts. Additionally, genome-scale metabolic models (GEMs) and machine learning approaches have accelerated efforts to create a broad range of compounds that help reduce dependency on fossil fuels, mitigate climate change, and offer sustainable alternatives to petrochemical-derived counterparts. In this review, we highlight the cutting-edge genetic tools driving yeast metabolic engineering and then explore the diverse applications of yeast-based platforms for producing value-added products. Collectively, this review underscores the pivotal role of yeast biotechnology in efforts to build a sustainable bioeconomy.

Keywords:  Chemical production; Genetic engineering; Microbial fermentation; Yeasts

DOI:  https://doi.org/10.1093/femsyr/foaf009
Angew Chem Int Ed Engl. 2025 Mar 10. e202502437

Using Colour to Control Conformation in a Chemical System Containing Multiple Tricyanofuran Photoacids.

Matthew M Wootten, Sofja Tshepelevitsh, Ivo Leito, Jonathan Clayden.

  Colour vision relies on selective, reversible isomerisation by visible light of a mixture of retinyl chromophores in photoreceptor cells. Synthetic molecular mimics of this wavelength-dependent induction of function are rare, despite the attractiveness of controlling chemical processes solely by the wavelength of incident light. Here, we report a colour-responsive chemical system composed of a cationic receptor complex, two competing chiral anionic ligands and two metastable photoacids with contrasting absorption properties. Tricyanofuran photoacids were synthesised with absorption maxima of varying wavelengths across the whole visible spectrum. Protons released by the photoacids upon selective irradiation reversibly mask the more basic receptor-bound ligand, leading to ligand exchange that can be observed as a shift in the circular dichroism (CD) spectrum of the reporter complex. A ~90 nm separation between the absorbance maxima of the photoacids allowed each to be selectively photoisomerised in the presence of the other. The concentration of released protons, and hence the magnitude of the shift in CD response, were controlled by changing the wavelength of the incident visible light. Different output behaviours (OR/AND logic gates and wavelength detection) were programmed into the system by varying the relative proportions of the photoacids.

Keywords:  Photoacids; circular dichroism; molecular logic; out-of-equilibrium systems; wavelength selectivity

DOI:  https://doi.org/10.1002/anie.202502437
ACS Chem Biol. 2025 Mar 13.

Dynamic Regulation of 5-Formylcytidine on tRNA.

Xuemeng Sun, Ralph E Kleiner.

Post-transcriptional modifications on RNA play an important role in biological processes, but we lack an understanding of the molecular mechanisms underlying the function of many modifications. Here we characterize the distribution and dynamic regulation of 5-formylcytidine (f5C), a modification primarily found on tRNAs, across different cell lines, mouse tissues, and in response to environmental stress. We identify perturbation in bulk f5C levels using nucleoside LC-MS and quantify individual modification stoichiometry at the wobble base of mt-tRNA-Met and tRNA-Leu-CAA using nucleotide resolution f5C sequencing technology. Our studies show that f5C modifications on tRNAs are dynamic, and responsive to fluctuations in cellular iron levels and O2 concentration. Further, we show using a translation reporter assay that decoding of Leu UUA codons is impaired in cells lacking f5C, implicating f5C(m)34 on tRNA-Leu-CAA in wobble decoding. Together, our work illuminates dynamic epitranscriptomic mechanisms regulating protein translation in response to environment.

DOI: https://doi.org/10.1021/acschembio.4c00866
bioRxiv. 2025 Mar 01. pii: 2025.02.25.640222. [Epub ahead of print]

Plug-and-play assembly of biodegradable ionizable lipids for potent mRNA delivery and gene editing in vivo.

Xuexiang Han, Ying Xu, Adele Ricciardi, Junchao Xu, Rohan Palanki, Vivek Chowdhary, Lulu Xue, Ningqiang Gong, Mohamad-Gabriel Alameh, William H Peranteau, James M Wilson, Drew Weissman, Michael J Mitchell.

mRNA-based gene editing therapeutics offer the potential to permanently cure diseases but are hindered by suboptimal delivery platforms. Here, we devise a robust combinatorial chemistry for plug-and-play assembly of diverse biodegradable ionizable lipids and identify a lead candidate that produces superior lipid nanoparticles for various gene editing tools delivery in vivo. Our study highlights the utility of this synthetic approach and the generality of this platform for potent in vivo gene editing.

DOI: https://doi.org/10.1101/2025.02.25.640222
ACS Appl Mater Interfaces. 2025 Mar 11.

Combination of Dynamic and Permanent Cross-Linking: A Pathway to Enhance Elasticity and Recyclability.

Xinyu Li, Jing Bai, Bing Yu, Fei Chen, Ming Tian.

  Thermosetting materials exhibit advantages such as dimensional stability and elasticity but lack reprocessability due to their permanently cross-linked internal structure. Introducing a reversible cross-linked network endows materials with reprocessability but often compromises resilience and mechanical properties. Hence, it is still a significant challenge to develop recyclable elastomers with high elasticity as traditional thermosetting materials and remolding ability as traditional thermoplastic materials. Based on this, this work incorporates both reversible and irreversible cross-linked networks into a polyurethane system, constructing synergistic networks with distinct properties to achieve high elasticity and reprocessability simultaneously. In addition, by adjusting the proportion of the synergistic networks, the relationship between elasticity and reprocessability in different materials was investigated, revealing the synergistic effect between the dynamic network and the chemical cross-linked network. This work provides theoretical support for the design of elastomer materials that combine the high resilience of thermoset materials with the remolding ability of thermoplastic materials.

Keywords:  dynamic and permanent cross-linking; elasticity; polyurethane network structure optimization; synergistic network; thermal recyclability

DOI:  https://doi.org/10.1021/acsami.5c02509
bioRxiv. 2025 Feb 27. pii: 2025.02.22.639682. [Epub ahead of print]

Cell Contractile Force-Mediated Morphodynamical Tissue Engineering via 4D Printed Degradable Hydrogel Scaffolds.

Aixiang Ding, Kaelyn L Gasvoda, David S Cleveland, Eben Alsberg.

Tissue morphogenesis is a critical aspect tissue development. Recent advances in four-dimensional (4D) cell scaffolds have shown promise for modeling morphogenic processes. While current 4D systems often rely on external stimuli, they tend to overlook the role of intrinsic cell-generated forces, such as cell contractile forces (CCFs), in driving tissue morphogenesis. The paradox between the inherent weakness of CCFs and the robustness of tissue scaffolds presents a significant challenge in achieving effective shape transformations. In this study, we introduce an easily printable, freestanding, cell-laden hydrogel platform designed to harness CCFs for 4D shape morphing. These hydrogels initially provide mechanical support to maintain structural integrity, followed by rapid degradation that amplifies CCFs through enhanced cell-cell interactions and increased local cell density, thereby inducing tissue morphogenesis. This platform enables the formation of scaffold-free constructs with programmed shape transformations. By modulating the initial printed geometries, complex and large tissue constructs can be generated via controlled global shape transformations. Furthermore, the platform supports 4D tissue engineering by facilitating tissue differentiation coupled with dynamic shape evolution. This CCF-4D system represents a significant advancement in biomimetic tissue engineering, offering new avenues for creating dynamic tissue models that closely replicate native morphogenesis.

DOI: https://doi.org/10.1101/2025.02.22.639682
Small Methods. 2025 Mar 09. e2500136

The TissueTractor: A Device for Applying Large Strains to Tissues and Cells for Simultaneous High-Resolution Live Cell Microscopy.

Jing Yang, Emily Hearty, Yingli Wang, Deepthi S Vijayraghavan, Timothy Walter, Sommer Anjum, Carsten Stuckenholz, Ya-Wen Cheng, Sahana Balasubramanian, Yicheng Dong, Adam V Kwiatkowski, Lance A Davidson.

  Mechanical strain substantially influences tissue shape and function in various contexts from embryonic development to disease progression. Disruptions in these processes can result in congenital abnormalities and short-circuit mechanotransduction pathways. Manipulating strain in live tissues is crucial for understanding its impact on cellular and subcellular activities, unraveling the interplay between mechanics and cells. Existing tools, such as optogenetic modulation of strain, are limited to small strains over limited distances and durations. Here, a high-strain stretcher system, the TissueTractor, is introduced to enable simultaneous high-resolution spatiotemporal imaging of live cells and tissues under strain applications varying from 0% to over 100%. We use the system with organotypic explants from Xenopus laevis embryos, where applied tension reveals cellular strain heterogeneity and remodeling of intracellular keratin filaments. To highlight the device's adaptability, the TissueTractor is also used to study two other mechanically sensitive cell types with distinct physiological roles: human umbilical vein endothelial cells and mouse neonatal cardiomyocytes, revealing cell morphological changes under significant strain. The results underscore the potential of the TissueTractor for investigating mechanical cues that regulate tissue dynamics and morphogenesis.

Keywords:  cytoskeletal remodeling; high‐resolution microscopy; live‐cell imaging; mechanosensors; mechanotransduction; tissue stretchers

DOI:  https://doi.org/10.1002/smtd.202500136
Nature. 2025 Mar;639(8054): 309-310

Metals squeezed to thickness of just two atoms.

Javier Sanchez-Yamagishi.



Keywords:  Materials science

DOI:  https://doi.org/10.1038/d41586-025-00548-8
Adv Colloid Interface Sci. 2025 Mar 09. pii: S0001-8686(25)00084-3. [Epub ahead of print]340 103473

Fusion of enzymatic proteins: Enhancing biological activities and facilitating biological modifications.

Agnieszka Rybarczyk, Talha Sultan, Nazim Hussain, Hafiz Muhammad Husnain Azam, Safa Rafique, Jakub Zdarta, Teofil Jesionowski.

  The fusion of enzymatic proteins represents a dynamic frontier in biotechnology and enzymatic engineering. This in-depth review looks at the many different ways that fusion proteins can be used, showing their importance in biosensing, gene therapy, targeted drug delivery, and biocatalysis. Fusion proteins have shown an astounding ability to improve and fine-tune biological functions by combining the most beneficial parts of different enzymes. Our first step is to explain how protein fusion increases biological functions. This will provide a broad picture of how this phenomenon has changed many fields. We dissect the intricate mechanisms through which fusion proteins orchestrate cellular processes, underscoring their potential to revolutionize the landscape of molecular biology. We also explore the complicated world of structural analysis and design strategies, stressing the importance of molecular insights for making the fusion protein approach work better. These insights broaden understanding of the underlying principles and illuminate the path toward unlocking untapped potential. The review also introduces cutting-edge techniques for constructing fusion protein libraries, such as DNA shuffling and phage display. These new methods allow scientists to build a molecular orchestra with an unprecedented level of accuracy, and thus use fusion proteins to their full potential in various situations. In conclusion, we provide a glimpse into the current challenges and prospects in fusion protein research, shedding light on recent advancements that promise to reshape the future of biotechnology. As we make this interesting journey through the field of enzymatic protein combination, it becomes clear that the fusion paradigm is about to start a new era of innovation that will push the limits of what is possible in biology and molecular engineering.

Keywords:  Biocatalysis; Biological activities; Enzymatic modification; Enzymatic protein; Fusion protein; Protein engineering; Protein enhancement

DOI:  https://doi.org/10.1016/j.cis.2025.103473
Nature. 2025 Mar 12.

Move over graphene! Scientists forge bismuthene and host of atoms-thick metals.

Katherine Bourzac.



Keywords:  Chemistry; Materials science

DOI:  https://doi.org/10.1038/d41586-025-00763-3
Biomed Mater. 2025 Mar 14.

Enhancing visible light-induced 3D bioprinting: alternating extruded support materials for bioink gelation.

Takashi Kotani, Takehito Hananouchi, Shinji Sakai.

  In 3D bioprinting, two promising approaches have gained significant attention: the use of support materials during printing and the utilization of bioinks gelled through ruthenium(II) tris-bipyridyl dication ([Ru(bpy)3]2+)-catalyzed photocrosslinking consuming sodium persulfate (SPS). Integrating these approaches while ensuring simplicity and printability remains a challenge. To address this challenge, we propose a technique in which the support material containing SPS is alternately extruded with the bioink containing polymer having phenolic hydroxyl moieties (polymer-Ph) and [Ru(bpy)3]2+under visible light irradiation. This method eliminates the problems of light shading and deformation caused by the support material, as the contact between the alternately extruded ink and the support material initiates the gelation of the ink via photocrosslinking. Using an ink containing 0.5 w/v% hyaluronic acid with phenolic hydroxyl moieties (HA-Ph) and 2.0 mM [Ru(bpy)3]2+alongside a support material containing 10 mM SPS, various constructs were successfully printed under 450 nm visible light. The human hepatoblastoma cells embedded in the printed construct showed approximately 95% viability after printing and proliferation over 14 days of culture. These results highlight the potential of this method to advance 3D bioprinting for tissue engineering applications.

Keywords:  hyaluronic acid; hydrogel; phenolic hydroxyl moiety; photocrosslinking; ruthenium; support material

DOI:  https://doi.org/10.1088/1748-605X/adc0d6
ACS Appl Mater Interfaces. 2025 Mar 09.

Database of Nonaqueous Proton-Conducting Materials.

Harrison J Cassady, Emeline Martin, Yifan Liu, Debjyoti Bhattacharya, Maria F Rochow, Brock A Dyer, Wesley F Reinhart, Valentino R Cooper, Michael A Hickner.

  This work presents the assembly of 48 papers, representing 74 different compounds and blends, into a machine-readable database of nonaqueous proton-conducting materials. SMILES was used to encode the chemical structures of the molecules, and we tabulated the reported proton conductivity, proton diffusion coefficient, and material composition for a total of 3152 data points. The data spans a broad range of temperatures ranging from -70 to 260 °C. To explore this landscape of nonaqueous proton conductors, DFT was used to calculate the proton affinity of 18 unique proton carriers. The results were then compared to the activation energy derived from fitting experimental data to the Arrhenius equation. It was found that while the widely recognized positive correlation between the activation energy and proton affinity may hold among closely related molecules, this correlation does not necessarily apply across a broader range of molecules. This work serves as an example of the potential analyses that can be conducted using literature data combined with emerging research tools in computation and data science to address specific materials design problems.

Keywords:  Python; acid-doped; database; imidazole; nonaqueous molecules; proton conductivity; proton exchange membrane; small molecules

DOI:  https://doi.org/10.1021/acsami.4c22618
STAR Protoc. 2025 Mar 13. pii: S2666-1667(25)00101-7. [Epub ahead of print]6(1): 103695

Protocol for chromatin immunoprecipitation of chromatin-binding proteins in Schizosaccharomyces pombe using a dual-crosslinking approach.

Jasbeer S Khanduja, Mo Motamedi.

  Single-crosslink chromatin immunoprecipitation (ChIP) is often ineffective at mapping the binding sites of chromatin-binding proteins that indirectly interact with DNA. Here, we present a protocol to map the genomic occupancy of different chromatin regulators and an RNA exosome adapter subunit in Schizosaccharomyces pombe using dual-crosslinking ChIP. We describe steps for cell growth, dual-crosslinking, cell lysis, sonification, and immunoprecipitation. We then detail procedures for washing, crosslink reversal, and DNA purification for downstream analysis using ChIP-qPCR and ChIP sequencing. For complete details on the use and execution of this protocol, please refer to Khanduja et al.1.

Keywords:  ChIP; ChIP-seq; Chromatin immunoprecipitation; Molecular Biology

DOI:  https://doi.org/10.1016/j.xpro.2025.103695
Biophys Rep. 2025 Feb 28. 11(1): 1-11

Single-molecule tracking in living microbial cells.

Xiaomin Chen, Qianhong Guo, Jiexin Guan, Lu Zhang, Ting Jiang, Liping Xie, Jun Fan.

  Some microbes are referred to as model organisms because they are easy to study in the laboratory and hold the ability to retain their characteristics during DNA replication, DNA transcription, and other fundamental processes. Studying these microbes in living cells via single-molecule imaging allows us to better understand these processes at highly improved spatiotemporal resolution. Single particle tracking photoactivated localization microscopy (sptPALM) is a robust tool for detecting the positions and motions of individual molecules with tens of nanometers of spatial and millisecond temporal resolution in vivo, providing insights into intricate intracellular environments that traditional ensemble methods cannot. With this approach, the fluorophores are photoactivated stochastically, a series of images are recorded, and the positions of fluorophores are identified in these images, and ultimately the locations are linked together to yield trajectories of individual molecules. Quantitative kinetic and spatial information, such as reaction rates, diffusion coefficients, and localization maps, can be obtained by further analysis. Here, we present a single-molecule tracking protocol that includes sample preparation, data acquisition and brief data processing. This protocol will enable researchers to directly unveil molecular and cellular mechanisms underlying the essential biological processes.

Keywords:  Diffusion coefficients; Living microbial cells; PALM; Single-molecule tracking; Trajectory

DOI:  https://doi.org/10.52601/bpr.2024.240028
bioRxiv. 2025 Feb 27. pii: 2025.02.23.639383. [Epub ahead of print]

Linker histone H1.0 loads onto nucleosomes through multiple pathways that are facilitated by histone chaperones.

Ehsan Akbari, Nathaniel L Burge, Michael G Poirier.

Linker histone H1 is an essential chromatin architectural protein that compacts chromatin into transcriptionally silent regions by interacting with nucleosomal and linker DNA, while rapidly exchanging in vivo . How H1 targets nucleosomes while being dynamic remains unanswered. Using a single-molecule strategy, we investigated human H1.0 interactions with DNA and nucleosomes. H1.0 directly binds nucleosomes and naked DNA with a preference toward nucleosomes. DNA-bound H1.0 exhibited a range of bound lifetimes with both mobile and immobile states, where the mobile H1.0 did not load onto nucleosomes. The histone chaperone Nap1 facilitated H1.0-nucleosome loading by enabling H1.0 loading through DNA sliding, reducing DNA resident times without impacting nucleosome resident times, increasing mobility along DNA, and targeting H1.0 loading onto the nucleosome dyad. These findings reveal linker histones load onto nucleosomes through multiple distinct mechanisms that are facilitated by chaperones to regulate chromatin accessibility.

DOI: https://doi.org/10.1101/2025.02.23.639383
bioRxiv. 2025 Feb 28. pii: 2025.02.25.640220. [Epub ahead of print]

Class I histone deacetylases catalyze lysine lactylation.

Takeshi Tsusaka, Mohd Altaf Najar, Isha Sharma, Mariola M Marcinkiewicz, Claudia Veronica Da Silva Crispim, Nathaniel W Snyder, George M Burslem, Emily L Goldberg.

Metabolism and post-translational modifications (PTMs) are intrinsically linked and the number of identified metabolites that can covalently modify proteins continues to increase. This metabolism/PTM crosstalk is especially true for lactate, the product of anaerobic metabolism following glycolysis. Lactate forms an amide bond with the ε-amino group of lysine, a modification known as lysine lactylation, or Kla. Multiple independent mechanisms have been proposed in the formation of Kla, including p300/CBP-dependent transfer from lactyl-CoA, via a high-energy intermediate lactoylglutathione species that non-enzymatically lactylates proteins, and several enzymes are reported to have lactyl transferase capability. We recently discovered that class I histone deacetylases (HDACs) 1, 2, and 3 can all reverse their canonical chemical reaction to catalyze lysine β-hydroxybutyrylation. Here we tested the hypothesis that HDACs can also catalyze Kla formation. Using biochemical, pharmacological, and genetic approaches, we found that HDAC-catalyzed lysine lactylation accounts for the majority of Kla formation in cells. Dialysis experiments confirm this is a reversible reaction that depends on lactate concentration. We also directly quantified intracellular lactyl-CoA and found that Kla abundance can be uncoupled from lactyl-CoA levels. Therefore, we propose a model in which the majority of Kla is formed through enzymatic addition of lactate by HDACs 1, 2, and 3.

DOI: https://doi.org/10.1101/2025.02.25.640220
J Biosci Bioeng. 2025 Mar 09. pii: S1389-1723(25)00047-7. [Epub ahead of print]

Development of an enzymatic cascade for semi de novo ATP production using thermophilic enzymes.

Takuma Suzuki, Suryatin Alim Gladwin, Kentaro Miyazaki, Hiroya Tomita, Kohsuke Honda.

  Industrial production of ATP has mostly relied on extraction from living cells. Although microbial and enzymatic ATP production have also been developed, the former suffers from complexity in product separation, while the latter requires expensive substrates, making their practical use difficult. To tackle these problems, we newly developed an enzymatic cascade for ATP production, which does not use expensive substrates, by assembling 16 thermophilic enzymes prepared through a heat-purification from the crude extract of recombinant Escherichia coli. This cascade consists of two modules: an ATP regeneration module based on a non-oxidative glycolysis and an ADP supply module. The ATP regeneration module can provide the energy required for phosphorylation of AMP and ADP to ATP while simultaneously supplying ribose-5-phosphate, a building block of adenosine phosphates, from inexpensive starch and inorganic phosphate. Ribose-5-phosphate is then adenylated with exogenously supplied adenine in the ADP supply module and further phosphorylated to ATP. This ATP production cascade is not accompanied by CO2 emission and is expected to be a novel ATP manufacturing platform with less environmental impact. In the present study, ATP production with 100 % molar conversion yield was achieved from 1 mM adenine. However, increasing the initial adenine concentration resulted in lower yields. Enzyme characterization and docking simulations revealed that this decline was due to non-competitive inhibition of certain enzymes by ATP, which could potentially be mitigated through protein engineering.

Keywords:  ATP; Docking simulation; Enzyme cascade; Non-oxidative glycolysis; Thermophilic enzymes

DOI:  https://doi.org/10.1016/j.jbiosc.2025.02.005
Nat Commun. 2025 Mar 07. 16(1): 2300

POSA for fast, amplified and multiplexed protein imaging.

Wenkang Zhang, Hengfeng Jiang, Liang Han, Jie Liu, Jie Wang, Feng He, Leilei Tian.

Fluorescent π-conjugated polymers (FCPs) are known for their superior brightness but are still unavailable for highly multiplexed molecular imaging in single cells as they are hydrophobic and lack targeting capability toward biomolecules. Herein, we develop a π-conjugated polymer-based amplification (POSA) method to achieve highly multiplexed signal amplification. Optical amplification by virtue of the high brightness of FCPs makes POSA a simple and quick signal amplification technique that can spatially resolve the distribution of multiplexed proteins in single cells, with a 28- to 126-fold signal amplification effect. By this POSA method, we demonstrate that the high brightness of FCPs can be used to strengthen the images of subcellular biomolecules and showcase the phenomenon of optical amplification of FCPs at the cellular level. Additionally, with its sensitivity, ease of use, and quick imaging features, the POSA technique proves to be a valuable tool for advanced biological research.

DOI: https://doi.org/10.1038/s41467-025-57589-w
mBio. 2025 Mar 12. e0406724

Myxosortase: an intramembrane protease that sorts MYXO-CTERM proteins to the cell surface.

Tingting Guo, Daniel H Haft, Daniel Wall.

  Cell surface proteins determine how cells interact with their biotic and abiotic environments. In social myxobacteria, a C-terminal protein sorting tag called MYXO-CTERM is universally found within the Myxococcota phylum, where their genomes typically contain dozens of proteins with this motif. MYXO-CTERM harbors a tripartite architecture: a short signature motif containing an invariant cysteine, followed by a transmembrane helix and a short arginine-rich C-terminal region localized in the cytoplasm. In Myxococcus xanthus, MYXO-CTERM is predicted to be posttranslationally lipidated and cleaved for subsequent cell surface localization by the type II secretion system. Here, following our bioinformatic discovery, we experimentally show that myxosortase (MrtX, MXAN_2755) is responsible for the C-terminal cleavage and cell surface anchoring of TraA, a prototypic cell surface receptor. The cleavage by MrtX depends on conserved cysteines within the MYXO-CTERM motif of TraA. M. xanthus mutants lacking myxosortase are defective in TraA-mediated outer membrane exchange and exhibit cell envelope defects. In a heterologous Escherichia coli expression system, the MYXO-CTERM motif is cleaved when MrtX is co-expressed. Therefore, MrtX represents a new family of sorting enzyme that enables cell surface localization of MYXO-CTERM proteins.IMPORTANCEThe CPBP (CaaX protease and bacteriocin processing) protease family is widespread across the three domains of life. Despite considerable research on eukaryotic homologs, prokaryotic CPBP family members remain largely unexplored. In this study, we experimentally reveal the function of a novel CPBP protease called myxosortase. Our findings show that myxosortase is responsible for the C-terminal cleavage and cell surface anchoring of substrate proteins containing MYXO-CTERM motifs in Myxococcus xanthus. MYXO-CTERM cleavage also occurred in a heterologous Escherichia coli host when myxosortase is co-expressed. This is the first report that a CPBP protease is involved in protein sorting in prokaryotes. This work provides important insights into the biogenesis and anchoring of cell surface proteins in gram-negative bacteria.

Keywords:  Myxococcus xanthus; cell surface protein; myxosortase; outer membrane exchange; protein sorting; sortase

DOI:  https://doi.org/10.1128/mbio.04067-24
bioRxiv. 2025 Feb 28. pii: 2025.02.24.639402. [Epub ahead of print]

Massively parallel assessment of designed protein solution properties using mass spectrometry and peptide barcoding.

David Feldman, Jeremiah N Sims, Xinting Li, Richard Johnson, Stacey Gerben, David E Kim, Christian Richardson, Brian Koepnick, Helen Eisenach, Derrick R Hicks, Erin C Yang, Basile I M Wicky, Lukas F Milles, Asim K Bera, Alex Kang, Evans Brackenbrough, Emily Joyce, Banumathi Sankaran, Joshua M Lubner, Inna Goreshnik, Dionne Vafeados, Aza Allen, Lance Stewart, Michael J MacCoss, David Baker.

Library screening and selection methods can determine the binding activities of individual members of large protein libraries given a physical link between protein and nucleotide sequence, which enables identification of functional molecules by DNA sequencing. However, the solution properties of individual protein molecules cannot be probed using such approaches because they are completely altered by DNA attachment. Mass spectrometry enables parallel evaluation of protein properties amenable to physical fractionation such as solubility and oligomeric state, but current approaches are limited to libraries of 1,000 or fewer proteins. Here, we improved mass spectrometry barcoding by co-synthesizing proteins with barcodes optimized to be highly multiplexable and minimally perturbative, scaling to libraries of >5,000 proteins. We use these barcodes together with mass spectrometry to assay the solution behavior of libraries of de novo -designed monomeric scaffolds, oligomers, binding proteins and nanocages, rapidly identifying design failure modes and successes.

DOI: https://doi.org/10.1101/2025.02.24.639402
Nat Mater. 2025 Mar 07.

Stiff and self-healing hydrogels by polymer entanglements in co-planar nanoconfinement.

Chen Liang, Volodymyr Dudko, Olena Khoruzhenko, Xiaodan Hong, Zhong-Peng Lv, Isabell Tunn, Muhammad Umer, Jaakko V I Timonen, Markus B Linder, Josef Breu, Olli Ikkala, Hang Zhang.

Many biological tissues are mechanically strong and stiff but can still heal from damage. By contrast, synthetic hydrogels have not shown comparable combinations of properties, as current stiffening approaches inevitably suppress the required chain/bond dynamics for self-healing. Here we show a stiff and self-healing hydrogel with a modulus of 50 MPa and tensile strength up to 4.2 MPa by polymer entanglements in co-planar nanoconfinement. This is realized by polymerizing a highly concentrated monomer solution within a scaffold of fully delaminated synthetic hectorite nanosheets, shear oriented into a macroscopic monodomain. The resultant physical gels show self-healing efficiency up to 100% despite the high modulus, and high adhesion shear strength on a broad range of substrates. This nanoconfinement approach allows the incorporation of novel functionalities by embedding colloidal materials such as MXenes and can be generalized to other polymers and solvents to fabricate stiff and self-healing gels for soft robotics, additive manufacturing and biomedical applications.

DOI: https://doi.org/10.1038/s41563-025-02146-5