# Metabolic Plasticity and Abiotic Stress Adaptation in Freshwater Algae During Phycoremediation of Polluted River Water

**Authors:** Dharmendra Kumar, Shivankar Agrawal, Sanjukta Sahoo, Elangbam Geetanjali, Dinabandhu Sahoo

PMC · DOI: 10.1002/pei3.70093 · Plant-Environment Interactions · 2025-10-18

## TL;DR

This study explores how freshwater algae adapt metabolically to polluted river water, aiding in ecological restoration and biomass production.

## Contribution

The study reveals species-specific metabolic adaptations and identifies nitrogen as a key driver in algal responses during phycoremediation.

## Key findings

- Chlorococcum sp. showed significant carotenoid accumulation and increased phenolic compounds, indicating photoprotective adaptations.
- Algal species exhibited distinct lipid content shifts, with Monoraphidium sp. showing the highest increase.
- PCA analysis revealed interspecific differences in stress-responsive metabolic traits and altered elemental stoichiometry.

## Abstract

Freshwater algae possess remarkable metabolic flexibility and environmental resilience, enabling them to adapt to polluted habitats and contribute to ecological restoration. This study investigates the physiological and biochemical responses of five green algal taxa: Monoraphidium sp., Scenedesmus sp., Nephrocytium sp., Chlorococcum sp., and Klebsormidium sp. during a 25‐day phycoremediation of contaminated water of the Yamuna River, New Delhi, India. The water, characterized by high concentrations of organic matter, nutrients, and heavy metals, induced species‐specific metabolic adjustments. A decline in chlorophyll a and b (31.25% ± 2.25% to 67.11% ± 5.37% and 11.49% ± 0.25% to 86.98% ± 3.21%, respectively) indicated stress or damage to the photosynthetic system. This decline can be caused by various abiotic or biotic stress factors, while carotenoid accumulation, particularly in Chlorococcum sp. (307.70% ± 4.32%), suggested photoprotective adaptations. Enhanced biosynthesis of phenolic compounds and flavonoids in Chlorococcum sp. (139.33% ± 4.32% and 81.81% ± 2.72%, respectively) correlated with elevated antioxidant activity across all species (27.67% ± 1.61% to 73.51% ± 2.44% DPPH inhibition). Lipid content shifts were species‐dependent, with Monoraphidium sp. showing the highest increase (63.02% ± 2.09%). Elemental CHNS analysis revealed increased carbon content and reduced nitrogen and sulfur levels, indicating altered nutrient dynamics. Principal Component Analysis (PCA) elucidated distinct clusters reflecting interspecific differences in stress‐responsive metabolic traits. This study demonstrates the metabolic plasticity and stress tolerance of green algae under complex pollutant loads, advancing our understanding of algal adaptation mechanisms. It shows that phycoremediation not only enhances interspecific biochemical divergence but also alters algal elemental stoichiometry. By integrating multivariate biochemical analysis with CHNS profiling, we identify nitrogen as the primary driver of post‐treatment differentiation. These findings highlight both the ecological and biotechnological relevance of algae in integrated water treatment and sustainable biomass utilization, while offering a novel framework for selecting candidate species in environmental remediation and biotechnological applications.

## Linked entities

- **Species:** Monoraphidium sp. (taxon 3120773), Scenedesmus sp. (taxon 2909984), Chlorococcum sp. (taxon 3064686), Klebsormidium sp. (taxon 13781), Mus musculus (taxon 10090)

## Full-text entities

- **Chemicals:** nitrogen (MESH:D009584), DPPH (MESH:C004931), chlorophyll a and b (-), carotenoid (MESH:D002338), Lipid (MESH:D008055), flavonoids (MESH:D005419), carbon (MESH:D002244), sulfur (MESH:D013455)
- **Species:** Klebsormidium sp. (species) [taxon 13781], Scenedesmus sp. (species) [taxon 2909984], Chlorophyta (green algae, phylum) [taxon 3041], PX clade (clade) [taxon 569578]

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12535203/full.md

## References

65 references — full list in the complete paper: https://tomesphere.com/paper/PMC12535203/full.md

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Source: https://tomesphere.com/paper/PMC12535203