Acid mine drainage (AMD) – one of Earth's most hostile habitats – forms when sulfide minerals are exposed to air, water and microbes, generating pH levels below 3 and high concentrations of heavy metals. Despite this harshness, AMD hosts diverse and specialized microbial communities that drive iron and sulfur geocycling, accelerating mineral weathering and acid generation. These microorganisms have stringent physiological needs – including specific electron donors, pH homeostasis and sometimes symbiotic dependencies – make them notoriously difficult to isolate. So far, over 97 percent of microorganisms in AMD have never been cultured, leaving their metabolism and adaptation strategies locked as "microbial dark matter." Now, a new culturomics‑driven resource called the Microbial Biobank of AMD (mbAMD) changes that. The collection contains 652 isolates spanning 42 species, including 21 novel taxa, and covers 86.7 percent of the global AMD core microbiome. Functional tests confirmed that 36 of these species actively metabolize iron or sulfur. Among them are the first pure cultures of acid‑tolerant sulfate reducers, organisms long sought for their potential to remediate AMD pollution.

A team led by scientists at the Institute of Microbiology, Chinese Academy of Sciences, publishing (DOI: 10.1016/j.ese.2026.100722) in Environmental Science and Ecotechnology on June 11, 2026, constructed the mbAMD – a culturomics-derived biobank from AMD samples collected at three mining sites in China. Using 12 tailored culture conditions, high-throughput plating and microfluidic technology, they recovered 652 phylogenetically distinct strains, including 11 formally described novel species, four new genera and one previously undescribed family.

The mbAMD's power lies in its functional validation. Through culture-based assays and comparative genomics, the team showed that 36 taxa actively oxidize or reduce iron or sulfur. Among the most striking finds: three novel acid-tolerant sulfate reducers – Alicyclobacillus curvatus ALEF1^T, Alicyclobacillus mengziensis S30H14^T and Acidiferrimicrobium ferridurans MYW30-Hm14 – are the first pure cultures of their kind, holding promise for bioremediation of acidic, metal-laden waters. Genomic analysis also uncovered surprises: several validated iron oxidizers lack all known iron-oxidation systems, hinting at entirely unknown electron transport pathways. Meanwhile, horizontal gene transfer (HGT) emerged as a dominant evolutionary driver, contributing 3.5–39.6 percent of genome content across AMD taxa. Transferred genes are functionally enriched in acid tolerance (e.g., clcA, kdpC), metal resistance (e.g., merA, mntH, znuB) and energy metabolism. The network analysis revealed that extremophiles preferentially acquire adaptive genes from phylogenetically close relatives rather than distant donors – a modular acquisition pattern that may accelerate niche specialization.

"For years, AMD's microbial dark matter remained out of reach – we knew it was there, but we couldn't identify their functions, let alone exploit them." the authors said. "With mbAMD, we've turned sequence predictions into living resources. Seeing that 70 percent of our isolates actively metabolize iron or sulfur, and discovering the first pure acid-tolerant sulfate reducers, was incredibly rewarding. Even more striking was the HGT pattern: these extremophiles don't borrow genes randomly. They consistently trade stress-survival tools with their close relatives. That's a very different picture of adaptation than what we see in many other environments."

The mbAMD provides a functional foundation for biohydrometallurgy and environmental remediation. The newly isolated sulfate reducers could be developed into bioremediation agents that precipitate metals under low-pH conditions – a long-standing challenge for treating AMD. Similarly, the collection’s iron- and sulfur-oxidizing strains may help optimize bioleaching processes for metal recovery from low-grade ores. Beyond applications, the resource enables a shift from metagenomic prediction to empirical testing, allowing researchers to validate metabolic pathways, dissect stress responses and explore evolutionary trade-offs in extreme environments. The study also offers a replicable culturomics framework that can be applied to other underexplored ecosystems – from deep-sea vents to alkaline soda lakes – to unlock their own microbial dark matter.

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References

DOI

10.1016/j.ese.2026.100722

Original Source URL

https://doi.org/10.1016/j.ese.2026.100722

Funding information

This work was funded by the Strategic Priority Research Program of the Chinese Academy of Sciences (XDB0810000), the Major Research Plan of National Nature Science Foundation of China (grant 92251307, 91851206), the National Natural Science Foundation of China (32570129), the National Key R&D Program of China (2022YFC2105300).

About Environmental Science and Ecotechnology

Environmental Science and Ecotechnology (ISSN 2666-4984) is an international, peer-reviewed, and open-access journal published by Elsevier. The journal publishes significant views and research across the full spectrum of ecology and environmental sciences, such as climate change, sustainability, biodiversity conservation, environment & health, green catalysis/processing for pollution control, and AI-driven environmental engineering. The latest impact factor of ESE is 14.3, according to the Journal Citation ReportsTM 2024.