Mitigation of microbial biocontamination in cyanobacterial ethanol synthesis via alginate encapsulation

Xiangxiao Liu , Xiang Liu , Yanfei Pan , Huili Sun , Bo Liang , Jiahui Sun , Tianzhong Liu , Guodong Luan , Xuefeng Lu

Bioresources and Bioprocessing ›› 2026, Vol. 13 ›› Issue (1) : 77

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Bioresources and Bioprocessing ›› 2026, Vol. 13 ›› Issue (1) :77 DOI: 10.1186/s40643-026-01076-7
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Mitigation of microbial biocontamination in cyanobacterial ethanol synthesis via alginate encapsulation
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Abstract

Background

Sustainable biofuels have spurred interest in cyanobacterial ethanol production, yet large-scale application is severely hindered by microbial contamination—a devastating challenge that lacks universally effective, biocompatible mitigation strategies. Traditional methods such as pH manipulation or antibiotic application are often physiologically incompatible, environmentally unsustainable, or ineffective against diverse contaminant consortia.

Results

Here, we propose and validate alginate encapsulation as a physical barrier strategy to address this challenge. Alginate, a biodegradable polysaccharide derived from brown algae, forms a porous hydrogel matrix that encapsulates cyanobacterial cells. This matrix blocks direct contact, uptake or ingestion by microbial contaminants while allowing the efficient diffusion of gases (CO2, O2), light, and nutrients to maintain photosynthetic and metabolic functions. Using our previously engineered, high-performance ethanol-producing strain (EP), we find that unprotected cultures rapidly collapse and cease ethanol production upon inoculation with a contaminant consortium, with cumulative ethanol yield falling to undetectable levels, whereas encapsulated cells sustain normal growth and photosynthetic activity under identical contamination pressure. After rinsing and re-cultivation, the encapsulated biomass partially restored ethanol productivity, achieving a cumulative titer of 320 mg/L over 4 days post-recovery. This suggests that the protective strategy is non-invasive and enables functional recovery of the production system following contamination exposure.

Conclusions

This study demonstrates that alginate encapsulation represents a promising strategy to mitigate microbial contamination, with the potential to enhance the technical resilience and operational stability of cyanobacterial biofuel production.

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Keywords

Cyanobacteria / Ethanol / Biocontamination / Alginate encapsulation / Microbial contaminants

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Xiangxiao Liu, Xiang Liu, Yanfei Pan, Huili Sun, Bo Liang, Jiahui Sun, Tianzhong Liu, Guodong Luan, Xuefeng Lu. Mitigation of microbial biocontamination in cyanobacterial ethanol synthesis via alginate encapsulation. Bioresources and Bioprocessing, 2026, 13 (1) : 77 DOI:10.1186/s40643-026-01076-7

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Abbasi P, Alemzadeh I, Vossoughi M. Characterizing an injectable alginate hydrogel as a co-encapsulating system for beta cells and curcumin in type 1 diabetes therapy. Canadian J Chem Eng, 2024, 102(10): 3358-3371.

[2]

Andrews F, et al.. Combinatorial use of environmental stresses and genetic engineering to increase ethanol titres in cyanobacteria. Biotechnol Biofuels, 2021, 14(1): 240.

[3]

Bustamante M, et al.. Viability of microencapsulated probiotics in cross-linked alginate matrices and chia seed or flaxseed mucilage during spray-drying and storage. Microorganisms, 2025.

[4]

Bustos-Terrones YA. A review of the strategic use of sodium alginate polymer in the immobilization of microorganisms for water recycling. Polymers (Basel), 2024.

[5]

Chen, Y., M. Meenu, and X. Baojun, A Narrative Review on Microencapsulation of Obligate Anaerobe Probiotics Bifidobacterium, Akkermansia muciniphila, and Faecalibacterium prausnitzii. Food Reviews International, 2021: p. 1–30.
[6]

Cherenkov IA, et al.. Numerical simulation of the diffusion of an electroactive molecule in biosimilar hydrogel media. Biophysics, 2024, 69(5): 811-819.

[7]

Covarrubias SA, et al.. Alginate beads provide a beneficial physical barrier against native microorganisms in wastewater treated with immobilized bacteria and microalgae. Appl Microbiol Biotechnol, 2012, 93(6): 2669-2680.

[8]

Day JG, Gong Y, Hu Q. Microzooplanktonic grazers – a potentially devastating threat to the commercial success of microalgal mass culture. Algal Res, 2017, 27: 356-365.

[9]

Dexter J, Fu P. Metabolic engineering of cyanobacteria for ethanol production. Energy Environ Sci, 2009, 2(8): 857-864.

[10]

Dexter J, et al.. The state of autotrophic ethanol production in cyanobacteria. J Appl Microbiol, 2015, 119(1): 11-24.

[11]

El-Araby R. Biofuel production: exploring renewable energy solutions for a greener future. Biotechnol Biofuels Bioprod, 2024, 17(1): 129.

[12]

Ernst A, et al.. Nitrate and phosphate affect cultivability of cyanobacteria from environments with low nutrient levels. Appl Environ Microbiol, 2005, 71(6): 3379-3383.

[13]

Gao Z, et al.. Photosynthetic production of ethanol from carbon dioxide in genetically engineered cyanobacteria. Energy Environ Sci, 2012, 5(12): 9857-9865.

[14]

Jíménez-Arias D, et al.. Encapsulation with natural polymers to improve the properties of biostimulants in agriculture. Plants (Basel), 2022.

[15]

John RP, et al.. Bio-encapsulation of microbial cells for targeted agricultural delivery. Crit Rev Biotechnol, 2011, 31(3): 211-226.

[16]

Karuppasamy S, et al.. Integrated grazer management mediated by chemicals for sustainable cultivation of algae in open ponds. Algal Res, 2018, 35: 439-448.

[17]

Kong HJ, Smith MK, Mooney DJ. Designing alginate hydrogels to maintain viability of immobilized cells. Biomaterials, 2003, 24(22): 4023-4029.

[18]

Kosourov SN, Seibert M. Hydrogen photoproduction by nutrient-deprived Chlamydomonas reinhardtii cells immobilized within thin alginate films under aerobic and anaerobic conditions. Biotechnol Bioeng, 2009, 102(1): 50-58.

[19]

Leino H, et al.. Extended H2 photoproduction by N2-fixing cyanobacteria immobilized in thin alginate films. Int J Hydrogen Energy, 2012, 37(1): 151-161.

[20]

Li JJ, et al.. Antibiotic pollution promotes dominance by harmful cyanobacteria: a case study examining norfloxacin exposure in competition experiments. J Phycol, 2021, 57(2): 677-688.

[21]

Li J, et al.. The released polysaccharide inhibits cell aggregation and biofilm formation in the cyanobacterium Synechocystis sp. PCC 6803. Eur J Phycol, 2021, 56(2): 119-128.

[22]

Liu M, et al.. Cultivation strategy optimization and pilot-scale production of Spirulina subsalsa grown in seawater and monosodium glutamate wastewater. Bioresources Bioprocess, 2025, 12(1): 83.

[23]

Mahmood T, et al.. Sustainable production of biofuels from the algae-derived biomass. Bioprocess Biosyst Eng, 2023, 46(8): 1077-1097.

[24]

McBride RC, et al.. Contamination management in low cost open algae ponds for biofuels production. Ind Biotechnol, 2014, 10(3): 221-227.

[25]

Méléder V, et al.. In vivo estimation of pigment composition and optical absorption cross-section by spectroradiometry in four aquatic photosynthetic micro-organisms. J Photochem Photobiol B Biol, 2013, 129: 115-124.

[26]

Molina-Grima E, et al.. Pathogens and predators impacting commercial production of microalgae and cyanobacteria. Biotechnol Adv, 2022, 55. ArticleID: 107884
[27]

Nalzaro PJ, Tumolva T. Kinetics modeling of water sorption and nutrient release of hydroxypropyl cellulose/carboxymethyl cellulose/sodium alginate hydrogel blends for agricultural applications. Ecol Eng Environ Technol, 2025, 26(5): 201-216.

[28]

Nguyen DD, et al.. Grazer-induced changes in molecular signatures of cyanobacteria. Algal Res, 2022, 61. ArticleID: 102575
[29]

Novoveská L, et al.. Overview and challenges of large-scale cultivation of photosynthetic microalgae and cyanobacteria. Mar Drugs, 2023.

[30]

Rakhimberdieva MG, et al.. Carotenoid‐induced quenching of the phycobilisome fluorescence in photosystem II‐deficient mutant of Synechocystis sp. FEBS Lett, 2004, 574(1-3): 85-88.

[31]

Sabat S, et al.. Phycochemistry and pharmacological significance of filamentous cyanobacterium Spirulina sp.. Bioresources Bioprocess, 2025, 12(1): 1-37
[32]

Selão TT, et al.. Growth and selection of the cyanobacterium Synechococcus sp. PCC 7002 using alternative nitrogen and phosphorus sources. Metab Eng, 2019, 54: 255-263.

[33]

Shi Y, et al.. The Ecology and Evolution of Amoeba-Bacterium Interactions. Appl Environ Microbiol, 2021, 87(2): e01866-e1920.

[34]

Shi Y, et al.. Soil amoebae are unexpected hotspots of environmental antibiotics and antibiotic resistance genes. Environ Sci Technol, 2024, 58(49): 21475-21488.

[35]

Simkovsky R, et al.. Impairment of O-antigen production confers resistance to grazing in a model amoeba–cyanobacterium predator–prey system. Proc Natl Acad Sci U S A, 2012, 109(41): 16678-16683.

[36]

Singh AK, Ducat DC. Generation of stable, light-driven co-cultures of cyanobacteria with heterotrophic microbes. Methods Mol Biol, 2022, 2379: 277-291.

[37]

Singh R, et al.. A review of biofuels and bioenergy production as a sustainable alternative: opportunities, challenges and future perspectives. J Environ Health Sci Eng, 2025, 23(2): 23.

[38]

Sun H, et al.. Engineered hypermutation adapts cyanobacterial photosynthesis to combined high light and high temperature stress. Nat Commun, 2023, 14(1): 1238.

[39]

Toda N, et al.. Phosphite reduces the predation impact of Poterioochromonasmalhamensis on cyanobacterial culture. Plants (Basel), 2021.

[40]

Toda N, et al.. Cell morphology engineering enhances grazing resistance of Synechococcus elongatus PCC 7942 for non-sterile large-scale cultivation. J Biosci Bioeng, 2024, 137(4): 245-253.

[41]

Touloupakis E, et al.. Effect of high pH on growth of Synechocystis sp. PCC 6803 cultures and their contamination by golden algae (Poterioochromonas sp.). Appl Microbiol Biotechnol, 2016, 100(3): 1333-1341.

[42]

Wang M, Luan G, Lu X. Engineering ethanol production in a marine cyanobacterium Synechococcus sp. PCC7002 through simultaneously removing glycogen synthesis genes and introducing ethanolgenic cassettes. J Biotechnol, 2020, 317: 1-4.

[43]

Wawszczak A, Kocki J, Kołodyńska D. Alginate as a sustainable and biodegradable material for medical and environmental applications-the case studies. J Biomed Mater Res B Appl Biomater, 2024, 112(9): 1-23.

[44]

Weger HG, et al.. Grazing preferences of three species of amoebae on cyanobacteria and green algae. J Eukaryot Microbiol, 2024, 71(2. ArticleID: e13018
[45]

Xu S, et al.. Antibiotic-accelerated cyanobacterial growth and aquatic community succession towards the formation of cyanobacterial bloom in eutrophic lake water. Environ Pollut, 2021, 290. ArticleID: 118057
[46]

Xu X, et al., (2025) FtsZ overexpression-induced cell miniaturization reshapes photosynthesis and enhances transformation efficiency in Synechococcus elongatus PCC 7942. Algal Research, p. 104473.
[47]

Yadav I, Rautela A, Kumar S. Approaches in the photosynthetic production of sustainable fuels by cyanobacteria using tools of synthetic biology. World J Microbiol Biotechnol, 2021, 37(12): 201.

[48]

Zhang S, et al.. Unlocking the potentials of cyanobacterial photosynthesis for directly converting carbon dioxide into glucose. Nat Commun, 2023, 14(1): 3425.

[49]

Zhu Z, et al.. Rescuing ethanol photosynthetic production of cyanobacteria in non-sterilized outdoor cultivations with a bicarbonate-based pH-rising strategy. Biotechnol Biofuels, 2017, 10: 93.

Funding

National Key Research and Development Program of China(2023YFB4203501)

Shandong Taishan Scholarship

National Natural Science Foundation of China(32400031)

Postdoctoral Fellowship Program of CPSF(GZC20251812)

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