Abstract
Soil salinization and crude oil contamination are critical global threats to ecosystems, agriculture, and human health. Bioremediation is widely recognized as a cost-effective and eco-friendly strategy for removing petroleum pollutants from soil. In this study, we investigated salinity-driven bacterial community dynamics collected from crude oil-contaminated soil in Cam Ranh Bay, Khanh Hoa, over a 21-day enrichment cultivation, using shotgun metagenomic and culture-based approaches. The enrichment cultivation was performed in Bushnell-Haas mineral salts (BHMS) medium supplemented with 5% (v/v) crude oil-diesel mixture (5:95) and 1.5% NaCl. Shotgun metagenomic analysis revealed that after 21 days of enrichment, the relative abundance of crude oil-degrading genera increased markedly in the enriched samples compared to the native samples-for example, Pseudomonas rose from 0.44% to 3.51%, Gordonia from 0.03% to 78.68%, and Achromobacter from 0.03% to 3.77%. Functional analysis further identified metabolic pathways, including hydrocarbon degradation, osmoprotection, and heavy metal detoxification. In addition, 36 representative bacterial strains were isolated from the enriched cultures, predominantly belonging to the genera Pseudomonas, Bacillus, Stenotrophomonas, and Achromobacter. All isolates were able to degrade crude oil under salinity stress conditions of up to 4%. Notably, Rhodococcus sp. KH5 and Gordonia sp. KH53 maintained consistently high degradation efficiencies across 0-4% salinity, ranging from 17.67-35.00% and 28.67-36%, respectively. Overall, our findings demonstrate that saline enrichment shifts the bacterial community toward halotolerant hydrocarbon and crude oil degraders.