This study evaluated the heavy metal-induced enhancement of azo dye degradation using three bacterial strains: Acinetobacter sp. SS1, Acinetobacter baumannii SS3, and Bacillus cereus SS2. Under normal monoculture (NM) conditions, dye degradation efficiencies ranged from 22.2% to 26.7%. Under 2.5% heavy metal stress, efficiencies increased to 32.8%-39.0%, indicating a ∼1.5-fold increase. The most significant improvement was observed in stress-adapted consortia, where degradation efficiencies ranged from 52.3% to 59.0%, representing a nearly 2.4-fold increase compared with those in NMs. Fourier-transform infrared analysis revealed more than 10 stress-specific functional groups, including nitriles, amides, and sulfonates, confirming metabolic reprogramming. Auto-aggregation reached a maximum of 41.6% in B. cereus SS2 after 16 h, while molecular docking of Dyp peroxidase (7YZT) and azoreductase (3W77) yielded binding energies of -24.7 kcal mol-1, supporting high enzyme interaction stability. Phytotoxicity assays showed 100% seed germination and enhanced stem height (by ∼45%) in plants treated with stress-consortia-remediated effluent. Two-way analysis of variance yielded statistically significant results across treatment groups (P 1 = 2.2693 for C1). These results confirm that microbial consortia preconditioned with metal stress exhibit significantly enhanced bioremediation capabilities in complex dye-contaminated systems.
Kumar et al. (Wed,) studied this question.