Synergistic role of PGPR and fungal isolates in mitigating As and Pb stress and promoting growth of Arachis hypogaea L.

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Published: Mar 24, 2026
DOI: https://doi.org/10.63369/ijat.2026.22.2.897-914.
Keywords:
Pseudomonas Arachis hypogaea Chemical fertilizer PGPF Arsenic Lead

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Sathya, C.
Soil Biology and PGPR Lab, Department of Botany, School of Life Science, Periyar University, Salem – 636 011, Tamil Nadu, India
Sridhar, D.
Soil Biology and PGPR Lab, Department of Botany, School of Life Science, Periyar University, Salem – 636 011, Tamil Nadu, India
Soytong, K.
Research Institute of Modern Organic Agriculture (RIMOA), King Mongkut’s Institute of Technology Ladkrabang (KMITL), Bangkok, Thailand
Song, J. J.
Research Institute of Modern Organic Agriculture (RIMOA), King Mongkut’s Institute of Technology Ladkrabang (KMITL), Bangkok, Thailand, King Mongkut’s Institute of Technology Ladkrabang (KMITL), Prince of Chumphon Campus, Chumphon, Thailand.
Lalitha, S.
Soil Biology and PGPR Lab, Department of Botany, School of Life Science, Periyar University, Salem – 636 011, Tamil Nadu, India

Abstract

Heavy metals, also known as toxic metals, are major environmental pollutants that adversely impact all forms of life, disturbing soil ecology and reducing agricultural productivity. Certain indigenous microbes possess remarkable tolerance to these metals and play a vital role in restoring contaminated soils. In the present study, plant growth-promoting rhizobacteria and fungi were isolated from the rhizosphere and evaluated for their metal tolerance potential. Among the bacterial isolates (Pseudomonas alcaliphila PAS1, Pseudomonas aeruginosa PAS2, Pseudomonas toyotomiensis PTS3, Bacillus subtilis BSS1) expressing resistance to arsenic and lead which observed up to concentrations of 100–1200 ppm on nutrient agar. The fungal isolate Aspergillus japonicus (AJ01) exhibited tolerance up to 200 ppm of Pb and 500 ppm of As.  Pot culture experiments were using Arachis hypogaea grown under As and Pb stresses with treatments of PGPR, PGPF, Compost and chemical control.  Pseudomonas alcaliphila PAS1 was significantly enhanced plant growth by 100% and Pseudomonas aeruginosa PAS2 by 60% in contaminated soil, indicating strong tolerance and growth-promoting potential. Pseudomonas alcaliphila PAS1 increased chlorophyll content by 92.3% under As stress as compared to the control, while Pseudomonas toyotomiensis PTS3 showed a 70% increased, demonstrating high metal tolerance. In contrast, As and Pb stressed plants showed adverse effects. These findings highlighted the potential of selected PGPR and fungi as eco-friendly alternatives for the remediation and recovery of heavy metal-contaminated soils in Arachis hypogaea cultivation.

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How to Cite
Sathya, C., Sridhar, D., Soytong, K., Song, J. J., & Lalitha, S. (2026). Synergistic role of PGPR and fungal isolates in mitigating As and Pb stress and promoting growth of Arachis hypogaea L. International Journal of Agricultural Technology, 22(2), 897–914. https://doi.org/10.63369/ijat.2026.22.2.897-914.
Issue
Vol. 22 No. 2 (2026): March
Section
Original Study
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This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

References

Akbar, M., El-Sabrout, A. M., Shokralla, S., Mahmoud, E. A., Elansary, H. O., Akbar, F., Din, B. U., Haroon, U., Ali, M. and Saleem, H. (2022). Preservation and recovery of metal-tolerant fungi from industrial soil and their application to improve germination and growth of wheat. Sustainability, 14: 5531.

Akpasi, S. O., Anekwe, I. M. S., Tetteh, E. K., Amune, U. O., Shoyiga, H. O., Mahlangu, T. P. and Kiambi, S. L. (2023). Mycoremediation as a potentially promising technology: Current status and prospects. Applied Sciences, 13:4978.

Alves, A. R. A., Yin, Q., Oliveira, R. S., Silva, E. F. and Novo, L. A. B. (2022). Plant growth-promoting bacteria in phytoremediation of metal-polluted soils: Current knowledge and future directions. Science of the Total Environment, 838:155000.

Amin, I., Nazir, R. and Rather, M. A. (2024). Evaluation of multi-heavy metal tolerance traits of soil-borne fungi for simultaneous removal of hazardous metals. World Journal of Microbiology and Biotechnology, 40:175.

Aslam, M., Aslam, A., Sheraz, M., Ali, B., Ulhassan, Z., Najeeb, U., Zhou, W. and Gill, R. A. (2021). Lead toxicity in cereals: Mechanistic insight into toxicity, mode of action and management. Frontiers in Plant Science, 11:587785.

Cervantes-Vega, C., Chavez, J., Córdova, N. and De la Mora, P. (1986). Resistance to metals by Pseudomonas aeruginosa clinical isolates. Microbios, 48:159-163.

Giongo, A., Crabb, D. B., Davis-Richardson, A. G., Chauliac, D., Mobberley, J. M., Gano, K. A., Mukherjee, N., Casella, G., Roesch, L. F., Walts, B. and Riva, A. (2010). PANGEA: Pipeline for analysis of next generation amplicons. ISME Journal, 4:852-861.

Gupta, R., Khan, F., Alqahtani, F. M., Hashem, M. and Ahmad, F. (2024). Plant growth–promoting rhizobacteria (PGPR) assisted bioremediation of heavy metal toxicity. Applied Biochemistry and Biotechnology, 196:2928-2956.

Iram, S., Arooj, A. and Parveen, K. (2012). Tolerance potential of fungi isolated from polluted soil of Multan, Pakistan. International Journal of Biosciences, 2:27-34.

Jayaram, S., Ayyasamy, P. M., Aishwarya, K. P., Devi, M. P. and Rajakumar, S. (2022). Mechanism of microbial detoxification of heavy metals: A review. Journal of Pure and Applied Microbiology, 16:1562-1574.

Li, Y., Guo, L., Yang, R., Yang, Z., Zhang, H., Li, Q. and Gao, W. (2023). Arsenite oxidation-dependent biological nitrogen fixation in arsenic-contaminated soils. Journal of Hazardous Materials, 443:130220.

López, J. E., Gallego, J. L., Vargas-Ruiz, A., Peña-Mosquera, A. L., Zapata-Zapata, A. D., López-Sánchez, I. J. and Botero-Botero, L. R. (2020). Fungal solubilization of rock phosphate and its effect on maize growth. Journal of Soil Science and Plant Nutrition, 20:2490-2501.

Malaie, S., Pourakbar, L., Siavash Moghaddam, S., Khezrinejad, N. and Xiao, J. (2025). Microbial agents enhance mercury stress tolerance in Vigna radiata. Acta Physiologiae Plantarum, 47:60.

Monsieurs, P., Moors, H., Van Houdt, R., Janssen, P.J., Janssen, A., Coninx, I., Mergeay, M. and Leys, N. (2011). Heavy metal resistance in Cupriavidus metallidurans. Biometals, 24: 1133-1151.

Mousavi, A., Pourakbar, L. and Siavash Moghaddam, S. (2022). Effects of malic acid and EDTA on oxidative stress in okra under cadmium stress. Environmental Science and Pollution Research.

Muhammad, I., Shalmani, A., Ali, M., Yang, Q.H., Ahmad, H. and Li, F.B. (2021). Mechanisms regulating photosynthesis under abiotic stress. Frontiers in Plant Science, 11:615942.

Naqqash, T., Fatima, M., Bukhat, S., Shahid, M., Shabir, G., Tahir, M., Arshad, M. and Babar, M. (2022). PGPR improves growth and photosynthetic machinery in wheat. Journal of Plant Growth Regulation, 41:1-15.

Nigra, A. E., Cazacu-De Luca, A. and Navas-Acien, A. (2022). Socioeconomic vulnerability and arsenic contamination in water. Environmental Pollution, 313:120113.

Oziegbe, O., Oluduro, A. O., Oziegbe, E. J., Ahuekwe, E. F. and Olorunsola, S. J. (2021). Bioremediation potential of bacteria from landfill soils. Saudi Journal of Biological Sciences, 28:3948-3956.

Rai, P., Singh, V. P., Sharma, S., Tripathi, D. K. and Sharma, S. (2022). Iron oxide nanoparticles improve arsenate stress tolerance in rice. Environmental Pollution, 307:119320.

Salam, A., Chang, J., Yang, L., Zeeshan, M., Iqbal, A., Khan, A. R., Afridi, M. S., Ulhassan, Z., Azhar, W., Zhang, Z. and Zhang, P. (2025). Brassinosteroid-mediated resistance to cobalt toxicity in maize. Plants, 14:2076.

Sathya, C., Karmegam, N. and Lalitha, S. (2024). Mitigation of heavy metal toxicity by Pseudomonas alcaliphila. Environmental Geochemistry and Health, 46:439.

Sheng, X., Zhu, J., Li, W., Wan, J., Wu, K., Yang, P., Duan, R., Yang, Z., Bai, J. and Zheng, Y. (2025). PGPR mitigates antimony toxicity in peppers. Frontiers in Microbiology, 16:1658223.

Singh, A., Rorrer, N. A., Nicholson, S. R., Erickson, E., DesVeaux, J. S. and Avelino, A. F. (2021). Impact analysis of enzymatic recycling of PET. Joule, 5:2479-2503.

Singh, R., Parihar, P. and Prasad, S. M. (2020). Calcium and nitric oxide reduce arsenic toxicity in mustard. Scientific Reports, 10:6900.

Srivastava, D. and Srivastava, N. (2023). Molecular mechanism of lead toxicity in plants. In: Lead Toxicity: Challenges and Solution. Springer, Cham.

Sridhar, D., Alherwairini, S. S., Eswaran, S. U. D., Barasarathi, J., Lalitha, S. and Sayyed, R. (2025). Soil microbiome enhances sesame growth under saline conditions. Scientific Reports, 15:29432.

Sridhar, D., Alheswairini, S. S., Barasarathi, J., Enshasy, H. A. E., Lalitha, S., Mir, S. H., Nithyapriya, S. and Sayyed, R. (2025). Halophilic rhizobacteria promote growth, physiology and salinity tolerance in Sesamum indicum L. grown under salt stress. Frontiers in Microbiology, 16:1590854.

Talha, M., Shani, M. Y., Ashraf, M. Y., De Mastro, F., Brunetti, G., Khan, M. K. R., Gillani, S. W., Khan, A., Abbas, S. and Cocozza, C. (2023). Lead toxicity effects in maize seedlings. Plants, 12:3335.

Tamura, K., Stecher, G. and Kumar, S. (2021). MEGA11: Molecular evolutionary genetics analysis version 11. Molecular Biology and Evolution, 38:3022-3027

Wei, Y., Zhao, Y., Zhao, X., Gao, X., Zheng, Y., Zuo, H. and Wei, Z. (2020). Heavy metal removal by compost microbes. Bioresource Technology, 296:122375.

White, T. J., Bruns, T., Lee, S. and Taylor, J. (1990). Amplification and sequencing of fungal rRNA genes for phylogenetics. Methods in Enzymology, 18:315-322.

Zhou, W., Li, M. and Achal, V. (2025). Environmental and health impacts of pesticide usage. Emerging Contaminants, 11:100410.