Duckweeds: from fundamental biology to a sustainable plant chassis for biotechnology

Gui-Min Yin; Lin Yang; Sha Li; Yan Zhang

doi:10.1007/s44307-026-00110-1

Advanced Biotechnology ›› 2026, Vol. 4 ›› Issue (2) :16 DOI: 10.1007/s44307-026-00110-1

Review

review-article

Duckweeds: from fundamental biology to a sustainable plant chassis for biotechnology

Author information +

History +

PDF

Abstract

Duckweeds (Lemnaceae), the smallest and fastest-growing flowering plants, have emerged as a transformative platform for sustainable biotechnology. This review synthesizes recent advances that underpin their potential as a next-generation plant chassis. We discuss duckweed's unique biology, characterized by reductive evolution, extreme phenotypic plasticity, and a simplified epigenome that favors transgene expression. The decoding of its minimalist genome, along with the establishment of efficient genetic tools including optimized transformation and CRISPR-Cas9 editing, enables precise genetic and metabolic engineering. While traditional uses in phytoremediation and animal feed validate its utility, duckweed's rapid growth in contained, soil-free culture and its edibility offer distinct advantages for molecular farming over established systems like tobacco. We highlight progress in engineering duckweeds to produce vaccines, therapeutic proteins, and high-value metabolites. To transition from proof-of-concept to an industrial workhorse, future efforts must focus on integrated omics databases, universal genetic toolkits, and scalable cultivation. Converging fundamental insights with synthetic biology principles positions duckweed as a versatile and powerful chassis for the bioeconomy.

Keywords

Duckweed / Plant chassis / Molecular farming / Sustainable biotechnology / Omics

Cite this article

Download citation ▾

Gui-Min Yin, Lin Yang, Sha Li, Yan Zhang. Duckweeds: from fundamental biology to a sustainable plant chassis for biotechnology. Advanced Biotechnology, 2026, 4(2): 16 DOI:10.1007/s44307-026-00110-1

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Abdullah M, Ali Z, Yasin MT, Amanat K, Sarwar F, Khan J, Ahmad K. Advancements in Sustainable Production of Biofuel by Microalgae: Recent Insights and Future Directions. Environ Res, 2024, 262(Pt 2): 119902

[2]	Abramson BW, Novotny M, Hartwick NT, Colt K, Aevermann BD, Scheuermann RH, Michael TP. The genome and preliminary single-nuclei transcriptome of Lemna minuta reveals mechanisms of invasiveness. Plant Physiol, 2022, 188(2): 879-897

[3]	Acosta K, Appenroth KJ, Borisjuk L, Edelman M, Heinig U, Jansen MAK, Oyama T, Pasaribu B, Schubert I, Sorrels S, Sree KS, Xu S, Michael TP, Lam E. Return of the Lemnaceae: duckweed as a model plant system in the genomics and postgenomics era. Plant Cell, 2021, 33(10): 3207-3234

[4]	An D, Zhou Y, Li C, Xiao Q, Wang T, Zhang Y, Wu Y, Li Y, Chao DY, Messing J, Wang W. Plant evolution and environmental adaptation unveiled by long-read whole-genome sequencing of Spirodela. Proc Natl Acad Sci U S A, 2019, 116(38): 18893-18899

[5]	Baek G, Saeed M, Choi HK. Duckweeds: their utilization, metabolites and cultivation. Appl Biol Chem, 2021, 64(1): 73

[6]

Baghban-Kanani P, Oteri M, Hosseintabar-Ghasemabad B, Azimi-Youvalari S, Di Rosa AR, Chiofalo B, Seidavi A, Phillips CJC. The effects of replacing wheat and soyabean meal with duckweed (Lemna minor) and including enzymes in the diet of laying hens on the yield and quality of eggs, biochemical parameters, and their antioxidant status. Anim Sci J, 2023, 94(1): e13888

[7]	Barragán-Borrero V, de Santana Lopes A, Rodrigues Batista ED, Höfer M, Elias R, Chakraborty A, et al. Strain, Procedures, and Tools for Reproducible Genetic Transformation and Genome Editing of the Emerging Plant Model Spirodela Polyrhiza. New Phytol. 2026;250(2):735–56.

[8]	Boehm R, Kruse C, Voeste D, Barth S, Schnabl H. A transient transformation system for duckweed (Wolffia columbiana) using Agrobacterium-mediated gene transfer. J Appl Philos, 2001, 75: 107-111

[9]	Bog M, Braglia L, Morello L, Noboa Melo KI, Schubert I, Shchepin ON, Sree KS, Xu S, Lam E, Appenroth KJ. Strategies for intraspecific genotyping of duckweed: comparison of five orthogonal methods applied to the giant duckweed Spirodela polyrhiza. Plants, 2022,

[10]	Chhabra G, Chaudhary D, Sainger M, Jaiwal PK. Genetic Transformation of Indian Isolate of Lemna Minor Mediated by Agrobacterium Tumefaciens and Recovery of Transgenic Plants. Physiol Mol Biol Plants. 2011;17(2):129–36.

[11]	Coughlan NE, Walsh É, Bolger P, Burnell G, O'Leary N, O'Mahoney M, Paolacci S, Wall D, Jansen MAK. Duckweed bioreactors: challenges and opportunities for large-scale indoor cultivation of Lemnaceae. J Cleaner Prod, 2022,

[12]	Denyer T, Wu PJ, Colt K, Abramson BW, Pang Z, Solansky P, Mamerto A, Nobori T, Ecker JR, Lam E, Michael TP, Timmermans MCP. Streamlined spatial and environmental expression signatures characterize the minimalist duckweed Wolffia australiana. Genome Res, 2024, 34(7): 1106-1120

[13]	Dombey R, Buendia-Avila D, Barragan-Borrero V, Diezma-Navas L, Ponce-Mane A, Vargas-Guerrero JM, Elias R, Mari-Ordonez A. Atypical epigenetic and small RNA control of degenerated transposons and their fragments in clonally reproducing Spirodela polyrhiza. Genome Res, 2025, 35(3): 522-544

[14]

Ernst E, Abramson B, Acosta K, Hoang PTN, Mateo-Elizalde C, Schubert V, Pasaribu B, Albert PS, Hartwick N, Colt K, Aylward A, Ramu U, Birchler JA, Schubert I, Lam E, Michael TP, Martienssen RA. Duckweed genomes and epigenomes underlie triploid hybridization and clonal reproduction. Curr Biol, 2025, 35(8): 1828-1847 e1829

[15]	Fang Y, Tian X, Jin Y, Du A, Ding Y, Liao Z, He K, Zhao Y, Guo L, Xiao Y, Xu Y, Chen S, Che Y, Tan L, Wang S, Li J, Yi Z, Chen L, Zhao L, Zhang F, Li G, Li J, Xiong Q, Zhang Y, Zhang Q, Cao XH, Zhao H. Duckweed evolution: from land back to water. Genomics Proteomics Bioinformatics, 2025,

[16]	Firsov A, Tarasenko I, Mitiouchkina T, Ismailova N, Shaloiko L, Vainstein A, Dolgov S. High-yield expression of M2e peptide of avian influenza virus H5n1 in transgenic duckweed plants. Mol Biotechnol, 2015, 57(7): 653-661

[17]	Fourounjian P, Slovin J, Messing J. Flowering and seed production across the Lemnaceae. Int J Mol Sci, 2021,

[18]	Garcia-Perez E, Vazquez-Vilar M, Orzaez D. Engineering conditional transgene expression in Nicotiana benthamiana. Plant Biotechnol J, 2025,

[19]	Gimpel JA, Specht EA, Georgianna DR, Mayfield SP. Advances in microalgae engineering and synthetic biology applications for biofuel production. Curr Opin Chem Biol, 2013, 17(3): 489-495

[20]	Gong Y, Hu H, Gao Y, Xu X, Gao H. Microalgae as platforms for production of recombinant proteins and valuable compounds: progress and prospects. J Ind Microbiol Biotechnol, 2011, 38(12): 1879-1890

[21]	Goodin MM, Zaitlin D, Naidu RA, Lommel SA. Nicotiana benthamiana: its history and future as a model for plant-pathogen interactions. Mol Plant Microbe Interact, 2008, 21(8): 1015-1026

[22]

Guo L, Fang Y, Wang S, Xiao Y, Ding Y, Jin Y, Tian X, Du A, Liao Z, He K, Chen S, Zhao Y, Tan L, Yi Z, Che Y, Chen L, Li J, Zhao L, Zhang P, Gu Z, Zhang F, Hong Y, Zhang Q, Zhao H. Duckweed: a starch-hyperaccumulating plant under cultivation with a combination of nutrient limitation and elevated Co2. Front Plant Sci, 2025,

[23]

Harkess A, McLoughlin F, Bilkey N, Elliott K, Emenecker R, Mattoon E, Miller K, Czymmek K, Vierstra RD, Meyers BC, Michael TP. Improved Spirodela polyrhiza genome and proteomic analyses reveal a conserved chromosomal structure with high abundance of chloroplastic proteins favoring energy production. J Exp Bot, 2021, 72(7): 2491-2500

[24]	Harkess A, Bewick AJ, Lu Z, Fourounjian P, Michael TP, Schmitz RJ, Meyers BC. The unusual predominance of maintenance DNA methylation in Spirodela polyrhiza. G3 Genes Genomes Genet, 2024,

[25]	Hoang PTN, Fuchs J, Schubert V, Tran TBN, Schubert I. Chromosome numbers and genome sizes of all 36 duckweed species (Lemnaceae). Plants, 2022,

[26]	Hofer M, Schafer M, Wang Y, Wink S, Xu S. Genome-wide association study of metabolic traits in the giant duckweed Spirodelapolyrhiza. Plant Biol (Stuttg), 2025, 27(1): 18-28

[27]	Islam T, Kalkar S, Tinker-Kulberg R, Ignatova T, Josephs EA. The "duckweed dip": aquatic Spirodela polyrhiza plants can efficiently uptake dissolved, DNA-wrapped carbon nanotubes from their environment for transient gene expression. ACS Synth Biol, 2024, 13(2): 687-691

[28]	Islam T, Ligaba-Osena A, Josephs EA. Systematic optimization enables near-perfect in vitro transformation efficiencies for Spirodela polyrhiza (greater duckweed). bioRxiv, 2025,

[29]	Khvatkov P, Chernobrovkina M, Okuneva A, Pushin A, Dolgov S. Transformation of Wolffia arrhiza (L.) Horkel ex Wimm. Plant Cell Tissue Organ Cult, 2015, 123(2): 299-307

[30]	Kim M, Hyeon DY, Kim K, Hwang D, Lee Y. Phytohormonal regulation determines the organization pattern of shoot aerenchyma in greater duckweed (Spirodela polyrhiza). Plant Physiol, 2024, 195(4): 2694-2711

[31]	Kirnev PCS, Carvalho JC, Vandenberghe LPS, Karp SG, Soccol CR. Technological mapping and trends in photobioreactors for the production of microalgae. World J Microbiol Biotechnol, 2020, 36(3): 42

[32]	Ko SM, Sun HJ, Oh MJ, Song IJ, Kim MJ, Sin HS, Goh CH, Kim YW, Lim PO, Lee HY, Kim SW. Expression of the protective antigen for Pedv in transgenic duckweed, Lemna minor. Hortic Environ Biotechnol, 2011, 52(5): 511

[33]	Kusmayadi A, Leong YK, Yen HW, Huang CY, Chang JS. Microalgae as sustainable food and feed sources for animals and humans - biotechnological and environmental aspects. Chemosphere, 2021, 271 129800

[34]

Le Mauff F, Loutelier-Bourhis C, Bardor M, Berard C, Doucet A, D'Aoust MA, Vezina LP, Driouich A, Couture MM, Lerouge P. Cell wall biochemical alterations during Agrobacterium-mediated expression of haemagglutinin-based influenza virus-like vaccine particles in tobacco. Plant Biotechnol J, 2017, 15(3): 285-296

[35]	Lee Y, Braglia L, Stepanenko A, Fuchs J, Schubert V, Gianì S, et al. Hybridity of Mainly Asexually Propagating Duckweeds in Genus Lemna - Dead End or Breakthrough? New Phytol. 2026;250(1):629–47.

[36]	León R, Fernández E. Nuclear transformation of eukaryotic microalgae: historical overview, achievements and problems. Adv Exp Med Biol, 2007, 616: 1-11

[37]	Li F, Yang J-J, Sun Z-Y, Wang L, Qi L-Y, A S, et al. Plant-on-Chip: Core Morphogenesis Processes in the Tiny Plant Wolffia Australiana. PNAS Nexus. 2023; 2(5):pgad141.

[38]	Liu Y, Wang Y, Xu S, Tang X, Zhao J, Yu C, He G, Xu H, Wang S, Tang Y, Fu C, Ma Y, Zhou G. Efficient genetic transformation and Crispr/Cas9-mediated genome editing in Lemna aequinoctialis. Plant Biotechnol J, 2019, 17(11): 2143-2152

[39]	Liu W, Xu J, Li Y, Liu X, Zhou X, Peng Y, Jia Y, Gao J, Jiang Q, He Y. Duckweed (Lemna minor L.) as a natural-based solution completely offsets the increase in ammonia volatilization induced by soil drying and wetting cycles in irrigated paddies. Sci Total Environ, 2024, 957 177789

[40]	Nguyen KD, Kajiura H, Kamiya R, Yoshida T, Misaki R, Fujiyama K. Production and N-glycan engineering of Varlilumab in Nicotiana benthamiana. Front Plant Sci, 2023, 14 1215580

[41]	Nielsen E. The small Gtpase superfamily in plants: a conserved regulatory module with novel functions. Annu Rev Plant Biol, 2020, 71: 247-272

[42]	Norkunas K, Harding R, Dale J, Dugdale B. Improving agroinfiltration-based transient gene expression in Nicotiana benthamiana. Plant Methods, 2018, 14 71

[43]	Park H, Park JH, Lee Y, Woo DU, Jeon HH, Sung YW, Shim S, Kim SH, Lee KO, Kim JY, Kim CK, Bhattacharya D, Yoon HS, Kang YJ. Genome of the world's smallest flowering plant, WolffiaAustraliana, helps explain its specialized physiology and unique morphology. Commun Biol, 2021, 4(1): 900

[44]	Pasaribu B, Acosta K, Aylward A, Liang Y, Abramson BW, Colt K, Hartwick NT, Shanklin J, Michael TP, Lam E. Genomics of turions from the greater duckweed reveal its pathways for dormancy and re‐emergence strategy. New Phytol, 2023, 239(1): 116-131

[45]	Patel AK, Albarico F, Perumal PK, Vadrale AP, Nian CT, Chau HTB, Anwar C, Wani H, Pal A, Saini R, Ha LH, Senthilkumar B, Tsang YS, Chen CW, Dong CD, Singhania RR. Algae as an emerging source of bioactive pigments. Bioresour Technol, 2022, 351 126910

[46]	Peterson A, Kishchenko O, Zhou Y, Vasylenko M, Giritch A, Sun J, Borisjuk N, Kuchuk M. Robust Agrobacterium-mediated transient expression in two duckweed species (Lemnaceae) directed by non-replicating, replicating, and cell-to-cell spreading vectors. Front Bioeng Biotechnol, 2021, 9 5

[47]	Rodolfi L, Chini Zittelli G, Bassi N, Padovani G, Biondi N, Bonini G, Tredici MR. Microalgae for oil: strain selection, induction of lipid synthesis and outdoor mass cultivation in a low-cost photobioreactor. Biotechnol Bioeng, 2009, 102(1): 100-112

[48]	Rolfe SA, Tobin EM. Deletion analysis of a phytochrome-regulated monocot rbcS promoter in a transient assay system. Proc Natl Acad Sci U S A, 1991, 88: 2683-2686

[49]	Sembada AA, Theda Y, Faizal A. Duckweeds as edible vaccines in the animal farming industry. 3 Biotech, 2024, 14(10): 222

[50]	Shen K, Xia L, Gao X, Li C, Sun P, Liu Y, Fan H, Li X, Han L, Lu C, Jiao K, Xia C, Wang Z, Deng B, Pan F, Sun T. Tobacco as bioenergy and medical plant for biofuels and bioproduction. Heliyon, 2024, 10(13): e33920

[51]	Shiu S-H, Fucile G, Di Biase D, Nahal H, La G, Khodabandeh S, Chen Y, Easley K, Christendat D, Kelley L, Provart NJ. Eplant and the 3d data display initiative: integrative systems biology on the world wide web. PLoS ONE, 2011,

[52]	Smith KE, Zhou M, Flis P, Jones DH, Bishopp A, Yant L. The evolution of the duckweed ionome mirrors losses in structural complexity. Ann Bot, 2024, 133(7): 997-1006

[53]	Song SJ, Diao HP, Guo YF, Hwang I. Advances in subcellular accumulation design for recombinant protein production in tobacco. BioDesign Res, 2024, 6 0047

[54]	Sowinski EE, Gilbert S, Lam E, Carpita NC. Linkage structure of cell-wall polysaccharides from three duckweed species. Carbohydr Polym, 2019,

[55]	Stomp AM. The duckweeds: a valuable plant for biomanufacturing. Biotechnol Annu Rev, 2005, 11: 69-99

[56]	Sun Z, Guo W, Yang J, Zhao X, Chen Y, Yao L, Hou H. Enhanced biomass production and pollutant removal by duckweed in mixotrophic conditions. Bioresour Technol, 2020,

[57]	Sun Z, Zhao X, Li G, Yang J, Chen Y, Xia M, Hwang I, Hou H. Metabolic flexibility during a trophic transition reveals the phenotypic plasticity of greater duckweed (Spirodela polyrhiza 7498). New Phytol, 2023, 238(4): 1386-1402

[58]	Tan X, Chen S, Fang Y, Liu P, Hu Z, Jin Y, Yi Z, He K, Li X, Zhao L, Wang H, Zhao H. Rapid and highly efficient genetic transformation and application of interleukin-17b expressed in duckweed as mucosal vaccine adjuvant. Biomolecules, 2022,

[59]	Tan X, Guo L, Chen S, Fang Y, Liu P, Hu Z, Jin Y, Yi Z, He K, Li X, Zhao L, Wang H, Zhao H. Duckweed-based edible vaccine confers complete protection against avian infectious bronchitis virus by inducing robust mucosal and systemic immunity. Plant Biotechnol J, 2025, 23(11): 4683-4693

[60]	Thingujam D, Pajerowska-Mukhtar KM, Mukhtar MS. Duckweed: beyond an efficient plant model system. Biomolecules, 2024,

[61]	Ujong A, Naibaho J, Ghalamara S, Tiwari BK, Hanon S, Tiwari U. Duckweed: exploring its farm-to-fork potential for food production and biorefineries. Sustain Food Technol, 2025, 3(1): 54-80

[62]	Ullah H, Gul B, Khan H, Akhtar N, Rehman KU, Zeb U. Effect of growth medium nitrogen and phosphorus on nutritional composition of Lemna minor (an alternative fish and poultry feed). BMC Plant Biol, 2022,

[63]	Van Hoeck A, Horemans N, Monsieurs P, Cao HX, Vandenhove H, Blust R. The first draft genome of the aquatic model plant Lemna Minor opens the route for future stress physiology research and biotechnological applications. Biotechnol Biofuels, 2015, 8 188

[64]

Vollheyde K, Dudley QM, Yang T, Oz MT, Mancinotti D, Fedi MO, Heavens D, Linsmith G, Chhetry M, Smedley MA, Harwood WA, Swarbreck D, Geu-Flores F, Patron NJ. An Improved Nicotiana Benthamiana Bioproduction Chassis Provides Novel Insights into Nicotine Biosynthesis. New Phytol, 2023, 240(1): 302-317

[65]	von Salzen J, Petersen F, Ulbrich A, Streif S. Modeling growth dynamics of Lemna minor: process optimization considering the influence of plant density and light intensity. Plants, 2025,

[66]	Vunsh R, Li J, Hanania U, Edelman M, Flaishman M, Perl A, Wisniewski JP, Freyssinet G. High expression of transgene protein in Spirodela. Plant Cell Rep, 2007, 26(9): 1511-1519

[67]	Wang K-T, Hong M-C, Wu Y-S, Wu T-M. Agrobacterium-mediated genetic transformation of Taiwanese isolates of Lemna aequinoctialis. Plants, 2021,

[68]	Wei C, Hu Z, Wang S, Tan X, Jin Y, Yi Z, He K, Zhao L, Chu Z, Fang Y, Chen S, Liu P, Zhao H. An endogenous promoter Lpsut2 discovered in duckweed: a promising transgenic tool for plants. Front Plant Sci, 2024, 15 1368284

[69]	Wijffels RH, Barbosa MJ. An Outlook on Microalgal Biofuels. Science, 2010, 329(5993): 796-799

[70]	Wilkinson MJ, Sweet J, Poppy GM. Risk Assessment of Gm Plants: Avoiding Gridlock?. Trends Plant Sci, 2003, 8(5): 208-212

[71]	Wu X, Singh SK, Patra B, Wang J, Pattanaik S, Yuan L. An overview of the regulation of specialized metabolism in Tobacco. Curr Plant Biol, 2025,

[72]	Xu J, Cui W, Cheng JJ, Stomp A-M. Production of High-Starch Duckweed and Its Conversion to Bioethanol. Biosyst Eng, 2011, 110(2): 67-72

[73]	Yamamoto YT, Rajbhandari N, Lin X, Bergmann BA, Nishimura Y, Stomp A-M. Genetic transformation of duckweed Lemna gibba and Lemna minor. In Vitro Cell Dev Biol Plant, 2001, 37(3): 349-353

[74]	Yang GL, Fang Y, Xu YL, Tan L, Li Q, Liu Y, Lai F, Jin YL, Du AP, He KZ, Ma XR, Zhao H. Frond transformation system mediated by Agrobacterium tumefaciens for Lemna minor. Plant Mol Biol, 2018, 98(4-5): 319-331

[75]	Yoshida A, Taoka KI, Hosaka A, Tanaka K, Kobayashi H, Muranaka T, Toyooka K, Oyama T, Tsuji H. Characterization of frond and flower development and identification of Ft and Fd genes from duckweed Lemna aequinoctialis Nd. Front Plant Sci, 2021, 12 697206

[76]	Yuan W, Xu EG, Zhu D, Zhang W, Liu W, Abdolahpur Monikh F, Lin L, Li L, Grossart HP, Yang Y, Rillig MC, Peijnenburg W. Nanoplastics in duckweed: single-cell responses and recovery. ACS Nano, 2025, 19(51): 42869-42880

[77]	Zhao X, Moates GK, Wellner N, Collins SRA, Coleman MJ, Waldron KW. Chemical characterisation and analysis of the cell wall polysaccharides of duckweed (Lemna minor). Carbohydr Polym, 2014, 111: 410-418

[78]	Zhong Y, Wang L, Ma Z, Du X. Physiological responses and transcriptome analysis of Spirodela polyrhiza under red, blue, and white light. Planta, 2021, 255(1): 11