Photosynthetic living fibers fabrication from algal-bacterial consortia with controlled spatial distribution

Living materials that combine active cells and synthetic matrix materials have become a promising research field in recent years. While multicellular systems present exclusive benefits in developing living materials over single-cell systems, creating artificial multicellular systems can be challenging due to the difficulty in controlling the multicellular assemblies and the complexity of cell-to-cell interactions. Here, we propose a co-culture platform capable of isolating and controlling the spatial distribution of algal-bacterial consortia, which can be used to construct photosynthetic living fibers. Through coaxial extrusion-based 3D printing, hydrogel fibers containing bacteria or algae can be deposited into designated structures and further processed into materials with precise geometries. In addition, the photosynthetic living fibers demonstrate a significant synergistic catalytic effect resulting from the immobilization of both bacteria and algae, which effectively optimize sewage treatment for bioremediation purposes. The integration of microbial consortia and 3D printing gives functional living materials that have promising applications in biocatalysis, biosensing, and biomedicine. Our approach provides an optimized solution for constructing efficient multicellular systems and opens a new avenue for the development of advanced materials.

[1]  M. Narita,et al.  Bioprinting microporous functional living materials from protein-based core-shell microgels , 2022, bioRxiv.

[2]  Hongwu Zhang,et al.  3D-printed high-density polyethylene scaffolds with bioactive and antibacterial layer-by-layer modification for auricle reconstruction , 2022, Materials today. Bio.

[3]  Wei Cheng,et al.  Biocatalytic Living Materials Built by Compartmentalized Microorganisms in Annealable Granular Hydrogels , 2022, SSRN Electronic Journal.

[4]  Shi Wenxin,et al.  Enhanced wastewater treatment performance by understanding the interaction between algae and bacteria based on quorum sensing. , 2022, Bioresource technology.

[5]  T. Lu,et al.  Engineered Living Hydrogels , 2022, Advanced materials.

[6]  M. Jiang,et al.  3D Printed Biocatalytic Living Materials with Dual-Network Reinforced Bioinks. , 2021, Small.

[7]  M. Salmerón-Sánchez,et al.  Engineered living biomaterials , 2021, Nature Reviews Materials.

[8]  Anders B. Dohlman,et al.  Living fabrication of functional semi-interpenetrating polymeric materials , 2021, Nature Communications.

[9]  S. Vaidyanathan,et al.  Co-culturing microbial consortia: approaches for applications in biomanufacturing and bioprocessing , 2021, Critical reviews in biotechnology.

[10]  Eric A. Appel,et al.  Translational Applications of Hydrogels , 2021, Chemical reviews.

[11]  A. Meyer,et al.  Bioprinting of Regenerative Photosynthetic Living Materials , 2021, Advanced Functional Materials.

[12]  F. Azam,et al.  Synthetic algal-bacteria consortia for space-efficient microalgal growth in a simple hydrogel system , 2021, Journal of Applied Phycology.

[13]  V. Krishnaswamy,et al.  Combined treatment of synthetic textile effluent using mixed azo dye by phyto and phycoremediation , 2021, International journal of phytoremediation.

[14]  James M. Wagner,et al.  Compartmentalized microbes and co-cultures in hydrogels for on-demand bioproduction and preservation , 2020, Nature Communications.

[15]  J. Tay,et al.  Microalgal-bacterial consortia: From interspecies interactions to biotechnological applications , 2020 .

[16]  A. T. Paulino,et al.  Pinus residue/pectin-based composite hydrogels for the immobilization of β-D-galactosidase. , 2020, International journal of biological macromolecules.

[17]  Yuanjin Zhao,et al.  Bioinspired structural color patch with anisotropic surface adhesion , 2020, Science Advances.

[18]  Haifeng Ye,et al.  Patterned Amyloid Materials Integrating Robustness and Genetically Programmable Functionality. , 2019, Nano letters.

[19]  Qing-tao Xu,et al.  Enhanced decolorization of methyl orange by Bacillus sp. strain with magnetic humic acid nanoparticles under high salt conditions. , 2019, Bioresource technology.

[20]  Xinyu Wang,et al.  Immobilization of functional nano-objects in living engineered bacterial biofilms for catalytic applications , 2019, National science review.

[21]  Xiaokeng Li,et al.  3D Printing of Multifunctional Hydrogels , 2019, Advanced Functional Materials.

[22]  Patrick K. H. Lee,et al.  Modular Metabolic Engineering for Biobased Chemical Production. , 2019, Trends in biotechnology.

[23]  T. Monisha,et al.  Enhanced decolorization of sulfonated azo dye methyl orange by single and mixed bacterial strains AK1, AK2 and VKY1 , 2018, Bioremediation Journal.

[24]  J Andrew Jones,et al.  Use of bacterial co-cultures for the efficient production of chemicals. , 2018, Current opinion in biotechnology.

[25]  Angelo S. Mao,et al.  Microfluidic Templated Multicompartment Microgels for 3D Encapsulation and Pairing of Single Cells. , 2018, Small.

[26]  O. Diegel,et al.  Cell immobilization on 3D-printed matrices: A model study on propionic acid fermentation. , 2018, Bioresource technology.

[27]  Xuyao Jiang,et al.  The interactions of algae-bacteria symbiotic system and its effects on nutrients removal from synthetic wastewater. , 2018, Bioresource technology.

[28]  Alshakim Nelson,et al.  Catalytically Initiated Gel-in-Gel Printing of Composite Hydrogels. , 2017, ACS applied materials & interfaces.

[29]  J. Frommer,et al.  Three-Dimensional Nanoprinting via Scanning Probe Lithography-Delivered Layer-by-Layer Deposition. , 2016, ACS nano.

[30]  H. Oh,et al.  Algae-bacteria interactions: Evolution, ecology and emerging applications. , 2016, Biotechnology advances.

[31]  Liang Ma,et al.  Coaxial nozzle-assisted 3D bioprinting with built-in microchannels for nutrients delivery. , 2015, Biomaterials.

[32]  Weichuan Qiao,et al.  Decolorization characteristics of a newly isolated salt-tolerant Bacillus sp. strain and its application for azo dye-containing wastewater in immobilized form , 2015, Applied Microbiology and Biotechnology.

[33]  Weichuan Qiao,et al.  Decolorization characteristics of a newly isolated salt-tolerant Bacillus sp. strain and its application for azo dye-containing wastewater in immobilized form , 2015, Applied Microbiology and Biotechnology.

[34]  G. Stephanopoulos,et al.  Engineering Escherichia coli coculture systems for the production of biochemical products , 2015, Proceedings of the National Academy of Sciences.

[35]  Samir M. Iqbal,et al.  A microfluidic device approach to generate hollow alginate microfibers with controlled wall thickness and inner diameter , 2015 .

[36]  Timothy K. Lu,et al.  Engineering Living Functional Materials , 2015, ACS synthetic biology.

[37]  G. Stephanopoulos,et al.  Distributing a metabolic pathway among a microbial consortium enhances production of natural products , 2015, Nature Biotechnology.

[38]  Matthew A. A. Grant,et al.  Direct exchange of vitamin B12 is demonstrated by modelling the growth dynamics of algal–bacterial cocultures , 2014, The ISME Journal.

[39]  Satoshi Ishii,et al.  Seasonal stability of Cladophora-associated Salmonella in Lake Michigan watersheds. , 2009, Water research.

[40]  Ji-ti Zhou,et al.  Biocalalyst effects of immobilized anthraquinone on the anaerobic reduction of azo dyes by the salt-tolerant bacteria. , 2007, Water research.

[41]  C. Yatome,et al.  Degradation of Crystal violet by Nocardia corallina , 2004, Applied Microbiology and Biotechnology.