Breakthrough in Phytoremediation: Acorus calamus L. Tackles Antibiotic Contamination
A new study published online on June 23, 2026, in the journal Environmental Research demonstrates that the wetland plant Acorus calamus L., commonly known as sweet flag, can achieve high removal rates of two widely used antibiotics, tetracycline and sulfamethoxazole, from contaminated water. The research, led by Yongwei Gong along with co-authors Haolang Liu, Yan Jiang, Yu Wang, and Yuqi Qi, reveals detailed mechanisms involving the plant's own genetic and metabolic responses as well as shifts in its vertically transmitted endophyte communities.
The full publication is available at https://www.sciencedirect.com/science/article/pii/S0013935126014143. This work highlights sustainable, plant-based approaches to addressing pharmaceutical pollutants in wastewater, a growing concern in environmental science research programs at universities worldwide.
Understanding the Contaminants and the Plant
Tetracycline and sulfamethoxazole are broad-spectrum antibiotics frequently detected in aquatic environments due to incomplete metabolism in humans and animals and subsequent excretion. These compounds contribute to the spread of antibiotic resistance, posing risks to ecosystems and public health. Phytoremediation uses plants and their associated microorganisms to extract, degrade, or stabilize pollutants in soil or water.
Acorus calamus L. is an emergent macrophyte native to wetlands in Asia, Europe, and North America. It has been studied previously for its tolerance to various stresses and its use in constructed wetlands. The current research quantifies its performance under controlled exposure to the two antibiotics, showing removal efficiencies of 88.78–94.82% for tetracycline and 40.67–54.24% for sulfamethoxazole, with biodegradation as the primary mechanism.
Key Findings on Removal Efficiency and Biodegradation Pathways
Experiments involved cultivating Acorus calamus L. plants under antibiotic stress. The plant maintained growth while transforming the compounds through processes such as hydroxylation, deamination, bond cleavage, and ring opening. Researchers identified twelve biodegradation products from tetracycline and four from sulfamethoxazole.
These transformations reduce the toxicity and persistence of the antibiotics. The study proposes specific metabolic routes supported by metabolite identification, providing a foundation for optimizing plant-based treatment systems in research and applied settings.
Host Plant Adaptations Revealed by Multi-Omics Analysis
Transcriptomic and metabolomic data showed that the plant adapts by enhancing photosynthesis, increasing ATP production, and remodeling phenylpropanoid biosynthesis pathways. These changes support energy demands for detoxification and help in sequestering or breaking down the pollutants.
Several cytochrome P450 enzymes, including CYP734A1, CYP75B137, and CYP707A2, were implicated in the initial biotransformation steps, consistent with a "green liver" model where plants perform Phase I detoxification reactions similar to animal livers. Computational modeling confirmed strong binding affinities of these enzymes to the antibiotic molecules.
Role of Vertically Transmitted Endophytes
A distinctive aspect of the study is the focus on vertically transmitted endophytes (VTEs), microbes passed from parent plants to offspring through seeds or vegetative tissues. Unlike horizontally acquired microbes from soil, VTEs form stable associations with the host.
Integrative analyses linked specific VTE taxa, such as Zoogloea, Acidovorax, and Rhizobium, to genes and metabolites involved in biodetoxification. These microbes appear to work synergistically with the plant, enhancing overall removal of the antibiotics. This finding opens avenues for research into microbiome engineering in university laboratories focused on sustainable agriculture and environmental remediation.
Implications for University Research and Environmental Programs
Such studies underscore the value of interdisciplinary research combining plant biology, microbiology, and environmental chemistry. Universities with strong programs in environmental science, ecology, and biotechnology are well positioned to build on these results through further experiments, field trials, and modeling.
PhD students and postdoctoral researchers in these fields can explore extensions like testing additional plant species, scaling systems for real-world wastewater treatment, or investigating genetic modifications to boost efficiency. The work also aligns with global priorities on antimicrobial resistance and nature-based solutions for pollution control.
Future Directions and Practical Applications
The authors note that vertically transmitted endophytes may offer advantages in dynamic environments like constructed wetlands, where flooding and drainage cycles can disrupt less stable microbial communities. Future research could focus on selecting or enhancing beneficial VTE strains for improved performance.
Practical applications include integration into bioretention systems, riparian buffers, and wastewater treatment wetlands. Institutions developing green infrastructure projects may draw on these mechanistic insights to design more effective, resilient systems.
Broader Context in Environmental Science
Antibiotic contamination represents a subset of emerging contaminants addressed through phytoremediation. Complementary approaches, such as combining plants with biochar or zero-valent iron, have shown promise in prior work. The current study provides a detailed mechanistic understanding that can inform hybrid technologies.
Researchers at academic institutions continue to investigate plant-microbe interactions for pollutant removal, contributing to both basic science and applied solutions for water quality management.
