Advances in actinobacteria-based bioremediation: mechanistic insights, genetic regulation, and emerging technologies

IF 3.1 4区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biodegradation Pub Date : 2025-03-14 DOI:10.1007/s10532-025-10118-4

Naureenbanu Makarani, Radhey Shyam Kaushal

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引用次数: 0

Abstract

Untreated wastewater from sewage, industries, and agriculture contaminates ecosystems due to rapid population growth and industrialization. It introduces hazardous pollutants, including pesticides, polycyclic aromatic hydrocarbons (PAHs), and heavy metals, which pose serious health risks such as cancer, lung disorders, and kidney damage, threatening both environmental and human well-being. Using microorganisms for bioremediation is thought to be safer and more effective. Compared to other approaches, bioremediation is the most effective way to absorb heavy metals. Due to the high cost and unreliability of traditional remediation techniques, such as chemical and physical treatments, interest in bioremediation as an environmentally benign substitute has grown. Through the use of microorganisms, bioremediation successfully removes heavy metals and breaks down organic contaminants from contaminated circumstances. Actinobacteria are unique among these microbes because of their flexibility in metabolism and capacity to endure severe environments. They create secondary metabolites, such as enzymes, that help break down a variety of pollutants. Actinobacteria also produce siderophores and extracellular polymeric substances (EPS), which aid in trapping organic contaminants and immobilizing heavy metals. This review explores the diverse applications of actinobacteria in bioremediation, with a focus on their mechanisms for breaking down and neutralizing pollutants. We highlighted the advancements in bioremediation strategies, including the use of mixed microbial cultures, biosurfactants, nanoparticles and immobilized cell technologies which enhance the efficiency and sustainability of pollutant removal. The integration of omics technologies such as metagenomics, meta-transcriptomics, and meta-proteomics provides deeper insights into the genetic and metabolic pathways involved in bioremediation, suggesting the way for the development of genetically optimized strains with enhanced degradation capabilities. By leveraging these emerging technologies and microbial strategies, actinobacteria-mediated bioremediation presents a highly promising approach for mitigating environmental pollution. Ongoing research and technological advancements in this field can further enhance the scalability and applicability of bioremediation techniques, offering sustainable solutions for restoring contaminated ecosystems and protecting human health.

Graphical abstract

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基于放线菌的生物修复研究进展：机制、基因调控和新兴技术

由于人口的快速增长和工业化，来自污水、工业和农业的未经处理的废水污染了生态系统。它引入了有害污染物，包括农药、多环芳烃（PAHs）和重金属，这些污染物构成严重的健康风险，如癌症、肺部疾病和肾脏损害，威胁着环境和人类福祉。利用微生物进行生物修复被认为更安全、更有效。与其他方法相比，生物修复是吸收重金属最有效的方法。由于传统的修复技术，如化学和物理处理的高成本和不可靠性，生物修复作为一种环境友好的替代品的兴趣日益增长。通过使用微生物，生物修复成功地去除重金属，并从污染环境中分解有机污染物。放线菌在这些微生物中是独一无二的，因为它们的代谢灵活性和忍受恶劣环境的能力。它们产生次级代谢物，如酶，帮助分解各种污染物。放线菌也产生铁载体和细胞外聚合物质（EPS），有助于捕获有机污染物和固定重金属。本文综述了放线菌在生物修复中的各种应用，重点介绍了放线菌分解和中和污染物的机制。我们强调了生物修复策略的进展，包括混合微生物培养、生物表面活性剂、纳米颗粒和固定化细胞技术的使用，这些技术提高了污染物去除的效率和可持续性。元基因组学、元转录组学和元蛋白质组学等组学技术的整合为生物修复中涉及的遗传和代谢途径提供了更深入的见解，为开发具有增强降解能力的遗传优化菌株提供了途径。通过利用这些新兴技术和微生物策略，放线菌介导的生物修复为减轻环境污染提供了一种非常有前途的方法。该领域正在进行的研究和技术进步可以进一步增强生物修复技术的可扩展性和适用性，为恢复受污染的生态系统和保护人类健康提供可持续的解决方案。图形抽象

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来源期刊

Biodegradation 工程技术-生物工程与应用微生物

CiteScore

5.60

自引率

0.00%

发文量

审稿时长

6 months

期刊介绍： Biodegradation publishes papers, reviews and mini-reviews on the biotransformation, mineralization, detoxification, recycling, amelioration or treatment of chemicals or waste materials by naturally-occurring microbial strains, microbial associations, or recombinant organisms. Coverage spans a range of topics, including Biochemistry of biodegradative pathways; Genetics of biodegradative organisms and development of recombinant biodegrading organisms; Molecular biology-based studies of biodegradative microbial communities; Enhancement of naturally-occurring biodegradative properties and activities. Also featured are novel applications of biodegradation and biotransformation technology, to soil, water, sewage, heavy metals and radionuclides, organohalogens, high-COD wastes, straight-, branched-chain and aromatic hydrocarbons; Coverage extends to design and scale-up of laboratory processes and bioreactor systems. Also offered are papers on economic and legal aspects of biological treatment of waste.